Candidate Gene Expression in Adult Zebrafish Models of Type 2 Diabetes Mellitus.

Animal models are an important tool for studying noncommunicable diseases (NCDs) as they provide a unique opportunity to investigate real-time changes that occur in the onset of, and during, the diseased state. This is of particular importance given that the global prevalence of NCDs, such as type 2 diabetes mellitus (T2DM), is rising at an alarming rate. In South Africa, which has one of the highest levels of HIV in the world, the incidence of T2DM is thought to be associated, in part, with exposure to combination antiretrovirals.

A regenerative approach to the pharmacological management of hard-to-heal wounds.

A wound is considered hard-to-heal when, despite the appropriate clinical analysis and intervention, the wound area reduces by less than a third at four weeks and complete healing fails to occur within 12 weeks. The most prevalent hard-to-heal wounds are associated with underlying metabolic diseases or vascular insufficiency and include arterial, venous, pressure and diabetic foot ulcers. Their common features include an abnormal immune response and extended inflammatory phase, a subdued proliferation phase due to cellular insufficiencies and finally an almost non-existent remodeling phase.

Co-culture of pro-inflammatory macrophages and myofibroblasts: Evaluating morphological phenotypes and screening the effects of signaling pathway inhibitors.

Skeletal muscle regeneration is a complex process influenced by non-myogenic macrophages and fibroblasts, which acquire different phenotypes in response to changes in the injury milieu or changes in experimental conditions. In vitro, serum stimulates the differentiation of fibroblasts into myofibroblasts, while lipopolysaccharide (LPS) stimulates the polarization of unstimulated (M0) macrophages to acquire an M1 pro-inflammatory phenotype. We characterized these phenotypes using morphology (with circularity as shape descriptor; perfect circularity = 1.

Ex vivo antioxidant preconditioning improves the survival rate of bone marrow stem cells in the presence of wound fluid.

The advancement of autologous mesenchymal stem cell (MSC) therapy for the treatment of non-healing diabetic wounds is hampered by endogenous MSC dysfunction and limited viability of cells post-transplantation into the pathological wound environment. The development of effective strategies to restore the functional capabilities of these impaired MSCs prior to transplantation may be a key to their ultimate success as wound repair mediators. The current study therefore investigated whether antioxidant preconditioning [7.

Antioxidant Preconditioning Improves the Paracrine Responsiveness of Mouse Bone Marrow Mesenchymal Stem Cells to Diabetic Wound Fluid.

Mesenchymal stem cells (MSCs) are a promising therapeutic tool for the treatment of nonhealing diabetic wounds. The pathological nature of the niche microenvironment limits the use of autologous cell therapy in diabetic patients. Prolonged exposure of endogenous MSCs to a pathological microenvironment in vivo reduces their ability to respond to environmental cues.

Simultaneous isolation of enriched myoblasts and fibroblasts for migration analysis within a novel co-culture assay.

Skeletal muscle injury elicits the activation of satellite cells and their migration to the wound area for subsequent terminal differentiation and tissue integration. However, interstitial fibroblasts recruited to the site of injury promote deposition of fibrotic tissue, which hampers myoblast-mediated muscle regeneration. Currently, analysis of myoblast migration in vitro can be accomplished using chemotactic, cell-exclusion, or wound healing assays.

Simple silicone chamber system for in vitro three-dimensional skeletal muscle tissue formation.

Bioengineering skeletal muscle often requires customized equipment and intricate casting techniques. One of the major hurdles when initially trying to establish in vitro tissue engineered muscle constructs is the lack of consistency across published methodology. Although this diversity allows for specialization according to specific research goals, lack of standardization hampers comparative efforts.

In vitro myoblast motility models: investigating migration dynamics for the study of skeletal muscle repair.

Skeletal muscle repair requires the migration of myoblasts (activated satellite cells) both to the injury site and then within the wound to facilitate cellular alignment in preparation for differentiation, fusion and eventual healing. Along this journey, the cells encounter a range of soluble and extracellular matrix factors which regulate their movement and ultimately determine how successful the repair process will be. Sub-optimal migration can lead to a number of scenarios, including reduced myoblast numbers entering the wound, poor alignment and insufficient differentiation to correctly repair the damage.

Satellite cell pool expansion is affected by skeletal muscle characteristics.

Introduction: We investigated changes in satellite cell (SC) pool size after an acute bout of strenuous exercise and evaluated the influence of baseline SC count and fiber type.

Methods: Participants completed a downhill running (DHR) intervention (5 × 8 min, 2-min rest; 80% VO2max ; -10% gradient). Muscle biopsies were taken 7 days before VO₂max and 7-9 days after the DHR intervention.

TGF-β isoforms inhibit IGF-1-induced migration and regulate terminal differentiation in a cell-specific manner.

Following muscle injury, the damaged tissue and influx of inflammatory cells stimulate the secretion of growth factors and cytokines to initiate repair processes. This release of chemotactic signaling factors activates resident precursor cells and stimulates their mobilization and migration to the site of injury where terminal differentiation can occur. The three transforming growth factor-β (TGF-β) isoforms, and insulin-like growth factor-1 (IGF-1) are among the known regulatory factors released following muscle damage.

Potential myogenic stem cell populations: sources, plasticity, and application for cardiac repair.

The ability of unspecialized stem cells to differentiate into mature, specialized cell types has made them attractive as potential agents for enhanced tissue repair and regenerative medicine. This is especially true of diseases and disorders for which no or only partially effective treatments are currently available. Recently, increased focus has been placed on the regenerative potential of satellite cells (myogenic precursor cells found in the adult skeletal muscle) in various muscular disorders, such as dystrophy and myocardial injury following ischemia.

TGF-beta's delay skeletal muscle progenitor cell differentiation in an isoform-independent manner.

Satellite cells are a quiescent heterogeneous population of mononuclear stem and progenitor cells which, once activated, differentiate into myotubes and facilitate skeletal muscle repair or growth. The Transforming Growth Factor-beta (TGF-beta) superfamily members are elevated post-injury and their importance in the regulation of myogenesis and wound healing has been demonstrated both in vitro and in vivo. Most studies suggest a negative role for TGF-beta on satellite cell differentiation.

The changing AMPK expression profile in differentiating mouse skeletal muscle myoblast cells helps confer increasing resistance to apoptosis.

AMP-activated protein kinase (AMPK) functions as a alpha/beta/gamma heterotrimer to preserve ATP levels and so cell viability during stressful conditions. However, its role in aiding survival of adult skeletal muscle precursor cells is unclear. Using the differentiating mouse C2C12 postnatal skeletal muscle myoblast cell line, we have determined that proteins for the AMPK subunit isoforms alpha2 and gamma2 are constitutively expressed, while those for alpha1, beta1 and beta2 are undetectable in undifferentiated myoblasts but increasingly expressed with differentiation to myotubes.

Old dogmas and new hearts: a role for adult stem cells in cardiac repair?

The vast developmental repertoire of embryonic stem cells is well recognised. These primitive stem cells can differentiate in vivo and in vitro into cells of all three embryonic germ layers (endoderm, mesoderm, ectoderm), making them attractive potential agents to target for enhanced tissue repair and regeneration. Adult stem cells on the other hand are considered more restricted in their lineage differentiation capabilities.