RESUMEN
Osteoarthritis (OA) is a common degenerative disease of the motor system with a high morbidity and disability rate. The pathogenesis of OA is not clear at present. Previous studies believe that the pathogenesis of OA is mainly related to trauma factors, while recent studies have shown that metabolic factors, including abnormal cholesterol metabolism, are also closely related to OA. The treatment of OA is mainly symptomatic treatment at the early stage and surgical treatment at the late stage, and there is no specific drug. Previously, BNTA, a small molecule drug with cartilage protective effects, has been shown to have a good effect on OA caused by trauma, but its effect on OA caused by high cholesterol remains unclear. In order to explore the therapeutic effect of BNTA on OA caused by high cholesterol and its mechanism, the OA model of rats was constructed by adopting high cholesterol diets, and paraffin sections of knee joints were taken for histological evaluation. Lipid accumulation in chondrocytes of rats was assessed by oil red O staining. The expression of genes and proteins related to anabolism, catabolism and cholesterol metabolism in chondrocytes was assessed by RT-qPCR, immunofluorescence and immunohistochemistry. The results showed that BNTA could alleviate OA pathological manifestations and improve the OARSI (Osteoarthritis Research Society International) score in the OA model of high cholesterol rats. In rat chondrocytes, BNTA can promote the expression of anabolism-related genes col2, sox9 and acan, inhibit the expression of catabolism-related genes mmp13 and adamts5, and improve the lipid accumulation caused by high cholesterol in rat chondrocytes. BNTA can up-regulate Insig1 expression in rat chondrocytes and the OA model of high cholesterol rats. This study confirmed that high cholesterol can aggravate OA in vivo and in vitro, and can increase lipid accumulation in rat chondrocytes. Taken together, BNTA can alleviate OA phenotypes induced by high cholesterol and improve abnormal lipid accumulation in chondrocytes, possibly by inhibiting cholesterol biosynthesis in cells by upregulating Insig1, thereby alleviating abnormal lipid accumulation.
RESUMEN
Objective To investigate the expression and regulation of programmed cell death protein 1 (PD1), B lymphocyte and T lymphocyte attenuator (BTLA) in peripheral blood of patients with non-small cell lung cancer (NSCLC); to examine the correlation of the mRNA levels between PD and BTLA in NSCLC. Methods Flow cytometry was used to detect the expression of PD1 and BTLA on the surfaces of CD8+ T cells and γδ+ T cells in the peripheral blood samples collected from 32 in-patients with stage IV NSCLC and 30 healthy individuals. We compared the expression of PD1 and BTLA on the surfaces of γδ+ T cells in the NSCLC patients with bone metastasis before and after the treatment of zoledronic acid. The correlations of PD1 and BTLA, as well as their ligands were analyzed using Pearson correlation analysis with the cBioPortal data platform. Results The frequency of PD1 on the surfaces of CD8+ T cells was significantly higher than that of the γδT cells in both healthy controls (t=2.324, P=0.024) and NSCLC patients(t=2.498, P=0.015). The frequency of PD1 on CD8+ T cells, rather than on γδ+ T cells, was significantly upregulated in advanced NSCLC patients compared with that in healthy controls (t=4.829, P<0.001). The PD1+ BTLA+γδT cells of the healthy controls were significantly lower than that of the NSCLC patients (t=2.422, P=0.0185). No differences in percentage of PD1+γδ+ and BTLA+γδ+ T cells were observed in 7 NSCLC patients with bone metastasis before and after zoledronic acid treatment. PD1 was positively correlated with BTLA in both lung adenocarcinoma (r=0.54; P<0.05) and lung squamous cell carcinoma (r=0.78; P<0.05). Conclusions The upregulation of co-inhibitory molecules occurs on the surfaces of both CD8+ T cells and γδT cells in advanced NSCLC, suggesting that these molecules were involved in regulating the inactivation of CD8+ T cells and γδ+ T cells, immune escape and tumor invasion.