Laurent Grossin

Gene transfer with HSP 70 in rat chondrocytes confers cytoprotection in vitro and during experimental osteoarthritis

Osteoarthritis is characterized by a gradual degradation of extracellular matrix, resulting from an excess of chondrocyte cell death, mainly due to an increase in apoptotis. Recent studies have revealed the essential role of HSP70 in protecting cells from stressful stimuli. Therefore, overexpressing HSP70 in chondrocytes could represent a good strategy to prevent extracellular matrix destruction. To this end, we have developed a vector carrying HSP70/GFP, and transduced chondrocytes were thus more resistant to cell death induced by mono‐iodoacetate (MIA). To overcome the barrier‐effect of matrix, we investigated the efficacy of plasmid delivery by electroporation (EP) in rat patellar cartilage. Two days after EP, 50% of patellar chondrocytes were HSP/GFP+. After 3 months, long‐term expression of transgene was only depicted in the deep layer (20–30% positive cells). HSP70 overexpression inhibited the natural endochondral ossification in the deep layer, thus leading to a lesser decrease in chondrocyte distribution. Moreover, overexpression of HSP70, after a preventive EP transfer in rat patella, was sufficient to decrease the severity of osteoarthritis‐induced lesions, as demonstrated histologically and biochemically. In conclusion, intracellular overexpression of HSP70, through EP delivery, could protect chondrocytes from cellular injuries and thus might be a novel chondroprotective modality in rat OA.—Grossin, L., Cournil‐Henrionnet, C., Pinzano, A., Gaborit, N., Dumas, D., Etienne, S., Stoltz, J. F., Terlain, B., Netter, P., Mir, L. M., Gillet, P. Gene transfer with HSP 70 in rat chondrocytes confers cytoprotection in vitro and during experimental osteoarthritis. FASEB J. 20, 65–75 (2006)

Evaluation of cartilage repair tissue after biomaterial implantation in rat patella by using T2 mapping

To evaluate the ability of MR T2 mapping (8.5 T) to characterize ex vivo longitudinally, morphologically and quantitatively, alginate-based tissue engineering in a rat model of patellar cartilage chondral focal defect. Calibrated rat patellar cartilage defects (1.3 mm) were created at day 0 (D0) and alginate sponge with (Sp/C+) or without (Sp/C−) autologous chondrocytes were implanted. Animals were sacrificed sequentially at D20, D40 and D60 after surgery and dissected patellae underwent MRI exploration (8.5 T). T2 values were calculated from eight SE images by using nonlinear least-squares curve fitting on a pixel-by-pixel basis (constant repetition time of 1.5 s, eight different echo times: 5.5, 7.5, 10.5, 12.5, 15.0, 20.0, 25.0 and 30.0 ms). On the T2 map, acquired in a transversal plane through the repair zone, global T2 values and zonal variation of T2 values of repair tissue were evaluated versus control group and compared with macroscopic score and histological studies (toluidine blue, sirius red and hematoxylin-eosin). “Partial”, “total” and “hypertrophic” repair patterns were identified. At D40 and D60, Sp/C+ group was characterized by a higher proportion of “total” repair in comparison to Sp/C− group. At D60, the proportion of “hypertrophic” repair was two fold in Sp/C− group versus Sp/C+ group. As confirmed morphologically and histologically, the T2 map also permitted the distinction of three types of repair tissue: “total”, “partial” and “hypertrophic”. “Total” repair tissue was characterized by high T2 values versus normal cartilage (p<0.05). Zonal variation, reflecting the collagen network organization, appeared only at D60 for Sp/C+ group (p<0.05). “Hypertrophic” tissue, mainly observed at D60, presented high T2 global values without zonal variation with cartilage depth. These results confirm the potency of the MR T2 map (8.5 T) to characterize macroscopically and microscopically the patterns of the scaffold guided-tissue repair of a focal chondral lesion in the rat patella (“total”, “partial” and “hypertrophic”). On T2 map, three parameters (i.e. MRI macroscopic pattern, T2 global values and zonal variation of T2 values) permit to characterize chondral repair tissue, as a virtual biopsy.

Direct gene transfer into rat articular cartilage by in vivo electroporation

To establish a system for efficient direct in vivo gene targeting into rat joint, we have evaluated a strategy of gene transfer by means of the delivery of external electric pulses (EP) to the knee after intraarticular injection of a reporter gene (GFP). Rats were killed at various times after the electro gene‐therapy to analyze GFP gene expression by immunohistochemistry. GFP staining was detected in the superficial, middle, and deep zones of the patellar cartilage at days 2 and 9, and thereafter only in the deep zone (months 1 and 2). The average percentage of GFP‐positive cells was estimated at 30% both one and 2 months after the gene transfer. Moreover, no pathologic change caused by the EP was detected in the cartilage. The level and stability of the long‐term GFP expression found in this study demonstrate the feasibility of a treatment of joint disorders (inflammatory or degenerative, focal or diffuse) using electric gene transfer.—Grossin, L., Cournil‐Henrionnet, C., Mir, L. M., Liagre, B., Dumas, D., Etienne, S., Guingamp, C., Netter, P., Gillet, P. Direct gene transfer into rat articular cartilage by in vivo electroporation. FASEB J. 17, 829–835 (2003)

Evaluation of intra-articular delivery of hyaluronic acid functionalized biopolymeric nanoparticles in healthy rat knees.

The aim of this study is to evaluate the toxicity of nanoparticles of poly(D,L-lactic acid) (PLA) or poly(D,L-lactic-co-glycolic acid) (PLGA) covered by chemically esterified amphiphilic hyaluronate (HA) which will be used for intra-articular injection as a drug carrier for the treatment of arthritis (RA) and/or osteoarthritis (OA). PLA and PLGA are FDA approved polymers that are already used for the preparation of nano or microparticles. HA is a natural polysaccharide already present in the articulations known to interact with the CD44 receptors of the cells (especially chondrocytes). Therefore, we can envisage that the HA covering can improve the interactions between the cells and the nanoparticles, leading to better targeting or biodistribution. The knee of healthy male rats was injected one to two times weekly, with various concentrations of nanoparticles encapsulating Dextran-FITC. The synovial membranes and the patellae were collected aseptically and histologically analyzed to assess the effects and localization of the nanocapsules in the knee joint. We did not observe significant modifications in the synovial membranes (weak hyperplasia) or patellae integrity after local administration of nanodevices into the rats. While we found some nanoparticles in the synovial membrane, none were detected in the patellae. Moreover, the histological observations for patellae were confirmed by radiosulfate intake, which depicted no decrease in proteoglycans biosynthesis in nanoparticles treated animals. Concerning the safety towards synovial membranes, we also had a look at the inflammatory response after injections of nanoparticles covered by amphiphilic HA or polyvinyl alcohol (PVA) by monitoring the mRNA expression levels of some specific early cytokines (IL-1β and TNF-α). Once again, no differences were observed between the control rats and the rats treated with nanoparticles. Considering these preliminary results obtained in healthy rats, we can establish that neither the amphiphilic HA-covered PLGA nanoparticles nor their degradation products induce major modifications of articular tissues functions, while injected into the knee of healthy rats. These results should be confirmed in OA or RA rat models, in order to confirm that nanoparticles do not worsen already altered (degenerative or inflamed) articular tissues. Once confirmed, such tuneable nanoparticles could be proposed as a safe drug delivery system for the treatment of articular disease, allowing a wide range of encapsulating molecules.

Local induction of heat shock protein 70 (Hsp70) by proteasome inhibition confers chondroprotection during surgically induced osteoarthritis in the rat knee

AIM to determine if chondrocytic Hsp70 induction, via intra-articular injections of a reversible proteasome inhibitor (MG132), can protect articular chondrocytes from cellular death in experimental rat OA knee induced surgically by anterior cruciate ligament transection (ACLT). MATERIALS AND METHODS ACLT was performed on D0. Histological lesions in naive (sham) controls (ACLT+saline) and treated (ACLT+MG132) rats were assessed according to Mankins score. Repeated intra-articular injections (1.5 muM MG132 or saline were performed on D1, D7, D14 and D21. Rats were sacrificed sequentially on D7, D14 and D28. Detection of active caspase-3 and protein expression of Hsp70 was also determined on D7, D14 and D28 by immunostaining methods. RESULTS MG132 significantly reduced OA lesions on D28 in the MG132 treated group. The expression of Hsp70 increased 11-fold in the MG132-treated group versus 2-3-fold in ACLT-control rats on D28. Concomitantly, cells expressing caspase-3 increased 4-fold in ACLT model and decreased 2-fold with MG132 treatment. CONCLUSIONS Intra-articular induction of Hsp70 by MG132 could be a safe and interesting tool in chondrocytes protection from cellular injuries and thus might be a novel chondroprotective modality in rat OA.

Ambivalent properties of hyaluronate and hylan during post-traumatic OA in the rat knee.

AIM To determine whether viscosupplementation with intra-articular (i.a.) low- or high-molecular-weight hyaluronate (HA) injections influenced both chondral and synovial lesions in rats with surgically-induced OA knee. METHODS On D0, rats underwent anterior cruciate ligament transection (ACLX) and were divided in 4 groups: sham group, ACLX-saline control group, ACLX-hyaluronate group, ACLX-hylan group. IA injections were performed on D7, D14 and D21. Histological grading of chondral and synovial lesions were performed on D28. Concomitant immunostainings of Caspase3a and Hsp70 were also performed. RESULTS Articular damages were significantly reduced in both HAs-treated knee joints. In contrast, a significant increase of histological score of synovial inflammation was noted in both ACLX + HAs groups. Apoptotic events significantly decreased as anti-apoptotic Hsp70 expression increased significantly in both HAs groups. CONCLUSION HAs may exert, independently of its molecular weight, ambivalent properties on articular structures, simultaneously exerting chondroprotective properties and promoting long-term subacute synovitis.

Evaluation of a rat knee mono-arthritis using microPET.

AIM Assessing the activity of synovitis, which is characterized by an increase in cell metabolism, is important for the prediction of future articular destruction in clinical and preclinical studies. To evaluate the correlation between ¹⁸F-FDG accumulation and arthritis pathology during its establishment, we used microPET to evaluted ¹⁸F-FDG accumulation in vivo during rat Mycobacterium wall-induced knee arthritis. METHODS ¹⁸F-FDG PET images of arthritic rats were acquired on days 1, 2, 3 and 7 after arthritis induction. The subjects (n=2/time) were subsequently subjected to macro-autoradiography, and ¹⁸F-FDG accumulation was compared with histological findings. RESULTS ¹⁸F-FDG PET images depicted swollen joints, and ¹⁸F-FDG accumulation increased with the progression of arthritis. Histologically, increased ¹⁸F-FDG accumulation correlated with the pannus rather than the infiltration of inflammatory cells around the joints. CONCLUSION ¹⁸F-FDG accumulation in arthritis reflects proliferating pannus and inflammatory activity enhanced by inflammatory cytokines. ¹⁸F-FDG microPET should be effective for quantifying the inflammatory activity of arthritis and/or its therapeutic response.