An Optimized RNA Extraction Method From Micro-quantities of Guinea Pig Cartilage and Synovium for Osteoarthritis Research.

Osteoarthritis (OA) is the primary cause of joint impairment, particularly in the knee. The prevalence of OA has significantly increased, with knee OA being a major contributor whose pathogenesis remains unknown. Articular cartilage and the synovium play critical roles in OA, but extracting high-quality RNA from these tissues is challenging because of the high extracellular matrix content and low cellularity. This study aimed to identify the most suitable RNA isolation method for obtaining high-quality RNA from microquantities of guinea pig cartilage and synovial tissues, a relevant model for idiopathic OA. We compared the traditional TRIzol(®) method with modifications to spin column-based methods (TRIspin-TRIzol(®)/RNeasy(TM), RNeasy(TM) kit, RNAqueous(TM) kit, and Quick-RNA(TM) Miniprep Plus kit), and an optimized RNA isolation protocol was developed to increase RNA yield and purity. The procedure involved meticulous sample collection, specialized tissue processing, and measures to minimize RNA degradation. RNA quality was assessed via spectrophotometry and RT-qPCR. The results demonstrated that among the tested methods, the Quick-RNA(TM) Miniprep Plus kit with proteinase K treatment yielded the highest RNA purity, with A(260:280) ratios ranging from 1.9 to 2.0 and A(260:230) ratios between 1.6 and 2.0, indicating minimal to no salt contamination and RNA concentrations up to 240 ng/μL from ⁓20 mg of tissue. The preparation, storage, homogenization process, and choice of RNA isolation method are all critical factors in obtaining high-purity RNA from guinea pig cartilage and synovial tissues. Our developed protocol significantly enhances RNA quality and purity from micro-quantities of tissue, making it particularly effective for RTqPCR in resource-limited settings. Further refinements can potentially increase RNA yield and purity, but this protocol facilitates accurate gene expression analyses, contributing to a better understanding of OA pathogenesis and the development of therapeutic strategies. Key features • Enables efficient RNA isolation from small, individual cartilage samples, eliminating the need for pooling and requiring minimal laboratory equipment. • Provides a reliable and cost-effective method for obtaining high-quality RNA suitable for RT-qPCR and gene expression analysis, from challenging tissue types like cartilage. Graphical overview Graphical representation comparing modified RNA isolation protocols for efficient RNA extraction from guinea pig cartilage and synovium.