S. Guidotti

Hydroxytyrosol prevents chondrocyte death under oxidative stress by inducing autophagy through sirtuin 1-dependent and -independent mechanisms

BACKGROUND Hydroxytyrosol (HT), a major phenolic antioxidant found in olive oil, can afford protection from oxidative stress in several types of non-tumoral cells, including chondrocytes. Autophagy was recently identified as a protective process during osteoarthritis (OA) development and critical for survival of chondrocytes. Therefore we have investigated the possibility to modulate chondrocyte autophagy by HT treatment. METHODS DNA damage and cell death were estimated in human C-28/I2 and primary OA chondrocytes exposed to hydrogen peroxide. Autophagic flux and mitophagy were monitored by measuring levels and location of autophagy markers through western blot, immunostaining and confocal laser microscopy. Late autophagic vacuoles were stained with monodansylcadaverine. The involvement of sirtuin 1 (SIRT-1) was evaluated by immunohistochemistry, western blot and gene silencing with specific siRNA. RESULTS HT increases markers of autophagy and protects chondrocytes from DNA damage and cell death induced by oxidative stress. The protective effect requires the deacetylase SIRT-1, which accumulated in the nucleus following HT treatment. In fact silencing of this enzyme prevented HT from promoting the autophagic process and cell survival. Furthermore HT supports autophagy even in a SIRT-1-independent manner, by increasing p62 transcription, required for autophagic degradation of polyubiquitin-containing bodies. CONCLUSIONS These results support the potential of HT as a chondroprotective nutraceutical compound against OA, not merely for its antioxidant ability, but as an autophagy and SIRT-1 inducer as well. GENERAL SIGNIFICANCE HT may exert a cytoprotective action by promoting autophagy in cell types that may be damaged in degenerative diseases by oxidative and other stress stimuli.

Hydroxytyrosol Prevents Increase of Osteoarthritis Markers in Human Chondrocytes Treated with Hydrogen Peroxide or Growth-Related Oncogene α

Hydroxytyrosol (HT), a phenolic compound mainly derived from olives, has been proposed as a nutraceutical useful in prevention or treatment of degenerative diseases. In the present study we have evaluated the ability of HT to counteract the appearance of osteoarthritis (OA) features in human chondrocytes. Pre-treatment of monolayer cultures of chondrocytes with HT was effective in preventing accumulation of reactive oxidant species (ROS), DNA damage and cell death induced by H2O2 exposure, as well as the increase in the mRNA level of pro-inflammatory, matrix-degrading and hypertrophy marker genes, such as iNOS, COX-2, MMP-13, RUNX-2 and VEGF. HT alone slightly enhanced ROS production, but did not enhance cell damage and death or the expression of OA-related genes. Moreover HT was tested in an in vitro model of OA, i.e. three-dimensional micromass cultures of chondrocytes stimulated with growth-related oncogene α (GROα), a chemokine involved in OA pathogenesis and known to promote hypertrophy and terminal differentiation of chondrocytes. In micromass constructs, HT pre-treatment inhibited the increases in caspase activity and the level of the messengers for iNOS, COX-2, MMP-13, RUNX-2 and VEGF elicited by GROα. In addition, HT significantly increased the level of SIRT-1 mRNA in the presence of GROα. In conclusion, the present study shows that HT reduces oxidative stress and damage, exerts pro-survival and anti-apoptotic actions and favourably influences the expression of critical OA-related genes in human chondrocytes treated with stressors promoting OA-like features.

Enhanced Osteoblastogenesis of Adipose-Derived Stem Cells on Spermine Delivery via β-Catenin Activation

The molecular mechanisms underlying spermine osteo-inductive activity on human adipose-derived stem cells (ASCs) grown in 3-dimensional (3D) cultures were investigated. Spermine belongs to the polyamine family, naturally occurring, positively charged polycations that are able to control several cellular processes. Spermine was used at a concentration close to that found in platelet-rich plasma (PRP), an autologous blood product containing growth and differentiation factors, which has recently become popular in in vitro and in vivo bone healing and engineering. Adipose tissue was surgically obtained from the hypodermis of patients undergoing hip arthroplasty. Patient age negatively affected both ASC yield and ASC ability to form 3D constructs. ASC 3D cultures were seeded in either non differentiating or chondrogenic conditions, with or without the addition of 5 μM spermine to evaluate its osteogenic potential across 1, 2, and 3 weeks of maturation. Osteogenic medium was used as a reference. The effects of the addition of spermine on molecular markers of osteogenesis, at both gene and protein level, and mineralization were evaluated. The effects of spermine were temporally defined and responsible for the progression from the early to the mature osteoblast differentiation phases. Spermine initially promoted gene and protein expression of Runx-2, an early marker of the osteoblast lineage; then, it increased β-catenin expression and activation, which led to the induction of Osterix gene expression, the mature osteoblast commitment factor. The finding that spermine induces ASC to differentiate toward mature osteoblasts supports the use of these easily accessible mesenchymal stem cells coupled with PRP for orthopedic applications.

Polyamine delivery as a tool to modulate stem cell differentiation in skeletal tissue engineering

The first step in skeleton development is the condensation of mesenchymal precursors followed by any of two different types of ossification, depending on the type of bone segment: in intramembranous ossification, the bone is deposed directly in the mesenchymal anlagen, whereas in endochondral ossification, the bone is deposed onto a template of cartilage that is subsequently substituted by bone. Polyamines and polyamine-related enzymes have been implicated in bone development as global regulators of the transcriptional and translational activity of stem cells and pivotal transcription factors. Therefore, it is tempting to investigate their use as a tool to improve regenerative medicine strategies in orthopedics. Growing evidence in vitro suggests a role for polyamines in enhancing differentiation in both adult stem cells and differentiated chondrocytes. Adipose-derived stem cells have recently proved to be a convenient alternative to bone marrow stromal cells, due to their easy accessibility and the high frequency of stem cell precursors per volume unit. State-of-the-art “prolotherapy” approaches for skeleton regeneration include the use of adipose-derived stem cells and platelet concentrates, such as platelet-rich plasma (PRP). Besides several growth factors, PRP also contains polyamines in the micromolar range, which may also exert an anti-apoptotic effect, thus helping to explain the efficacy of PRP in enhancing osteogenesis in vitro and in vivo. On the other hand, spermidine and spermine are both able to enhance hypertrophy and terminal differentiation of chondrocytes and therefore appear to be inducers of endochondral ossification. Finally, the peculiar activity of spermidine as an inducer of autophagy suggests the possibility of exploiting its use to enhance this cytoprotective mechanism to counteract the degenerative changes underlying either the aging or degenerative diseases that affect bone or cartilage.

Infrapatellar fat pad-derived mesenchymal stromal cells from osteoarthritis patients: In vitro genetic stability and replicative senescence

Different sources of mesenchymal stromal cells can be considered for regenerative medicine applications. Here we analyzed human adipose‐derived stromal cells from infrapatellar fat pad (IFPSC) of osteoarthritis patients, representing a very interesting candidate for cartilage regeneration. No data are available concerning IFPSC stability after in vitro expansion. Indeed, replicative potential and multipotency progressively decrease during culture passages while DNA damage and cell senescence increase, thus possibly affecting clinical applications. To investigate whether in vitro expansion influences the genetic stability and replicative senescence of IFPSC, we performed long‐term cultures and comparatively analyzed cells at different culture passages. Stromal vascular fraction was harvested from infrapatellar fat pad of 11 osteoarthritis patients undergoing knee replacement surgery. Cell recovery, growth kinetics, surface marker profile, and differentiation ability in inductive culture conditions were recorded. Genetic integrity maintenance was estimated by microsatellite instability analysis and mismatch repair gene expression, whereas telomere length and telomerase activity were assessed to evaluate replicative senescence. Anchorage‐dependent growth was tested by soft agar culture. IFPSC displayed a phenotype similar to mesenchymal stromal cells from subcutaneous fat and showed differentiation ability. No microsatellite instability was documented even at advanced culture times in accordance to a sustained expression of mismatch repair genes, thus highlighting stability of short repeated sequences in the genome. No significant telomere attrition nor telomerase activity were documented during culture and cells did not lose anchorage‐dependent growth ability. The presented data support the suitability and safety of in vitro expanded IFPSC from osteoarthritis patients for applications in regenerative medicine approaches.

267 ROLE OF POLYAMINES IN HYPERTROPHY AND TERMINAL DIFFERENTIATION OF OSTEOARTHRITIC CHONDROCYTES

Following the first 9 scans, the DMEM was removed and replaced with 0.1, 1, 10 or 55ng/mL IL-1a or the corresponding vehicular control (PBS). A [Ca]i response was defined as an increase in the fluorescence ratio Fluo 4/Fura Red >3 sd above background measured during the first nine scans. The percentage of cells responding with single or multiple fluxes was determined and statistically analyzed (c2, p < 0.05). Results: Thirty percent of chondrocytes responded with [Ca]i when exposed to 1, 10 or 55ng/mL IL-1a. This response was consistently and significantly greater than the corresponding vehicular controls. In contrast, there was no significant effect at 0.1 ng/mL IL-1a (Fig. 2). Conclusions: Our data suggests that 1ng/mL is the threshold concentration of IL-1a which exerts a significant effect on chondrocytes in intact murine femora. Such a threshold response may imply the activation of the chondrocyte immunoglobulin IL-1 receptor. Thirty percent of chondrocytes responded with [Ca]i fluxes in a dose independent manner, perhaps indicating a saturation of IL-1 receptors at 1 ng/mL IL-1a. This is in contrast to previous studies that have imaged chondrocytes in explants or culture and reported a larger percentage of cells responding in a dose dependent manner (24% at 0.1 ng/ml, 90% at10ng/mL in explants). Notwithstanding species (porcine/murine) and diffusion contrasts between these studies, we hypothesize that there is a saturation of the IL-1 receptors at 1 ng/mL IL-1a in intact murine cartilage and that the integrity of the extracellular matrix interactions with both the subchondral bone and chondrocyte membrane influence both the number of chondrocytes responding and the dose dependent characteristics of this response. In conclusion, these data provide further evidence that the increased concentration of IL-1a present in osteoarthritic joints has the ability to influence the biological activity of chondrocytes in vivo.