Synoviocytes assist in modulating the effect of Ross River virus infection in micromass-cultured primary human chondrocytes.

Wesley Freppel, Elisa X Y Lim, Penny A Rudd, Lara J Herrero
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Abstract

Introduction. Ross River virus (RRV) is a mosquito-borne virus prevalent in Australia and the islands of the South Pacific, where it causes an arthritogenic illness with a hallmark feature of severe joint pain. The joint space is a unique microenvironment that contains cartilage and synovial fluid. Chondrocytes and synoviocytes are crucial components of the joint space and are known targets of RRV infection.Hypothesis/Gap statement. Understanding the relationship between synoviocytes and chondrocytes during RRV infection will provide further insights into RRV-induced joint pathology.Methodology. To better understand the unique dynamics of these cells during RRV infection, we used primary chondrocytes cultured in physiologically relevant micromasses. We then directly infected micromass chondrocytes or infected primary fibroblast-like synoviocytes (FLS), co-cultured with micromass chondrocytes. Micromass cultures and supernatants were collected and analysed for viral load with a PCR array of target genes known to play a role in arthritis.Results. We show that RRV through direct or secondary infection in micromass chondrocytes modulates the expression of cellular factors that likely contribute to joint inflammation and disease pathology, as well as symptoms such as pain. More importantly, while we show that RRV can infect micromass-cultured chondrocytes via FLS infection, FLS themselves affect the regulation of cellular genes known to contribute to arthritis.Conclusion. Single-cell culture systems lack the complexity of in vivo systems, and understanding the interaction between cell populations is crucial for deciphering disease pathology, including for the development of effective therapeutic strategies.

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滑膜细胞有助于调节罗斯河病毒感染对微量培养的原代人类软骨细胞的影响。
导言。罗斯河病毒(RRV)是一种由蚊子传播的病毒,流行于澳大利亚和南太平洋岛屿,可引起关节炎性疾病,其主要特征是关节剧痛。关节间隙是一个包含软骨和滑液的独特微环境。软骨细胞和滑膜细胞是关节间隙的重要组成部分,也是已知的 RRV 感染目标。了解 RRV 感染期间滑膜细胞和软骨细胞之间的关系将有助于进一步了解 RRV 引起的关节病理学。为了更好地了解这些细胞在 RRV 感染期间的独特动态,我们使用了在生理相关的微质量中培养的原代软骨细胞。然后,我们直接感染微质量软骨细胞或感染与微质量软骨细胞共同培养的原代成纤维细胞样滑膜细胞(FLS)。收集微量培养物和上清液,用已知在关节炎中起作用的靶基因的 PCR 阵列分析病毒载量。我们的研究结果表明,RRV 通过直接或继发感染微质量软骨细胞,调节了细胞因子的表达,而这些因子可能会导致关节炎症、疾病病理以及疼痛等症状。更重要的是,虽然我们表明 RRV 可以通过 FLS 感染微质量培养软骨细胞,但 FLS 本身会影响已知会导致关节炎的细胞基因的调控。单细胞培养系统缺乏体内系统的复杂性,而了解细胞群之间的相互作用对于破译疾病病理,包括开发有效的治疗策略至关重要。
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