Abstract Exploring the role of phase separation in intracellular compartment formation is an active area of research. However, the associations of phase separation with intestinal stem cell (ISC)-dependent regeneration and aging remain unclear. Here, we demonstrate that BuGZ, a coacervating mitotic effector, shows age- and injury-associated condensation in Drosophila ISC nuclei during interphase. BuGZ condensation promotes ISC proliferation, affecting Drosophila gut repair and longevity. Moreover, m^6A reader YT521-B acts as the transcriptional and functional downstream of BuGZ. The binding of YT521-B promotor or m^6A writer Ime4/ Mettl14 to BuGZ controls its coacervation, indicating that the promotor may accelerate the phase transition of its binding transcription factor. Hence, we propose that phase separation and m^6A regulators may be critical for ameliorating ISC-dependent gut regeneration and aging and requires further study. Subject terms: Ageing, Intestinal stem cells, RNA modification __________________________________________________________________ Phase separation serves to compartmentalize and concentrate cellular components to facilitate essential physiological processes. Here, the authors elucidate the role and mechanism of BuGZ-mediated phase separation in the context of gut regeneration and aging. Introduction Biological liquid-liquid phase separation (LLPS) triggers the formation of condensed liquid-like droplets, resembling intracellular compartmentations that spatiotemporally facilitate or attenuate biochemical reactions^[44]1,[45]2. The biophysical properties of these macromolecular condensates are precisely controlled by their concentrations, structural features including intrinsically disordered regions (IDRs) and post-translational modifications (PTMs), contiguous environment and interacting chaperones containing DNA, RNA, and proteins^[46]3–[47]5. DNA-protein complexes such as centrosomes, mitotic spindle, actin polymerization complex, telomere, chromatin, heterochromatin, and nucleolus form droplet-like condensates^[48]6,[49]7. Despite super-enhancer, enhancer, exogenous pathogen, and telomere DNA have been shown to induce phase separation of their corresponding associated proteins^[50]7,[51]8, whether the promotor influences the phase transition of its targeted transcription factor (TF) during the transcription process remains ambiguous. Biological functions and impacts of phase separation have been ill-defined and fueled by the ease of visualizing the droplet-shaped coacervations and disrupting the reversible condensate assembly in vivo and in vitro, which have advanced various biological fields^[52]2,[53]8–[54]10. Most studies on phase separation referred to stem cells focus on embryonic stem cells (ESCs) during organ development instead of adult stem cells (ASCs, also known as resident stem cells)^[55]11,[56]12 during tissue homeostasis and aging. A recent finding revealing that phase separation regulates the asymmetric localization of Numb and PAR complexes and contributes to neuroblast division in neural stem cells (NSC), suggests a possible regulatory role of LLPS on some ASCs^[57]13,[58]14. However, no protein has been shown to undergo functionally relevant phase transition during ASCs-mediated tissue regeneration or aging, typically regulated by genetic mutations, epigenetic changes, and extrinsic factors, including glucose, lipid, Ca^+ metabolism, and niche environment^[59]15–[60]17. To evaluate this phenomenon, we utilize intestinal stem cells (ISCs) in the midgut of Drosophila as the ASCs model to study tissue regeneration and aging, which divide asymmetrically and differentiate into enteroblasts (EBs) or enteroendocrine mother cells (EMCs) to maintain intestinal homeostasis upon subjected to external injuries or the aging process^[61]18,[62]19. N^6-methyladenine mRNA (m^6A) modification is the most prevalent posttranscriptional RNA modification of the common RRACH (R = G or A, H = A, C or U) sequences^[63]20. The m^6A modification modulated by writers (RNA methyltransferases), readers (m^6A recognizers), and erasers (RNA demethylases)^[64]20, is required for distinct cellular processes under different cellular contexts^[65]20. Although previous studies have shown that m^6A writer Mettl14 and reader YTHDF1 separately facilitate ISC maintenance and gut homeostasis^[66]21–[67]23, no m^6A regulator has been shown to function in ISC aging. Beyond its mitotic functions in microtubule (MT)–kinetochore interaction, spindle assembly checkpoint (SAC), and spindle assembly, BuGZ is also required for proper mRNA splicing, synaptic vesicles (SV) cycling, and hESC reprogramming during interphase^[68]24–[69]26. BuGZ shows the condensation behavior involved in the MT polymerization during mitosis^[70]27. Nonetheless, whether BuGZ undergoes phase separation during interphase, and whether BuGZ and its condensation behavior contribute to ISC proliferation and aging are still unknown. In this study, we uncover the role of phase separation on ASC-dependent regeneration and aging, the mechanism for controlling the corresponding TF coacervation via its downstream promotor DNA, and the effect of m^6A regulators on modulating the phase transition of the key driver in ASCs. Results BuGZ forms coacervation puncta in ISCs BuGZ facilitates the mitosis of cancer cells and enhances self-renewal and pluripotency of human ESCs^[71]24,[72]26,[73]27. However, its role in ASCs is still unknown. To investigate this phenomenon, a FLAG-tagged BuGZ protein-trap reporter line^[74]28 was used to observe the expression pattern of endogenous BuGZ in Drosophila intestines. Immunofluorescence analyses showed that BuGZ was specifically expressed in the nuclei of esg-lacZ^+ ISCs and progenitor cells, Pros^+ EEs (Supplementary Fig. [75]1a), Dl^+ ISCs (Supplementary Fig. [76]1b), and NRE-lacZ^+ EBs (Supplementary Fig. [77]1c), but not in differentiated ECs with Polyploidy nuclei (Supplementary Fig. [78]1a) in Drosophila midguts. Interestingly, BuGZ formed nuclear puncta in the esg^+ ISCs and progenitor cells of aged Drosophila (Fig. [79]1a). The expression level of BuGZ (Fig. [80]1b), and the size, and number of BuGZ puncta also increased in the esg^+ cells of aged Drosophila (Fig. [81]1c, d). Furthermore, real-time-quantitative polymerase chain reaction (RT-qPCR) (Fig. [82]1e) and western blotting (Supplementary Fig. [83]1e) data of the sorted esg^+ cells (Supplementary Fig. [84]1d) also showed that both mRNA and protein levels of BuGZ were elevated in aged-esg^+ cells. Moreover, bleomycin (BLM)- or paraquat (PQ)-induced gut injury elevated BuGZ levels (Fig. [85]1e, f), promoting the formation of nuclear puncta in Dl^+ ISCs (Fig. [86]1g–i) of Drosophila. Fig. 1. BuGZ forms condensation puncta in ISCs during aging and after injury. [87]Fig. 1 [88]Open in a new tab a–d BuGZ forms puncta in esg^+ cells during aging. Image of endogenous BuGZ (red) in esg^+ cells (a). LacZ indicates esg^+ cells (ISCs and EBs, green), nucleus is labeled by DAPI (blue). Fluorescence intensity of BuGZ (b). Area (c), number (d) of BuGZ puncta. Each dot corresponded to one esg^+/BuGZ^+ cell and DAPI is used to calculate the area of the nucleus (b, 10D: 54 cells; 30D:36 cells). If the puncta area is bigger than 0.001 pixels, the puncta area is calculated. Otherwise, the area is calculated as zero (c, 10D: 99 area; 30D 124 area). d 10D: 99 cells; 30D: 124 cells. e BuGZ mRNA level increases in old and BLM/PQ-injured esg^+ cells (n = 3 biologically independent experiments). f–i BuGZ forms puncta in BLM-/PQ-injured ISCs. Images of injured BuGZ puncta (i). Dl (Delta) labeled ISCs (i). Fluorescence intensity (f), area (g), number (h) of BuGZ or BuGZ puncta. (f, Mock: 58 cells; BLM: 98 cells; PQ: 72 cells. g, 100 areas. h, Mock: 53 cells; BLM: 97 cells; PQ: 104 cells). j–m BuGZ undergoes concentration- or temperature-dependent phase separation. Image of BuGZ puncta (j). BuGZ is labeled by BuGZ antibody (red), GFP indicates esg^+ cells (green). Quantification of the fluorescence intensity (k), area (l), number (m) of BuGZ or BuGZ puncta. (k, upper: 106 cells; middle: 118 cells; below: 69 cells. l, upper: 200 areas; middle: 71 areas; below: 204 areas. m, upper: 98 cells; middle: 61 cells; below: 98 cells). n–r Puncta of BuGZ does not co-locate with nucleolus marked with Fribrillin (n), PML body marked with SUMO (o), γH2AVD labeled DNA repair foci (p), HP1α labeled heterochromatin (q), but partially co-locate with chromatin marked with H3K27me3 (r). The experiments were independently repeated three times, yielding similar results. Scale bars represent 5 μm. Bars are mean ± SD. P-values were calculated by two-tailed, unpaired Student’s t-test. Source data are provided as a Source Data file. To further verify that BuGZ undergoes concentration-dependent phase separation in esg^+ cells, we used the esg-Gal4, UAS-GFP, tub-Gal80^TS system (hereafter referred to as esg^TS)^[89]29 to overexpress HA-tagged BuGZ cDNA in esg^+ cells. We found that overexpressing BuGZ indeed induced BuGZ puncta formation in the esg^+ cells of young Drosophila (Fig. [90]1j). To test whether the BuGZ puncta exhibited phase separation property, we exposed the BuGZ-overexpressing Drosophila midguts to different temperatures because BuGZ phase separation is sensitive to temperature shifts^[91]27. We found that BuGZ puncta diffused when the midguts were transferred from 25 to 4 °C, and the diffused protein concentrated again to form more but smaller puncta when these low temperature-cultured midguts were transferred back to 25 °C with or without MG132 (which was used for inhibiting protein degradation) treatment (Fig. [92]1j–m and Supplementary Fig. [93]1f–i). Moreover, the purified His-tagged Drosophila BuGZ protein in E. coli (Supplementary Fig. [94]2a) formed droplets in vitro and was regulated by a crowding agent, salt hydronium concentration, temperature and pH (Supplementary Fig. [95]2b–e), consistent with our previous study^[96]27. The His-dBuGZ protein also exhibited the fusion property (Supplementary Fig. [97]2f). All these data indicated that Drosophila BuGZ protein indeed underwent liquid-liquid phase separation (LLPS) in vivo and in vitro. In addition, we found that BuGZ reversible puncta was partially located with TriMethyl-Histone H3-K27-labeled chromatins, but not the Fibrillarin-labeled nucleus, SUMO-labeled Promyelocytic leukemia (PML) bodies, HP1α-labeled heterochromatins, or γH[2]AvD-labeled DNA repair foci (Fig. [98]1n–r). BuGZ regulates ISC division after injury The specific localization pattern of BuGZ in the Drosophila intestinal stem and progenitor cells suggested that it might regulate intestine regeneration and aging. To verify this hypothesis, we first determined whether BuGZ controlled the proliferation of ISCs. We found that BuGZ depletion with two different RNA interference (RNAi) lines in the esg^+ cells (Supplementary [99]3a) did not affect the number of esg^+ (ISC and progenitor cell), Delta^+ (Dl; labels ISC cells) or phospho-histone H3^+ (pH3^+; an immunomarker of cell proliferation) cells in young (7 days) Drosophila under normal conditions (Fig. [100]2a–c and Supplementary [101]3c, d). However, BuGZ depletion in esg^+ cells diminished ISC proliferation (indicated by increased esg^+ cells, pH3^+ and Dl^+ cells in the midguts) after the BLM-induced gut injury (Fig. [102]2a–c and Supplementary [103]3c, d). Thus, we proposed that BuGZ enhanced ISC proliferation to repair the damaged gut epithelial after injury but was not required for ISC basic maintenance. Fig. 2. BuGZ regulates activation of ISC proliferation after gut injury and during aging. [104]Fig. 2 [105]Open in a new tab a–c BuGZ controls ISC proliferation after gut injury. Images of esg^+ cells in control (UAS-LacZ), BuGZ^RNAi#1 (BDSC:27996), BuGZ^RNAi#2 (VDRC: v104498) midguts (a). Ratio of esg^+ cells to DAPI cells (b, from left to right are 30, 13, 28, 19, 13, 31 views). pH3^+ cells per midguts (c, from left to right are 22, 15, 12, 30, 24, 25 guts). GFP indicates esg^+ cells (green). d–f BuGZ mediates ISC proliferation after injury by performing cell-autonomous functions. pH3^+ cells per young (7D) or injured midguts under ISC^TS (d), NRE^TS (e), 386Y-gal4 (f). (d: from left to right are 17, 9, 18, 16, 14, 13 guts; e: from left to right are 14, 14, 16, 14, 11, 12 guts; f: from left to right are 18, 17, 20, 16, 12, 13 guts). g Model of mutually independent BuGZ-null allele. h, i BuGZ depletion suppresses ISC proliferation after clone induction. Images of MARCM clones (h, green, outlined by white dotted lines). Number of cells per clone (i, from left to right are 90, 62, 79, 90 clones). GFP indicates ISCs (green). j, k Flip-out(F/O) lineage-tracing clone system is used to mark ISCs and their newborn progenies. Images of F/O clones (j). Number of cells per clone (k, from left to right are 63, 25, 23 clones). GFP indicates ISCs (green). l–n BuGZ elevation leads to an increase ISC proliferation upon aging. Images of midguts with esg^+ staining (l). GFP indicates esg^+ cells (green). Ratio of esg^+ cells to DAPI cells (m, from left to right are 31, 34, 16, 20, 15 views). Number of pH3^+ cells per midgut (n, from left to right are 15, 21, 23, 14, 19 views). DAPI stained nuclei (blue). Scale bars represent 25 μm. View size is 3.4 × 10^4 μM^2. Bars are mean ± SD. P-values were calculated by two-tailed, unpaired Student’s t-test. Source data are provided as a Source Data file. Furthermore, the cell-type-specific BuGZ RNAi in the ISC cells induced by ISC^TS (NRE-lacZ; esg-GAL4, UAS-GFP/CyO; tub-Gal80ts, NRE-Gal80) inhibited the proliferation of ISC after injury (Fig. [106]2d). BuGZ depletion in EBs induced by NRE^TS (NRE-GAL4, UAS-GFP, tub-Gal80ts/CyO), or in EEs by 386y-Gal4 had no effect on the proliferation of ISC following the BLM treatment (Fig. [107]2e, f). Moreover, different from inhibited BuGZ level in ISCs upon BuGZ RNAi using ISC^TS, BuGZ-specific depletion in EBs or EEs did not affect the protein expression of BuGZ in ISCs (Supplementary Fig. [108]3e–h). Thus, BuGZ mediated the ISC proliferation and gut repair after injury by performing cell-autonomous functions. To further determine the functions of BuGZ in ISC proliferation, we generated two BuGZ-null mutant alleles (BuGZ^3 and BuGZ^8) using the CRISPR/Cas9 knock-out system (Fig. [109]2g). We found that BuGZ-null mutants of Drosophila (BuGZ^3/BuGZ^8) showing efficient depletion effect (Supplementary Fig. [110]3i) died before the white pupae stage. We analyzed the BuGZ-null clones via mosaic analysis with a repressible cell marker (MARCM), which labels all progenies of a single active ISC from one clone with a visible GFP marker. After 10 days of clone induction, we found that the BuGZ-null clones were smaller than the wild-type clones, and the ISC proliferation defect observed in the BuGZ-null clones could be reversed by expressing the full-length BuGZ cDNA (BuGZ^FL) (Fig. [111]2h–i). The Flip-out (F/O) lineage-tracing analyses of the RNAi clones also showed that BuGZ depletions suppressed the ISC proliferation after clone induction (Fig. [112]2j, k). Previous studies have shown that BuGZ depletion blocked prometaphase-metaphase transition and elevated the mitotic index in a symmetric division of tumor cells^[113]24. Conversely, we found that BuGZ RNAi reduced mitotic index (indicated by decreased esg^+ cells and pH3^+ cells in the midguts) in the asymmetric cell division of ISC after injury. To understand this phenomenon, we evaluated whether BuGZ regulates the asymmetric cell division process of Drosophila ISCs by quantifying the proportions of BuGZ RNAi or control cells at different mitotic stages using pH3^+ and DAPI as markers after the BLM-induced injury. The results indicated that the proportion of prophase/prometaphase or metaphase BuGZ RNAi cells showed no difference with the control (Supplementary Fig. [114]3j–l), suggesting that BuGZ had no similar effect on the asymmetric division of ISCs as the symmetric division of tumor cells. Furthermore, the proliferation rate of ISCs (indicated by EdU) in the S phase induced by BuGZ depletion was significantly reduced after the injury (Supplementary Fig. [115]3m, n). Thus, BuGZ was not required for the asymmetric division of ISCs but was essential for regulating the proliferation rate during the S phase. According to the terminal-deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL) assay, BuGZ-null clones did not show higher apoptotic signals than control clones (Supplementary Fig. [116]3o, p). By checking the cell-type-specific makers in the BuGZ-null clones, we found that the presence of Dl^+ ISCs, Pros^+ EEs, NRE-LacZ^+ EBs, and polyploid ECs (Supplementary Fig. [117]3q–s) in BuGZ-null clones on day10 after clone induction (ACI). This proposed that BuGZ was indispensable for ISC proliferation and might not be important for ISC differentiation. BuGZ leads to gut hyperplasia upon aging As Drosophila ages, the ISCs in their midguts undergo uncontrolled hyperproliferation even without injury^[118]18,[119]19. Since BuGZ level was elevated in ISCs of aged Drosophila (Fig. [120]1b, e and Supplementary Fig. [121]1e), we wanted to know whether increasing BuGZ level contributed to age-associated ISC hyperproliferation. We found that overexpressing BuGZ^FL in the esg^+ cells of young Drosophila elevated the ISC proliferation rate (Fig. [122]2l–n and Supplementary Fig. [123]3b), and BuGZ^FL-overexpressing MARCM clones were also bigger than the control clones (Fig. [124]2h, i), indicating that BuGZ overexpression led to an increase in ISC proliferation. Additionally, we found that BuGZ depletion in ISCs of aged Drosophila induced by esg^TS-driven RNAi significantly rescued the age-associated ISC hyperproliferation phenotype (Fig. [125]2l–n). Based on these data, it could be inferred that age-associated BuGZ elevation promoted ISC proliferation upon aging. LLPS of BuGZ mediates ISC proliferation Since BuGZ augmentation resulted in condensation and increased proliferation of ISCs, we examined whether the ISC proliferation was controlled by BuGZ coacervation in aged or damaged midguts. We generated a UAS transgenic fly expressing a modified BuGZ^13S protein whose 6 tyrosines (Y) and 7 phenylalanines (F) were replaced by serines to disrupt the phase separation property of BuGZ, as previously reported^[126]27 (Fig. [127]3a). Overexpression of BuGZ^13S under esg^TS diminished BuGZ puncta formation compared with BuGZ^FL overexpression under the same intensity of protein level (Fig. [128]3b–e). BuGZ^13S overexpression in esg^+ cells showed fewer esg^+ and pH3^+ cells, compared with BuGZ^FL overexpression (Fig. [129]3b, f, g). BuGZ^13S-overexpressing MARCM clones also had smaller sizes than BuGZ^FL-overexpressing clones (Fig. [130]3h, i). Meanwhile, cell number reduction in BuGZ-null clones was prevented by overexpressing BuGZ^FL but not overexpressing BuGZ^13S (Fig. [131]3h, i). Thus, it revealed that the ability of BuGZ protein to form phase-separation-mediated puncta was essential for its function in ISC proliferation. Fig. 3. LLPS of BuGZ regulates ISC proliferation. [132]Fig. 3 [133]Open in a new tab a Model of BuGZ mutants (BuGZ^13S, BuGZ^C, and BuGZ^CS). b–g ISC proliferation is controlled by BuGZ coacervation. Images of midguts with esg^+/BuGZ^+ staining (b). BuGZ is indicated by the BuGZ antibody. GFP indicates esg^+ cells (green). Fluorescence intensity (c), area (d), number (e) of BuGZ puncta. (c, UAS-BuGZ^FL, UAS-BuGZ^13S: 51, 79 cells. d, UAS-BuGZ^FL, UAS-BuGZ^13S: 200, 208 cells. e, UAS-BuGZ^FL, UAS-BuGZ^13S: 53, 52 cells). Ratio of esg^+ to DAPI cells (f, UAS-BuGZ^FL, UAS-BuGZ^13S: 26, 40 views). pH3^+ numbers per midgut (g, UAS-BuGZ^FL, UAS-BuGZ^13S: 17, 29 guts). h, i LLPS of BuGZ is essential for ISC proliferation. Images of MARCM clones (i). Cell numbers per clone (h from left to right: 83, 37, 244, 53, 34, 136 clones). GFP indicates ISCs (green). j–l BuGZ phase separation regulates ISC proliferation upon gut injury. Images of esg^+ cells (j). Ratio of esg^+ to DAPI cells (k, from left to right: 30, 25, 24, 30, 24, 32 views). pH3^+ numbers per midgut (l, from left to right: 30, 33, 27, 28, 26, 29 guts). GFP indicates esg^+ cells (green). m Overexpression of BuGZ^C inhibited the LLPS of BuGZ during gut repair, while BuGZ^C exhibited more effective influence than BuGZ^CS on suppressing BuGZ condensate. Dl labels ISCs. White arrow indicates puncta. Experiments were independently repeated three times. n–r Truncated IDR peptide BuGZ^C instead of BuGZ^CS inhibits ISC proliferation by disrupting LLPS of BuGZ. Images of midguts with esg^+/BuGZ^+ staining. BuGZ is indicated by BuGZ antibody (n). GFP indicates esg^+ cells (green). Quantification of the area (o), number (p) of BuGZ puncta (o, from left to right: 200, 209, 288 areas. p, from left to right: 206, 223, 223 cells). Ratio of esg^+ to DAPI cells. (q, from left to right: 18, 34, 29 views). pH3^+ numbers per midgut (r, 20, 40, 40 guts). Scale bars represent 5 μm (b, n), 10 μm (m), 25 μm (i, j). View size is 3.4 × 10^4 μM^2. Bars are mean ± SD. P-values were calculated by two-tailed, unpaired Student’s t-test. Source data are provided as a Source Data file. The presence of intrinsically disordered regions (IDRs), modulating the emergent behavior and properties of LLPS, is one of the common molecular signatures of phase separation^[134]3,[135]5,[136]6. Our previous study showed that BuGZ peptide C (BuGZ^C) in the IDR region, but not CS (BuGZ^CS) (Fig. [137]3a) suppressed the coacervation of wild-type BuGZ in vitro^[138]27. We found that overexpressing either BuGZ^C or BuGZ^CS in esg^+ cells in young Drosophila had no significant changes in ISC proliferation under normal conditions (Fig. [139]3j–l). Interestingly, BuGZ^C overexpression in esg^+ cells inhibited ISC proliferation, whereas BuGZ^CS overexpression showed less effect than BuGZ^C on ISC proliferation after BLM-induced injury (Fig. [140]3j–l). Moreover, compared with BuGZ^CS, BuGZ^C overexpression shows more effective suppression for BuGZ condensate in ISCs caused by gut repair (Fig. [141]3m). To further determine the effects of BuGZ^C and BuGZ^CS peptides on regulating ISC proliferation, we co-expressed BuGZ^FL with BuGZ^C or BuGZ^CS in esg^+ cells. We observed that BuGZ^C showed stronger effects than BuGZ^CS on reducing the size of BuGZ puncta resulting from BuGZ overexpression and activation of ISC proliferation (Fig. [142]3n–r). Thus, the truncated IDR peptide BuGZ^C inhibited ISC proliferation by disrupting the phase separation of BuGZ, and BuGZ^CS attenuated the peptide interference of BuGZ coacervation and ISC proliferation, which confirmed that BuGZ regulated the ISC proliferation based on its phase separation property. BuGZ affects gut repair and longevity Previous studies have reported that the misregulation of ISCs leads to a significant decrease in digestive functions in aging Drosophila^[143]19,[144]30. This, in turn, reduces the lifespan of Drosophila^[145]31. Since BuGZ level increased in ISCs upon aging, we explored whether BuGZ elevation and its phase separation promoted Drosophila intestine aging. As expected, overexpressing BuGZ^FL in ISCs reduced the food intake (Supplementary Fig. [146]4a, c), disrupted the gastrointestinal acid-base homeostasis (Supplementary Fig. [147]4a, d), and inhibited excretion (Supplementary Fig. [148]4b, e) in young flies. However, these defects in Drosophila overexpressing BuGZ^13S (which shows diminished property of BuGZ LLPS) were not as severe as in Drosophila overexpressing BuGZ^FL (Supplementary Fig. [149]4a–e). Similar to the effects of BuGZ^C or BuGZ^CS on BuGZ phase separation and ISC proliferation (Fig. [150]3m–r), the effect of BuGZ^C on alleviating gastrointestinal acid-base homeostatic disruption, reduction of food intake, and suppression of excretion was stronger in young overexpressing BuGZ^FL flies or in aged flies than those overexpressing BuGZ^CS (Supplementary Fig. [151]4a–h). Furthermore, BuGZ depletion significantly reversed the decline of intestinal digestive functions in aged Drosophila (Supplementary Fig. [152]4a, b, f–h). Next, we analyzed whether BuGZ or its phase separation regulated Drosophila lifespan. BuGZ RNAi in the esg^+ cells extended the lifespan of Drosophila after eclosion under normal conditions (Supplementary Fig. [153]4i). Overexpression of BuGZ^FL in ISCs effectively shortened Drosophila longevity, whereas BuGZ^13S overexpression had fewer effects on reducing the Drosophila lifespan (Supplementary Fig. [154]4i). Additionally, overexpressing BuGZ^C peptides prolonged the lifespan of Drosophila with or without co-expressing BuGZ^FL more significantly than BuGZ^CS (Supplementary Fig. [155]4j). Since the integrity of the epithelial barrier and length of the midgut were associated with gut turnover^[156]32,[157]33, we assessed the integrity and length of the intestine in BuGZ^C/CS overexpressed ISCs. Armadillo immunostaining assay, which was used to test the integrity of gut epithelium^[158]33, indicated that overexpression of BuGZ^C induced unrecoverable injury to the intestinal epithelium (Supplementary Fig. [159]4k), which also resulted in shortened length of the midguts (Supplementary Fig. [160]4l, m). Additionally, consistent with BuGZ RNAi (Supplementary Fig. [161]4n), overexpression of BuGZ^C caused higher mortality following BLM-induced chronic injury (Supplementary Fig. [162]4o). Besides, BuGZ^CS showed compromised effects on the intestinal integrity, length and lifespan when compared with BuGZ^C (Supplementary Fig. [163]4k–m and Supplementary Fig. [164]4o). Based on these findings, we concluded that BuGZ phase separation played a crucial role on promoting intestinal integrity during gut repair. Thus, we showed that BuGZ and its phase separation affected the lifespan and gut repair of Drosophila, mediated by gut homeostasis (Supplementary Fig. [165]4p). BuGZ promotes ISC division by YT521-B Previous studies showed a strong relationship between RNA-associated proteins and BuGZ^[166]34,[167]35, we noticed that BuGZ showed strong interactions of BuGZ with RNA-associated proteins, especially with m^6A-related proteins in ESCs, inferring that m^6A-related proteins might be involved in the physiological functions of BuGZ in stem cells (Supplementary Fig. [168]5a). To investigate the underlying mechanism by which BuGZ regulates the proliferation of ISC, we performed a genetic screen with m^6A-associated genes to uncover the potential genes that could rescue BuGZ RNAi phenotype in regulating the ISC proliferation after gut injury (Supplementary Fig. [169]5b). We found that YT521-B (m^6A reader) RNAi rescued the suppressed ISC proliferation in BuGZ depletion Drosophila after BLM-induced injury (Fig. [170]4a–c). Furthermore, inhibiting YT521-B expression restored the disrupted ISC proliferation in BuGZ-null MARCM clones (Fig. [171]4d, e), and overexpression of YT521-B diminished ISC hyperproliferation caused by BuGZ overexpression (Fig. [172]4f–h). Both depletion and overexpression of YT521-B did affect its expression level (Supplementary Fig. [173]5c). Consistently, depletion of YT521-B in ISCs using esg^TS increased pH3^+ cells and esg^+ cells in the midguts of young or injured Drosophila (Supplementary Fig. [174]5d–f and Fig. [175]4a–c). YT521-B-depleted MARCM clones were bigger than the control clones (Fig. [176]4d, e). Overexpression of YT521-B had no effect on regulating the proliferation of ISC in young Drosophila (Fig. [177]4f–h) but inhibited ISC hyperproliferation in old or injured Drosophila (Supplementary Fig. [178]5g–i). Fig. 4. BuGZ facilitates Drosophila ISC proliferation via m^6A reader YT521-B. [179]Fig. 4 [180]Open in a new tab a–c Expression of YT521-B^RNAi promotes the proliferation of ISCs and rescues the defect of ISCs proliferation caused by BuGZ depletion after injury in esg^+ cells. Immunofluorescence images of esg^+ cells (a). Ratio of esg^+ cells to DAPI cells (b, from left to right are 29, 33, 35, 29 views). Number of pH3^+ cells per midgut (c, from left to right are 29, 25, 28, 19 guts). GFP indicates esg^+ cells (green). Bars are mean ± SD, Two-tailed unpaired Student’s t-test. d, e Immunofluorescence images of MARCM clones (green, outlined by white dotted lines) (d). Cell numbers per clone (e, from left to right are 184, 253, 123, 122 clones, bars are mean ± SD, Two-tailed unpaired Student’s t-test.). GFP indicates ISCs (green). f–h Overexpression of YT521-B significantly restrains the hyperproliferation of ISCs caused by BuGZ^FL-overexpressing. Representative images of esg^+ cells (f). Ratio of esg^+ cells to DAPI cells (g, from left to right are 30, 21, 25, 30 views). Number of pH3^+ cells per midgut (h, from left to right are 11, 15, 27, 21 guts). GFP indicates esg^+ cells (green). Bars are mean ± SD, Two-tailed unpaired Student’s t-test. i Percentage of the ratio of flies of eating to each indicated genotypes of young (7D) flies. Error bars show the SD of three independent experiments. Two-tailed unpaired Student’s t-test. j Percentage of the intestinal homeostasis categories from flies with indicated genotypes. Error bars show the SD of three independent experiments. Two-tailed unpaired Student’s t-test. k Excretion of Drosophila treated with Bromophenol blue from young (7D) flies with indicated genotypes. Tests were repeated as three independent experiments. Two-tailed unpaired Student’s t-test. l Percentage of survival of adults under esg^TS. (Control: n = 199 flies; YT521-B^RNAi: n = 364 flies; BuGZ^RNAi: n = 231 flies; BuGZ^RNAi; YT521-B^RNAi: n = 210 flies). Tests were repeated as three independent experiments. Statistical significance among genotypes was calculated with a chi-square log-rank test. Scale bars represent 25 μm. The area of the view size is 3.4 × 10^4 μM^2. Source data are provided as a Source Data file. In addition, inhibiting YT521-B expression disrupted the intestinal digestive functions in young Drosophila, while YT521-B overexpression rescued the intestinal digestion defects caused by the overexpression of BuGZ in ISCs (Fig. [181]4i–k). Moreover, YT521-B RNAi of the ISCs decreased the lifespan and augmented the mortality of BuGZ-depleted Drosophila with aging (Fig. [182]4l). Thus, YT521-B acted as the downstream regulator of BuGZ to regulate ISC proliferation, intestinal function, and longevity of Drosophila. BuGZ prevents YT521-B transcription Since BuGZ was shown to function in nuclei as a transcription factor^[183]36, we explored whether BuGZ could affect the transcription of YT521-B. RT-qPCR analyses using sorted esg^+ cells showed that the mRNA level of YT521-B increased in BuGZ-depleted esg^+ cells (Supplementary Fig. [184]6a). Western blotting analyses further indicated that inhibiting BuGZ in ISCs upregulated the YT521-B protein level (Supplementary Fig. [185]6b). Accordingly, the mRNA and protein levels of YT521-B in ISCs decreased in aged Drosophila, with the increase of BuGZ protein level (Supplementary Fig. [186]6c, d). To verify the roles of BuGZ and its phase transition in controlling the transcription of YT521-B, we first observed the YT521-B mRNA level in BuGZ^FL and BuGZ^13S overexpressed ISCs. The results demonstrated that the overexpression of BuGZ^FL, in contrast to BuGZ^13S, inhibited the mRNA level of YT521-B (Supplementary Fig. [187]6e). Besides, BuGZ^C overexpression increased the YT521-B mRNA level upon gut injury, whereas BuGZ^CS overexpression showed compromised effect on prompting YT521-B expression level in relative to BuGZ^C (Supplementary Fig. [188]6f). Moreover, we generated a transgenic fly (YT521-B-Luciferase), carrying a luciferase sequence with a promotor region of YT521-B, to sort out the esg^+ cells to perform the following experiments (Supplementary Fig. [189]6g). We found that BuGZ RNAi of ISCs in aged Drosophila increased the transcription activity of the YT521-B promotor (Supplementary Fig. [190]6h). Conversely, overexpression of BuGZ^FL but not BuGZ^13S suppressed the transcription activity of the YT521-B promotor in ISCs of young Drosophila (Supplementary Fig. [191]6h). Additionally, our Chip-qPCR data indicated that BuGZ^FL exhibited enhanced binding to the YT521-B promoter in contrast to BuGZ^13S (Supplementary Fig. [192]6i). Meanwhile, BuGZ^C overexpression suppressed the binding of the YT521-B promoter to BuGZ in Flag-BuGZ knock-in flies under BLM treatment, whereas BuGZ^CS overexpression displayed diminished effect on attenuating the binding of BuGZ to the YT521-B promotor when compared with BuGZ^C (Supplementary Fig. [193]6j). Thus, these findings revealed BuGZ condensate inhibits YT521-B transcriptional by promoting DNA binding. BuGZ-YT521-B axis regulates MAPK pathway To identify the downstream pathway by which the BuGZ-YT521-B axis regulated ISC proliferation, RNA-sequencing analyses were performed using Drosophila midguts overexpressing BuGZ in esg^+ cells. The mitogen-activated protein kinase (MAPK) signaling pathway was detected using the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis (Supplementary Fig. [194]7a), which was reported previously to regulate ISC proliferation and self-renewal^[195]37,[196]38. Multiple typical regulators that positively controlled the MAPK signaling pathway and ISC proliferation were upregulated in Drosophila overexpressing BuGZ (Supplementary Fig. [197]7b). We found that active MAPK signaling by overexpressing activated versions of EGFR (UAS-EGFR^CA, activated form of epidermal growth factor receptor) or Ras85D (UAS-Ras85D, Ras oncogene at 85D) accelerated the disrupted ISC proliferation in BuGZ-null MARCM clones (Supplementary Fig. [198]7c, d) and MAPK signaling inhibition by expressing a dominant-negative version of EGFR (UAS-EGFR^DN) prevented the ISC hyperproliferation caused by YT521-B depletion (Supplementary Fig. [199]7e–g). To study the detailed mechanism of how YT521-B modulated the MAPK pathway, we examined the ERK activity assessed by immunostaining against the double phosphorylated ERK kinase (dpERK), which behaved as the key downstream target of the MAPK pathway^[200]39. Our data showed that YT521-B overexpression inhibited the ERK activation caused by BuGZ overexpression (Supplementary Fig. [201]7h). BuGZ depletion in ISCs resulted in a significant decrease of dpERK signial in ISCs (Supplementary Fig. [202]7i), while YT521-B RNAi restored the down-regulation of dpERK in ISCs caused by BuGZ depletion (Supplementary Fig. [203]7i). We also investigated the impact of BuGZ and YT521-B on the mRNA expressions of Argos (aos), Kekkon 1 (kek1), and Sprouty (sty) in sorted esg^+ cells, all of which were reported to act as downstream targets of MAPK signaling pathway^[204]37,[205]40–[206]42. We found that the overexpression of BuGZ^FL augmented the mRNA levels of kek1, sty, and aos (Supplementary Fig. [207]7j). Accordingly, the overexpression of YT521-B reversed the increased mRNA levels of kek1, sty, and aos induced by BuGZ^FL overexpression (Supplementary Fig. [208]7j). Moreover, YT521-B RNAi rescued the reduction of aos, kek1, and sty mRNA levels caused by BuGZ RNAi during gut regeneration (Supplementary Fig. [209]7k). Thus, BuGZ-YT521-B functioned as the upstream regulator of the MAPK signaling pathway to modulate ISC proliferation in Drosophila (Supplementary Fig. [210]7l). YT521-B promotor enhances LLPS of BuGZ Recent studies have suggested that the ‘transcriptional condensates’ contain TFs, cofactors, and RNA Pol II, assembled at the enhancer and promoter regions of key cell-identity genes^[211]8. However, it is still unknown whether the promotor can promote the phase separation of its binding transcription factor and whether the promotor condensates function in cell or organism development. To address this issue, we added three different fractions of the YT521-B promotor regions (Supplementary Fig. [212]8a) into the BuGZ droplets in vitro. We found that three fragments upstream of the YT521-B gene, especially the first 1 kb fraction (1K^1), enhanced the formation of BuGZ droplets (Supplementary Fig. [213]8b, c). We also identified a 100 bp DNA fragment within 1K^1 (P^8) that strongly promoted BuGZ phase separation (Supplementary Fig. [214]8a, d, g, h). Moreover, the Chip-qPCR experiment indicated that BuGZ directly interacted with P^8 in young or old flies, and the interaction between BuGZ and P^8 was enhanced upon aging (Fig. [215]5a). To further verify the role of P^8 in BuGZ phase separation, we performed in vitro purification of the Drosophila BuGZ^ΔZinc domain (with depleted the zinc finger), which was unable to bind DNA in our previous study^[216]27 (Supplementary Fig. [217]8e). The droplet formation of BuGZ^Δzinc relied on its protein concentration but not the DNA fragment P^8 (Supplementary Fig. [218]8f–h). Additionally, we generated a transgenic fly, BuGZ^ΔZinc, to further elucidate the function of the DNA binding property of BuGZ in its phase separation and proliferation of ISCs. The in situ hybridization assay showed that, unlike BuGZ^ΔZinc, BuGZ^FL protein specifically co-localized with the DNA fragment P^8 (Fig. [219]5b). BuGZ^ΔZinc overexpression in ISCs of young Drosophila showed less induction of ISC proliferation and attenuated puncta formation compared with BuGZ^FL overexpression (Fig. [220]5c–i). To further explore the function of the P^8 to BuGZ phase separation, we performed the FRAP assay to observe the dynamics of BuGZ droplets with or without adding P^8. The fluorescence recovery rate after photobleaching showed the DNA fragment P^8 inhibited the dynamics of BuGZ condensate (Supplementary Fig. [221]8i–l). Thus, beyond the simple physical binding, the YT521-B promotor might recruit the BuGZ condensate to stably bind to the transcription region to constantly exert its transcriptional function. Fig. 5. The binding of YT521-B promotor to BuGZ accelerates its coacervation to control the proliferation of ISCs. [222]Fig. 5 [223]Open in a new tab a The interaction between BuGZ and P^8 fragment by Chip-qPCR in the young or old guts of transgenic BuGZ-FLAG fly. The results demonstrated that the interaction between BuGZ and P^8 was enhanced upon aging. b The in situ hybridization assay shows that, compared with BuGZ^ΔZinc, BuGZ^FL protein exerted stronger behavior of condensation co-located with the DNA fragment P8. The experiments were independently repeated three times, yielding similar results. c–e BuGZ^Δzinc does not affect the proliferation of ISCs. Immunofluorescence images of control (UAS-LacZ), BuGZ^FL-HA overexpressing, BuGZ^Δzinc-HA overexpressing esg^+ cells (c). Ratio of esg^+ cells to DAPI cells (d, 31 views). Number of pH3^+ cells per midguts (e, Control: n = 20 guts; UAS-BuGZ^FL: n = 20 guts; UAS-BuGZ^Δzinc: n = 15 guts). GFP indicates esg^+ cells (green). f–h Overexpression of BuGZ^Δzinc shows smaller puncta than BuGZ^FL-overexpressing in esg^+ cells. BuGZ foci (red, outlined by white dotted lines) is labeled by BuGZ antibody (f). Quantification of the fluorescence intensity (g), area (h), number (i) of BuGZ puncta. (g, UAS-BuGZ^Δzinc: n = 108 guts; UAS-BuGZ^FL: n = 204 cells. h, UAS-BuGZ^Δzinc: n = 105 areas; UAS-BuGZ^FL: n = 101 areas. i, UAS-BuGZ^Δzinc: n = 124 cells; UAS-BuGZ^FL: n = 97 cells). GFP indicates esg^+ cells (green). DAPI stained nuclei (blue). Scale bars represent 5 μm (b, c), 25 μm (f). The area of the view size is 3.4 × 10^4 μM^2. Bars are mean ± SD. P-values were calculated by two-tailed, unpaired Student’s t-test. Source data are provided as a Source Data file. Ime4 and Mettl14 suppress LLPS of BuGZ Among the candidate genes that could abrogate the inhibition of ISC proliferation caused by BuGZ depletion after gut injury, beyond YT521-B, the depletions of another two m^6A regulators Ime4 and Mettl14 also restored the reduction of ISC number with BuGZ RNAi (Supplementary Fig. [224]5a, b and Supplementary Fig. [225]9a–e). The accumulation of esg^+ cells and pH3+ cells in the midguts of young or injured Drosophila with either Ime4 or Mettl14 RNAi in ISCs showed that both Ime4 and Mettl14 inhibited ISC proliferation (Supplementary Fig. [226]9c–h). MARCM analysis further demonstrated that either Ime4 or Mettl14 RNAi rescued the suppressed ISC proliferation in BuGZ-null MARCM clones (Supplementary Fig. [227]9i, j). Ime4 or Mettl14 RNAi MARCM clones grew bigger than the control, further manifesting the effect of Ime4 or Mettl14 on suppressing the proliferation of ISC (Supplementary Fig. [228]9i, j). Overexpression of either Ime4 or Mettl14 decreased the ISC proliferation in old and injured, but not young Drosophila (Supplementary Fig. [229]9a, b, k–m). In conclusion, Ime4 and Mettl14 also counteracted the effect of BuGZ on the proliferation of ISC beyond YT521-B. Different from YT521-B, BuGZ depletion in sorted esg^+ cells did not affect the transcription level of Ime4 or Mettl14 mRNA (Supplementary Fig. [230]9n). However, we found that BuGZ interacted with Ime4 or Mettl14 protein, but not YT521-B (Supplementary Fig. [231]9o–q). To further explore the age-dependent interaction between Ime4/Mettl14 and BuGZ, we performed the immunoprecipitation assay by precipitating FLAG-BuGZ in midguts for endogenous Ime4 or Mettl14. Compared with young midgut, FLAG-BuGZ pulled down less Ime4 or Mettl14 in aged midgut when loading the same level of precipitated FLAG-BuGZ. Since BuGZ level increased, but Ime4/Mettl14 level showed no difference upon aging, our binding assay proposed that protein level enhancement of BuGZ might resulted in the reduced interaction between BuGZ and Ime4/Mettl14 in Drosophila midgut upon aging (supplementary Fig. [232]9r). To further demonstrate the mechanism of the interaction of Ime4/Mettl14 and BuGZ, we performed Co-Ip experiments in 293HEK cells. The results showed BuGZ^Δzinc did not interact with Ime4 or Metll14 (Supplementary Fig. [233]9s). Moreover, purified Ime4 or Mettl14 diminished the droplet formation of BuGZ but not BuGZ^Δzinc in vitro (Supplementary Fig. [234]9t, u), suggesting that both P8 and Ime4/Metll14 bound to the zinc finger domain of BuGZ, and P8 and Ime4/Mettl14 might regulate BuGZ condensation with the same mechanism. Additionally, overexpressing either Ime4 or Mettl14 in ISCs suppressed the formation of BuGZ puncta without affecting its protein level in BuGZ^FL-overexpressing ISCs (Fig. [235]6a–d). Depletion of either Ime4 or Mettl14 in the ISCs enhanced BuGZ puncta formation in Drosophila overexpressing BuGZ^FL (Fig. [236]6e–h). In addition, overexpression of either Ime4 or Mettl14 diminished the ISC hyperproliferation caused by BuGZ^FL overexpression (Fig. [237]6i, j). Then, we further found depletion of either Ime4 or Mettl14 in esg^+ cells reduced the YT521-B mRNA levels (Fig. [238]6k), whereas overexpressing either Ime4 or Mettl14 enhanced YT521-B mRNA levels in BuGZ^FL overexpressing esg^+ cells (Fig. [239]6l). Fig. 6. Ime4 and Mettl14 suppress ISC proliferation by inhibiting LLPS of BuGZ. [240]Fig. 6 [241]Open in a new tab a–c BuGZ foci is inhibited by Ime4 or Mettl14 overexpression. Images of esg^+ cells (a). BuGZ foci labeled by BuGZ antibody. Fluorescence intensity (b), size (c), number (d) of BuGZ puncta. (b, from left to right are 45 cells, 55 cells, 69 cells. c, from left to right are 216, 55, 69 cells. d, from left to right are 204, 204, 209 cells). GFP indicates esg^+ cells (green). e–h LLPS of BuGZ is promoted by Ime4 or Mettl14 depletion. Images of esg^+ cells (e). BuGZ foci are labeled by BuGZ antibody. Fluorescence intensity (f), size (g), number (h) of BuGZ puncta (f, from left to right are 61, 63, 64 cells. g, from left to right are 200, 203, 201 puncta. h, from left to right are 213, 213, 213 cells). GFP indicates esg^+ cells (green). i, j Hyperproliferation of ISCs caused by BuGZ^FL overexpression is inhibited by overexpressing Ime4 and Mettl14 (h). Ratio of esg^+ cells to DAPI cells (i, from left to right are 15, 24, 13 views). Number of pH3^+ cells per midgut (j, from left to right are 24, 22, 21 guts). k Ime4/Mettl14 depletion results in elevated YT521-B mRNA levels in sorted esg^+ cells (n = 3 biologically independent experiments). l Ime4 or Mettl14 overexpressing rescues YT521-B transcription suppression caused by BuGZ overexpression in sorted esg^+ cells (n = 3 biologically independent experiments). m Model of mechanism: how BuGZ modulates ISC proliferation. LLPS of BuGZ inhibits YT521-B transcription to promote ISC proliferation by MAPK pathway. Additionally, both Ime4 and Mettl14 regulate YT521-B transcription by inhibiting BuGZ phase separation in ISCs, while in turn the promotor of YT521-B promotes the LLPS of BuGZ.DAPI stained nuclei (blue). Scale bars represent 5 μm. Bars are mean ± SD. P-values were calculated by two-tailed, unpaired Student’s t-test. Source data are provided as a Source Data file. Therefore, we proposed that two m^6A-related genes, Ime4 and Mettl14, inhibited BuGZ phase separation in Drosophila ISCs, to attenuate the transcription inhibitory property of BuGZ, promote the transcription of m^6A reader YT521-B, the downstream of BuGZ, and prevent the proliferation of ISCs through the MAPK pathway (Fig. [242]6m). Discussion Due to the impediments of observing the protein condensation processes in vivo and difficulties in verifying its physiological functions^[243]2,[244]4,[245]7,[246]9,[247]10,[248]43,[249]44, the functions of protein phase separation in vivo, especially in tissue homeosltasis, organ regeneration, and individual aging, are largely unknown. Based on our investigation, the functions of BuGZ coacervation in regulating ISC activation and proliferation during aging and gut repair, imply that protein phase separation participates in tissue homeostasis, regeneration, and aging processes mediated by ASCs. Accordingly, we find that inhibiting BuGZ phase transition in ISCs of aged Drosophila improves intestinal functions and prolongs the lifespan of Drosophila, revealing that manipulating protein phase transition may delay or antagonize ASC-associated aging. Moreover, our findings reveal the physiological significance of the BuGZ condensate formation in DNA binding and transcriptional regulation in aging and gut repair and provide insights into the regulatory mechanisms underlying the BuGZ-mediated modulation of gene expression. Additionally, we report a mechanism that another cis-regulatory element (CRE) of genes the promotor facilitates the compartmentalization of its binding transcriptional condensate beyond enhancer and super-enhancer, other CREs including silencer and insulator may also possess feedback on regulating the coacervation behavior of their associated transcription factors. Since RNA m^6A modification behaves as the most common nucleotide modification of the eukaryotic mRNAs, previous studies have demonstrated that mRNA m^6A modification widely affects various aspects of metabolism, homeostasis, ontogenesis, and pathema^[250]45–[251]49. One previous study indicates that m^6A reader YTHDF1 maintains stem cell traits during regeneration and tumorigenesis in intestines by mediating Wnt activation. In addition, since YTHDF1 upregulation is observed in both human and mouse intestinal cancer, YTHDF1 may behave as a biomarker for CRC^[252]21. Recently, another study uncovered that the m^6A writer Mettl14, is required for modulating the homeostatic self-renewal in colonic stem cells. Mettl14 depletion in mouse colon results in colonic stem cell apoptosis, mucosal barrier dysfunction and severe colitis by modulating the NF-κB pathway^[253]22. In addition, previous reports indicated Mettl14-mediated GsdmC N6-adenomethylation is essential for the survival of Lgr5^+ intestinal stem cells and the maintenance of normal colonic epithelial regeneration^[254]23. However, whether and how m^6A regulators function in ISC-mediated gut regeneration upon injury and organ aging, remains largely unexplored. In our study, by systematically investigating the function of YT521-B in ISCs during aging in Drosophila, we find that m^6A reader YT521-B plays an indispensable role in the ISC proliferation, gut homeostasis and lifespan. Under the transcriptional regulation of BuGZ, YT521-B functions as the upstream regulator of the EGFR/RAS/MAPK signaling pathway to mediate ISC proliferation. Moreover, BuGZ coacervation negatively regulates the mRNA transcription of YT521-B, whose promotor reversely enhances the phase separation of BuGZ. Meanwhile, we validate that m^6A writers, Ime4 and Mettl14, inhibit the proliferation of ISC by suppressing the phase separation of BuGZ to regulate the transcription of YT521-B. Thus, our data reveals the relationship between m^6A regulators and phase separation in controlling ISC proliferation during gut regeneration and aging. Meanwhile, we report a mechanism that controls the candidate TF coacervation by the downstream promotor and a way of probing the roles of m^6A regulators in phase transition and regulation of ISCs. Additionally, our study not only deciphers a new regulatory mechanism of m^6A reader YT521-B transcription but also a new function of m^6A writer (Ime4, Mettl14) or reader (YT521-B) in ASCs homeostasis and aging. Despite previous studies showing that m^6A writer Mettl14 and reader YTHDF1 separately facilitate stem cell maintenance and regeneration in the m^6A-dependent manner^[255]21–[256]23, some other studies propose that m^6A regulators exert some physiological functions independent of their m^6A modification activities. The m^6A writer METTL3 plays a catalytic-independent role in recruiting eIF3 to the translation initiation complex to regulate the translation of oncogenic transcripts including EGFR and TAZ. This activity also enhances the PES1 mRNA translation in the cytoplasm of chronic myeloid leukemia cells and amplifies p53 signaling in response to cellular stress^[257]50–[258]55. Another m^6A writer, METTL16, also interacts with eIF3 to enhance mRNA translation during tumorigenesis in an m^6A-independent manner^[259]56. Thus, future studies should evaluate whether the roles of m^6A regulators (Ime4, Mettl14, and YT521-B) on ISC proliferation via the EGFR signaling pathways are mediated by the m^6A modification. Future studies should also determine whether BuGZ and its phase separation act as the upstream regulator of m^6A modification to affect m^6A levels during gut regeneration and aging. Recently, the core m^6A reader, YTHDF1/3, has been reported to promote stress granule formation through its phase transition^[260]57,[261]58. Phase separation of m^6A reader YTHDF1 promotes mRNA degradation by interacting with AGO2^[262]59, while the m^6A reader YTHDF2 undergoes m^6A-mediated phase separation in mESCs^[263]60. Additionally, the phase separation of the m^6A writer, METTL3, regulates the dynamic assembly of the mRNA m^6A methyltransferase complex^[264]61. The predicted IDR domains within the m^6A writers Ime4 (Drosophila ortholog of METTL3) and Mettl14 (data not shown) suggest that Ime4 and Mettl14 may adjust the ISC proliferation via their property of phase separation, and their interferences in BuGZ coacervation also may rely on the interactions with BuGZ through their phase transition. Methods Cell lines HEK293 cells (ATCC, #CRL-3216) were cultured at 37 °C, 5% CO[2] in Dulbecco’s Modified Eagle Medium (DMEM, Gibco) supplemented with 10% fetal bovine serum (FBS, Gibco) and 5% antibiotics (penicillin/streptomycin, Invitrogen). Spodoptera frugiperda (Sf9, ATCC, #CRL-1711) cells used for the recombinant virus were grown in semi-suspension in Grace’s Insect Medium (Supplemented) supplemented with 10% FBS at 27 °C. High Five^TM (Hi5, from Sinobiological company) cells used for recombinant protein expression were grown in suspension in SIM HF Expression Medium at 27 °C, 150 rpm. Drosophila strains and fly genetics The following Drosophila strains were used in this paper [obtained from the Bloomington Drosophila Stock Center (BDSC)]: w^1118; PBac{BuGZ-GFP.FPTB}VK00033 (BDSC:67713), 386Y-GAL4 line: w*; P{w [+mW.hs] =GawB}386Y (BDSC:25410), MARCM line: w^1118; P{ry[+t7.2]=neoFRT}40 A/CyO;P{ry[+t7.2]=ey-FLP.N}6, ry[506] (BDSC:8212), BuGZ RNAi: y^1 v^1; P{TRiP.JF02830}attP2 (BDSC:27996), UAS-Ime4 line: y^1 w*; P{UAS-Mettl3.HA.H}attP40/CyO (BDSC:77882), UAS-YT521-B line: y^1 w*; P{UAS-Ythdc1.HA}attP40 (BDSC:77884), UAS-EGFR-DN line: y^1 w*; P{UAS-EGFR.DN.B}29-77-1; P{UAS-EGFR.DN.B}29-8-1 (BDSC:5364), UAS-EGFR-CA line: w*; P{Egfr.2.A887T.UAS}8-2 (BDSC:9533), UAS-LacZ line: w^*; P{w[+mC]=UAS-lacZ.Exel}2 (BDSC:8529), UAS-mCherry line: w*; P{w[+mC]=UAS-mCherry.NLS}2; MKRS/TM6B, Tb^1 (BDSC:38425). BuGZ RNAi: P{[265]KK109387}VIE-260B (VDRC: v104498), Ime4 RNAi: w^1118; P{GD9882}v20969/TM3 (VDRC: v20969), Mettl14 RNAi: w^1118; P{GD16300}v48560 (VDRC: v48560) were obtained from Vienna Drosophila Resource Center (VDRC). YT521-B RNAi: THU1532, Fl(2)d RNAi: TH02871.N; nito RNAi: THU0697; Vir RNAi: TH02977.N; CG6422 RNAi: TH03062.N, MARCM line: hsFLP, tub-GAL4, UAS-GFP-NLS/FM7; tub-Gal80, FRT40A/CyO (TB00132) were obtained from Tsinghua Fly Center. esg-GFP (Carnegie Protein Trap line esg^CB02017), Flipout line: yw, hsFLP; Act.FRT-CD2-FRT.GAL4, UAS-GFP^S65T/CyO, UAS-Ras85D line: w^1118;UAS-Ras85D.V12 were obtained from Allan Spradling. esg-lacZ (esg^M5-4) was obtained from Mark Van Doren. NRE-lacZ, esg^TS-GAL4 line: esg-GAL4, UAS-GFP, tub-Gal80^TS/CyO, ISC^TS-GAL4 line: NRE-lacZ; esg-GAL4, UAS-GFP/CyO; tub-Gal80^TS, NRE-Gal80, NRE^TS-GAL4 line: NRE-GAL4, UAS-GFP, tub-Gal80^TS/CyO were obtained from Benjamin Ohlstein. Full Drosophila genotypes as they appear in each figure panel are listed in Supplementary Data [266]3. Drosophila husbandry Unless otherwise noted, fly stocks were reared on the standard cornmeal/yeast medium (the recipe for 1 liter food contains: cornmeal 50 g, yeast 18.75 g, sucrose 80 g, glucose 20 g, agar 5 g, and propionic acid 30 ml). If not specifically mentioned, flies were maintained at 25 °C and 65% humidity on a 12 h light/dark cycle. Crosses not involving conditional expression of transgenes were incubated at room temperature. Crosses involving conditional Gal80ts-dependent expression of transgenes including RNAi or gene overexpression were maintained at 18 °C until adult offspring were enclosed. Adults were kept at 18 °C for 1–3 days before they were shifted to 29 °C to turn on the GAL4 system for another 7–10 days or 30 days before dissection. For the experiment, only mated females were used on the Drosophila midguts. The w^1118 strain was used as the control. BuGZ mutant line was generated with the CRISPR/Cas9 method using a synthetic guide RNA against the first common exon of all annotated BuGZ isoforms (sgRNA target sequence (5’−3’): GTCCGGTGTACAACTTCTTG), which was injected into w^1118 embryos. After screening the offspring of the line containing sgRNA cross to the vasa-cas9 flies which express Cas9 in the germline, 7 bp deleted (BuGZ^8) and 5 bp deleted (BuGZ^3) BuGZ-null flies which result in a premature stop codon were generated by sequencing confirmed. We did not see a difference between BuGZ^8/+ or BuGZ^3/+ flies and w^1118 flies, indicating that BuGZ^8 and BuGZ^3 are recessive mutations, and most time we used BuGZ^8 flies for the following experiments. Full indicated genotypes of flies used in this paper were listed in Supplementary Data [267]3. Generation of transgenic fly lines Transgenic lines that we made house including: UAS-dBuGZ^FL-HA, UAS-dBuGZ^13S-HA, UAS-dBuGZ^C-HA, UAS-dBuGZ^CS-HA, UAS-dBuGZ^Δzinc-HA, UAS-dMettl14-HA. The final plasmids were cloned and verified by sequencing, then injected by UniHuaii Corporation (Zhuhai, China). Briefly, cDNA of dBuGZ^FL (isoform B from Flybase database), dBuGZ^13S, dBuGZ^Δzinc, dBuGZ^C, dBuGZ^CS, dMettl14 were cloned into the pEntry-3×HA vector and then subcloned into pTW vector (Gift from Allan Spradling). Primers used for these constructs are shown in Supplementary Data [268]1. Additionally, in order to observe the endogenous YT521-B transcription level, YT521-B-luciferase transgenic lines were made (Fangjing, China). To get the knock-out line for BuGZ, the synthesized sgRNA sequence was cloned into a PMD18T vector to acquire U6 promoter. After the U6 promoter and sgRNA were amplified from the PMD18T vector by PCR, the products were subcloned together into the PCR8 vector with Golden Gate assembly. Then, the U6 promotor and sgRNA products were recombined into the attB vector by LR recombination reaction to generate the sgRNA construct. The final plasmids were injected by UniHuaii Corporation (Zhuhai, China). Clonal analyses For MARCM clone analysis, we used the BuGZ mutant and FLP/FRT-mediated mitotic recombination technique. FRT40A (from Bloomington) was recombined with BuGZ mutant to produce FRT40A, BuGZ^8-null mutant, which was then crossed to yw hsFLP, tub-Gal4, UAS-nls GFP/FM7; tubGal80 FRT40A/CyO to obtain hsFLP, tub-GAL4, UAS- nls GFP/+; tub-Gal80, FRT40A/ FRT40A, BuGZ^8 flies. Crosses were kept at 25^oC. To induce clones, adult flies, after eclosion 1~3 days old, were subjected to the 37 °C water bath for 1 h heat shock. Flies were maintained at 29 °C for 24 h within 2~3 days ACI after heat shock, and then these flies were dissected and observed at 10 days ACI. For RNAi clone analysis, the FRT “Flipout (F/O)” method was used. Clones were generated by crossing hsFLP; Act.FRT-CD2-FRT.GAL4, UAS-GFP/CyO flies to the BuGZ^RNAi#1, BuGZ^RNAi#2, or W^1118 flies. Crosses were maintained at 25 °C. Then, 1~3 days old adults were subjected to the 37 °C water bath for 1 h heat shock to induce clones. After heat shock, these flies were maintained at 29 °C for 24 h within 2~3 days ACI, and then these flies were dissected and observed at 10 days ACI. FACS, RT-qPCR, and western blotting analyses As previously^[269]62, the Drosophila adult midguts (R1~R5) were dissected into ice-cold PBS prepared with diethylpyrocarbonate (DEPC) water. After removing the foregut, malpighian tubules, hindgut and ovaries, the midguts were incubated with Trypsin-EDTA (diluting 100× 0.5% Trypsin-EDTA with DEPC-PBS) solution to each sample. Dissociated samples were pelleted, following resuspended in ice-cold DEPC-PBS and sorted using a FACS Aria II sorter (BD Biosciences) after filtering with 70 μm filters. Using w^1118 midgut to set the fluorescence gate, GFP^+ cells in the midgut of corresponding RNAi or indicated genotype flies driven by esg^TS were sorted out. For each of the three biological replicates of RT-qPCR, about 100,000 esg-GFP^+ cells were sorted. Total RNA was harvested using the RNA isolation kit (Cat.No.RE-03111, FOREGENE) based on the manufacturer’s protocol. cDNA was synthesized using the PrimeScript RT reagent Kit (AG). Expression values were calculated using the 2^−ΔΔCT method and relative expression was normalized to RpL15. The expression in the control sample was further normalized to 1. Primer sequences used for qPCR are available in Supplementary Data [270]1. For each of the three biological replicates of western blotting, about 300,000 esg-GFP^+ cells were sorted. Primary antibodies used for western blotting in this study include anti-BuGZ (rabbit, 1:1000), anti-α-tubulin (rabbit, 1:2000, Cell Signaling Technology, Cat# 2125), anti-YT521-B (rabbit, 1:1000). Secondary antibodies were horseradish peroxidase-conjugated goat anti-mouse (1:5000, Jackson ImmunoResearch Labs, Cat# 115-035-174), goat anti-rabbit (1:5000, Jackson ImmunoResearch Labs, Cat# 211-032-171). RNA-seq RNA-sequencing was performed using Drosophila midguts overexpressing BuGZ in esg^+ cells. The RNA sequencing was carried out by Shanghai OE Biotech Co., Ltd. (China). The sequence platform is based on novaseq 6000 (Illumina, San Diego, US) using a 150 bp paired-end run resulting in over 20 million reads per sample. The initial quality control of the raw fastq files was performed using FastQC (v0.11.9, [271]http://www.bioinformatics.babraham.ac.uk/projects/fastqc/), and the adapter sequences were removed by Trim Galore (v0.6.7, [272]https://www.bioinformatics.babraham.ac.uk/projects/tri-m_galore/). The trimmed RNA-seq reads were aligned to the Drosophila reference sequence Ensembl build BDGP6 ([273]https://support.illumina.com/sequencing/sequencing_software/igeno -me.html) with hisat2 (v2.20^[274]63). Aligned reads were then sorted by chromosome position using SAMtools (v1.15.1, [275]https://sourceforge.net/projects/samtools/files/samtools/) and converted into bam files. Gene raw counts matrix per sample was computed using StringTie (v2.2.1, [276]https://ccb.jhu.edu/software/stringtie/). Gene symbols were annotated by Drosophila melanogaster BDGP6 from Ensembl ([277]https://support.illumina.com/sequencing/sequencing_soft-ware/igen ome.html). Differentially expressed genes were determined using DESeq2 (v1.26.0^[278]64,) with default parameters. Genes were considered differentially expressed if the absolute value of the log2 fold change was greater than 0.5 between modification (i.e., Overexpressed) and control at padj < 0.05. Downstream pathway analysis was performed via clusterProfiler (v3.14.3^[279]65,) using genes at padj < 0.05. Immunofluorescence microscopy for Drosophila tissue Midguts immunostaining was carried out as previous^[280]62, female midguts were dissected in PBS and fixed in 4% EM-grade paraformaldehyde fixation buffer (100 mM glutamic acid, 25 mM KCl, 20 mM MgSO[4], 4 mM Na[2]HPO[4], 1 mM MgCl[2], pH 7.4, 8% paraformaldehyde (Fisher Scientific, Cat# 5025997)) for 60 min at room temperature. For Delta immunostaining, dissected female guts are first fixed in fixation buffer (50% 4% paraformaldehyde plus 50% heptane) for 40 min and then fixed with methanol 10 min 3 times. For dpREK immunostaining, dissected female guts are first fixed in 8% paraformaldehyde buffer for 40 min and then fixed with methanol for 10 min at −20 °C. After 10 min washing (wash buffer: PBS plus 0.1% Triton X-100) 3 times, midguts were further blocked in 0.5% BSA (wash buffer plus 0.5% BSA) 30 min and then incubated with primary antibodies (anti-GFP, Abcam Cat# ab13970, 1:1000; anti-β-Galactosidase, Abcam Cat# ab9361,1:1000; anti-FLAG, Cell Signaling Technology Cat#14793, 1:1000; anti-phosphoHistone H3, Millipore Cat# 06-570, 1:1000; anti-Prospero, DSHB Cat# MR1A, 1:200; anti-Delta, DSHB Cat# C594, 1:100; anti-phospho-p44/42 MAPK (dpERK), Cell Signaling Technology Cat# 9101S, 1:1000; anti-Fibrillarin, ABclonal Cat# A13490, 1:200; anti-SUMO, ABclonal Cat# A2130, 1:1000; anti-γ‐H2AvD, Rockland Cat# 600‐401‐914, 1:1000; anti-Hp1α, abcam Cat# ab77256, 1:1000; anti-H3-k27, Abclonal Cat# A2363; anti-Armadillo, DHSB Cat# N2 7A1, 1:100; anti-BuGZ, self-preparing, 1:1000.) diluted in the wash buffer overnight at 4 °C. The following day, after washing 10 min 3 times, the tissues were incubated with secondary antibodies (Alexa 488, Thermo Fisher Cat# A-11001, Cat# A-11034, Cat# A-11039; Alexa 568, Thermo Fisher Cat# A-11004, Cat# A-11011, and Alexa 647, Thermo Fisher Cat# A-21235, Cat# A-21245, 1:2000) and DAPI (1 µg/ml) with for 2 h at room temperature. Three 10-min-washing steps were performed and midguts were mounted onto slides to observe using microscopy. To carry out the temperature-dependent culture experiment in vitro, midguts were dissected in PBS at 25 °C. For 4 °C, the dissected guts were cultured in ice-cold Schneider’s Drosophila Medium (Gibco) plus 5 µM MG132 at 4 °C for 1 h. For recovery from 4 to 25 °C, midguts incubated at 4 °C were shifted to room temperature for the next 1 h. After three different conditions treatments, midguts were fixed in fixation buffer and immunostained as mentioned above. Generation of antibodies Antibodies against dBuGZ and dYT521-B were generated at ABclonal. For anti-dBuGZ sera, rabbit was immunized with a 122 amino-acid-long peptide (1–121 amino acids (AA)); for anti-YT521-B sera, rabbit was immunized with a 276 amino-acid-long peptide (29–304 amino acids (AA)). All serums were affinity-purified using peptide antigens crosslinked to sepharose columns. DNA in situ hybridization For in situ hybridization, midguts were dissected in PBS and transferred to 4% formaldehyde for 10 min. After washing midguts 3 times in PBS, permeabilization was performed by using 0.5% Triton X-100 in PBS for 5 min at 4 °C, following 3 times PBS washes. Midguts were then incubated with preheated pre-hybridization buffer (RIBOBIO, [281]C10910) at 37 °C for 30 min. After removing the pre-hybridization buffer, add probe hybridization mixture (100 μl of FISH Hybridization Buffer (RIBOBIO, [282]C10910), 15 μl of FISH probe) to fully soak midguts, denatured at 78 °C for 5 min and transferred to 37 °C in the dark overnight. After removing the probe hybridization mixture, midguts were washed with washing buffer I (4×SSC, 0.1%Tween-20) 3 times, washing buffer II (2×SSC) 1 time, washing buffer III (1×SSC) 1 time, successively. After washing midguts 3 times in PBS, fixed with 4% PFA in PBS for another 10 min and washed 3 times in PBS, midguts were then incubated with the indicated primary antibody. Midguts were washed with PBS 3 times, followed by incubation with secondary antibody and DAPI for 2 h. Three 10-min washing steps were performed and midguts were mounted onto slides for observation. DNA FISH probes were custom-designed and generated by Wuhan servicebio technology CO to target the YT521-B promotor. Chip-qPCR Chromatin was immunoprecipitated using a variation of the protocol described as the protocol of SimpleChIP® Plus Enzymatic Chromatin IP Kit (Magnetic Beads, cat #9005). In brief, approximately 50 corresponding genotype flies were grinded in liquid nitrogen and then were immediately fixed with 1% formaldehyde in Schneider’s Drosophila Medium (Gibco). After filtering the sample, the cells were washed twice with ice-cold PBS, pelleted, and resuspended in Buffer A. After centrifuging, samples were resuspended in Buffer B. Cells were sonicated with a Ningbo Scientz Biotechnology Sonifier for 9 s/9 s 10 cycles at 30% power. After centrifuging at 13,000×g for 10 min, and the samples were diluted 10-fold in ChIP dilution buffer. The sample was incubated at 4 °C 4 h with antibodies against FLAG (1:50, Cat # 14793S)/ HA (1:50, Cat # 3724S) or Normal Rabbit IgG (1:50, Cat #2729). Complexes were precipitated with ChIP-Grade Protein G Magnetic Beads (Cat #9006). Beads were then washed sequentially with low-salt immune complex wash, high-salt immune complex wash (DNA wash buffer plus with NaCl). Immunoprecipitated chromatin was eluted in ChIP Elution Buffer, incubated at 65 °C for 30 min and then treated with proteinase K and 5 M NaCl for 6 h. At last, DNA was purified by Purification of DNA by centrifugation column as protocol. ChIP (enriched) and control (negative control) DNA samples were amplified by SimpleChIP® Universal qPCR Master Mix (Cat #88989). TUNEL assay To detect apoptotic cells by TUNEL assay, female midguts were dissected in PBS and fixed with 4% paraformaldehyde in PBS for 24 h at 4 °C following washing with PBST (PBS with 0.1% Triton X-100) and immunostaining based on the in situ Cell Death Detection Kit manufacturer’s protocol (Roche, Cat# 11684795910). EdU labeling For EdU immunostaining, midguts were dissected in PBS and incubated in Schneider’s Drosophila Medium with 50 µM EdU at room temperature. After 2 h, tissues were fixed as described above and stained for EdU using Cell-Light EdU Apollo567 In Vitro Kit (RIBOBIO, Cat# C10310-1) based on the manufacturer’s protocol. Bromophenol blue treatment Bromophenol blue assay was performed^[283]30,[284]66 and two categories of Drosophila midguts were observed^[285]67 as previously described. After adding 250 µl of 2% Bromophenol blue sodium (pH indicator, Sigma, B5525) to a food vial which poked 4–6 holes using a pipet tip to allow full absorption, starved 2-h flies were put into the vial. After 24 h treatment, flies were immediately dissected to acquire images. Fly excretion measurement For fly excretion measurement, as described previously^[286]68, flies were drily starved for 2 h and put into Bromophenol blue vial food for 24 h, and then the deposits on the vial wall were imaged and quantified. Midgut measurement Female Drosophila was orally administered BLM 24 h, after which guts were dissected in ice-cold 4% PBS. After dissection, the guts were mounted on slides. After being observed and imaged under fluorescence stereo microscopes (Leica M205 FA), Drosophila gut lengths were measured using LAS X software. Bleomycin and paraquat treatment Bleomycin and paraquat treatment are carried out as previously^[287]62. Briefly, 25 µg/ml bleomycin (Aladdin, B107423) or 5 mM paraquat (Aladdin, M106761) dissolved in 5% (wt/vol) sucrose was added to chromatography paper that was cut into 3.7 × 5.8 cm strips. After being starved in empty vials for 2 h, flies then were transferred into vials with bleomycin-, or paraquat-solution-saturated chromatography paper. 5% (wt/vol) sucrose was used as controls (Mock). For microscopy, female guts were dissected to observe after 24 h treatment with paraquat or bleomycin feeding. Lifespan and survival experiments For lifespan experiments, 80–100 mated female flies of the same genetics were separated and equally transferred into five vials containing the standard fly diet or standard fly diet supplement with 5 μg/ml bleomycin. Dead flies were counted and the food vial was exchanged every two or three days. The lifespan was repeated as three independent experiments. Luciferase activity assays Firefly luciferase was measured using the Dual Luciferase Reporter Assay Kit (Vazyme, China, DL101-01). 300,000 esg^+ cells were sorted and frozen immediately with liquid nitrogen. Then, detecting the luciferase signals according to the manufacturer’s protocol provided by the Dual Luciferase Reporter Assay Kit (Vazyme, Cat# DL101-01). Simultaneously, 20 μl of the lysate supernatant was collected for measurement of protein concentration by a BCA kit. The luciferase activity was determined by the absorbance normalized to protein concentration. Three replicates for each genotype and condition were performed. Cell transfection For all transfections into HEK293T, Calcium Phosphate Cell Transfection Kit (Beyotime, Cat# C0508) was used. For transfections into Sf9 cells, Cellfectin® II Reagent (Gibco, Cat# 10362100) was used. Co-immunoprecipitation assay For the co-immunoprecipitation assay in HEK293T, the plasmid of pCDNA3.1-FLAG-Ime4/Mettl14/YT521-B and pCDNA3.1-Myc-BuGZ^FL or pCDNA3.1-FLAG-BuGZ^FL/ pCDNA3.1-FLAG-BuGZ^Δzinc and pCDNA3.1-Myc-Ime4/Mettl14 were co-transfected into HEK293T cells seeded in a 10 cm cell culture dish. After 48-h transfection, HEK293 cells were harvested, lysed using lysis buffer (50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 0.5% Triton X-100, with 1 mM PMSF) in a 1.5 ml centrifuge tube and rotated head-over-tail for 30 min at 4 °C. For immunoprecipitation assays in midguts, BuGZ-FLAG midguts were dissected in cold PBS. After homogenizing in liquid nitrogen, samples are lysed in 1% PBST buffer in a 1.5 ml centrifuge tube for 30 min on ice. The supernatant was collected after 10-min centrifugation at 1000×g at 4 °C. Protein concentrations were determined using a BCA kit. For immunoprecipitation, supernatant (Millipore, Cat# A2220) was added into anti-FLAG M2 gel and rotated head-over-tail overnight at 4 °C for 4 h. The beads were washed 3 times for 10 min with lysis buffer. Immunoprecipitated proteins and input samples were analyzed by western blotting after elution with SDS-PAGE sample buffer. Protein expression and purification pet28a^+-dBuGZ^FL/dBuGZ^Δzinc/GFP construct was transformed into BL21 (DE3). To induce protein expression, 1 mM IPTG was added to the culture upon OD600 reached 0.6–1, then cooled the culture to 16 °C with shaking for 16 h. After centrifugation at 3800 rpm for 20 min at 4 °C, bacteria were collected. The bacteria were broken by sonicating (SCIENTZ-IID) until the lysis buffer (50 mM NaH[2]PO4, 300 mM NaCl, 10 mM imidazole, 1 mM PMSF, cocktail, 1:100, pH 7.8) became clear (~25 min), and the lysate was centrifuged at 12000 rpm for 30 min at 4 °C. The supernatant was transferred to a column (Glass Econo-Column®, Bio-RAD) containing 2 ml of 50% slurry of Ni-NTA beads (Qiagen). After rotating the mixture at 4 °C for 4 h, the column was washed with 100 ml wash buffer 1 (50 mM NaH[2]PO4, 300 mM NaCl, 20 mM imidazole, pH 7.8) and following 100 ml wash buffer 2 with 25 mM imidazole. At last, proteins were eluted with 16 ml Elution buffer (50 mM NaH[2]PO4, 300 mM NaCl, 250 mM imidazole, pH 7.8) in 1 ml fractions. The elution was concentrated to 100~350 μM with Amicon Ultra 30 K device (Millipore) at 4 °C and exchanged with PBS buffer at the same time. The protein stocks were divided into 10 µl aliquots, snap-frozen in liquid nitrogen, and stored at −80 °C. For expression and purification of His-GFP-3×GGGS-dIme4/dMettl14, the manual of Bac-to-Bac Baculovirus Expression system (Invitrogen) was used. After getting recombined P1-P3 virus from Sf9, and 600 ml of High Five cells suspension was used to express the corresponding protein. High Five cells were harvested and lysed in 40 ml of binding buffer (20 mM phosphate buffer, pH 7.4, 1 mM MgCl2, 1 mM β-mercaptoethanol, 1% Triton X-100, 0.5 M NaCl, 25 mM imidazole, 10% glycerol) supplemented with 1 mM phenylmethylsulfonyl fluoride (PMSF). The cell lysate was centrifuged at 12,000 rpm for 30 min at 4 °C. The supernatant was loaded onto a column packed with 4 ml of 50% slurry of Ni-NTA beads (Qiagen) and followed by washing with 20 volumes of His-binding buffer. The protein was then eluted with 8×2 ml of His-elution buffer (same as His-binding buffer except with 500 mM imidazole). The eluted fractions were combined and concentrated by Amicon Ultra 30 K device (Millipore) to a final volume of 2–3 ml. Samples were exchanged with PBS buffer twice at 4 °C, divided into 10 µl aliquots, snap-frozen in liquid nitrogen, and stored at −80 °C. All protein purification steps were performed at 4 °C. The purified protein was quantified using an ND-2000C NanoDrop spectrophotometer (NanoDrop Technologies) with OD 280. In vitro phase separation assays For the standard phase-separation assay, 5 µl of His-dBuGZ^FL, His-dBuGZ^Δzinc proteins at the indicated concentrations were prepared by diluting the stock solutions into ice-cold PBS buffer. After incubation of the mixtures at 37 °C for 5 min, the droplets were immediately observed. Temperature-dependent phase separation experiments were performed by incubating the indicated protein mixture at 37, 30, 25 and 4 °C for 5 min after removal from ice. To visualize the salt hydronium concentration-dependent phase transitions, His-dBuGZ dissolved in storage buffer were mixed at a desired ratio and concentration, and the concentration of NaCl was adjusted with buffer containing 25 mM HEPES pH 7.5, 1 M NaCl and 1 mM DTT. To assay whether His-GFP-dIme4, His-GFP-dMettl14 regulate His-dBuGZ droplets, we mixed 30 µM His-dBuGZ-FL/Δzinc with 30 µM His-GFP, His-GFP-dIme4, His-GFP-dMettl14 on ice. DNA-dependent droplet formation experiments were performed by adding 10 μM indicated DNA to 16.7 µM or 8.3 µM His-dBuGZ^FL or 16.7 µM His-dBuGZ^Δzinc in the storage buffer. The solution was incubated at 37 °C for 5 min and immediately the state of the droplet was observed. Formation and fusion of liquid droplets was observed by bright field of fluorescence microscopy using a 40× objective in Leica DM6-B microscope. Fluorescence recovery after photobleaching (FRAP) was performed on scarlet-BuGZ droplets. Briefly, one BuGZ droplet was bleached and the fluorescence recovery was monitored. 10 μM P8 was added to 20 μM His-scarlet-dBuGZ^FL. Percentage of cells, fluorescence intensity and area of puncta statistics The results of the immunofluorescence image were analyzed based on z stacks acquired with confocal microscopy. The percentage of indicated genotype cells is measured by calculating all the positive cells in a picture and then normalized by DAPI counts. Fluorescence intensity of the region of interest (ROI) or cell was calculated using LAS X software. The methods involved are as below: Integrated Density = Integrated Density of ROI or cell—Integrated Density of background region/Area of background region × Area of ROI or cell. The area of puncta was calculated using Image J. Statistics and reproducibility All experiments’ statistical analyses were performed using Prism 7 (GraphPad Software). Statistical significance was shown are means ± SD of three independent replicates. Differences between means were assessed with unpaired two-tailed Student’s t-tests. Reporting summary Further information on research design is available in the [288]Nature Portfolio Reporting Summary linked to this article. Supplementary information [289]Supplementary Information^ (11.3MB, pdf) [290]Peer Review File^ (2.2MB, pdf) [291]41467_2023_42474_MOESM3_ESM.pdf^ (89.5KB, pdf) Description of Additional Supplementary Files [292]Supplementary Data 1^ (15.8KB, xlsx) [293]Supplementary Data 2^ (761.8KB, xlsx) [294]Supplementary Data 3^ (14.4KB, xlsx) [295]Reporting Summary^ (4MB, pdf) Source data [296]Source Data^ (17.9MB, zip) Acknowledgements