Single-Cell Sequencing Analysis Fibrosis Provides Insights into the Pathobiological Cell Types and Cytokines of Radiation-Induced Pulmonary Fibrosis

doi:10.21203/rs.3.rs-2461622/v1

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V体育平台登录 - Single-Cell Sequencing Analysis Fibrosis Provides Insights into the Pathobiological Cell Types and Cytokines of Radiation-Induced Pulmonary Fibrosis

https://doi.org/10.21203/rs.3.rs-2461622/v1

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published 28 Apr, 2023

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Single-cell transcriptome sequencing source and pre-processing

The study used the RIPF-associated single-cell transcriptome sequencing dataset in the Sequence Read Archive (SRA, https://www. ncbi. nlm VSports app下载. nih. gov/sra) database, PRJNA768942.

The SRA files of the PRJNA768942 dataset were converted to fastq files in SRA Toolkit software (version 2. 11. 0), and Cell Ranger software (version 6. 0. 2) was used to complete the cellranger count process to obtain single-cell mRNA expression data V体育官网.

In the R environment (version 4.0.3), each sample of the single-cell transcriptome sequencing dataset underwent quality control using the Seurat package under the following conditions: nFeature_RNA 200–6,000%, mt < 15%, and nCount_RNA > 10. The QC'd single-cell sequencing samples were combined separately, and the NormalizeData and ScaleData function was used to logarithmic normalization and linear regression scaling of the data; and the principal component analysis (PCA) method was then used to characterize all gene expressions. Dimensionality reduction analysis was performed, and Harmony R package was combined to correct for batch effects between different samples. FindNeighbors function was used to construct a graph of the dimensionality reduction results. Clustering was then performed using the FindClusters function.

Analysis of gene expression differences between T cells and B cells

Seurat objects of T and B cells were separately extracted using the Seurat package in the R4.0.3 environment and combined using the Harmony package to recalibrate the batches and clusters.

The FindMarkers function was used to find the differential genes between T cells and B cells in the disease and control groups, respectively, and the genes with mean log2FC absolute values > 1 and BH corrected p-values < 0.05 were selected, and biological function enrichment analysis was performed using the clusterprofiler package. The ten functions with the smallest p-values were selected for visualization; PPI was then constructed in the STRING v11.5 database (https://cn.string-db.org/), and the network was visualized using the ggraph package and tidygraph package.

Animal experiments

Sprague–Dawley rats (male, 7-week-old, 200 ± 20 g) were obtained from the Center for Experimental Animals, Zhejiang Chinese Medical University. The protocol was approved by the Experimental Animal Management and Ethics Committee of Zhejiang University of Traditional Chinese Medicine (Approval No.: IACUC-20210315-09). Animals were randomly divided into two groups: the control group and 30 Gy group. Radiographs were selected as the radioactive source and irradiated at the Irradiation Center of the Zhejiang Cancer Hospital. The animals were anesthetized with 3 mg/mL sodium pentobarbital (1 mL/100 g), fixed using a mold, and irradiated at a single dose rate of 1 Gy/min.

Histological staining

Rats were euthanized at the 2nd month after illumination, and fresh lung tissue was harvested and cut into paraffin sections. The sections were then subjected to, immunohistochemical (IHC) (YT4002: RuiYing Biotechnology Company, China, A3694, A5597: ABclonal Technology Co.,Ltd., and 60291-1-1lg: Proteintech Wuhan Sanying, China), hematoxylin-eosin (H&E) and Masson's trichrome staining (Wuhan Pinuofei Biological Technology Co., Ltd., China) to assess the lung structure and protein expression.

Determination of cytokine cytokines

According to the manufacturer's instructions (EK1129, EK189, and EK182HS, ELK Wuhan Biotechnology CO., Ltd., China), enzyme-linked immunosorbent assay (ELISA) kits were used to examine serum levels of CCL5, ICAM1, PF4, and TNF-α in cell culture supernatants of A549 and BEAS-2B(National Collection of Authenticated Cell Culture, China) at the 48th hour after 10Gy irradiation. All samples were measured in duplicates.

ScRNA-seq analysis

PCA and t-SNE analyses were performed. Depending on the expression of maturation markers, the cells were classified into 11 different cell types based on cell type-specific gene expression (Table 1). Cells in the two datasets were separately arranged using the following threshold conditions: average expression proportion of markers in each clustering subgroup > 30% and average expression value > zero. Annotations with overlapping subgroups were selected for annotation with a greater proportion of marker expression.

The abundance of each cluster of control versus RIPF cells is shown in Fig. 1, which demonstrates the relative abundance of each cell type genotype.

In these scRNA-Seq data, the relative abundance of B and T cells in the RIPF group remarkably changed compared to that in the controls (Fig. 2); therefore, we initially analyzed these two cell types, and differentially expressed gene (DEG) analyses were performed on these data.

Table 1

Lung tissue cells are classified into 11 different cell types.
Cell types	Markers
T cells	Cd3d, Cd3e, and Cd3g
NK cells	Klrd1, Gzma, Nkg7, and Il2rb
B cells	Ighd, Ms4a1, Cd79a, and Cd79b
macrophages	Adgre1, Cd68, and Lyz2
monocytes	S100a8andS100a9
Dendritic cells	Cd83, Cd86, H2-Eb1, and H2-Ab1
platelets	Nrgn, Clec1b, Itga2b, and Itgb3
Epithelial cells	Scgb1a1, Sftpa1, Ager, and Krt7
Endothelial cells	Pecam1, Egfl7, Flt1, and Eng
fibroblasts	Col1a1, Col1a2, and Col3a1

Analysis of DEGs of B cells

Analysis of differential genes in B cells between the disease and control groups revealed significant differential expression of the following biological processes: structural constituent of the eye lens, intermediate filament binding, immunoglobulin receptor binding, immunoglobulin complex, circulating immunoglobulin complex, euchromatin, DNA-directed DNA polymerase activity, DNA polymerase activity, DNA binding, and antigen binding (Fig. 3B). These genes were enriched in the following pathways: positive regulation of B-cell activation, plasma membrane invagination, phagocytosis, recognition, phagocytosis, engulfment, membrane invagination, immunoglobulin-mediated immune response, humoral immune response mediated by circulating immunoglobulin, complement activation, classical pathway, complement activation, and B-cell receptor signaling pathway (Fig. 3A). The analysis revealed positive regulatory activation of B cells in the disease group, resulting in a significant increase in the number of B cells and a high correlation with immunoglobulins (Fig. 3C). Ionizing radiation can induce the secretion of immunoglobulins by activating B cells. Immunoglobulins reportedly enhance inflammation and promote the production of extracellular matrix and fibrogenic cytokines (22). Therefore, we hypothesized that immunoglobulins could induce cytokine secretion, thereby promoting RIPF.

Analysis of DEG of T cells

The analysis of differential genes in T cells revealed that the following biological processes significantly differed: T cell differentiation, regulation of leukocyte differentiation, regulation of adaptive immune response, lymphocyte differentiation, antigen processing and presentation of peptide antigen, antigen processing and presentation of exogenous peptide antigen via MHC class II, antigen processing and presentation of exogenous peptide antigen, antigen processing and presentation of exogenous antigen, antigen processing and presentation, and adaptive immune response based on somatic recombination of immune receptors built from immunoglobulin superfamily domains (Fig. 4A). The top ten pathways with significant variation were as follows: T cell differentiation, regulation of T cell differentiation, regulation of T cell activation, regulation of lymphocyte differentiation, regulation of leukocyte differentiation, regulation of cell–cell adhesion, positive regulation of T cell activation, positive regulation of lymphocyte activation, positive regulation of leukocyte cell − cell adhesion, and lymphocyte differentiation (Fig. 4B). An apparent decrease in the number of T cells was observed in the lung tissue of rats following ionizing irradiation (Fig. 2). In summary, differentiation and activation signals in T cells and leukocytes and positive regulation of leukocyte cell–cell adhesion showed remarkable changes following ionizing radiation. Among the genes involved in these biological processes, we identified many cytokine-related genes, including CCL5, SMAD7, IL7r, IL18r1, TNFAIP3, and IL2rb, and immunoglobulin-related genes IGKC, IGHA, and IGHG2C (Fig. 4C). Considering the above, we speculated that RIPF may be closely related to cytokines.

RIPF and cytokines

The analysis of differences in gene expression between T cells and B cells indicated that a number of cytokines may be the underlying causative agent for the pathogenesis of RIPF. Consequently, RIPF single-cell transcriptome sequencing results were compared between those of disease and control groups, and the differential cytokines among them were selected for tSNE visualization. Four of these factors were visibly altered: CCL5, ICAM1, PF4, and TNFα (Fig. 5).

Lung histopathological sections indicated that the alveolar structure of non-irradiated rats was normal. After 30 Gy irradiation, the alveolar septum was thickened and infiltrated by numerous inflammatory cells. Masson staining results were consistent with the pathological alteration seen in HE staining. The results demonstrated pronounced fibrous exudation of lung tissue in the irradiated group, exhibiting signs of RIPF (Fig. 6A).

ELISA results showed that the levels of CCL5, ICAM1, and TNFα in the supernatant of BEAS-2B cells evidently increased following ionizing radiation (Fig. 6B).

IHC staining showed that CCL5, ICAM1, PF4, and TNFα levels were significantly upregulated in the lung tissue of rats in the RIPF group (Fig. 6C).

RIPF is a serious complication, the mechanism of which is still unclear, thereby affecting the survival and prognosis of patients undergoing radiation therapy to shrink tumors. In biological processes, cytokines perform an overriding and significant role.

It has been previously demonstrated that chemokines are of considerable relevance in PF (23–26), and that C-C chemokines are involved in PF. CCL2 and CCL5 are upregulated in irradiated human lung epithelial cells, and inhibiting their expression constrains epithelial–mesenchymal transition and suppresses PF (27). Previous studies have revealed that CCL2 facilitates fibrosis by supporting the monocyte/macrophage inflammatory response, fibroblast collagen synthesis, myofibroblast differentiation, and fibroblast recruitment and survival (28, 29), thereby protecting against PF in the absence of CCR2 signaling (30). It has been suggested that CD4 + T lymphocytes of CCR2 are a subpopulation of CD4 + cells with anti-inflammatory and anti-fibrotic properties (31). Our gene expression analysis revealed that CCL5 expression in T cell and dendritic cells was significantly upregulated in lung tissue after irradiation (Fig. 5A). ELISA results showed that CCL5 was upregulated in the cell culture supernatant of BEAS-2B cells after IR. IHC staining also demonstrated that CCL5 was upregulated in the lung tissue of RIPF rats (Fig. 6). Therefore, we hypothesized that CCL5(+) T cells may have an essential function in RIPF.

ICAM1 is a cell surface glycoprotein and a member of the immunoglobulin superfamily (32). T cells and pro-inflammatory monocytes are recruited to the left ventricle via myocardial endothelial ICAM1, and ICAM1 upregulation may be associated with the stress overload induction of IL-1β and IL-6. When inflammatory infiltration occurs, leukocytes further release cytokines that promote cardiac inflammation, fibrosis, and cardiac insufficiency (33). Recent studies have also reported that blocking ICAM1 can silence CD4IL4T cell differentiation in allergic rhinitis (34). Therefore, it is reasonable to hypothesize that ICAM1 has a dearth of understudied connections with RIPF. We observed a highly detectable upregulation of ICAM1 in many types of cells in post-irradiation rat lung tissue, including monocytes, fibroblasts, endothelial cells, epithelial cells, and macrophages (Fig. 5B). ELISA results showed that ICAM1 level was upregulated in the cell culture supernatant of BEAS-2B cells after IR. IHC staining also demonstrated that ICAM1 was upregulated in the lung tissue of RIPF rats (Fig. 6). Therefore, we speculated that ICAM1 plays a little-known and critical role in RIPF; according to previous studies, this could be caused by T cell-induced inflammatory responses. However, this hypothesis requires further investigation.

Human platelet factor IV (PF4) is a heparin-binding protein contained in platelet alpha granules and is a member of the chemokine family, which is secreted upon platelet activation and is considered a marker of platelet activation (35, 36)^,. PF4 levels are elevated in the BALF of patients with scleroderma interstitial lung disease, and platelet activation occurs in the lungs (37). In bleomycin-induced PF, platelet accumulation is associated with collagen deposition in the lungs and involved in the development of interstitial lung disease (38). This indicates that platelets play a crucial role in idiopathic pulmonary pathogenesis. We found significant upregulation of PF4 in platelets in post-IR rat lung tissue in tSNE, which may also suggest a major unexplained function of platelets in RIPF (Fig. 5C). IHC staining also demonstrated that PF4 is upregulated in the lung tissue of RIPF rats (Fig. 6), thereby supporting the hypothesis that PF4 is implicated in RIPF.

TNF is a pleiotropic inflammatory cytokine that plays a central role in many pathophysiological processes and can mediate tissue destruction by recruiting immune cells (e.g., neutrophils) (39). The overexpression of TNF genes can lead to the development of pulmonary inflammation and fibrosis, and blocking TNF can dampen lung injury (40). The depletion of CD4CD8 T lymphocytes prevented bleomycin-induced TNF levels and inhibited the extent of increased fibrosis. T lymphocytes led to impaired lung function and lung fibrosis by inducing an increase in lung TNF production (41). Inflammatory mononuclear cells originate from the bone marrow and migrate to the lungs after radiation exposure (42). The recruitment and activation of monocytes/macrophages are pivotal components of radiation-induced fibrosis (43). We analyzed the changes in TNF levels in different cells and found that TNF levels decreased in macrophages and increased in monocytes. The principal biological function of TNF is TNFα; therefore, we assayed the level of TNFα in the cell supernatant after IR. ELISA results showed that the level of TNF-α was upregulated in the cell culture supernatant of BEAS-2B cells after IR. IHC staining results also demonstrated that TNF-α was upregulated in the lung tissue of RIPF rats (Fig. 6). Therefore, we assume that TNF plays a role in inducing RIPF in T cells and monocytes.

In conclusion, through single-cell sequencing, we have gained further insights into the RIPF cell population and changes in the abundances of various cell types, with the most significant changes observed in the abundance of T- and B cells. We have also gained further insights into the role of cytokines in RIPF, based on the analysis of differential genes in these two cell types, confirming that four cytokines, CCL5, ICAM1, PF4, and TNF, play an important role in RIPF. Further investigation is required to assess their specific roles in RIPF.

ELISA, enzyme-linked immunosorbent assay

H&E, hematoxylin-eosin

IHC, immunohistochemical

PCA, principal component analysis

RIPF, Radiation-induced pulmonary fibrosis

RT, Radiotherapy

PF, pulmonary fibrosis

scRNA-seq, single-cell RNA-sequencing

Acknowledgments

We acknowledge SRA database for providing their platforms and contributors for uploading their meaningful datasets.

Funding

National Natural Science Foundation of China (Grant Nos.: 8211101233; 8217131437; 82003189 and 82003853); Zhejiang Provincial Natural Science Foundation of China (Grant Nos.: LY20H310001, LYY21H310011, LYY19H280001); Chinese Medicine Research Program of Zhejiang Province (Grant Nos.: 2020ZZ003, 2021ZZ001); Medical and Health Research Program of Zhejiang Province (Grant Nos.: 2021KY040, 2022KY069);"10000 Talents Plan" of Zhejiang Province to Ping Huang(Grant No.: 2020R52029); Zhejiang Provincial Program for the Cultivation of New Heath Talents to Yiwen Zhang.

Contributions

PH and YZ conceived and designed the study. ZS, YL, FS, XZ, YH and HDing collected, processed and validated data. XH analyzed data and prepared figures. ZS drafted the manuscript. All authors read and approved the final manuscript.

Ethics approval and consent to participate

We confirm that all experiments were approved by the Experimental Animal Management and Ethics Committee of Zhejiang University of Traditional Chinese Medicine (Approval No.: IACUC-20210315-09). We confirm that all experiments were performed in accordance with relevant guidelines and regulations. And we ensure that manuscript reporting adheres to the ARRIVE guidelines (https://arriveguidelines.org) for the reporting of animal experiments.

Consent for publication

Not applicable

Availability of data and materials

The datasets analysed during the current study are available in the Sequence Read Archive (SRA, https://www.ncbi.nlm.nih.gov/sra) database, PRJNA768942.

Competing interests

The authors declare that they have no competing interests.

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No competing interests reported.

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