Project description:Huntingtin-interacting protein 1 Related (HIP1R) protein, shares some function similarities with HIP1, and HIP1 regulates arthritis and RA fibroblast-like synoviocytes (FLS) invasiveness. Therefore, we hypothesized that HIP1R might be involved in the regulation of FLS phenotypes and molecular processes relevant to RA. siRNA was used to knockdwon HIP1R, HIP1 or control in RA FLS followed by cell studies for invasion in Matrigel, migration, proliferation and adhesion. RNA was sequenced and analyzed. HIP1R knockdown significantly reduced RA FLS invasiveness and migration (P<0.05). The DEGs in siRNA HIP1R had an enrichment for GO processes “astrocyte and glial cell projection”, “small GTPase signaling” and “PDGFR signaling”. The most significantly DEGs had decreased expression in siRNA HIP1R and included AKT1S1, GABBR2, GPR56, and TXNDC12. siRNA HIP1 RA FLS had an enrichment for the “Rap1 signaling pathway” and “Growth factor receptor binding”. The most significantly DEGs in HIP1 siRNA included FGF2, PGF, and SLC39A8. HIP1R and HIP1 DEG lists had a greater than expected number of similar genes (P=0.0015), suggesting that, despite the major differences detected, both have partially overlapping functions in RA FLS. The most significant DEGs in both HIP1R and HIP1 analyses are involved in cancer cell behaviors and outcomes. HIP1R is a new gene implicated in RA FLS invasiveness and migration, and regulates unique pathways and cell processes relevant to both RA as well as cancer biology. Our study provides new insight into processes implicated in FLS invasiveness, which is relevant for joint damage in RA, and identify new potential gene targets for FLS-specific treatments.

Project description:Background: The fibroblast-like synoviocyte (FLS) has a central role in rheumatoid arthritis (RA) pathogenesis and its invasive behavior strongly correlates with disease severity and joint damage. Yet, the regulation of FLS invasiveness is incompletely understood. Distal-less homeobox 4 (DLX4) is a transcription factor implicated in cancer cell invasion and metastasis, and we considered that it might also be involved in the regulation of FLS phenotypes. Results: siRNA knockdown of DLX4 significantly reduced RA FLS invasiveness (P=0.028) and migration in the scratch/wound healing assay (P=0.008). RNA sequencing analyses revealed that DLX4 knockdown significantly affected processes and pathways implicated in diverse types of cancer and in cancer biology and cell invasion, including cell cycle, DNA replication, transcription, p53 signal transduction, RHO GTPase signaling, regulation of cytokinesis, as well as response to oxygen levels and to oxidative stress. HMOX1 and SOD2 were among the genes with the most significantly increased expression, while CPNE3 and HADHA were among those with the most significantly decreased expression in FLS knocked down for DLX4 compared with controls. Conclusion: We describe a new role for DLX4 in the regulation of RA FLS behaviors relevant to disease pathogenesis and joint damage, and identify a new transcriptomic signature regulated by this gene. These findings raise the possibility that DLX4, or one of its target genes and pathways may become a target for treatment

Project description:Inflammation-mediated oncogenesis has been implicated in a variety of cancer types. Rheumatoid synovial tissues can be viewed as a tumor-like mass, consisting of hyperplastic fibroblast-like synoviocytes (FLSs). FLSs of rheumatoid arthritis (RA) patients have pro-migratory and invasive characteristics, which may be caused by chronic exposure to genotoxic stimuli, including hypoxia and growth factors. We tested whether a transformed phenotype of RA-FLSs is associated with placental growth factor (PlGF), a representative angiogenic growth factor induced by hypoxia. Here, we identified PlGF-1 and PlGF-2 as the major PlGF isoforms in RA-FLSs. Global gene expression profiling revealed that cell proliferation, apoptosis, angiogenesis, and cell migration were mainly represented by differentially expressed genes in RA-FLSs transfected with siRNA for PlGF. Indeed, PlGF-deficient RA-FLSs showed a decrease in cell proliferation, migration, and invasion, but an increase in apoptotic death in vitro. PlGF gene overexpression resulted in the opposite effects. Moreover, exogeneous PlGF-1 and PlGF-2 increased survival, migration, and invasiveness of RA-FLSs by binding their receptors, Flt-1 and NP-1, up-regulating the expression of anti-apoptotic molecules, pErk and Bcl2. Knock-down of PlGF transcripts reduced RA-FLS proliferation in a xeno-transplantation model. Collectively, in addition to their role for neovascularization, PlGF-1 and -2 promote proliferation, survival, migration, and invasion of RA-FLSs in an autocrine and paracrine manner. These results demonstrated how primary cells of mesenchymal origin acquired an aggressive and transformed phenotype. PlGF and its receptors thus offer new targets for anti-FLS therapy. The FLSs were prepared from the synovial tissues of RA patients and incubated in DMEM supplemented with 10% FBS. Cells were cultured in RPMI supplemented with 10% FBS. There are 4 FLS samples treated with PlGF siRNA, and 4 FLS samples treated with control siRNA.

Project description:Rheumatoid synoviocytes, which consist of fibroblast-like synoviocytes (FLS) and synovial macrophages (SM), are crucial for the progression of rheumatoid arthritis (RA). Particularly, FLS of RA patients (RA-FLS) exhibit invasive characteristics reminiscent of cancer cells, destroying cartilage and bone, although it remains unresolved how RA-FLS exhibit invasive phenotype. RA-FLS and SM originate differently from mesenchymal and myeloid cells, respectively, but share many pathologic functions. However, the molecular signatures and biological networks representing the distinct and shared features of the two cell types are unknown. Presently, we performed global transcriptome profiling of FLS and SM obtained from RA and osteoarthritis patients. By comparing the transcriptomes, we identified distinct molecular signatures and cellular processes defining invasiveness of RA-FLS and pro-inflammatory properties of RA synovial macrophages (RA-SM), respectively. Interestingly, under interleukin1β-stimulated condition, RA-FLS newly acquired pro-inflammatory signature mimicking RA-SM without losing invasive properties. We next reconstructed a network model that delineates the shared, RA-FLS-dominant (invasive), and RA-SM-dominant (inflammatory) processes. From the network model, we selected 13 genes, including POSTN and TWIST1, as novel regulator candidates responsible for FLS invasiveness. Of note, POSTN and TWIST1 expressions were elevated in independent RA-FLS and were further instigated by interleukin1β. In vitro functional assays demonstrated the requirement of POSTN and TWIST1 for migration and invasion of RA-FLS stimulated with interleukin1β. Taken together, our systems approach to rheumatoid synovitis provides a basis for identifying novel regulators responsible for pathological features of RA-FLS and RA-SM, demonstrating how a certain type of cells acquires functional redundancy under chronic inflammatory conditions. To identify molecular signatures of FLS and MLS in RA joints, we isolated FLS from synovial tissues of RA and osteoarthritis (OA) patients, obtained synovial macrophages from synovial fluid of RA patients, and differentiated control macrophages from peripheral blood of healthy subjects. Also, we stimulated FLS with IL1β, and then analyzed gene expression profiles of both IL1β-stimulated RA-FLS and OA-FLS

Project description:The variant rs26232, in the first intron of the C5orf30 locus, has recently been associated with both risk of developing rheumatoid arthritis (RA) and severity of tissue damage. The biological activities of human C5orf30 are unknown, and neither the gene nor protein show significant homology to any other characterized human sequences. The C5orf30 gene is present only in vertebrate genomes with a high degree of conservation implying a central function in these organisms. Here we report that C5orf30 is highly expressed in the synovium of RA patients compared with control synovial tissue, and that it is predominately expressed by synovial fibroblast (RASF) and macrophages in the lining and sublining layer of the tissue. These cells play a central role in the initiation and perpetuation of RA and are implicated in cartilage destruction. RASFs lacking C5orf30 exhibit increased cell migration and invasion in vitro and gene-profiling following C5orf30 inhibition confirmed upregulation of genes involved in cell migration, adhesion, angiogenesis, and immune and inflammatory pathways. Importantly, loss of C5orf30 contributes to the pathology of inflammatory arthritis in vivo, since inhibition of C5orf30 in the collagen-induced arthritis model markedly accentuated joint inflammation and tissue damage. Our study reveal C5orf30 to be a novel negative regulator of tissue damage in RA and this may act by modulating the autoaggressive phenotype that is characteristic of RASFs. Rheumatoid arthritis (RA) is a chronic, autoimmune, inflammatory disease that affects synovial joints. A key characteristic of RA is hyperplasia of fibroblast-like synoviocytes (FLS) which develop a stable, auto-aggressive phenotype that augments tissue destruction. It is unknown how this phenotype is stably maintained; however, epigenetic changes have been implicated. Histone deacetylation is one proposed method; a process controlled by histone deacetylases (HDACs). However, there have recently been reports publishing conflicting data regarding the expression of HDACs in RA synovium and FLS. The objective of this thesis is to determine the role of HDACs in regulating the auto-aggressive phenotype of RA through studies in FLS and in mice. Real time-quantitative PCR was used to assess the levels of HDAC1-11 in RA compared to osteoarthritis (OA) FLS. Immunohistochemistry and western blotting were used to assess protein expression of HDAC1 in RA and OA synovial tissue and FLS. HDAC1 was found to be overexpressed in RA compared to OA. HDAC1 was knocked down in RA FLS, then cell proliferation, migration and invasion were assessed by using tritiated thymidine, a scratch assay and a Matrigel invasion assay respectively. All three functions were significantly reduced following HDAC1 knockdown. An Illumina BeadChip (47,000 transcripts) was used to analyse global gene expression changes after knockdown. This revealed significant gene changes in important functional clusters, such as proliferation and migration. HDAC1 knockout is embryonic lethal in mice, so the in vivo role of HDAC1 was investigated in a mouse model of collagen-induced arthritis (CIA) using in vivo siRNAs. Clinical scores of CIA were measured daily and HDAC1 knockdown mice showed a significantly reduced clinical score compared to controls, comparable to dexamethasone-treated mice. The bones were analysed using a microCT scanner and histology. Knocking down HDAC1 showed reduced bone erosion, joint inflammation and cartilage degradation compared to controls. Overall, this study shows that HDAC1 is dysregulated in RA and it has a significant role in the autoaggressive phenotype shown in RA FLS and collagen-induced arthritis. The novel data shown in this thesis demonstrates that inhibiting HDAC1 may provide a powerful new target for treating RA. Three independent patient RASF samples were analysed in this study for each siRNA gene knockdown. Also a non targerting control siRNA was also used for each of the patient RASFs

Project description:Rheumatoid synoviocytes, which consist of fibroblast-like synoviocytes (FLS) and synovial macrophages (SM), are crucial for the progression of rheumatoid arthritis (RA). Particularly, FLS of RA patients (RA-FLS) exhibit invasive characteristics reminiscent of cancer cells, destroying cartilage and bone, although it remains unresolved how RA-FLS exhibit invasive phenotype. RA-FLS and SM originate differently from mesenchymal and myeloid cells, respectively, but share many pathologic functions. However, the molecular signatures and biological networks representing the distinct and shared features of the two cell types are unknown. Presently, we performed global transcriptome profiling of FLS and SM obtained from RA and osteoarthritis patients. By comparing the transcriptomes, we identified distinct molecular signatures and cellular processes defining invasiveness of RA-FLS and pro-inflammatory properties of RA synovial macrophages (RA-SM), respectively. Interestingly, under interleukin1β-stimulated condition, RA-FLS newly acquired pro-inflammatory signature mimicking RA-SM without losing invasive properties. We next reconstructed a network model that delineates the shared, RA-FLS-dominant (invasive), and RA-SM-dominant (inflammatory) processes. From the network model, we selected 13 genes, including POSTN and TWIST1, as novel regulator candidates responsible for FLS invasiveness. Of note, POSTN and TWIST1 expressions were elevated in independent RA-FLS and were further instigated by interleukin1β. In vitro functional assays demonstrated the requirement of POSTN and TWIST1 for migration and invasion of RA-FLS stimulated with interleukin1β. Taken together, our systems approach to rheumatoid synovitis provides a basis for identifying novel regulators responsible for pathological features of RA-FLS and RA-SM, demonstrating how a certain type of cells acquires functional redundancy under chronic inflammatory conditions.

Project description:Inflammation-mediated oncogenesis has been implicated in a variety of cancer types. Rheumatoid synovial tissues can be viewed as a tumor-like mass, consisting of hyperplastic fibroblast-like synoviocytes (FLSs). FLSs of rheumatoid arthritis (RA) patients have pro-migratory and invasive characteristics, which may be caused by chronic exposure to genotoxic stimuli, including hypoxia and growth factors. We tested whether a transformed phenotype of RA-FLSs is associated with placental growth factor (PlGF), a representative angiogenic growth factor induced by hypoxia. Here, we identified PlGF-1 and PlGF-2 as the major PlGF isoforms in RA-FLSs. Global gene expression profiling revealed that cell proliferation, apoptosis, angiogenesis, and cell migration were mainly represented by differentially expressed genes in RA-FLSs transfected with siRNA for PlGF. Indeed, PlGF-deficient RA-FLSs showed a decrease in cell proliferation, migration, and invasion, but an increase in apoptotic death in vitro. PlGF gene overexpression resulted in the opposite effects. Moreover, exogeneous PlGF-1 and PlGF-2 increased survival, migration, and invasiveness of RA-FLSs by binding their receptors, Flt-1 and NP-1, up-regulating the expression of anti-apoptotic molecules, pErk and Bcl2. Knock-down of PlGF transcripts reduced RA-FLS proliferation in a xeno-transplantation model. Collectively, in addition to their role for neovascularization, PlGF-1 and -2 promote proliferation, survival, migration, and invasion of RA-FLSs in an autocrine and paracrine manner. These results demonstrated how primary cells of mesenchymal origin acquired an aggressive and transformed phenotype. PlGF and its receptors thus offer new targets for anti-FLS therapy.

Project description:The variant rs26232, in the first intron of the C5orf30 locus, has recently been associated with both risk of developing rheumatoid arthritis (RA) and severity of tissue damage. The biological activities of human C5orf30 are unknown, and neither the gene nor protein show significant homology to any other characterized human sequences. The C5orf30 gene is present only in vertebrate genomes with a high degree of conservation implying a central function in these organisms. Here we report that C5orf30 is highly expressed in the synovium of RA patients compared with control synovial tissue, and that it is predominately expressed by synovial fibroblast (RASF) and macrophages in the lining and sublining layer of the tissue. These cells play a central role in the initiation and perpetuation of RA and are implicated in cartilage destruction. RASFs lacking C5orf30 exhibit increased cell migration and invasion in vitro and gene-profiling following C5orf30 inhibition confirmed upregulation of genes involved in cell migration, adhesion, angiogenesis, and immune and inflammatory pathways. Importantly, loss of C5orf30 contributes to the pathology of inflammatory arthritis in vivo, since inhibition of C5orf30 in the collagen-induced arthritis model markedly accentuated joint inflammation and tissue damage. Our study reveal C5orf30 to be a novel negative regulator of tissue damage in RA and this may act by modulating the autoaggressive phenotype that is characteristic of RASFs. Rheumatoid arthritis (RA) is a chronic, autoimmune, inflammatory disease that affects synovial joints. A key characteristic of RA is hyperplasia of fibroblast-like synoviocytes (FLS) which develop a stable, auto-aggressive phenotype that augments tissue destruction. It is unknown how this phenotype is stably maintained; however, epigenetic changes have been implicated. Histone deacetylation is one proposed method; a process controlled by histone deacetylases (HDACs). However, there have recently been reports publishing conflicting data regarding the expression of HDACs in RA synovium and FLS. The objective of this thesis is to determine the role of HDACs in regulating the auto-aggressive phenotype of RA through studies in FLS and in mice. Real time-quantitative PCR was used to assess the levels of HDAC1-11 in RA compared to osteoarthritis (OA) FLS. Immunohistochemistry and western blotting were used to assess protein expression of HDAC1 in RA and OA synovial tissue and FLS. HDAC1 was found to be overexpressed in RA compared to OA. HDAC1 was knocked down in RA FLS, then cell proliferation, migration and invasion were assessed by using tritiated thymidine, a scratch assay and a Matrigel invasion assay respectively. All three functions were significantly reduced following HDAC1 knockdown. An Illumina BeadChip (47,000 transcripts) was used to analyse global gene expression changes after knockdown. This revealed significant gene changes in important functional clusters, such as proliferation and migration. HDAC1 knockout is embryonic lethal in mice, so the in vivo role of HDAC1 was investigated in a mouse model of collagen-induced arthritis (CIA) using in vivo siRNAs. Clinical scores of CIA were measured daily and HDAC1 knockdown mice showed a significantly reduced clinical score compared to controls, comparable to dexamethasone-treated mice. The bones were analysed using a microCT scanner and histology. Knocking down HDAC1 showed reduced bone erosion, joint inflammation and cartilage degradation compared to controls. Overall, this study shows that HDAC1 is dysregulated in RA and it has a significant role in the autoaggressive phenotype shown in RA FLS and collagen-induced arthritis. The novel data shown in this thesis demonstrates that inhibiting HDAC1 may provide a powerful new target for treating RA.

Project description:Platelet microparticles (PMPs) are closely related to the activity of rheumatoid arthritis, and promote the migration and invasion of rheumatoid arthritis fibroblast-like synoviocytes (RA-FLSs). In order to identify the possible mechanisms of the promotion effect on migration and invasion of RA-FLS by PMP, we used microarray analysis to detect the gene expressions of RA-FLSs after treatment with PMPs.

Project description:To determine the mechanism of abnormal activity of RA FLS, we have done some research and found out that lncRNA HASML and protein HuR have some effects on migration and invasion of RA FLS. To more deeply explore how HASML and HuR regulate the functions of RA FLS, RNA sequencing analysis was used to evaluate the transcriptome of siHASML and siHuR treatment and negative control (NC) group. A P-value less than 0.05 was considered significant.