The T Cell Receptor Immune Repertoire Protects the Liver From Reconsitution

Aberrant immune cell infiltrates and microcircumstances represent characteristic features of liver fibrosis. In this study, we profiled the transcriptomes of intrahepatic CD45+ immune cells, from mice, using single-cell RNA sequencing (scRNA-seq) technology to understand the landscape of intrahepatic immune cells during the pathogenesis of fibrosis. Analysis of approximately 10,000 single-cell transcriptomes revealed an increase in dendritic cells (DCs), macrophages, and neutrophils and a decrease in T and natural killer T (NKT) cells. In addition, we report changes in the transcriptomes of diverse immune cell types, implying a deteriorating intrahepatic immune microcircumstance. Furthermore, we uncovered a novel fibrosis-associated CD8 T (Ccl5+, Ccl4+) and CD4 T (mt-Co1+) cell subpopulation, which infiltrates fibrotic liver and is characterized by abnormal activation or inactivation as well as a TCR decline. The results from scRNA-seq and bulk immune repertoire sequencing (IR-seq) revealed an obvious decline in T cell receptor (TCR) clonotypes combined with shrinking VJ and VDJ segment usage, as well as lower complementarity-determining region 3 (CDR3) amino acid (AA) diversity from fibrotic liver. Interestingly, a deficiency of TCR IR (TcrbKO mice) led to a deterioration of liver fibrosis, coupled with activation of hepatic stellate cells (HSCs) induced by the upregulation of macrophage and γδ T cell distribution in fibrotic TcrbKO livers. Our findings reveal the landscape and dynamics of single immune cells in liver fibrosis, and clarify the protective role of TCR IR in response to chronic liver injury.


INTRODUCTION
Liver fibrosis, a common final pathway for most chronic liver diseases, poses a threat to public health worldwide, accounting for more than 1 million deaths each year (1,2). The condition mainly results from chronic liver inflammation, often induced by virus-associated hepatitis, drug/alcohol abuse, or autoimmune liver disease, and features excess accumulation of extracellular matrix subsequent to chronic liver injury (3)(4)(5). Accumulating evidence has revealed the critical role of activated hepatic stellate cells (HSCs) in collagen and extracellular matrix (ECM) production (3,6,7). Upon liver injury, HSCs, the major source of collagen in the liver, transdifferentiate from quiescent lipocytes into myofibroblast-like cells to drive fibrogenesis, which is characterized by enhanced chemotaxis, survival and collagen production (4,8,9). Despite their importance in liver wound healing, it is hypothesized that activated HSCs may encourage pathogenesis during liver fibrosis.
The liver is a central immunologic organ, known to induce immune tolerance and immunity (10). Abundant immune cells in the liver function to maintain intrahepatic immune homeostasis. Recent studies have emphasized the crucial role played by different intrahepatic immunocyte subsets, especially macrophages, in the progression of liver inflammation and fibrosis (11)(12)(13)(14)(15). Activation of HSCs depends on the intrahepatic immune microcircumstance, including immune cells (T, B, natural killer (NK) and macrophages cells) and signaling in an autocrine and/or paracrine fashion (16)(17)(18)(19). Recent studies have described the role of T cells, including gd T cells, Th17 cells and natural killer T (NKT) cells, in modulating inflammation and fibrosis in response to liver injury (17,20,21). However, their contributions to HSC activation as well as the molecular mechanisms of T cells in fibrotic pathogenesis remain largely unknown.
In our previous work, we demonstrated that TCR IR reconstitution acts more like a "commander" than an "executor" in the intrahepatic immune microenvironment (22), indicating that it contributes not only to TCR-mediated recognition and pathogen clearance, but also to tissue immunosurveillance and immunoregulation. However, the TCR-mediated precise connection between the TCR clonotype and the transcriptomic state of intrahepatic T cells remains largely unknown. In the current study, we applied scRNA-seq to characterize CD45 + immune cells from different phases of fibrotic liver. Combining transcriptomic profiles with TCR usage revealed the emergence of distinct activated T cell subsets as well as associations between T cell state and TCR transformation in liver fibrogenesis. We limited the present analysis to determining a functional link between TCR IR and liver fibrosis. Overall, our results demonstrate the regulatory role of TCR IR in the intrahepatic immune microcircumstance and provide a novel viewpoint of the role of T cells in liver fibrogenesis.

Animals and Fibrotic Models
WT C57BL/6 and TCRb KO mice were housed in pathogen-free animal rooms at the Animal Care Centre of Xiamen University (Xiamen, China). All animal experiments were approved and conducted under the Guidelines of the Xiamen University Committee on Animal Care and Use. For liver fibrosis, 6-to 8week-old male mice were injected intraperitoneally with carbon tetrachloride (CCl 4 , dissolved in olive oil with a volume ratio: 1:1) (Sigma-Aldrich, St. Louis, MO, USA) at a dose of 1 ml/g body weight thrice per week for 4 or 8 weeks. Samples were collected 1 day after the last injection. Bile duct ligation (BDL) and sham laparotomy were conducted as described previously (23). The 2week time point was chosen to study liver fibrosis.

Preparation of Single-Cell Suspensions and scRNA-Seq
The isolation of mouse intrahepatic immunocytes was performed as previously described (22). Based on FACS analysis, single CD45 + cells (1 × 10 6 cells, 90%-95% viability, four mice per sample) from untreated, 4-and 8-week CCl 4treated livers were sorted into 1.5 ml tubes with 50 ml sorting buffer. For droplet-based scRNA-seq, the cells were loaded onto a 10X Genomics Chromium chip (10X Genomics, Pleasanton, USA) as per the factory recommendations. Reverse transcription and library preparation were performed using the 10X Genomics Single Cell v2 kit following the manufacturer's protocol. For single-cell VDJ sequencing, the cDNA encoding the TCR library was amplified with two-round PCR using the DNA primers provided in the kit, followed by selection with SPRI beads (Bulldog Bio Inc. New Hampshire, USA). The libraries were sequenced on an Illumina HiSeq 4000.

Statistical Analysis
All statistical data were analyzed using the GraphPad Prism 8.0 Package (GraphPad Software, La Jolla, CA). Data are presented as the mean ± standard deviation (SD). Student's t-test was used to compare values between two groups. Differences among multiple groups were determined using one-way analysis of variance (ANOVA) followed by Sidak's multiple comparisons test for mean separation. Statistical significance was accepted at P<0.05.
For further details regarding the materials and methods used, please refer to the Supplementary Materials.

scRNA-Seq Reveals an Aberrant Immune Microcircumstance in Fibrotic Liver
To characterize the state of immune cells during liver fibrosis, we performed scRNA-seq on CD45 + cells isolated from untreated (Ctrl) and CCl 4 -induced 4 (4 W) and 8-week (8 W) livers. For TCR IR analysis, both scRNA-seq and IR-seq methods were applied simultaneously to evaluate TCR transformation during liver fibrosis ( Figure 1A). We obtained expression profiles for 10,436, 10028, and 8,144 pure CD45 + cells from the Ctrl, 4 W and 8 W groups, respectively ( Figure S1A). Analysis of singlecell transcriptomes using t distributed stochastic neighbor embedding (tSNE) projection revealed 7 distinct immunocyte subsets in the liver ( Figure 1B). Characterization of their markers indicated that they were B cells, dendritic cells (DCs), innate lymphoid cells (ILCs), macrophages, NK cells, neutrophils, and T cells ( Figure S1B, Table S1). Notably, we observed a shift in the gross number of cells from normal to fibrotic livers ( Figure 1C). As expected, fibrogenesis was accompanied by an aberrant cell distribution ( Figure 1D Table S2). Notably, the total cell number and percentage of macrophages expanded to orchestrate liver fibrosis progression, as has previously been reported (14). Furthermore, the results from KEGG analysis indicated enrichment of differential genes in immune signaling pathways, including TNF-a, IL-17, NF-kb, TCR, and BCR signaling ( Figure 1G, Table S3). In summary, analysis of scRNA-seq data resulted in the identification of multiple immune cell populations with aberrant distribution patterns and transcriptomic states during liver fibrosis.

Fibrogenesis Diminishes the Intrahepatic T Cell Population
Interestingly, we found a reduction in the T cell population (earlier observed in Figure 1D) in fibrotic liver (both in CCl 4induced liver and BDL-induced liver) based on the results from immunofluorescence staining (Figure 2A and Figure S2A). Livers from cirrhotic patients also exhibited a reduction in CD3 + cells, indicating that the reduction of the T cell population in fibrotic liver occurs in both mice and humans ( Figure 2B). To characterize the T cells during fibrosis, we used tSNE to visualize the T profiles from the single-cell transcriptomic data. Notably, we found that T cells from Ctrl (3606 cells), 4 W (3052 cells), and 8 W (1915 cells) generally partitioned into distinct areas, suggesting a difference between T cells in fibrotic liver and those in the Ctrl ( Figure 2C). To clarify  Table S3).
the T cell transition, we used the Monocle method to construct potential developmental trajectories of the four T cell clusters based on the expression data ( Figure S2B). The developmental trajectories revealed distinct functional states in the late fibrosis phase, with T cells from 8 W positioned at the opposite end of those from Ctrl, and T cells from 4 W located in between, indicating intermediate functional states ( Figure 2D). In rodent models, HSC-induced T cell hyporesponsiveness is associated with enhanced apoptosis (24,25). Analysis of scRNA-seq data from the T cells revealed a significant upregulation of apoptosisrelated genes in fibrotic liver, including Casp3, Casp4, Casp8, Bax, Fasl, Pdcd4, Ptpn6, and Bbc3 ( Figure 2E, Figures S2C, D).
Overall, these findings indicated that intrahepatic T cells, widely experiencing apoptosis, may partly account for the T cell population shrinkage.

Intrahepatic T Cell Clusters Exhibit Diverse Patterns
Characterization of markers identified CD4 T, CD8 T, gd T, and NKT cells ( Figure 3A, Figure S3A, Table S4). Strikingly, singlecell transcriptome data and fluorescence activated cell sorting (FACS) revealed a gradually diminishing NKT cell population, while CD8 T cells were expanded in fibrotic liver (Figures 3B, C and Figure S3B). Similarly, NKT cells were highly enriched in the early pseudotime period ( Figures 3D, E), demonstrating the protective roles of NKT cells in liver injury models (26,27). Furthermore, we observed an expansion of CD8 T cells in the middle of the pseudotime ( Figures 3D, E), confirming that these cells invade into fibrotic liver to promote fibrosis (28). To investigate the role of T cell subpopulation, ab T cells were classified as native T Figures S4A, B).

cells, helper T cells, cytotoxic T cells (CTL), regulatory T cells (Treg), exhausted T cells, memory T cells, proliferative T cells according to cell marker (
Notably, a gradually expanded Treg cell population was found in liver fibrosis ( Figures S4C, D). The variation of gene expression in Treg were showed in Figures S4E, F, Table S5. Our results were consistent with previous studies, suggesting that liver fibrogenesis expands liver Treg, which reduce the function of bulk intrahepatic T cells yet limit liver injury (29,30). To further understand the T cell heterogeneity during liver fibrosis, we performed unsupervised clustering, based on tSNE, and identified 11 cell clusters ( Figure 3F, Figure S3C, Table S6).
Notably, we identified highly activated clusters from the Ctrl and 4 W groups. These included clusters 4 and 10 (higher expression of Ccl5 + , Fos + , Dusp2 + ) and clusters 6, 3, and 7 (higher expression of Ccl5 + , Ccl4 + ), which expressed several markers of NKT and CD8 T cells. Clusters 8 and 2 exhibited higher expression of mt-Co1 with lower activation of infiltrates in late-phase liver fibrosis (Figures 3G, H, Figure S3D, Table S7). Taken together, these results indicated that activation of NKT cells is essential for hepatic homeostasis. Liver injury gives rise to CD8 T cell infiltration and activation; therefore, inactivating CD4 T cells leads to liver fibrosis.

TCR Clonotypes Show a Lower Diversity in Liver Fibrosis
Studies have reported that a diverse repertoire of TCR leads to a continuous spectrum of T cell activation, obscuring the transitional states (31). To investigate whether TCR diversity variation contributed to T cell inactivation, we performed scRNA paired V (D)J sequencing of T cells in the same sample (Table S8). In general, we observed less TCRa, TCRb, and TCRab during liver fibrosis ( Figure S5A), while T cell clusters with high activation were significantly expressed in diverse TCR clonotypes, similar to that seen in Figure 3G ( Figure 4A). Conversely, almost no expression of TCR was recorded in T cells from late-phase fibrotic liver ( Figure 4B).  Consequently, we analyzed the V(D)J sequencing data of cells from the Ctrl and 4 W groups and found a significant decrease in TCR clonotypes from fibrotic liver relative to those in the Ctrl group ( Figure 4C and Figure S5B), although the compositions of the VJ and VDJ clonotypes showed no differences ( Figure 4D, Figure S5C, Table S9). TCR diversity and their abundance in fibrogenesis were significantly constrained ( Figure 4E). To gain deeper insights into the characteristics of the TCR clonotypes, we focused on the top 40 TCR clonotypes and found enrichment of high-frequency TCR clonotypes in T cell clusters (clusters 6, 10, 3, and 4) with activation, which belonged to CD8 T, gd T, and NKT cells. On the other hand, CD4 T cells exhibited fewer highfrequency TCR clonotypes ( Figure 4F). These findings supported the idea that high-frequency TCR clonotypes contribute to T cell activation during fibrogenesis.
We further assessed the distribution and diversity of TCR using bulk TCRb IR-seq from untreated and 8 week CCl 4induced livers and identified a total of 25 V, 13 J, 290 VJ, and 551 VDJ segments from all samples (Table S10). Usage patterns for most V, J, VJ, and VDJ segments were similar between the two groups, whereas only 2 V, 12 VJ, and 7 VDJ segments revealed significant usage differences ( Figure S6). Strikingly, multiple VJ and VDJ combinations were absent during fibrogenesis, revealing shrunken and centralized VJ as well as VDJ combination usage in liver fibrosis ( Figure 4G and Figure  S6E). Given the importance of CDR3 AA clonotypes in determining the diversity of TCRb IR, we identified 379,994 distinct CDR3 AA clonotypes (Table S11). Liver fibrosis led to obvious reductions in both total and shared CDR3 AA clonotypes, along with an increase in the percentage of shared CDR3 usage ( Figures 4H-K). Similarly, Shannon diversity also exhibited remarkably diminished CDR3 AA diversity in liver fibrosis ( Figure 4L). In addition, shrunken CDR3 AA richness and evenness were verified by rank-abundance analysis ( Figure  4M), with the usage frequency of most CDR3 AA segments similar between the two groups ( Figure 4N).
To explore the reconstitution of the TCR repertoire in fibrosis, we evaluated the differences in V-CDR3-J usage   (Table S12). Overall, the TCR IR showed highly private clonotypes in the Ctrl liver, while several high-frequency CDR3 AA clonotypes were evident in 8-week CCl 4 -treated liver ( Figure  S7A). In addition, the percentage of the top 20 clonotypes was significantly higher in fibrotic liver, suggesting that fibrogenesis induced the usage of several key high-frequency CDR3 AA clonotypes ( Figure S7B). We also assessed the frequency of terminal CDR3 AA motifs and found that fibrogenesis induced a higher frequency of terminal CDR3 AA motif glutaminetyrosine-phenylalanine (QYF) as well as a lower frequency of terminal CDR3 AA motif leucine-tyrosine-phenylalanine (LYF) ( Figures S7C, D and Table S13). Taken together, these results demonstrated a reconstitution of TCR IR during liver fibrosis, which leads to TCR diversity extinction.  Table S11).

The Absence of TCR IR Leads to Susceptibility to Liver Fibrosis
A key question is whether TCR-mediated T cell activation plays a function in liver fibrosis. Consequently, we subjected wild-type (WT) and Tcrb KO mice to repetitive CCl 4 treatments. We found that the livers of the control untreated adult Tcrb KO mice were normal in appearance, size and weight, with no significant differences in architecture and inflammation compared to those from the control untreated WT mice (Figures S8A-C). The efficient deletion of TCRb in the Tcrb KO mice was confirmed by immunofluorescence analysis (Figure S8A). Masson staining and Sirius red assays revealed that TCRb deficiency increased CCl 4induced liver fibrosis compared to WT mice ( Figure 5A). Consistently, aggravated liver fibrosis development in Tcrb KO mice was confirmed by elevated fibrogenic gene expression (Sma, Col1, Tgfb), along with abnormal intrahepatic immune status (including alleviated levels of Il2, Il6, Il23, Ifng, and enhanced levels of Il17 and Tnfa) ( Figures 5B, C). In addition, immunofluorescent staining revealed a high proliferation of HSCs in Tcrb KO liver ( Figure 5D). We, therefore, hypothesized that TCRmediated T cell activation plays a critical role in intrahepatic homeostasis, which regulates the process of liver fibrosis.

The Intrahepatic Immune Microenvironment, Not T Cells Alone, Modulates HSCs
To investigate the mechanisms by which TCR IR regulates hepatic inflammation and fibrosis, we cocultured primary HSCs (isolated from fibrotic liver) with or without T cells (isolated from normal liver) to verify whether T cells alone are responsible for the enhanced HSC proliferation. Interestingly, we found no differences in HSC proliferation and activation ( Figures S8D, E), indicating that TCR IR is not the direct driver of HSC activation. In fact, other factors also contribute to this process. To explore the regulatory role of the intrahepatic immune microenvironment on HSCs, cocultures of WT mouse primary HSCs with intrahepatic immune cells, isolated from CCl 4 -treated WT mice or Tcrb KO mice were performed for 3 days. CCK-8 assays and Ki67 immunostaining were performed to confirm HSC activation in vitro. Coculture with intrahepatic immune cells isolated from Tcrb KO mice notably accelerated HSC growth and proliferation ( Figures 5E, F). Together, these results demonstrated that HSC activation is modulated by the intrahepatic immune microenvironment rather than by T cells alone. Due to the aberrant immune milieu in the fibrotic livers, we investigated whether TCRb deficiency affects liver fibrosis by influencing the recruitment and activation of neighboring immunocyte subsets. We performed mass cytometry, targeting a global panel of 38 markers, and generated a detailed profile of the intrahepatic immune microcircumstance ( Figure S9A). The results indicated the presence of 20 cell clusters using unsupervised clustering based on tSNE ( Figure 5G, Figure S9B, Table S14). Furthermore, characterization of the markers revealed 10 distinct immunocyte subsets, including B cells, DCs, ILCs, macrophages, NK cells, neutrophils, CD4 T cells, CD8 T cells, gd T cells and NKT cells in the liver ( Figure 5H, Figure S9C, Table S14). Notably, Tcrb KO livers displayed negligible T cell populations (both CD4 T and CD8 T cells) as well as expanded activated macrophages (cluster 7) and gd T cells (cluster 15) in liver fibrosis (Figures 5I, J). FACS analysis also revealed significantly expanded macrophages and enhanced macrophages-labelled TNF-a levels. In addition, we observed an increased percentage of gd T cells with elevated IL-17 levels in the fibrotic Tcrb KO livers compared to WT mice ( Figure 5K). Collectively, these results suggest that TCR IR deficiency selectively elevates TNF-a-producing macrophages and IL-17-producing gd T cells, which leads to a deterioration of the immune milieu in the fibrotic liver.

DISCUSSION
The liver consists of parenchymal cells (hepatocytes and cholangiocytes), nonparenchymal cells (endothelial cells, biliary cells, and HSCs), and manifold immunocytes from the innate and adaptive immune system (32). Chronic liver injury typically provokes an aberrant intrahepatic immune microenvironment that is tightly modulated by the interplay of multiple pathways, molecules, and systems. It is dominantly dependent on interactions between damaged parenchymal cells, activated HSCs, and resident and infiltrating immune cells (33)(34)(35)(36). Herein, we generated transcriptome data based on scRNA-seq. The data covered 28,608 individual CD45 + cells from the liver in different fibrogenesis stages, providing a rich resource for understanding the multidimensional characterization of immune cells during liver fibrosis. Consequently, using transcriptomic data, we identified a deteriorating intrahepatic immune microenvironment, along with aberrant cell distributions. However, macrophage/myeloid cell subsets will likely not be sufficiently discriminated due to the approach of CD45 + cell sorting.
Liver fibrosis is known to occur mainly through the hepatocyte-macrophage-HSC network (15,37). However, there is also evidence for liver fibrosis occurring via direct interactions between immune cells and HSCs (7). The role of macrophages in liver cirrhosis has been studied in humans using scRNA-seq data. A study reported a decreased T-cell population (both CD4 T and CD8 T cells) in cirrhotic livers (14). In the present study, liver fibrogenesis resulted in a decrease in T cells via the upregulation of apoptosis-related genes in T cells, an observation that was consistent with previous findings (24,38). We identified four distinct T cell subsets (CD4 T, CD8 T, gd T, and NKT cells) and their states to further explore the transition of T cell subsets in fibrogenesis. Highly activated NKT cells were enriched in the normal liver, but faded away during liver fibrosis, suggesting that NKT might be a potential suppressor of liver fibrosis. A previous study suggested that CD8 T cells (Ccl5 + , Ccl4 + ) might promote liver fibrosis via extrahepatic recruitment in response to liver injury (28). Additionally, the accumulation of 'exhausted' CD4 T cells (mt-Co1 + ) has been found in a terminal stage of liver fibrosis, indicating that CD4 T cells could be a negative regulator in liver injury and fibrosis (39).
The features of T cells are mainly shaped by TCR-mediated activation and TCR-dependent environmental exposures (31). Similar to T cell transition, a diminished diversity of TCR clonotypes has been observed during liver fibrosis, and a high frequency of TCR clonotypes is associated with activated T cell clusters, which suggests that TCR diversity could account for the continuous spectrum of T cell activation. Additionally, this continuity might be conducive for maintaining homeostasis via crosstalk between T cells and other immune cells. Emerging evidence suggests that TCR IR is associated with various liver diseases, including viral hepatitis, liver regeneration, hepatocellular carcinoma, primary sclerosing cholangitis, and alcoholic liver disease (40)(41)(42)(43). Therefore, the identification and tracking of TCR IR may provide a novel strategy for investigating the dynamics and distribution of all T cell clonotypes and it represents a 'footprint' of immune status. In this study, we showed an intact characteristic of V, D, J, VJ, and VDJ segment usage and the distribution of CDR3 AA clonotypes in liver fibrosis. These results were consistent with scRNA-seq VDJ data, indicating that liver fibrogenesis reconstitutes TCR IR, leading to a remarkably lower TCR IR diversity. A restriction of the T cell immune repertoire was also found in chronic liver diseases and was related to limited antigen-driven T cell stimulation (40). Our work detected the precise connection between the TCR clonotype and the transcriptomic state of T cells by scRNA-seq analysis. These TCR usage patterns, together with the specific TCR signaling associated with environmental exposures, jointly define the discrete states of intrahepatic T cells. Diverse TCR specificities, strong drivers of downstream transcriptional signaling, may alter the levels of transcripts associated with responses to environmental stimuli (31). Our characterization of the transcriptome data, coupled with detailed TCR-based lineage information, revealed the tight association between the TCR clonotype and transcriptional phenotype in liver fibrosis. In agreement with our observation regarding the accumulation of a highly aberrant immune milieu in TCRb-deficient liver, it has been postulated that TCR reconstitution acts more like a "commander" than like an "executor" in the intrahepatic immune microcircumstance (22). However, the exact mechanism of the T cell interaction with other immunocytes remains unclear. In the present study, the ablation of TCRb resulted in a significant exacerbation of liver fibrosis, as manifested by an aberrant immune milieu and HSC activation. Additionally, an unusual distribution of macrophages and gd T cells combined with altered TNF-a and IL-17 levels was found in fibrotic TCRb-deficient livers. The expanded amount of TNF-a-producing macrophages and IL-17-producing gd T cells, which have been shown to promote hepatic fibrosis progression (44)(45)(46), may act as a feedback mechanism responding to TCR deficiency, thereby assuring aggravated hepatic fibrogenesis. The mechanism may be complicated. Multiple variables can impact the activation of macrophages and gd T cells. According to pathway enrichment for DEGenes of scRNA-seq data, cytokines (Ccl5, Ccl4, Ccl3, Gzmk, Gzma, Cxcr4, Il-4ra, Il10ra) may be candidates for controlling pathogenic macrophages or gd T cells.
The current study also elucidated the connection between TCR IR and HSCs in liver fibrosis, which revealed that TCR IR deficiency facilitated HSC activation. Notably, the coculture of HSCs with T cells did not affect HSC viability. This was consistent with our earlier speculation that the hepatic biological effect may be regulated by the intrahepatic immune microenvironment rather than solely via T cells (22). Although the nature of the crosstalk between HSCs and immune cells is still unclear, HSCs do receive many signals from individual  immunocytes and, in turn, produce many fibrotic mediators that elaborate signals influencing the progression of liver fibrosis. Additionally, HSCs can inhibit immunogenic T cell activation by antigen-presenting cells, thus resulting in T cell apoptosis (25,47). Collectively, these results indicate that HSCs significantly contribute to and participate in the intrahepatic immune microcircumstance by interacting with immune cells in a positive feedback manner ( Figure 6).

CONCLUSION
Immunosurveillance and immunoregulation of T cells are mainly dependent on TCR recognition (48). Our comprehensive scRNAseq and TCR IR-seq databases revealed that TCR rearrangement does play a critical role in the regulation of the intrahepatic immune microcircumstance, which regulates HSC activation in the liver. Our observation of TCR IR reconstitution provides a novel setting for the fibrosis-associated immune microenvironment in response to liver damage. Additionally, it offers new insights into the immunosurveillance and immunoregulation of T cells.

DATA AVAILABILITY STATEMENT
The sequencing data has been deposited in the NGDC GSA database (https://bigd.big.ac.cn/gsa/; accession number: CRA003280).

ETHICS STATEMENT
The animal study was reviewed and approved by Xiamen University Committee on Animal Care and Use.

AUTHOR CONTRIBUTIONS
KW and QYL conceived and designed the study. QL, MZ, CL, WZ, YL, PZ, and YC performed experiments. QYL and YH analyzed the scRNA-seq data. KW and PX analyzed the bulk IRseq data. KW wrote this manuscript. All authors contributed to the article and approved the submitted version.