Abstract

Background

   Long Interspersed Nuclear Element-1 (LINE-1, L1) is increasingly
   regarded as a genetic risk for lung cancer. Transcriptionally active
   LINE-1 forms a L1-gene chimeric transcript (LCTs), through somatic L1
   retrotransposition (LRT) or L1 antisense promoter (L1-ASP) activation,
   to play an oncogenic role in cancer progression.

Methods

   Here, we developed Retrotransposon-gene fusion estimation program
   (ReFuse), to identify and quantify LCTs in RNA sequencing data from
   TCGA lung cancer cohort (n = 1146) and a single cell RNA sequencing
   dataset then further validated those LCTs in an independent cohort
   (n = 134). We next examined the functional roles of a cancer specific
   LCT (L1-FGGY) in cell proliferation and tumor progression in LUSC cell
   lines and mice.

Results

   The LCT events correspond with specific metabolic processes and
   mitochondrial functions and was associated with genomic instability,
   hypomethylation, tumor stage and tumor immune microenvironment (TIME).
   Functional analysis of a tumor specific and frequent LCT involving FGGY
   (L1-FGGY) reveal that the arachidonic acid (AA) metabolic pathway was
   activated by the loss of FGGY through the L1-FGGY chimeric transcript
   to promote tumor growth, which was effectively targeted by a combined
   use of an anti-HIV drug (NVR) and a metabolic inhibitor (ML355).
   Lastly, we identified a set of transcriptomic signatures to stratify
   the LUSC patients with a higher risk for poor outcomes who may benefit
   from treatments using NVR alone or combined with an anti-metabolism
   drug.

Conclusions

   This study is the first to characterize the role of L1 in metabolic
   reprogramming of lung cancer and provide rationale for L1-specifc
   prognosis and potential for a therapeutic strategy for treating lung
   cancer.

Trial registration

   Study on the mechanisms of the mobile element L1-FGGY promoting the
   proliferation, invasion and immune escape of lung squamous cell
   carcinoma through the 12-LOX/Wnt pathway, Ek2020111. Registered 27
   March 2020 ‐ Retrospectively registered.

Supplementary Information

   The online version contains supplementary material available at
   10.1186/s12943-022-01618-5.

   Keywords: LINE-1, Transposable element, NSCLC, LUSC, LUAD, FGGY,
   Metabolic

Introduction

   The Long Interspersed Nuclear Element-1 (LINE-1, L1), representing a
   family of non-long-terminal repeat (LTR) transposable elements (TEs),
   constitute 17% of the human genome with ~ 500,000 copies widely
   distributed in the genome [[49]1]. Transcriptionally active L1s can
   propagate themselves and insert into a gene locus in the genome via the
   reverse transcription of the transposon [[50]2] (called L1
   retrotransposition (LRT)). In other cases, through the activation of
   the L1 antisense promoter (L1-ASP), the L1s within an intronic region
   can also be transcribed into the adjacent exon of a gene through a
   splicing site to generate L1-gene chimeric transcripts (LCTs) which
   might affect the expression or functions of a gene [[51]3, [52]4]. The
   LCTs through L1-ASP activation were reported to have abnormally high
   expression in most cancer tissues and be associated with oncogenic
   activity [[53]5–[54]7].

   Increased L1 activity is associated with cancer, neural degenerative
   diseases and many other diseases. Therefore, the detection of LRTs and
   trans-splicing events is key to understand how L1s can alter gene
   expression or function leading to disease development and progression.
   Many strategies have been performed to observe LRTs at the DNA level
   based on the whole exome or genome sequencing and L1-targeted
   sequencing [[55]8–[56]12]. While DNA sequencing may lack the resolution
   to capture trans-splicing events and quantify the level of L1
   activities at the transcriptional level, alternative approaches have
   begun to place some emphasis on developing informatic tools to detect
   LCTs based on short-read RNA sequencing data [[57]13–[58]15]. Because
   of technical limitations, such as requiring high sequencing depth for
   sequencing assembly or other restrictions, LCT events detected by these
   tools remain limited. In addition, these analytical tools rely on
   paired end sequencing data, making it difficult to infer from single
   cell sequencing data to study LCT events at a single cell level.
   Therefore, an analytical framework that allows for accurate detection
   of genome-wide LCTs at whole transcriptome or single cell level is
   needed in cancer biology to better interrogate the role LCTs play in
   oncogenesis.

   Lung cancer remains among the most common cancer types which has
   estimated 1.6 million death each year [[59]16] and the 5-year survival
   rate of only about 18.1%, mainly due to the late diagnosis of advanced
   disease [[60]16]. Non-small cell lung cancer (NSCLC), with common
   subtypes as lung adenocarcinoma (LUAD) and lung squamous cell carcinoma
   (LUSC), account for ~ 85% of lung cancer patients [[61]17]. Results
   from whole exome sequencing (WES) of tumor samples have shown that the
   NSCLC corresponds with higher L1 activity among different cancer types
   [[62]18]. In our previous study, we detected 13 frequent and recurrent
   LCTs from RNA sequencing data of TCGA LUSC cohort by the DeFuse
   program, a gene fusion detection-based program with a limitation in
   genome-wide LCT detection [[63]19]. We detect one of the most prominent
   tumor-specific LCTs, L1-FGGY, which is formed by transcription of L1 in
   the intron region into the exon 13 of FGGY through L1-ASP activation.
   Interestingly, FGGY is involved with arachidonic acid metabolism and
   regarded as a putative tumor suppressor gene. L1-FGGY interferes with
   the tumor suppressor function of FGGY, thereby, promotes cancer cell
   proliferation, invasion and accelerated tumor growth corresponding with
   a tumor microenvironment deplete of immune cell populations to forge a
   cytotoxic response to tumor cells. This implicates the role of L1 in
   altering tumor cell metabolism thus allowing for the evasion of
   immunity in NSCLC [[64]19], thereby requiring further genome-wide LCT
   assessment and functional studies in tumorigenesis.

   In this study, we generated a novel bioinformatic approach called,
   ReFuse (Retrotransposon-gene fusion estimation program), as a means to
   accurately detect LCTs at a genome-wide scale from both bulk and single
   cell RNA sequencing data of NSCLC with greater sensitivity. Our
   approach reveals that LCT frequently affect genes corresponding with
   mitochondrial biogenesis and energetics linked with overall metabolic
   capacities with the underlying oncogenic roles of L1-FGGY in driving
   metabolic reprogramming in NSCLC. Finally, we confirm that reverse
   transcriptase inhibitors can disrupt L1 activity that results in the
   metabolic programming as putative rationales for considering the
   treatment of patients observed with higher levels of L1 activity. Our
   study is the first to report a functional role of L1 activity resulting
   in the reprogramming of metabolism leading to changes in the tumor
   microenvironment leading to accelerated lung cancer progression. The
   intersection between LCTs and their corresponding targets in the human
   genome leading to increased oncogenesis could represent a promising
   prognosis biomarker and therapeutic target in NSCLC.

Result

LCTs are frequently detected in NSCLC and mainly involved in mitochondrial
function and metabolic process

   To detect LCTs with a high level of accuracy at the genome-wide scale
   using Illumina-based short read data of RNA sequencing data derived
   from TCGA, we developed a local alignment-based program, ReFuse, to
   identify and quantify LCTs (Fig. [65]1A and Methods). Briefly, after
   filtering out the raw sequence reads that were fully aligned to RefSeq
   transcripts, we identified the chimeric sequence reads with one end
   partially aligned to RefSeq transcripts and the other end to L1
   reference sequences. An LCT candidate was initially generated from a
   chimeric sequence read by combining sequences of RefSeq and L1 extended
   from the junction site with the length of read length minus one bp. All
   the LCTs were then clustered to remove duplicates to obtain the unique
   LCTs. The candidate LCTs were then aligned to all TE sequences from
   RepeatMasker database in a gap allowed manner to remove false
   positives, which could be a fusion of L1 and other TE sequences. All
   raw reads were aligned back to these unique LCTs to derive the final
   LCT candidates with a full alignment coverage by at least 5 reads and
   the expression value of LCT was quantified by the count of reads
   covering the LCT candidates (Fig. [66]1A and Methods).

Fig. 1.

   [67]Fig. 1
   [68]Open in a new tab

   LCT Activity Identified by Refuse in LUSC and LUAD. A Workflow of the
   Refuse analysis. B Bar plot shows total number of LCT events detected
   and a box plot showing expression of LCT (normalized as reads per
   million) for each patient. Red represents tumor samples and blue
   represents normal controls. C The proportion of LCT events in coding,
   UTR3 or UTR5 region, and proportion of LCT events in splicing or
   non-splicing region in TCGA LUSC and LUAD separately. D The absolute
   frequency of tumor and normal samples containing LCT affected genes.
   Each gene was calculated separately and top 20 most frequently
   represented genes were showed. E Enriched GO terms for genes
   recurrently affected by LCT (in more than 2 samples), dot size
   represents the number of genes enriched in each term and the color
   scale represents the -log[10](p value) of enrichment

   We then applied ReFuse to bulk RNAseq data of LUSC (n = 551, 48 normal
   tissues) and LUAD (n = 595, 57 normal tissues) in TCGA cohort and an
   independent LUSC cohort from Tianjin Medical University Cancer
   Institute and Hospital (TJMUCH) as a validation (n = 134, 22 normal
   tissues) to identify genome-wide LCTs in all cohorts. We detected 1131
   LCT events in 691 genes for LUSC and 725 LCT events in 545 genes for
   LUAD, respectively (Fig. [69]1B and Table S[70]1). In the independent
   TJMUCH LUSC cohort, we observed a significant portion (351/848, 41.4%)
   of LCTs were overlapped with TCGA LUSC cohort (Figure S[71]1A). There
   we confirmed the most frequent LCT event involving the intronic L1
   transcription into exon13 in FGGY gene through ASP activation in both
   LUSC and LUAD, which was discovered in our previous study (Figure
   S[72]2A). Another example demonstrated a novel frequent LCT event
   within non-coding gene LINC01980, which was formed by trans-splicing of
   intronic L1 into the 5th exon of LINC01980 (Figure S[73]2B). Totally,
   we detected an average of 37.65 LCT events in LUSC (SD = 26.29) and
   16.05 events in LUAD samples (SD = 9.56), consistent with previously
   reported higher L1 activity in LUSC than LUAD [[74]18](Table S[75]1).
   We compared the overall methylation level (normalized M value as
   described in Methods) between LUSC and LUAD patients and found LUSC had
   significantly lower methylation level (Figure S[76]1B), which is
   consistent with a previous report [[77]20]. We hypothesized that the
   hypomethylation in LUSC genome might cause L1-ASP activation, which
   will lead to frequent LCT events. As expected, we also detected
   significantly increased LCT events and expression in tumor samples
   compared to normal lung tissues in both LUSC and LUAD (Fig. [78]1B,
   Figure S[79]1C, Figure S[80]1D and Table S[81]1). Among LCT events in
   LUSC, 107 (9.5%) were found in 3’UTR region and 284 (25.1%) in 5’UTR
   region, while a majority of events (740, 64.5%) were found in coding
   regions. LUAD has similar distribution (Fig. [82]1C). Surprisingly the
   majority of LCTs (67.9% for LUSC, 52.97% for LUAD) occurred at
   splice-junction sites (less than 3 bp close to the exon boundary),
   implicating trans-splicing through intronic L1 promoter activation
   might be a major cause of LCT formation, which was not reported before
   (Fig. [83]1C). The LCTs that frequently occurred in at least 3 samples
   covered many driver genes related to tumorigenicity in both LUSC and
   LUAD (Fig. [84]1D and Table S[85]2), including PON3 [[86]21], INPP4B
   [[87]22, [88]23], which were also confirmed in TJMUCH LUSC cohort
   (Figure S[89]1E; Table S[90]3). Interestingly, the functional Gene
   Ontology enrichment of those genes in recurrent LCT events revealed the
   significant functions in mitochondrial electron transport and multiple
   metabolic processes, as well as immune related pathways and WNT pathway
   (Fig. [91]1E, Table S[92]4), which were also observed in the TJMUCH
   LUSC cohort (Figure S[93]1F; Table S[94]5).

LCT activity is associated with increased metabolic process and suppressed
immune response, genomic instability and clinical status

   To determine the association of overall LCT level with genomic,
   transcriptomic, epigenetic profiles and clinical outcomes, we
   summarized the reads covering LCTs and normalized by sequencing depth
   in each tumor sample to represent the overall L1 activity of the
   corresponding tumor sample. The correlation of L1 activity with RNA
   sequencing data in both LUSC and LUAD revealed L1 is positively
   correlated with gene expression of mitochondrial translation and NADH
   metabolic process, DNA replication/DNA repair and methylation whereas
   negatively correlated with gene expression in immune response
   especially T cell immunity, which were also seen in the Tianjin LUSC
   cohort (Fig. [95]2A, Figure S[96]3A, Figure S[97]3B and Table
   S[98]6,[99]7,[100]8,[101]9). Negative correlation of L1 activity with
   immune response was also confirmed by GSEA analysis with immune
   cell-type features (Fig. [102]2B, Figure S[103]3C and Methods). We
   clearly observed a negative correlation of L1 with methylation levels
   and positive correlation with genomic instability (copy number
   aberration data) (Fig. [104]2C and Methods), as reported earlier
   [[105]24, [106]25], consistent with the correlation of L1 integration
   with the dysregulation of methylation and DNA replication/repair
   pathways and these transcriptomic, epigenetic and genomic aberrations
   also promote tumor development and progression [[107]26]. As expected,
   the L1 activity had positive correlation with tumor stage and TMB level
   in both LUSC and LUAD (Fig. [108]2D). These data implicated a role of
   LCTs in regulating key pathways associated with lung cancer development
   and progress. These data also indicated that LCTs have potential as a
   lung cancer diagnostic and prognostic marker.

Fig. 2.

   [109]Fig. 2
   [110]Open in a new tab

   Association of LCT with Metabolic, Immune process, Genomic Instability
   and Clinical States. A Enriched GO terms of genes positively or
   negatively co-expressed with overall LCT expression in each sample.
   B The GSEA enrichment plot for meta-markers of each immune cell type.
   Genes are ranked by the fold change of expression in LCT-high samples
   (left) versus LCT-low samples (right) (C) Correlation of methylation
   level and CNV level with overall LCT activity in each sample.
   D Comparison of LCT expression in different cancer stages and TMB
   quartiles. E Differentially expressed LCT events (named by targeted
   gene), which are highly expressed in tumor than control. Left panel
   shows the number of samples containing the LCT event while right panel
   shows the expression of LCT events among all the samples, grouped by
   tumor (red) and normal control (blue). F Survival curve of patients
   grouped as L1-high and L1-low by the total expression of survival
   related LCTs

   Next, we performed differential expression analysis between tumor and
   normal samples in LUSC and LUAD to identify characteristic LCTs
   associated with each tumor type separately (Methods). We identified 74
   differentially expressed LCTs involving 40 genes in LUSC including
   L1-ADGRV1, L1-LINC01980, L1-PLCB1, and L1-FGGY (Fig. [111]2E, left,
   Table S[112]10 and Methods), which were also found in TJMUCH cohort
   (Figure S[113]1G, Table S[114]11 and Methods). In LUAD, 13
   differentially expressed LCTs corresponding to 13 genes were discovered
   (Fig. [115]2E, right, Table S1[116]2 and Methods), among which five
   events (L1-MCM3, L1-PHF20, L1-INPP4B, L1-SLC44A5, L1-SUGCT) are
   overlapped with those detected in LUSC suggesting their common and
   unified role in carcinogenesis of NSCLC. Interestingly, 2 genes (INPP4B
   and SUGCT) are associated with metabolic pathways or disorders
   [[117]27, [118]28]. MCM3 and INPP4B has been reported before to be
   related to cancer [[119]29, [120]30], while other three might be
   potential candidates for further study. These differentially expressed
   LCTs in LUSC and LUAD could serve as a potential diagnostic marker to
   identify LUSC tumors that are caused by L1 activation. By using a cox
   regression model, we also identified survival related LCTs in LUSC and
   LUAD respectively and the summarized expression level of these LCTs
   could envisioned as possible prognostic markers for NSCLC
   (Fig. [121]2F, Table S[122]13-[123]14 and Methods).

LCTs promote mitochondrial function and metabolic process in tumors at single
cell level

   To investigate LCT events specifically in tumor cell and immune cell in
   heterogenous cell population in a tumor sample, we applied the ReFuse
   program to a single cell RNAseq dataset of 19 samples from 5 NSCLC
   patients including both LUSC and LUAD (Figure S[124]4A and Methods)
   [[125]31]. Four samples including adjacent healthy tissue, tumor edge,
   tumor middle and tumor core were collected from 4 patients and one
   patient donated 3 samples (tumor edge, tumor middle and tumor core).
   Among the total 19 samples, including tumor edge, tumor middle, tumor
   core and adjuvant normal tissues, we identified 573 recurrent LCT
   events, among which a significant portion were detected by bulk RNAseq
   of TCGA cohort (161 in LUSC, 140 in LUAD and 100 in both)
   (Fig. [126]3A, Figure S[127]4A and Table S1[128]5). Many highly
   recurrent LCTs detected by bulk RNAseq data (L1-FGGY, L1-PLCB1,
   L1-ABCB8 and L1-LINC01980) were also confirmed in single cell RNAseq
   dataset. These data demonstrated high consistency of LCT events
   detected by ReFuse from either bulk or single cell RNAseq data.

Fig. 3.

   [129]Fig. 3
   [130]Open in a new tab

   LCT activity at single cell level in NSCLC. A The number of overlapped
   events determined between TCGA bulk RNAseq and single cell sequencing
   data sets. B UMAP plot of cells colored by cell type. C UMAP plot of
   cells colored by LCT activity. Red colored dots represent cells with
   LCT event detected. D The percentage of cells with LCT activity in each
   cell of each patient. The summary of each patient or each cell type
   tested is shown as the bar plot on the left and bottom. The UMAP (E)
   plot and pseudo time trajectory analysis (F) of tumor cells from
   patient 3 and patient 4 is shown. Red colored dots represent cells with
   LCT event detected. G Enriched GO termed of genes highly expressed in
   tumor subtype enriched with LCT events versus other tumor cells. (H)
   Enriched GO terms of genes highly expressed in LCT positive tumor cells
   versus LCT negative tumor cells

   To further examine LCT events in each specific cell type in tumor
   sample, we performed the unsupervised clustering analysis on scRNAseq
   data and identified major cell types using the markers of NSCLC
   reported in the original paper and later studies in lung cancer
   [[131]31, [132]32] (Fig. [133]3B and Figure S[134]4C). We then
   investigated LCT events at single cell level by mapping LCT events to
   each cell of a specific cell type. Although LCT events are widely
   distributed among different cell types (Fig. [135]3C), we found higher
   LCT events in tumor cells and epithelial cells as demonstrated by a
   UMAP plot (Fig. [136]3C) and illustrated from a heatmap (Fig. [137]3D).
   We also observed a trend of increasing LCT events from adjacent normal,
   edge, middle to core in three patients, which might reflect tumor
   heterogeneity and a trend of increasing tumor cell density from the
   edge to the core (Fig. [138]3D).

   One interesting finding of LCT events in tumor cells was that, unlike
   other types of LCT-containing cells which evenly scattered among cell
   clusters, LCT-containing tumor cells are aggregated in one cluster,
   implicating distinct transcriptomic features of LCT-enriched tumor
   cells different from the rest of tumor cells. We further extracted
   tumor cells from each patient and conducted subtype analysis (Methods).
   We surprisingly found an individual tumor cell cluster highly enriched
   with LCT events (Fig. [139]3E; Figure S[140]4) amongst all the patients
   analyzed. When aligning those cell populations along pseudo time
   trajectory (Methods), we found the LCT-containing tumor cell cluster
   concentrated on one end of the trajectory (Fig. [141]3F; Figure
   S[142]5A), suggesting their unique cell fate within in tumor cells as
   shown. Differential expressed gene (DEG) analysis and GO enrichment
   indicated that in the most differentially expressed genes in
   LCT-enriched tumor cell cluster (Figure S[143]5Band Table S[144]16)
   related to response to stress, such as response to oxidative stress,
   cellular response to external stimulus, and response to hypoxia in
   multiple patients (Fig. [145]3G and Table S[146]17). In a summary, the
   LCT-enriched NSCLC tumor cell sub-cluster represents a specific tumor
   cell status with increased stress response.

   To further test the influence of LCT on transcriptomic dysregulation at
   a single cell level, we performed DEG analysis between LCT-positive and
   LCT-negative cells in the LCT-enriched tumor sub-cluster from five
   patients (Figure S[147]5Cand Table S1[148]8). GO enrichment identified
   increased mitochondrial function, ribosome biogenesis and activated
   metabolic pathway in LCT-positive tumor cells, which is consistent with
   the result from bulk RNAseq analysis presented above (Fig. [149]3H and
   Table S[150]19). This LCT activity analysis from scRNASeq analysis
   indicate that the L1 plays an oncogenic role by intronic L1 promoter
   activation in a cancer gene, leading to the formation of LCT, involved
   with mitochondrial function and metabolic process, thereby,
   reprogramming metabolism favorable for tumorigenicity.

L1-FGGY initiated arachidonic acid (AA) metabolism reprogramming and
activated 12-LOX pathway in LUSC

   Considering the high frequency and potential biological functions of
   L1-FGGY in metabolic control mechanisms, here we selected it for
   further explorations to elucidate the underlying oncogenic role of L1
   in tumorigenesis and tumor progression. The comparison of expression
   profiles between L1-FGGY^+ and L1-FGGY^− samples from TCGA LUSC
   specimens identified altered control of metabolic pathways, including
   glutathione metabolism, AA metabolism, and drug metabolism
   (Fig. [151]4A), which was further confirmed from an independent Chinese
   cohort of 109 LUSC tumor samples (52 L1-FGGY^+ vs. 57 L1-FGGY^−)
   (Fig. [152]4A). We next examined the expression levels of the specific
   genes involved in the downstream key pathways of AA metabolism (i.e.
   cytochrome P450 (CYP450), lipoxygenase (LOX), and cyclooxygenase (COX))
   [[153]33] and observed 12-LOX and 15-LOX (both in LOX pathway) were
   elevated while other pathways were either downregulated or reflected no
   significant change (Fig. [154]4B), implicating L1-FGGY to activate the
   LOX pathway through AA metabolism.

Fig. 4.

   [155]Fig. 4
   [156]Open in a new tab

   L1-FGGY initiated arachidonic acid (AA) metabolism reprogramming and
   activated 12-LOX pathway in LUSC. A The KEGG pathway enrichment
   analysis of differential expression between L1-FGGY^+ tissues and
   L1-FGGY^− tissues based on RNAseq data from TCGA and an independent
   Chinese cohort of 109 LUSC tumor samples (52 L1-FGGY^+ vs. 57
   L1-FGGY^−) from TJMUCH. B The gene expression profiles (log[2] (count
   per million (CPM))) of the downstream key components involved in AA
   metabolism was compared between L1-FGGY^+ tissues and L1-FGGY^− tissues
   based on the RNAseq data. C The KEGG pathway enrichment analysis of
   differential expression between H520^OV−L1−FGGY and H520^OV−CTRL based
   on proteomics analysis. D The protein expression involved in different
   metabolic pathways was compared between H520^OV−L1−FGGY and
   H520^OV−CTRL based on proteomics analysis. E The KEGG pathway
   enrichment analysis of proteins with different fold changes between
   H520^OV−L1−FGGY and H520^OV−CTRL based on proteomics analysis. F The
   results of metabolomics assay targeting AA pathway metabolites were
   compared between H520^OV−L1−FGGY and H520^OV−CTRL. G The ELISA results
   of AA pathway metabolites from cells and tissues. The data are shown in
   plots. * and ** indicate p < 0.05 and p < 0.01, respectively between
   the groups as indicated

   In order to further investigate the biological processes affected by
   L1-FGGY, we constructed NCI-H520 cells over-expressing L1-FGGY
   (H520^OV−L1−FGGY), and empty vector (H520^OV−CTRL). Proteomics analysis
   of these two cell lines identified 951 (618 up and 333 down)
   dysregulated proteins in H520^OV−L1−FGGY at an adjusted p value of 0.05
   with enriched functions in fatty acid metabolism (Fig. [157]4C and
   [158]4D), particularly proteins with more than twofold increase in
   H520^OV−L1−FGGY were enriched in AA metabolism pathway, regulation of
   lipolysis in adipocytes, IL-17 signaling pathway and MAPK signaling
   pathway (Fig. [159]4E). We also observed L1-FGGY altered the morphology
   of mitochondria slightly, significantly promoted mitochondrial
   oxidative phosphorylation activity, membrane enhancement and ATP
   production (Figure S[160]6). Further metabolomics analysis targeting AA
   pathway analytes detected increased level of 12S-HETE (a downstream
   metabolite of 12-LOX), but not 15S-HETE (a downstream metabolite of
   15-LOX) in H520^OV−L1−FGGY (Fig. [161]4F). We then measured the levels
   of AA metabolites using Enzyme-linked immunosorbent assay (ELISA) kits.
   The increased secretion levels of 12S-HETE was detected in
   H520^OV−L1−FGGY vs H520^OV−CTRL cell lines (Fig. [162]4G) and further
   validated in 50 LUSC tissues compared to matched adjacent normal
   tissues (Table S[163]20-S[164]21) as well as L1-FGGY^+ vs FGGY^− tumor
   tissues (Fig. [165]4G).

   Collectively, these results indicated that L1-FGGY corresponds with
   induced lipid metabolism, specifically reprogramming of AA metabolism,
   which activates the downstream 12-LOX pathway, leading to an increased
   production of the 12S-HETE metabolite.

L1-FGGY exhibited an oncogenic role dependent on activation of 12-LOX/GPR31
metabolic pathway

   We further explored the three central enzymes involved in the LOX
   metabolic pathways, i.e. 5-LOX, 12-LOX, and 15-LOX [[166]34] in 147
   LUSC tumor samples (77 L1-FGGY^+ vs. 70 L1-FGGY^−) from the TJMUCH
   cohort (Table S20-S21). We observed increased expression of both 12-LOX
   and 15-LOX rather than 5-LOX in L1-FGGY^+ tissues compared to L1-FGGY^−
   tissues (Fig. [167]5A) and the increased expression of 12-LOX was
   exclusively associated with poor survival (Fig. [168]5B). At the
   protein level, a high level 12-LOX (but not 15-LOX) IHC staining was
   observed in L1-FGGY^+ tumor tissues (Fig. [169]5C). GPR31, the membrane
   receptor of 12-LOX metabolic 12S-HETE [[170]35] was upregulated in
   L1-FGGY^+ tissues compared to L1-FGGY^− tissues (Fig. [171]5C). In
   order to determine whether L1-FGGY induced tumorigenicity depends on
   12-LOX or 15-LOX metabolic pathway, we treated H520^OV−L1−FGGY cells
   with either 12-LOX inhibitor ML355 [[172]36] or 15-LOX inhibitor
   [173]PD146176 [[174]37]. We found that over-expression of L1-FGGY
   caused upregulation of 12-LOX and 15-LOX gene expression, but only an
   increased release of 12S-HETE but not of 15S-HETE (Fig. [175]5D-E). As
   expected, ML355 (but not [176]PD146176) efficiently suppressed the
   increased 12S-HETE release in H520^OV−L1−FGGY cells though both
   inhibitors had no effect on 15S-HETE level (Fig. [177]5E). We further
   explored the role of 12-LOX in L1-FGGY-driven tumorigenicity. We found
   an accelerated proliferation rate in H520^OV−L1−FGGY which was
   significantly reduced by ML355 treatment (Fig. [178]5F). Next, we found
   that the wound closure rate (WCR) of H520^OV−L1−FGGY was significantly
   higher than H520^OV−CTRL (Fig. [179]5G), Consistently, more of those
   cells expressing L1-FGGY migrated across the matrigel layer after 48 h
   (Fig. [180]5H), whereby, the increased migration and invasion abilities
   in H520^OV−L1−FGGY were both reversed by ML355 treatment, but not with
   the treatment of [181]PD146176 (Fig. [182]5G-H). We further confirmed
   our findings in a different LUSC cell line, SK-MES-1, in which we
   previously confirmed L1-FGGY promoted cell proliferation and migration,
   reduced cell apoptosis, as well as promoted AA metabolism [[183]19].
   Figure S[184]7 demonstrated that, in SK-MES-1 cell, over-expression of
   L1-FGGY caused upregulation of 12-LOX and metabolite 12S-HETE and thus
   promoted cell proliferation and migration dependent on activating the
   12-LOX/GPR31 metabolic pathway.

Fig. 5.

   [185]Fig. 5
   [186]Open in a new tab

   L1-FGGY exhibited an oncogenic role dependent on activation of
   12-LOX/GPR31 metabolic pathway. A The relative RNA expression values of
   5-LOX, 12-LOX and 15-LOX detected in 147 LUSC tumor samples (77
   L1-FGGY^+ vs. 70 L1-FGGY^−) from TJMUCH. B The OS was compared between
   5-LOX^+ and 5-LOX^−, 12-LOX^+ and 12-LOX^−, 15-LOX^+ and 15-LOX^−
   patients respectively grouped according to mRNA levels. C Different
   resolutions of IHC staining results of the FGGY, 12-LOX, 15-LOX and
   GPR31 antigen expression in L1-FGGY^− and L1-FGGY^+ LUSC tumor samples.
   The statistical results of IHC staining were shown at right. D The
   relative RNA expression of 12-LOX and 15-LOX detected in H520^OV−CTRL
   and H520^OV−L1−FGGY, as well as in H520^OV−L1−FGGY treated with either
   ML355 or [187]PD146176. E The secretion value of 12S-HETE and 15S-HETE
   detected in H520^OV−CTRL, H520^OV−L1−FGGY, and H520^OV−L1−FGGY treated
   with either ML355 or [188]PD146176. F The proliferation of
   H520^OV−CTRL, H520^OV−L1−FGGY, H520^OV−L1−FGGY+sh−GPR31, and
   H520^OV−L1−FGGY treated with either ML355 or [189]PD146176 was detected
   using CCK8 method. G Representative images of H520^OV−CTRL,
   H520^OV−L1−FGGY, H520^OV−L1−FGGY+sh−GPR31, and H520^OV−L1−FGGY treated
   with either ML355 or [190]PD146176 in wound healing assays. The
   statistical results of migration rate were shown at the right of the
   panel. (H) Representative images of H520^OV−CTRL, H520^OV−L1−FGGY,
   H520^OV−L1−FGGY+sh−GPR31, and H520^OV−L1−FGGY treated with either ML355
   or [191]PD146176 in trans-well invasion assays. The statistical results
   of invasion number were shown at right. The data are shown as mean ± SD
   with plots. * and ** indicate p < 0.05 and p < 0.01, respectively
   between the groups as indicated

   Taken together, these results suggest that L1-FGGY exhibits an
   oncogenic role by activating the metabolic pathway that exploits 12-LOX
   which can be partially reversed by ML355.

L1-FGGY activated Wnt signaling pathway in LUSC via accelerating GPR31
deubiquitination and enhancing 12S-HETE/GPR31 interaction

   Next, in order to explore which signaling pathways are involved in
   L1-FGGY-driven carcinogenesis, we profiled 12 pairs of
   L1-FGGY^+/L1-FGGY^− LUSC tissues with nCounter® PanCancer IO-360™ Panel
   [[192]38]. We observed a trend by the elevation of cell proliferation
   and metabolic stress, the loss of apoptosis and autophagy in L1-FGGY^+
   tissues (Figure S[193]8A). Specially, a significant upregulation of Wnt
   signaling pathway was detected in L1-FGGY^+ tissues compared to
   L1-FGGY^− tissues (Fig. [194]6A). Our data also showed a significant
   loss of several immune-related cell signaling pathways (i.e., antigen
   presentation, immune cell adhesion and migration, interferon signaling,
   and cytokine and chemokine signaling) (Figure S8A), and cell signatures
   (tumor infiltrating lymphocyte (TILs), dendritic cells (DCs) and mast
   cells) (Figure S[195]8B) in L1-FGGY^+ tissues, indicating L1-FGGY
   corresponded with a dysregulated immune microenvironment.

Fig. 6.

   [196]Fig. 6
   [197]Open in a new tab

   L1-FGGY activated Wnt signaling pathway in LUSC via accelerating GPR31
   deubiquitination and enhancing 12S-HETE/GPR31 interaction. A The
   pathway scores of different signaling pathways were compared between
   L1-FGGY^+ tissues and L1-FGGY^− tissues (n = 12) detected in nCounter®
   PanCancer IO-360™ Panel. B The relative RNA expression of Wnt3a, Wnt5a,
   β-catenin and TCF4 detected in 147 LUSC tumor samples from TJMUCH as
   mentioned above. C The relative RNA expression of Wnt3a, Wnt5a,
   β-catenin and TCF4 detected in H520^OV−CTRL and H520^OV−L1−FGGY. D The
   secretion value of Wnt3a and Wnt5a detected in H520^OV−CTRL and
   H520^OV−L1−FGGY treated with ML355. The cells treated with DMSO were as
   controls. E Western blot results to detect protein expression of Wnt3a,
   Wnt5a, β-catenin, and the phosphorylation level of GSK and JNK in
   H520^OV−CTRL and H520^OV−L1−FGGY treated with either DMSO or ML355 were
   shown at left. And western blot results to detect key proteins involved
   in Wnt signaling pathway in H520^OV−L1−FGGY and
   H520^OV−L1−FGGY+sh−GPR31 were shown at right. F Western blot results to
   detect expression of GPR31 from whole lysate, fraction of cell membrane
   and cytosol individually in H520^OV−CTRL and H520^OV−L1−FGGY. G The
   relative RNA expression of GPR31 detected in H520^OV−CTRL and
   H520^OV−L1−FGGY. H FGGY is indicated to have an association with USP24
   by STRING. I The cell lysates from H520^OV−CTRL and H520^OV−L1−FGGY
   were used in immunoprecipitation (IP) with flag antibody to detect the
   ubiquitination level of flag-GPR31. MG132 (10 μM) was added for 6 h
   before the cells were harvested. J Interaction of FGGY with USP24 (top)
   and interaction of GPR31 with USP24 (bottom). H520 cells were
   transfected with the plasmids as indicated. At 24 h post-transfection,
   the cell lysates were used in IP and immunoblotting (IB) using the
   antibodies as indicated. K The cell lysates from H520^sh−CTRL and
   H520^sh−USP24 were used in IP with flag antibody to detect the
   ubiquitination level of flag-GPR31. MG132 (10 μM) was added for 6 h
   before the cells were harvested. L Western blot results to detect
   protein expression of FGGY and USP24 in H520^OV−CTRL and
   H520^OV−L1−FGGY were shown on top. IP results to detect protein level
   of USP24 which has an interaction with flag-GPR31 in H520^OV−CTRL and
   H520^OV−L1−FGGY were shown below

   We next validated the upregulation of Wnt signaling in the 147 LUSC
   tumor samples by qPCR and the results showed that the expression of key
   components in Wnt signaling, i.e., Wnt3a, Wnt5a, β-catenin, and TCF4
   were all significantly higher in L1-FGGY^+ tissues than L1-FGGY^−
   tissues (Fig. [198]6B), which were then validated in the
   H520^OV−L1−FGGY cell line (Fig. [199]6C). Furthermore, the over
   expression of Wnt3a and Wnt5a was suppressed by the 12-LOX inhibitor
   ML355 (Fig. [200]6D). The protein expression of Wnt3a, Wnt5a,
   β-catenin, and the phosphorylation level of GSK and JNK were higher in
   H520^OV−L1−FGGY (Fig. [201]6E). And either inhibition of 12-LOX or
   suppressing GPR31 could block the upregulation of Wnt signaling in
   H520^OV−L1−FGGY (Fig. [202]6E). These findings reveal that L1-FGGY
   activated Wnt signaling depends on expression of the 12-LOX/GPR31
   metabolic pathway.

   Since 12S-HETE/GPR31 interaction is the key component of 12-LOX/GPR31
   metabolic pathway, we also examined the expression and distribution of
   GPR31 protein in H520^OV−L1−FGGY cells. We found L1-FGGY induced a high
   level of GPR31 protein in the cell membrane rather than cytosol in
   H520^OV−L1−FGGY cell (Fig. [203]6F). Considering no significant change
   in RNA level of GPR31 by L1-FGGY overexpression (Fig. [204]6G), the
   increased GPR31 protein expression induced by L1-FGGY led us to explore
   the possibility that ubiquitin-mediated degradation of the protein is
   altered by L1-FGGY, as the FGGY protein was shown to have an
   association with USP24, a ubiquitin carboxyl-terminal hydrolase, by
   STRING analysis, as a protein–protein interaction network prediction
   tool (Fig. [205]6H). We firstly observed that the ubiquitination level
   of GPR31 was reduced in H520^OV−L1−FGGY (Fig. [206]6I). Then we
   detected binding of USP24 with FGGY or GPR31 (Fig. [207]6J),
   illustrating the physical interaction of USP24 with either FGGY or
   GPR31, whereby, the ubiquitination of GPR31 was increased by USP24
   knockdown (Fig. [208]6K) to indicate that USP24 acts as a
   deubiquitination enzyme of GPR31. Considering that L1-FGGY limits FGGY
   expression and that FGGY interacts with USP24, a de-ubiquitination
   enzyme of GPR31, we consider that L1-FGGY-mediated decrease of FGGY
   abundance may free USP24 to interact with GPR31, leading to GPR31
   de-ubiquitination. The interaction of GPR31 with USP24 was increased in
   H520^OV−L1−FGGY cells (Fig. [209]6L) by using an immunoprecipitation
   assay, whereas, the total USP24 protein level in cell lysates did not
   change. This result appears consistent with our hypothesis.

   Collectively, these findings implied that the L1-FGGY reduces the
   expression of FGGY, thereby, facilitating the binding of more USP24 to
   GPR31 that increases GPR31 de-ubiquitination and activation of
   metabolic pathway for AA/12-LOX/12S-HETE and the subsequent signaling
   through the Wnt pathway in tumor cells for enhanced cell proliferation
   and invasion (Figure S[210]9).

Reverse transcriptase inhibitor and 12-LOX inhibitor impaired growth of LUSC
xenografts and reversed immunosuppressive microenvironment in vivo

   We tested the roles of the 12-LOX metabolic pathway activated by
   L1-FGGY for tumorigenesis in vivo by over expressing L1-FGGY in the
   mouse LUSC cell line KLN205 (KLN205^OV−L1−FGGY). The KLN205^OV−CTRL and
   KLN205^OV−L1−FGGY cells were engrafted subcutaneously in DBA2 mice as
   xenografts, followed by administration of either NVR (50 mg/kg/day) or
   ML355 (3 mg/kg/day), or combined. After 24 days, the average volume of
   the tumors analyzed in mouse group receiving the KLN205^OV−L1−FGGY
   cells were characterized as being much larger than those in
   KLN205^OV−CTRL group (p < 0.05, Fig. [211]7A-B). Furthermore, the
   growth of the xenografts we generated within KLN205^OV−L1−FGGY cell
   group were significantly reduced by either NVR or ML355 treatment, and
   further reduced when treated with the two inhibitors, simultaneously
   (Fig. [212]7A-B). The body weight curves indicated that both inhibitors
   displayed comparable physiological responses since neither whole-body
   weight lost, food intake or mortality occurred during the treatment
   (Fig. [213]7B).

Fig. 7.

   [214]Fig. 7
   [215]Open in a new tab

   Reverse transcriptase inhibitor and 12-LOX inhibitor impaired growth of
   LUSC xenografts and reversed immunosuppressive microenvironment in
   vivo. A KLN205^OV−CTRL and KLN205^OV−L1−FGGY were inoculated
   subcutaneously in the DBA2 mice which were subjected to either NVR
   (50 mg/kg/day) or ML355 (3 mg/kg/day) treatment, or subjected with the
   two inhibitors simultaneously. Representative images of the forming
   tumors were shown. B The tumor volume (left panel) and body weight
   (right panel) of the mice at various time points upon injection. C The
   qPCR results of genes involved in AA metabolic pathways (left) and qPCR
   results of genes involved in Wnt signaling (right) were shown as
   relative expression values in KLN205^OV−CTRL mouse group,
   KLN205^OV−L1−FGGY mouse group, NVR-treated KLN205^OV−L1−FGGY mice,
   ML355-treated KLN205^OV−L1−FGGY mice and NVR + ML355-treated
   KLN205^OV−L1−FGGY mouse group. D Western blot results to detect
   expression of FGGY, 12-LOX, and GPR31 in different mouse groups we
   constructed. E The proportions of various immunocytes in different
   mouse groups using multispectral immuno-fluorescent staining.
   F Representative images of multispectral immuno-fluorescent staining
   results

   Consistent with the results from human cell lines used, the key enzymes
   involved in fatty acid metabolism were elevated in the mouse group
   receiving the KLN205^OV−L1−FGGY cells, which could be inhibited by
   either NVR or ML355 treatment (Figure S[216]10A). As anticipated, the
   transcription of the enzymes for 12-LOX and 15-LOX for AA metabolism
   pathway was elevated in the mouse group represented as
   KLN205^OV−L1−FGGY and was reduced following the treatment with the drug
   inhibitors (Fig. [217]7C). Similarly, the mRNA level of Wnt3a, Wnt5a,
   β-catenin, and TCF4 was all significantly higher in the
   KLN205^OV−L1−FGGY group and was reduced after inhibitor treatment by
   either drug (Fig. [218]7C). Consistent with the results in human LUSC
   cells, significant decrease of FGGY protein was detected in
   KLN205^OV−L1−FGGY mice which was fully recovered by NVR and combined
   treatment, but partly recovered by ML355 treatment. On the contrast,
   increased protein level of 12-LOX and GPR31 was detected in
   KLN205^OV−L1−FGGY mice which was fully suppressed by NVR and combined
   treatment, but partly suppressed by ML355 alone (Fig. [219]7D).

   Tumor development is always accompanied with the changes in the immune
   microenvironment [[220]39]. We then further examined the proportions of
   various immune cell populations from different mouse groups by using
   multispectral immuno-fluorescent staining. Reduced CD3^+ T cells and
   CD8^+ T cells were observed in KLN205^OV−L1−FGGY mouse group,
   indicating L1-FGGY affected T lymphocyte populations, especially those
   involving cytotoxic T cell infiltration, thereby, promoted an
   immunosuppressive or exhaustive tumor microenvironment. Similarly, the
   number of infiltrating CD86^+ cells, which is a biomarker for DCs
   [[221]40], was dramatically reduced in the mouse group
   KLN205^OV−L1−FGGY (Fig. [222]7E-F), consistent with the results of cell
   type analysis in human tumor tissues by IO360. As we expected, the
   decrease of these immune cell populations from the KLN205^OV−L1−FGGY
   mouse group was reversed by the treatment with two inhibitors
   (Fig. [223]7E-F). The similar distribution pattern of these immunocytes
   was obtained by flow cytometry (Figure S[224]10B).

Precision-guided approaches for lung cancer patients with a poor prognosis
that correspond with high LCT activity

   By summarizing the reads that mapped to L1 in RNA sequencing data of
   the H520^OV−L1−FGGY cell line treated with NVR or ML355, we observed a
   decrease of L1 activity after the treatment with either inhibitor
   (Fig. [225]8A and Methods), The reduction of expression from those gene
   transcripts following NVR and ML355 treatment were enriched in ATP
   metabolic process, cell cycle, cell growth, which are associated with
   LCT activity (Fig. [226]8A). These data along with their capacity to
   inhibit tumor growth implicate a potential application of NVR and ML355
   or other anti-HIV and anti-metabolic drugs in treating lung cancer
   patients with a high level of LCT activity and poor survival outcome.

Fig. 8.

   [227]Fig. 8
   [228]Open in a new tab

   Precision-guided evidence for lung cancer patients with a poor
   prognosis that correspond with high LCT activity. A Overall L1
   expression in samples treated with NVR or ML355 are illustrated. L1
   expression was normalized as read per million for each sample where the
   enriched GO terms of those genes whose expression decreased after
   treatment is noted. B The top drug candidates for the 46 LCT related
   genes. Heatmap shows the correlation score of each drug in each cell
   line predicted using the “Cmap” database. C Top panel shows the
   z-normalized expression of the 46 genes in all tumor samples. Middle
   panel shows the overall expression of LCT in two groups based on the
   expression of 46 genes. On the lower panel, two groups are divided into
   four based on the total expression value of survival related LCT in
   each sample. The mortality rate and number of mortality cases within
   36 months of each group was labeled in each group

   To best stratify which lung cancer patients who would benefit with
   anti-HIV and anti-metabolic drugs, we determined 47 genes whose
   expression is positively-correlated with survival-related LCT activity
   in bulk RNA sequencing data and increased in LCT-positive vs
   LCT-negative tumor cells from single cell sequencing data (Methods;
   Table S[229]22). By performing drug repurposing on these 47 genes with
   CMAP database, we identified a set of drugs including PI3K/MTOR/HMGCR
   inhibitors which could be repurposed to suppress the expression of
   these 47 genes (Fig. [230]8B). Simvastatin is one of these predicted
   HMGCR inhibitors and widely used to lower cholesterol level. We found
   repurposed drug and other metabolic drug (Metaformin) can suppress L1
   activity and recover metabolism reprogramming in cancer cell lines by
   reducing expression of multiple molecules in mitochondria and metabolic
   processes in public datasets (Figure S[231]11A-C), suggesting these
   anti-metabolic drugs along with anti-HIV drugs could be considered as
   potential therapies given the poor prognosis of lung cancer patients
   with a high LCT activity. Based on overall expression of these 47
   candidate genes and survival-associated LCTs, we stratified the LUSC
   and LUAD samples from TCGA into four groups (Fig. [232]8C). The
   thresholds were optimized based on the 36 months fatality rate of
   patients in each group (Methods). The patient group with the high
   expression of 47 genes and LCTs showed over 50% rate in mortality
   within 3 years, suggesting these could be candidates for consideration
   with these drugs, especially when other therapies fail.

Discussion

   In this study, we developed a local-alignment based bioinformatic tool
   to detect genome-wide LCTs with a high sensitivity in lung cancer in
   both bulk and single cell RNA sequencing data. We observe that LCTs are
   preferably involved among genes with mitochondrial function(s) and
   metabolic process, leading to the reprogramming of metabolism favorable
   for tumor cell growth and survival and subsequent progression leading
   to metastasis. In particular, in our comprehensive in vitro and in vivo
   functional studies of the LCT to reveal the highly recurrent L1-FGGY
   that directly influences oncogenesis by stimulating the 12-LOX pathway
   through the pathways that manage arachidonic acid and fatty acid
   metabolism which in-turn stimulates Wnt signaling and other oncogenic
   signaling pathways. Finally, a set of metabolic transcripts and LCT
   markers were determined to identify the patients with a high risk of
   poor outcomes who would benefit by treatments with NVR and other
   inhibitors of metabolism. Our investigations are initial studies using
   genome-wide and accurate detection of LCTs with high sensitivity using
   both bulk and single cell RNA sequencing data from lung cancer
   specimens and represents to reveal the functional role of L1
   integration in metabolic programming in tumorigenicity of lung cancer.
   This could reflect the similar behavior of LCTs in other cancer types.

   In previous study, we used the DeFuse program that was used to detect
   the fusion from two different gene loci, to identify a limited number
   of LCTs for LUSC. Considering this general approach may not detect many
   fusion events within a gene locus, we developed the ReFuse program,
   which can identify L1-chimeric transcript using a more sensitive
   detection methods and alignments of the genomic locations of the L1
   position and LCT partner. Here, we have identified many LCTs with the
   majority involving splice-junction sites through L1-ASP activation that
   implicate intronic L1-ASP activation as a predominant mechanism of how
   L1 integration is involved in lung cancer tumorigenicity at the
   transcript level. However, due to the high similarity of short-read
   sequences of L1 families, there are limitations is revealing the exact
   origin of many L1s from short read RNA sequencing, therefore, long read
   sequencing (ISO-Seq) of the whole LCT could enhance the analysis as a
   framework and as a reference transcriptome for considering the origins
   of L1s to target their LCTs and further validate their frequencies and
   importance in human cancer.

   Metabolic reprogramming has been shown as a means of cancer cells to
   navigate a microenvironment favorable to promote tumor occurrence and
   progression [[233]41, [234]42]. Specific metabolites can directly
   participate in the transformation processes or support the biological
   processes that facilitate tumor growth and progression [[235]43,
   [236]44] by a variety of internal and external factors. The downstream
   pathways of oncogenes and tumor suppressors have been reported to
   regulate the metabolism of cancer cells [[237]45]. Genomic changes may
   also lead to an increase or decrease in the expression of genes
   encoding metabolic enzymes [[238]46, [239]47]. As a widely distributed
   transposable element, L1 has been known as promoting tumor development
   by disturbing the transcription of tumor-related genes, as well as
   trigging genome instability, however, the roles of L1 in directing
   tumor cell metabolism and the surrounding microenvironment remains
   unclear. In this LCT study, we observed the L1s form LCT transcripts by
   preferably integrating with metabolic genes to affect mitochondrial
   function and metabolic process, which indicated a promising mechanism
   in cancer metabolism modulation, and even put forward a novel mechanism
   of L1 regulation in cancer development.

   The balance of glucose and lipid metabolism is important for
   maintaining cell physiological homeostasis and normal biological
   functions [[240]48, [241]49]. Dysfunction of glucose and lipid
   metabolism can lead to a variety of diseases, especially in cancer
   [[242]50]. In LUSC, there is an obvious imbalance of glucose and lipid
   metabolism, which presents upregulation of fatty acid oxidation
   [[243]51, [244]52]. Targeted inhibition of fatty acid synthesis can
   effectively reduce tumor cell proliferation and invasion [[245]42],
   suggesting that lipid reprogramming is of great significance for
   maintaining the progression of LUSC. Therefore, breaking through the
   traditional therapy and mining and potential therapeutic targets at the
   metabolome level might improve the prognosis and outcome of LUSC.

   FGGY is a metabolic gene which encodes carbohydrate kinase [[246]53].
   FGGY was first reported to be related with sporadic amyotrophic lateral
   sclerosis [[247]54]. Besides that, FGGY can regulate dietary obesity in
   mice by regulating lipid metabolism [[248]55]. Here we showed that
   there was an abnormal fatty acid metabolism in L1-FGGY^+ LUSC.
   Specially, L1-FGGY activated the downstream of AA metabolism, i.e.
   12-LOX/GPR31/Wnt signaling. AA is an essential fatty acid, and its
   metabolites participate in a variety of physiological activities in
   cells, such as cell proliferation, migration, and apoptosis [[249]56].
   AA metabolism includes three pathways: LOX, CYP450 and COX [[250]57].
   Among them, LOX is a key enzyme in the metabolism of fatty acid, which
   catalyzes AA to generate HETE and other biologically active
   metabolites, which could affect cell metabolism and signal
   transduction, thereby playing an important role in cancer cells and
   inflammatory response [[251]58]. Fatty acids could promote the
   expansion of natural killer cells by improving energy metabolism,
   including enhancing the oxygen consumption rate (OCR), promoting ATP
   production and elevating the energy flux [[252]20]. PGE2, an AA
   metabolism, has been reported to enhance oxidative phosphorylation in
   macrophages [[253]59]. Here consistent with the analysis results from
   database which indicated the LCT transcripts affected mitochondrial
   function, we observed L1-FGGY could promote mitochondrial oxidative
   phosphorylation activity, enhance membrane potential and produce more
   ATP levels. We noticed the increased degree of oxidative
   phosphorylation triggered by L1-FGGY alone was modest, which indicated
   L1-FGGY and other LCT transcripts also co-played roles in mitochondrial
   function alteration and thus metabolic reprogramming. Since the results
   from transmission electron microscopy (TEM) showed L1-FGGY did not
   alter the morphology of mitochondria severely, we hypothesized that the
   accelerated energy metabolism and more energy production might be
   caused by the activated AA metabolism, but not the alteration of
   mitochondrial morphology.

   GPR31 is a member of the G protein-coupled receptor (GPCR) family and
   is located in the cell membrane [[254]35, [255]60]. A large amount of
   evidence shows that GPCR is important for 12S-HETE-mediated signal
   transduction and may be involved in the progression of a variety of
   tumors [[256]35]. We found that L1-FGGY increased the expression of
   GPR31 on the cell membrane, but did not affect its RNA level,
   suggesting L1-FGGY may regulate the membrane expression of GPR31
   through post-translational modification. It is reported in the
   literature that the level of GPCR membrane protein is regulated by
   deubiquitinating enzyme (USP) [[257]61]. USP regulates the
   ubiquitination level of the target protein GPCR to reduce GPCR
   degradation and increase its expression on the cell membrane [[258]62].
   Here we discovered that L1-FGGY down-regulated the expression of FGGY,
   followed by reducing the binding of FGGY and USP24, which increased
   free USP24 to increase the deubiquitination level of GPR31, and
   eventually promoted its membrane expression and therefore activated
   12-LOX/Wnt signaling.

   The coordination between the immune, stromal and tumor cell populations
   within the microenvironment play a central role in navigating
   tumorigenicity and metastasis [[259]39]. Our study indicates that
   12S-HETE, the 12-LOX metabolite, was involved in L1-FGGY mediated AA
   pathway activation and immune microenvironment dysregulation. 12S-HETE
   has previously been identified as a mediator in inflammatory response
   [[260]63, [261]64]. In hepatocytes, treatment with 12S-HETE resulted in
   greater p65 (RELA), JNK, p38 and ERK phosphorylation and inflammatory
   gene expression, suggesting the proinflammatory action of 12S-HETE
   [[262]64]. While delivery of 12S-HETE to the airway of mice has been
   reported to attenuate allergic airway inflammation [[263]65].
   Furthermore, 12S-HETE has been shown to promote secretion of IL-4 and
   IL-13, thereby polarizing macrophages to a more M2-like phenotype
   [[264]66]. In this study, we observed the L1-FGGY directed elevation of
   12S-HETE also involves proteins with functions in T cell activation and
   L1 activity is correlated with the down-regulation of T cell activation
   pathways, implicating a negative regulation of L1 in tumor immune
   microenvironment as an alternative mechanism for the tumor to escape
   from immune surveillance, and even suggesting a novel treatment by
   combined of targeting L1 and immunotherapy. However, more extensive
   functional and mechanism-based studies with immune cells are needed to
   elucidate the roles of L1 in innate and adaptive immune response
   activity associated with tumorigenicity and progression.

   Here we showed L1 promoted tumor progression via coordinating its
   effects on multiple metabolic processes and immune activities. We not
   only proposed L1 as a candidate marker for cancer diagnosis and
   prognosis, but also suggested potential drugs to develop more effective
   cancer treatment strategies for patients carrying the LCT events.

Conclusions

   In this study, we developed a bioinformatic method, ReFuse, to identify
   and quantify LCTs in bulk and singe cell RNA sequencing data of lung
   cancer. The LCT events affected genes involved in specific metabolic
   processes and mitochondrial functions. Function analysis of a tumor
   specific and frequent LCT involving FGGY (L1-FGGY) reveal that the AA
   metabolic pathway was activated by the loss of FGGY through the L1-FGGY
   chimeric transcript to promote tumor growth, which was effectively
   targeted by a combined use of an anti-HIV drug (NVR) and a metabolic
   inhibitor (ML355). Those findings characterize the role of L1 in
   metabolic reprogramming of lung cancer and provide rationale for
   L1-specifc prognosis and potential for a therapeutic strategy for
   treating lung cancer.

Data and Method

L1 and Refseq reference

   The repeat gene family annotation for hg38 was downloaded from the
   RepeatMasker [[265]67] database and repeat families annotated as
   “LINE/L1” were extracted for further analysis. We then selected the L1
   families whose coordinates located within the upstream and downstream
   50 kb of coding genes from NCBI Refseq database [[266]68]. The
   sequences of these L1 families were extracted from the human genome
   hg38 using bedtools getfasta [[267]69] based on their genome
   coordinates. makeblastdb of blast 2.2.26 + [[268]70] was used to build
   the reference for blast mapping. Meanwhile, all the repeat sequences
   from RepeatMasker were also extracted and genomeGenerate was used to
   build the reference for STAR mapping to remove false positive chimeric
   candidates.

   Refseq RNA sequences was downloaded from NCBI data base. Repeatmasker
   4.0.7 ([269]http://www.repeatmasker.org >) was used to identify and
   mask the repeat sequences in the RNA sequence using hmmer method. The
   repeat sequence identified from the RNA sequence was replaced with Ns.
   Two reference transcriptomes were generated with makeblastdb of blast
   2.2.26 + , one with original Refseq sequence and one for masked
   reference. A bwa reference for the unmasked RNA sequence was also built
   with bwa index with default parameters [[270]71].

Refuse strategy

   Raw RNA sequences were mapped to the Refseq transcript reference
   (unmasked) using bwa mem with default parameters. Unmapped reads and
   soft clipped reads were selected using samtools 1.9 [[271]72] and
   further aligned to L1 reference sequence using blastn in
   blast/2.2.26 + with default parameters. Reads with one end partially
   mapped to L1 family were trimmed and the unmapped end was blast against
   the Repeat-masked Refseq sequence using blast-short since some
   fragments might be short in length (Repeat-masked Refseq was used here
   to avoid false positive reads that mapped to different L1-repeat
   sequence in two ends). Then the reads that partially aligned to L1 and
   Refseq was identified. Considering balstn can only handle reads longer
   than 18 bp, some partially mapped reads might be missed. We then extend
   the identified reads ReadLength-1 bp along the corresponding L1 and
   Refseq sequencing from the junction site and constructed a candidate
   L1-chimeric sequence set. The candidate chimeric sequences are
   clustered with cd-hit [[272]73] with 100% identity to remove duplicates
   and then mapped to all repeat sequences using STAR [[273]74] in a gap
   allowed manner to remove false positive that containing repeat sequence
   fusions. Finally, all the unmapped reads were blast back to this
   candidate L1-chimeric sequence set to find more support reads. The
   final expression value for L1-chimeric transcript was quantified by the
   counting the supported reads.

Identification of differentially expressed LCT Events

   Raw LCT-sample counts were normalized with the total RNAseq reads in
   each sample and then log transferred. Then two strategies were used to
   identify differentially expressed LCT events. 1) limma test [[274]75]
   was performed on the normalized expression value of LCTs in tumor
   samples against normal controls. The LCT events with L1 chimeric p
   value <  = 0.05, log2 fold change > 0 were selected as differentially
   expressed events. 2) For each event, the number of occurrences in
   cancer and control of LCTs and normal transcripts were counted and
   Fisher’s exact test was performed to calculate the significance p
   value. The LCT events with p value <  = 0.05 were selected as
   differentially expressed events. Finally, the union set of
   differentially expressed events identified in the two strategies were
   selected as the differentially expressed events.

Correlation analysis and survival analysis

   The “M” methylation value was calculated as described in [[275]76] and
   the methylation value of each sample was calculated as the median
   methylation M value of all sites in the sample and the correlation with
   LCT expression was tested using Pearson correlation test. A sample
   level copy number was quantified by the sum of absolute Gistic2 copy
   number value of all the genes in each sample. The correlation of sample
   level copy number and the LCT expression was tested using Pearson
   correlation test. A sample level LCT activity was calculated as the sum
   of LCT supported reads and normalized by the total RNAseq read number
   of each sample.

   All LCT activity related genes were identified by correlating the
   overall LCT expression level and individual gene expression levels
   using a Pearson correlation test. LCT correlated genes were identified
   with p value <  = 0.0001 and further divided into positive related
   (> 0) and negative related (< 0) based on the estimated correlation
   value by Pearson correlation test between sample-level LCT and gene
   log[2] FPKM expression. The Cox model was used for survival analysis.

Immune markers and GSEA analysis

   In-house markers for immune cells populations were identified based on
   7 individual PBMC single cell and 5 bulk RNAseq data sets of sorted
   immune cell. For each cell type, their expression profile was compared
   against other cell types one by one with Wilcoxon rank sum test. Genes
   with p value < 0.01 and mean log[2] fold change larger than 0 in all
   comparisons was selected as the specific markers of the cell type. Each
   cell type was calculated in the same way in each sample and markers
   identified more than 3 times was selected as the meta-marker for the
   cell type. A “gmt” file for GSEA analysis was then constructed using
   the identified meta marker list [[276]77]. GSEA analysis was done by
   “fgsea” R package with fold change for each gene calculated using limma
   [[277]75].

Single cell clustering, trajectory and differential analysis

   Expression profile of raw gene counts on cell level of each sample was
   downloaded from Array Express. Genes expressed in less than 3 cells and
   Cells expressing more than 8000 genes were filtered. Cells whose
   mitochondrial RNA content takes larger than 15% of the total RNA were
   filtered. Filtered cells are further clustered using Seurat 3.1.5
   [[278]78] with resolution 0.8 and first 10 PCA dimensions, and cell
   clusters were annotated based on the markers in the original paper and
   another single cell papers on lung cancer [[279]79]. Differentially
   expressed genes between cell types and L1versus non-L1 cells were
   identified using Wilcoxon rank sum test with p value less than 0.01 and
   log (fold change) greater than 0.25.

Apply refuse on single cell RNAseq data

   Raw sequence data of the single cell study were downloaded from Array
   Express. The file containing RNA sequence reads (R2 for 10 × v2 and R1
   for 10 × v3) of each sample was submitted to run on Refuse to identify
   LCT events as single end bulk RNAseq data. The barcodes of LCT
   supporting reads were extracted in the barcode sequencing file and
   clustered using CD-hit [[280]73] using end-to-end mode with identity
   score larger than 0.85 to allow for sequencing errors. Barcodes
   clustered together were annotated as the same cell and the barcode
   found in expression profiles was selected as the representative barcode
   of the cell cluster.

LCT affected candidate genes and drug repurposing

   Genes identified to be positively correlated with overall survival
   related LCT activity (p <  = 0.0001 and estimate > 0) and
   differentially expressed by cells with L1 versus without L1 in > 3 cell
   types/patients (myeloid, T cell and tumor cell in 5 patients, totally
   15 comparisons) were selected as candidate genes affected by LCT. Those
   genes were submitted to the CMAP database [[281]80] for drug
   repurposing for potential treatment on patients with high LCT activity.

   The log[2] RPKM gene expression in all the patients of each candidate
   gene was z-normalized, and an aggregate score was calculated by summing
   up the z score of all the 47 candidate genes for each sample. The
   patients were divided into 4 groups with the threshold of aggregate
   gene score and survival related LCT expression. By iterating the two
   thresholds, a high-risk group was identified having 50% fatality rate
   within 3 years, which could be highly related to LCT activity.

Potential treatment for LCT related patients

   Raw sequence data of cancer cell line treated with Metformin and
   simvastatin were generated from NCBI GEO data base with accession
   number [282]GSE146982, [283]GSE141052 and [284]GSE149566 [[285]81,
   [286]82]. LCT analysis was performed with ReFuse and the overall LCT
   levels was summarized by adding up all the junction reads supporting
   LCT events and normalized with the read depth in each sample. For
   simvastatin data sets, few LCT were found as it is not from a cancer
   cell line, so we quantified the L1 activity with L1 reference sequence.
   First, the raw sequences were mapped to Refseq using bwa mem 0.7.15
   [[287]71] and the unmapped reads were then mapped to L1 reference using
   STAR 2.7.0f [[288]74]. The overall L1 activity was quantified by
   counting all the reads mapped to L1 reference and normalized by the
   read depth in each sample.

Patient information

   All the LUSC patients were obtained from Cancer Biobank of Tianjin
   Medical University Cancer Institute and Hospital (TJMUCH, Table
   S20-S21) which were treated with partial lung resection surgery at the
   Department of Lung Cancer of TJMUCH. No prior treatments, including
   chemotherapy or radiotherapy, were conducted before lung resection
   surgery was performed. This project was approved by the Ethics
   Committee of Tianjin Medical University (Approved No.: Ek2020111) and
   written informed consents were obtained from the patients. All
   experiments were performed in accordance with the principles of the
   Declaration of Helsinki.

Cell lines

   NCI-H520 and SK-MES-1 were purchased from Cellcook Co., Ltd. with cell
   authentication via STR multi-amplification method. KLN205 was obtained
   from Chinese Academy of Medical Sciences tumor cell libraries. NCI-H520
   was cultured in RPMI1640 (Gibco BRL). SK-MES-1 was cultured in MEM.
   KLN205 was cultured in H-DMEM. All medium contained 10% FBS and 1%
   penicillin/streptomycin. For 12/15-LOX inhibitor treatment experiments,
   ML355 and [289]PD146176 was diluted in medium, followed by replacing
   the cell medium 5 h after cells seeded respectively. Cell lines were
   routinely evaluated for Mycoplasma contamination. All experiments were
   completed less than 2 months after establishing stable cell lines or
   thawing early-passage cells.

Mouse models

   The DBA2/2NCrl mice are an inbred line and were obtained from SPF
   biotechnology Co. Ltd. (Beijing). The weights and tumor sizes of each
   mouse were monitored every 2 days. Each experimental group contained 5
   mice. The tumor volume (V) of the xenograft was calculated by the
   formula: V = π × L × W × H/6 (L: length, W: width, H: height). For drug
   treatment studies, animals were subjected to treatment with either NVR
   or ML355 every day, or subjected with the two inhibitors
   simultaneously. All animal protocols were approved by the Ethics
   Committee for Animal Experiments of TJMUCH (Approved No.:
   NSFC-AE-2020101), and was performed in accordance with the Guide for
   the Care and Use of Laboratory Animals.

Lentivirus construction

   The construction of human L1-FGGY insertion lentivirus was performed as
   previously described [[290]19]. For mouse L1-FGGY insertion lentivirus
   construction, the recombinant lentivirus with L1-FGGY sequence was
   generated by co-transfection in the packaging KLN205 cells. For
   GPR31/USP24 knockdown lentivirus construction, the recombinant
   lentivirus with GPR31/USP24 shRNA sequence (constructed by Hanbio Co.,
   Ltd.) was generated by co-transfection in H520^OV−L1−FGGY cells as
   previously described [[291]19].

RNA extraction, Reverse Transcription-Polymerase Chain Reaction (RT-PCR), and
quantitative Real-time PCR (qPCR) analysis

   RNA was extracted with TRIzol™ reagent (Life Technologies). Reverse
   transcription was performed with PrimeScript™ RT Master Mix (Takara)
   according to the manufacturer’s instructions. qPCR was performed using
   TB Green™ Premix Ex Taq™ (Takara) and ABI PRISM 7500 real-time PCR
   System (Applied Biosystems). The primers used are shown in Table S23.
   The relative mRNA levels were calculated as previously described
   [[292]19].

RNA library preparation, sequencing and enrichment analysis

   Library preparation and sequencing steps were performed as previously
   described [[293]19]. Briefly, the libraries were sequenced on Illumina®
   (NEB) following manufacturer’s recommendations. The RNAseq data has
   been uploaded to GEO database (accession number: [294]GSE181042 and
   [295]GSE181043). Raw sequencing data was aligned to hg38 reference
   using STAR 2.5.3a [[296]74] and HTseq 0.11.2 [[297]83] was used to
   quantify the gene-sample expression profiles. Differentially expressed
   genes (DEG) were identified with limma voom [[298]84] with FDR adjusted
   p value < 0.01. KEGG and GO function enrichment analysis of the
   interested gene sets were performed using clusterProfiler package
   [[299]85].

Quantitative proteomics

   The quantitative proteomic studies were performed by Jingjie PTM BioLab
   Co. Ltd (Hangzhou) as previously described [[300]86]. Briefly, the
   protein extracted was digested and then the resulting peptides were
   desalted, reconstituted, tandem mass tag labeled, and analyzed by
   Liquid chromatography-tandem mass spectrometry (LC–MS/MS). Tandem mass
   spectra were searched against human Uniprot database
   ([301]http://www.ebi.ac.uk/uniprot/) concatenated with reverse decoy
   database.

Metabolite analysis targeting arachidonic acid (AA) signaling

   AA metabolite detection was performed by Shanghai Applied Protein
   Technology Co., Ltd. Cells were homogenized on ice in a mixture of
   chloroform, methanol and water. The samples were then centrifuged and
   the supernatant was transferred to an LC sampling vial. The deposit was
   rehomogenized with methanol and supernatant was added to the same vial.
   After reconstituted with mobile phase, the extract as well as reference
   standards were analyzed with ACQUITY ultra performance liquid
   chromatography coupled with mass spectrometer (Waters). UPLC-MS raw
   data obtained with negative mode were analyzed using TargetLynx
   applications manager to obtain calibration equations and the
   quantitative concentration of each AA metabolite in the samples.

Gene expression (RNA) profiling: NanoString methodology

   Gene expression analysis was conducted on the NanoString nCounter gene
   expression platform (NanoString Technologies) as previously described
   [[302]87]. Briefly, RNA was mixed in a 3′-biotinylated capture probe
   and 5′-reporter probe tagged with a fluorescent barcode. Probes and
   target transcripts were hybridized overnight. Hybridized samples were
   run on the NanoString nCounter preparation station by using a
   high-sensitivity protocol. The cartridge samples were scanned at
   maximum resolution by using the nCounter digital analyzer. GEP scores
   were calculated as a weighted sum of normalized expression values for
   the genes.

Cell proliferation assay

   The cell proliferation was detected by Cell Counting Kit 8 (CCK8)
   proliferation assay as previously described [[303]19]. Briefly, cells
   were trypsinized and incubated with CCK8 for 4 h. Then the absorbance
   reading at 450 nm was taken by a microplate reader (Synergy HT).

Wound healing assay

   The wound healing assay was performed as previously described
   [[304]19]. Briefly, when the seeded cells reached 80 ~ 90% confluency,
   we made a straight line in the cell monolayer. At 0 and 48 h, images
   were obtained, and the distance of the wound was measured.

Transwell invasion assay

   The transwell invasion assay was performed as previously described
   [[305]19]. Briefly, we seeded cells in Matrigel and serum-free
   RPMI-1640. Medium supplemented with 10% FBS was placed in the lower
   chamber of the Transwell. After 48 h’ incubation, we fixed the cells on
   the membrane’s lower surface and subjected them to staining with 1%
   toluidine blue. After staining photographs were taken under a
   microscope, the number of invading cells was recorded.

Enzyme-linked immunosorbent assay (ELISA)

   The levels of 5S-HETE, 12S-HETE, 15S-HETE, PGD2, PGE2, PGF2, Wnt3a and
   Wnt5a either in cell culture supernatants or from tissue samples were
   measured using commercially available ELISA kits (Abcam and Bioswamp)
   according to the manufacturer’s instructions.

Western blot

   Proteins were electrophoresed by SDS/PAGE and blots were incubated
   overnight with primary antibody. The following antibodies were used:
   anti-GPR31 (Abcam, ab75579), anti-ATPase Na^+/K^+ β2 (Bioss, bs-1152R),
   anti-Wnt3a (Cell signaling Technology (CST), #2391), anti-Wnt5a (CST,
   #2530), anti-pGSK-3β (phospho Ser9, CST, #5558), anti-JNK (phospho
   Thr183/Tyr185, CST, #4671), anti-β-catenin (CST, #8480), anti-HA tag
   (CST, #5017), anti-flag tag (CST, #14,793), anti-USP24 (Proteintech,
   13,126–1-AP), anti-FGGY (Abnova, ABN-H00055277), anti-β-Actin (CST,
   #4967), and anti-GAPDH (Abcam, ab181602). After incubated with
   HRP-conjugated α-rabbit or α-mouse secondary antibodies for 1 h,
   protein bands were detected with chemiluminescence substrate (Perkin
   Elmer) using the ChemiDoc Imaging System (Bio-Rad).

Immunoprecipitation

   Cell lysates were harvested using lysis buffer, rotated at 4 °C and as
   previously described [[306]88]. Lysates were clarified by spinning.
   Protein concentrations were measured using BCA standard curves
   (Pierce). Flag antibody (for binding to flag-GPR31, Thermo Fisher
   Scientific) was added to protein lysate and rotated overnight. IP was
   carried out using the Invitrogen Dynabeads Protein G
   Immunoprecipitation Kit as directed. Lysates were next subjected to
   SDS-PAGE and immunoblot analysis. Each immunoprecipitation experiment
   was performed a minimum of twice.

Immunohistochemistry

   All procedures were performed as described above [[307]89]. The
   antibodies are as follows: anti-FGGY (Abcam), anti-12-LOX (Abcam),
   anti-15-LOX (Abcam), anti-GPR31 (Abcam), and a biotinylated secondary
   goat anti-mouse IgG antibody (Santa Cruz), labeled with HRP using a DAB
   staining kit (Maixin Biotechnology) according to the manufacturer’s
   instructions. For negative controls, IgG1 was used. Positively stained
   cells were counted in 5 fields at 200 × magnification.

Flow cytometry

   Cells were incubated with different antibodies for 30 min at 4 °C as
   indicated. The following antibodies were used: PerCP anti-mouse CD45,
   APC anti-mouse CD3, FITC anti-mouse CD4, PE anti-mouse CD8, PE
   anti-mouse CD11c, and FITC anti-mouse CD86. We selected isotype-matched
   immunoglobulin G1 antibodies (BD Biosciences) to serve as a negative
   control. The cells were analyzed on a BD FACS CantoTM II flow cytometer
   and FlowJo software (BD Biosciences).

Multispectral immunofluorescence (IF) staining

   We performed multispectral IF staining as previously described
   [[308]90]. In brief, the slides were deparaffinized and rehydrated.
   After antigen retrieval and blocking, the primary antibody was applied
   and incubated overnight. Opal polymer HRP was used as the secondary
   antibody. The slides were washed, and tyramide signal amplification
   (TSA) dye (PerkinElmer) was applied. The slides were then exposed to
   microwaves to remove the primary and secondary antibodies, washed, and
   blocked again. Afterward, other primary antibodies, as well as DAPI
   were applied successively. Finally, slides were placed on a coverslip.
   Five fields at 200 × magnification was imaged and recorded, and
   StrataQuest Image Analysis software was used to generate a spectral
   library for unmixing.

Transmission electron microscopy (TEM)

   Cells were fixed with 2.5% glutaraldehyde, postfixed with 0.5% osmium
   tetroxide and contrasted using tannic acid and uranylacetate. Specimens
   were dehydrated in a graded ethanol series and embedded in Polybed.
   Ultrathin sections were analyzed in a HT7800 transmission electron
   microscope.

Measurements of oxygen consumption and extracellular acidification

   The rates of oxygen consumption rate (OCR) and extracellular
   acidification rate (ECAR) in various cell lines were measured with a
   Seahorse Bioscience XF-24 extracellular flux analyzer, as detailed
   previously [[309]91, [310]92]. Cells were seeded at a density of
   1 × 10^4 cells per well on Seahorse XF-24 polystyrene tissue culture
   plates. Inhibitors were used at the following concentrations:
   Oligomycin (1.5 μM), Carbonyl cyanide
   4-trifluoromethoxy-phenylhydrazone (FCCP) (0.8 μM), Antimycin A
   (1.5 μM) and Rotenone (3 μM).

Assessment of mitochondrial membrane potential (MMP)

   JC-1 was used to measure the MMP according to the manufacturer’s
   instructions (Bioss). Cells in 6-well plates were incubated with JC-1
   staining solution at 37 °C for 30 min and then washed with JC-1 buffer.
   Fluorescent signals were obtained using flow cytometry.

Measurement of intracellular ATP levels

   ATP levels were measured using the Enhanced ATP Assay Kit (Beyotime
   Biotechnology) according to the manufacturer’s instructions. The
   substrate was gently mixed with reaction reagent at room temperature.
   The luminescence was then measured using a Beckman Coulter.

Statistical analysis

   Data were statistically analyzed with SPSS 20.0 and GraphPad Prism 5.0
   software following the manufacturers’ instructions. Measurement data
   were expressed as means ± standard deviations. We analyzed correlations
   between 2 datasets using Spearman’s correlation coefficient. One- and
   two-way analysis of variance with subsequent Bonferroni post-hoc tests
   was used for comparisons between 2 groups. Cumulative survival was
   determined via the Kaplan–Meier method. All data were normally
   distributed. P < 0.05 was taken to indicate a statistically significant
   result.

Supplementary Information

   [311]12943_2022_1618_MOESM1_ESM.docx^ (4.8MB, docx)

   Additional file 1. Figure S1. Validation of LCT activity in TJMUCH
   cohort.(A) Number of LCT events overlapped between TJMUCH cohort and
   TCGA LUSC cohort.(B) Comparison of overall methylation level between
   LUSC and LUAD patients fromTCGA. (C) Distribution of LCT event number
   in each sample. (D) Expression (readper mission) between tumor and
   control samples. (E) Frequency of the top 20 LCTevents (named by their
   target genes). (F) Enriched GO terms of the recurrentLCT affected genes
   (more than 2 samples). (G) Differentially expressed LCTsbetween tumor
   and normal samples. Left panel showing the number of samplesdetected
   with each LCT event and the right panel showing the expression
   ofcorresponding LCT event across samples (red represents tumor samples
   while bluerepresents normal samples). Figure S2. Association of LCT
   with Metabolic, Immuneprocess, Genomic Instability and Clinical States.
   (A) Enriched GO terms ofgenes positively or negatively co-expressed
   with overall LCT expression in eachsample. (B) The GSEA enrichment plot
   for meta-markers of each immune cell type.Genes are ranked by the fold
   change of expression in LCT-high samples (left)versus LCT-low samples
   (right) (C) Correlation of methylation level and CNVlevel with overall
   LCT activity in each sample. (D) Comparison of LCTexpression in
   different cancer stages and TMB quartiles. (E) Differentiallyexpressed
   LCT events (named by targeted gene), which are highly expressed intumor
   than control. Left panel shows the number of samples containing the LCT
   eventwhile right panel shows the expression of LCT events among all the
   samples,grouped by tumor (red) and normal control (blue). (F) Survival
   curve ofpatients grouped as L1-high and L1-low by the total expression
   of survivalrelated LCTs. Figure S3. Validation of the association of
   overall LCTactivity and Immune function in TJMUCH cohort. (A) Enriched
   GO terms of thegenes positively co-expressed with overall LCT activity.
   (B) Enriched GO termsof the genes negatively co-expressed with LCT
   activity. (C) GSEA analysis ofthe immune markers enrichment in LCT-high
   versus LCT-low samples. Figure S4. LCT activity in tumor cells. (A)
   Frequencyof overlapped LCT between bulk and single cell data sets. Left
   panel shows thefrequency of each LCT event in each cancer type from
   TCGA bulk sequencing.Right panel shows the occurrence of each LCT event
   in each sample from singlecell data set. (B) Umap of cells colored by
   individual. (C) Markers for annotationof each cell type. (D) the
   proportion of each cell type in each sample. Figure S5. LCT related
   DEGs between cellpopulation. (A) Umap and trajectory of tumor cells
   fromPatient1, Patient2 and Patient5. Cells detected with LCT events
   were coloredred. (B) DEGs between LCT enriched tumor subtype versus
   other tumor cells. (C)DEGs between LCT positive tumor cells versus LCT
   negative tumor cells in LCTenriched tumor subtype. FigureS6. The
   mitochondrialmorphology and functions. (A) The TEM results of
   H520^OV-CTRL, H520^OV-L1-FGGY, and BEAS-2B. (B) The OCR and ECAR
   results ofH520^OV-CTRLand H520^OV-L1-FGGY. (C) The MMP results of
   H520^OV-CTRLand H520^OV-L1-FGGY.(D) The ATP productionof
   H520^OV-CTRLand H520^OV-L1-FGGY. Figure S7. The oncogenic roles of
   L1-FGGY/12-LOX/GPR31in SK-MES-1 cells. (A) The relative RNA expression
   of 12-LOX and 15-LOXdetected in SK-MES-1^OV-CTRL and
   SK-MES-1^OV-L1-FGGY, as well as in SK-MES-1^OV-L1-FGGY treated with
   either ML355 or PD146176. (B) The secretionvalue of 12S-HETE and
   15S-HETE detected in SK-MES-1^OV-CTRL, SK-MES-1^OV-L1-FGGY, and
   SK-MES-1^OV-L1-FGGY treated with either ML355or PD146176. (C) The
   proliferation of SK-MES-1^OV-CTRL, SK-MES-1^OV-L1-FGGY,
   SK-MES-1^OV-L1-FGGY+sh-GPR31, and SK-MES-1^OV-L1-FGGY treated with
   either ML355 or PD146176 was detectedusing CCK8 method. (D) The
   statistical results of migration rates of
   SK-MES-1^OV-CTRL,SK-MES-1^OV-L1-FGGY,SK-MES-1^OV-L1-FGGY+sh-GPR31, and
   SK-MES-1^OV-L1-FGGY treated with either ML355or PD146176 in wound
   healing assays. (E) The statistical results of invasionnumber of
   SK-MES-1^OV-CTRL, SK-MES-1^OV-L1-FGGY, SK-MES-1^OV-L1-FGGY+sh-GPR31,
   and SK-MES-1^OV-L1-FGGY treated with either ML355or PD146176 in
   trans-well invasion assays. The data are shown as mean ± SD withplots.
   * and ** indicate p<0.05 and p<0.01, respectively between thegroups as
   indicated. Figure S8. The results of nCounter® PanCancer IO-360™Panel
   detected in L1-FGGY^+tissues and L1-FGGY^-tissues (n=12). (A) The
   pathway scores of different signaling pathwayswere compared between
   L1-FGGY^+tissues and L1-FGGY^-tissues. (B) The cell type scores of
   immunocytes were compared between L1-FGGY^+ tissues and L1-FGGY^-
   tissues. Figure S9. The model of L1-FGGYactivated 12-LOX/GPR31/Wnt
   signaling through competitive combination-inducedUSP24-mediated
   deubiquitination. Figure S10. NVR and ML355 triggered metabolism
   reprogramming andaltered the immune microenvironment invivo. (A) The
   qPCR results of genes involved inglucose and lipid metabolism were
   shown as relative expression values in KLN205^OV-CTRLmouse group,
   KLN205^OV-L1-FGGYmouse group, NVR-treated KLN205^OV-L1-FGGYmice,
   ML355-treated KLN205^OV-L1-FGGYmice and NVR+ML355-treated
   KLN205^OV-L1-FGGYmouse group. (B) The proportions of various
   immunocytes in different mousegroups using flow cytometry. Figure S11.
   Potential effects of drug on LCT activity. (A) Distribution of LCT
   expression in samples treatedwith Metaformin and control samples in two
   public data sets. (GSE141052 andGSE146982) (B) Distribution of L1
   expression in samples treated withSimvastatin and control samples in
   two pancreatic cancer cell line (PANC-1 andMiaPaCa-2
   (GSE149566)). Table S1. Basic statistics of LCT events in all
   3cohorts. Table S2. Overlapped LCT genes between TCGA LUSCand
   LUAD. Table S3. Overlapped LCTgenes between TCGA and TJMUCH LUSC
   samples. Table S4. Overlapped GO BPterms enriched with recurrent LCT
   genes between TCGA LUSC and LUAD. Table S5. Enriched GO BPterms with
   recurrent LCT genes in TJMUCH cohort. Table S6. GO BP termsenriched
   with genes positively co-expressed with overall LCT level in TCGA
   LUSCand LUAD samples. Table S7. GO BP termsenriched with genes
   negatively co-expressed with overall LCT level in TCGA LUSCand LUAD
   samples. Table S8. GO BP termsenriched with genes positively
   co-expressed with overall LCT level in TJMUCHLUSC samples. Table S9. GO
   BP termsenriched with genes negatively co-expressed with overall LCT
   level in TJMUCHLUSC samples. Table S10. Differentiallyexpressed LCTs
   between tumor and normal samples in TCGA LUSC. Table S11.
   Differentiallyexpressed LCTs between tumor and normal samples in TJMUCH
   LUSC. Table S12. Differentiallyexpressed LCTs between tumor and normal
   samples in TCGA LUAD. Table S13. Survival relatedLCTs in TCGA
   LUSC.Table S14. Survival relatedLCTs in TCGA LUAD. Table S15. Recurrent
   LCTsbetween bulk RNAseq from TCGA and 19 SC RNAseq samples. TableS16.
   Differentially expressed genes between LCT enriched tumor cell cluster
   andother tumor cell clusters in each patient. TableS17.GO BP enrichment
   of differentially expressed genes between LCT enrichedtumor cell
   cluster and other tumor cell clusters in each patient. Table S18.
   Differentiallyexpressed genes between tumor cells with LCT versus tumor
   cells without LCT inLCT enriched tumor cell cluster in each
   patient. TableS19. GO BP enrichment of differentially expressed genes
   between tumor cells withLCT versus tumor cells without LCT in LCT
   enriched tumor cell cluster in eachpatient. Table S20. The basic
   clinical pathologicalinformation of all TJMUCH patients. Table
   S21.Distributions of clinical-pathological parameters of patients with
   L1-FGGY^+and L1-FGGY^- of TJMUCH.TableS22. List of 47 LCT related genes
   selected for grouping of patients.TableS23.The sequences of primers in
   RT-qPCR analysis.

Acknowledgements