Abstract

   Hepatoma is one of the most common malignant tumor, and most patients
   have very poor prognosis. Early prediction and intervention of the
   hepatoma recurrence/metastasis are the most effective way to improve
   the patients' clinical outcomes. Here, we used isobaric tags for
   relative and absolute quantitation (iTRAQ) based quantitative
   phospho-proteomics approach to identify biomarkers associated with
   hepatoma recurrence/metastasis in hepatoma cell lines with increasing
   metastasis ability. In total, 75 phosphorylated peptides corresponding
   to 60 phosphoproteins were significantly dysregulated. Bioinformatics
   analysis (GO, KEGG and IPA) allowed these data to be organized into
   distinct categories. These data represent the first in-depth proteomics
   analysis of a serial hepatoma cell lines with increasing invasion and
   metastasis potential. The data are related to (Xing et al., 2019).

   Keywords: Hepatoma, Quantitative phospho-proteomics, FLNA^Ser2152,
   ANXA2^Tyr23, Prognosis
     __________________________________________________________________

   Specifications Table
   Subject area Biology
   More specific subject area Phospho-proteomics on a serial hepatoma cell
   lines with increasing invasion and metastasis potential
   Type of data Raw, List of identified proteins, phosphopeptides as
   [40]tables (.xls)
   How data was acquired The data was acquired by Liquid chromatography
   mass spectrometry in tandem (LC-MS/MS). The samples were separated by
   an EASY-nLC1000 system (Thermo Fisher Scientific, Bremen, Germany) and
   detected by a quadrupole-Orbitrap mass spectrometer (Q-Exactive Plus)
   (Thermo Fisher Scientific, Bremen, Germany).
   Data format Raw, Filtered and analyzed
   Experimental factors A serial hepatoma cell lines with increasing
   invasion and metastasis potential (Hep3B-a nonmetastatic HCC cell line,
   HepG2-a lowly metastatic HCC cell line, MHCC97L-a moderately metastatic
   HCC cell line, MHCC97H-a highly metastatic HCC cell line) were used to
   comprehensively and systematically investigate the alternations of the
   proteome and phospho-proteome through iTRAQ-based quantitative
   phosphoproteomics approach (LC-MS/MS). The samples were labeled with
   the iTRAQ 8-plex reagent as follows: four groups (Hep3B, HepG2, MHCC97L
   and MHCC97H) were labeled with 113, 114, 115 and 116 isobaric tag,
   respectively; and the peptides from the biological repetitions of above
   4 groups were labeled with 117, 118, 119 and 121, respectively.
   Meanwhile, the proteomics dataset was performed with the same as
   strategy described above and used to normalize the change of
   phosphopeptide abundance against the change in total protein levels,
   avoiding fluctuations due to variations in protein amount. For
   phosphoprotomics, the combined and dried digest was subjected to
   phosphopeptide enrichment using Magnetic Titanium Dioxide
   Phosphopeptide Enrichment Kit.
   Experimental features Proteins were extracted form a serial hepatoma
   cell lines with increasing invasion and metastasis potential, iTRAQ
   labeled, phosphopeptide enriched and then prepared for liquid
   chromatography-massspectrometry (LC-MS/MS) analysis.
   Data source location Fuzhou, China, Mengchao Hepatobiliary Hospital of
   Fujian Medical University
   Data accessibility Repository name: iProX
   Data identification number: IPX0001763001
   Direct URL to data: [41]https://www.iprox.org/
   Related research article Author's name: Xiaohua Xing, Hui Yuan, Ying
   Sun, Kun Ke, Xiuqing Dong, Hui Chen, Xiaolong Liu, Bixing Zhao, and
   Aimin Huang
   Title: ANXA2Tyr23 and FLNASer2152 Phosphorylation Associate with poor
   prognosis in Hepatic carcinoma revealed by Quantitative
   hosphoproteomics analysis
   Journal: Journal of Proteomics
   [42]https://doi.org/10.1016/j.jprot.2019.03.017
   [43]Open in a new tab
   Value of the Data
     * •
       The first in-depth proteomics and phospho-proteomics analysis of a
       serial hepatoma cell lines with increasing invasion and metastasis
       potential.
     * •
       The first proteome and phospho-proteome profile of a serial
       hepatoma cell lines with increasing invasion and metastasis
       potential, which might be useful for further study the mechanisms
       of hepatoma recurrence and metastasis.
     * •
       These data could provide a theoretical basis for the follow-up
       researches on the mechanisms of hepatoma recurrence and metastasis.

   [44]Open in a new tab

1. Data

   The dataset contains raw sequencing data obtained through the
   phospho-proteome from a serial hepatoma cell lines with increasing
   invasion and metastasis potential (Hep3B-a nonmetastatic HCC cell line,
   HepG2-a lowly metastatic HCC cell line, MHCC97L-a moderately metastatic
   HCC cell line, MHCC97H-a highly metastatic HCC cell line). The raw data
   has been available publicly on a data repository (iProX,
   [45]https://www.iprox.org/) with an accession ID as IPX0001763001. The
   data are related to [[46]1].

2. Experimental design, materials and methods

2.1. Experimental design

   A serial hepatoma cell lines with increasing invasion and metastasis
   potential (Hep3B-a nonmetastatic HCC cell line, HepG2-a lowly
   metastatic HCC cell line, MHCC97L-a moderately metastatic HCC cell
   line, MHCC97H-a highly metastatic HCC cell line) were used to
   comprehensively and systematically investigate the alternations of the
   proteome and phospho-proteome through iTRAQ-based quantitative
   phosphoproteomics approach (LC-MS/MS). We expect to be able to discover
   novel potential biomarkers and therapeutic targets associated with
   invasion and metastasis of hepatoma, and further explain the
   metastasis/recurrence mechanisms. The samples were labeled with the
   iTRAQ 8-plex reagent as follows: four groups (Hep3B, HepG2, MHCC97L and
   MHCC97H) were labeled with 113, 114, 115 and 116 isobaric tag,
   respectively; and the peptides from the biological repetitions of above
   4 groups were labeled with 117, 118, 119 and 121, respectively.
   Meanwhile, the proteomics dataset was performed with the same as
   strategy described above and used to normalize the change of
   phosphopeptide abundance against the change in total protein levels,
   avoiding fluctuations due to variations in protein amount. For
   phosphoprotomics, the combined and dried digest was subjected to
   phosphopeptide enrichment using Magnetic Titanium Dioxide
   Phosphopeptide Enrichment Kit (Thermo Fisher Scientific, Bremen,
   Germany).

2.2. Materials and methods

   Cells were harvested and extracted with lysis buffer (9M Urea, 10 mM
   Tris-HCl (pH 8.0), 75 mM NaCl, 10 mM IAA, 1 mM NaF, 1 mM
   β-glycerophosphate, 1 mM Sodium orthovanadate (Na3VO4), 1 mM Sodium
   pyrophosphate, 1 mM sodium dihydrogen phosphate, 1 mM PMSF, 1%
   phosphatase inhibitor cocktail 2 (Sigma, St. Louis, MO USA), 1%
   phosphatase inhibitor cocktail 3 (Sigma)), and 1 tablet of EDTA-free
   protease inhibitor cocktail (Roche, Basel, Switzerland) for every 10 mL
   lysis buffer. The cell lysate was sonicated on ice for 1 s followed by
   a 5 s rest for 8 min. The mixture was centrifuged at 17,000 g for 10
   min at 4 °C to remove cell debris. The protein concentration of the
   supernatant was determined by BCA assay (TransGen Biotech, Beijing,
   China) following the manufacturer's protocol. After that, the protein
   mixture was reduced by 10 mM DTT at 55 °C for 30min and alkylated by 50
   mM IAA in the darkness at room temperature for 30 min.

   The protein digestion and iTRAQ labeling followed our previous reported
   procedures with modification [[47]2]. Briefly, 100μg proteins were
   digested via the FASP protocol with spin ultrafiltration units with
   molecular weight cut off 10,000 Da. Then, proteins were digested with
   trypsin, and the peptide mixture was further labeled using the iTRAQ
   reagent kit (AB SCIEX, USA). Peptides were labeled with the iTRAQ
   8-plex reagent respectively. Equal amount of 8 labeled samples were
   combined and cleaned up by Sep-Pak Vac C[18] cartridges (Waters) and
   then dried in a vacuum centrifuge for further usage.

   For phosphoprotomics, the combined and dried digest was subjected to
   phosphopeptide enrichment using Magnetic Titanium Dioxide
   Phosphopeptide Enrichment Kit (Thermo Fisher Scientific, Bremen,
   Germany). Briefly, TiO[2] magnetic beads were firstly washed by binding
   buffer three times. Then the peptide mixtures were incubated with
   magnetic beads in loading buffer (80% ACN, 2% FA). And then, the
   magnetic beads were washed in turn by binding buffer and washing
   buffer. Finally, the phosphopeptides were eluted by elution buffer and
   dried in a vacuum centrifuge for further usage.

   The LC-MS/MS analysis follows our previously reported protocol with
   certain modification [[48]2]. Briefly, the phosphopeptides were
   respectively re-suspended with 5 μL solvent A (0.1% formic acid in
   water), and separated by an EASY-nLC1000 system (Thermo Fisher
   Scientific, Bremen, Germany) and analyzed by a quadrupole-Orbitrap mass
   spectrometer (Q-Exactive Plus) (Thermo Fisher Scientific, Bremen,
   Germany) equipped with an online nano-electrospray ion source. 4 μL
   peptides was loaded onto the trap column (Thermo Scientific Acclaim
   PepMap C18, 100 μm × 2 cm) with a flow of 10 μL/min, and subsequently
   separated on the analytical column (Acclaim PepMap C18, 75 μm × 150 cm)
   with a gradient of 2–8% solvent B for 15min, 8–15% solvent B for 30
   min, 15–32% solvent B for 25 min, 32–80% solvent B for 1 min followed
   by isocratic conditions at 80% solvent B for 5 min with a flow rate of
   300 nl/min at 40 °C.

   The Q-Exactive Plus mass spectrometer was operated in the
   data-dependent mode to switch automatically between MS and MS/MS
   acquisition. The electrospray voltage of 2.1 kV at the inlet of the
   mass spectrometer was used. Survey full-scan MS spectra (m/z 350–1200)
   was acquired with a mass resolution of 70 K, followed by 15 sequential
   high energy collisional dissociation (HCD) MS/MS scans with a
   resolution of 17.5 K. In all cases, one microscan was recorded using
   dynamic exclusion of 30 seconds.

   Immunohistochemistry was performed on hepatocellular carcinoma tissue
   microarray as previously described [[49]3]. Briefly, following
   pretreatment at pH 6 and peroxidase blocking, the slides were
   respectively incubated with the primary antibody (anti-p-FLNA, 1/200
   dilution and anti-p-ANXA2, 1/200 dilution) for 30 min. Then, the slides
   were washed, treated with the envision FLEX/HRP system for 20 min and
   revealed with the envision FLEX-DAB chromogen (Dako) and with Mayer's
   Hematoxylin (Lille's Modification) Histological Staining Reagents (Dako
   53309) for 3 minutes and distilled by water for 5 minutes.

2.3. Data analysis

   MS data acquiring was processed using Proteome Discoverer (Thermo
   Fisher Scientific, Bremen, Germany; version 1.4) against the uniprot
   human_database (released at 2014-04-10, 20,264 entries). The complete
   list of identified proteins and phosphopeptides in our study was shown
   in [50]Tables 1 and 2 in Supplementary data.

   To identify phosphopeptides whose phosphorylation level was
   significantly altered with increasing invasion and metastasis
   potential, we set a threshold of fold change >1.5 or <0.67 (log[2]
   ratio lower than −0.58 or higher than 0.58). In order to screen
   abnormal phosphorylation contribute to the invasion and metastasis of
   hepatoma cells, we focused on the most reliable quantitative data, i.e.
   phosphoproteins and phosphopeptides that the abundance was steady
   increased or decreased from the lowest metastatic cell line to the
   highest metastatic cell line (from Hep3B to MHCC97H). Despite this very
   stringent criterion, we found that 75 phosphopeptides corresponding to
   60 phosphoproteins ([51]Table 3 in Supplementary data) were steadily
   changing their abundance according with the metastatic potential,
   revealing the important phosphorylation events associated with the
   metastasis ability of cell lines.

2.4. Bioinformatic analysis

   The Gene Ontology (GO) annotation and pathway enrichment analysis of
   all the identified proteins and differentially expressed proteins were
   implemented using the online tool DAVID
   ([52]http://david.abcc.ncifcrf.gov/). The GO analysis about biological
   processes and molecular functions of the dysregulated phosphoproteins
   were displayed in [53]Fig. 1. The GO annotations were ranked in term of
   the enrichment of the differentially expressed proteins.

Fig. 1.

   [54]Fig. 1
   [55]Open in a new tab

   The involved biological processes (A) and molecular functions (B) of
   the dysregulated phosphoproteins by GO analysis.

   To further confirm the correlation between these two phosphorylation
   events and recurrence and metastasis of hepatoma in patients,
   alternation pattern of these two phosphoproteins at phosphorylation
   level was performed in a cohort of 80 HCC patients using tissue
   microarray. The IHC results were independently assessed by two
   pathologists double-blindly. All tissues were manually scored as 0
   (negative), 1 (weak), 2 (strong) or 3 (very strong). Each case was
   considered to be low expression if the final score was 0–1, while high
   expression if the final score was 2–3 ([56]Fig. 2). The representative
   images of ANXA2 immunostaining in hepatoma tissues were shown in
   [57]Fig. 3.

Fig. 2.

   [58]Fig. 2
   [59]Open in a new tab

   The presentative images of ANXA2 immunostaining in tumor tissues and
   its corresponding adjacent non-tumor tissues of different groups. Scale
   bar, 50μm, *p < 0.05.

Fig. 3.

   [60]Fig. 3
   [61]Open in a new tab

   The levels of FLNA validated by IHC are not changed in the recurrent
   hepatoma patients comparing with nonrecurrent hepatoma patients.

Acknowledgments