Topical RT1640 treatment effectively reverses gray hair and stem cell loss in a mouse model of radiation-induced canities.

Gray hair is a visible sign of tissue degeneration during aging. Graying is attributed to dysfunction of melanocyte stem cells (McSCs) that results in depletion of their melanin-producing progeny. This non-lethal phenotype makes the hair follicle and its pigment system an attractive model for investigating mechanisms that contribute to tissue aging and therapeutic strategies to combat this process. One potential combination therapeutic is RT1640, which is comprised of two drugs that are known to stimulate hair growth (cyclosporine A [CsA] and minoxidil), along with RT175, a non-immunosuppressive immunophilin ligand that is implicated in tissue regeneration. Using the ionizing radiation-induced acute mouse model of hair graying, we demonstrate that RT1640, over CsA alone, promotes regeneration of the hair pigment system during and following treatment. In non-irradiated mice, RT1640 is also physiologically active and successfully speeds hair growth and expands the McSC pool. It appears that this effect relies on the combined activities of the three drugs within RT1640 to simultaneously activate hair growth and McSCs as RT175 alone was insufficient to induce hair cycling in vivo, yet sufficient to drive the upregulation of the melanogenic program in vitro. This study sets the stage for further investigation into RT1640 and its components in McSC biology and, ultimately, melanocyte hypopigmentary disorders associated with disease and aging.

The refined biomimetic NeuroDigm GEL™ model of neuropathic pain in a mature rat.

Background: Many humans suffering with chronic neuropathic pain have no objective evidence of an etiological lesion or disease. Frequently their persistent pain occurs after the healing of a soft tissue injury. Based on clinical observations over time, our hypothesis was that after an injury in mammals the process of tissue repair could cause chronic neural pain. Our objectives were to create the delayed onset of neuropathic pain in rats with minimal nerve trauma using a physiologic hydrogel, and characterize the rats' responses to known analgesics and a targeted biologic. Methods: In mature male Sprague Dawley rats (age 9.5 months) a percutaneous implant of tissue-derived hydrogel was placed in the musculofascial tunnel of the distal tibial nerve. Subcutaneous morphine (3 mg/kg), celecoxib (10 mg/kg), gabapentin (25 mg/kg) and duloxetine (10 mg/kg) were each screened in the model three times each over 5 months after pain behaviors developed. Sham and control groups were used in all screenings. A pilot study followed in which recombinant human erythropoietin (200 units) was injected by the GEL™ neural procedure site. Results: The GEL group gradually developed mechanical hypersensitivity lasting months. Morphine, initially effective, had less analgesia over time. Celecoxib produced no analgesia, while gabapentin and duloxetine at low doses demonstrated profound analgesia at all times tested. The injected erythropoietin markedly decreased bilateral pain behavior that had been present for over 4 months, p ≤ 0.001. Histology of the GEL group tibial nerve revealed a site of focal neural remodeling, with neural regeneration, as found in nerve biopsies of patients with neuropathic pain. Conclusion: The refined NeuroDigm GEL™ model induces a neural response resulting in robust neuropathic pain behavior. The analgesic responses in this model reflect known responses of humans with neuropathic pain. The targeted recombinant human erythropoietin at the ectopic neural lesion appears to alleviate the persistent pain behavior in the GEL™ model rodents.

GM1485, a nonimmunosuppressive immunophilin ligand, promotes neurofunctional improvement and neural regeneration following stroke.

Stroke is the leading cause of disability in the industrialized world, and the development of pharmacologic strategies to promote poststroke recovery is of paramount importance. GM1485, a nonimmunosuppressive immunophilin ligand, promotes regeneration of multiple cell types following injury. In the present study, we evaluated the effect of GM1485 treatment on functional recovery and neurogenesis following rat stroke. Transient cerebral ischemia was induced in rats receiving daily GM1485 (5 mg/kg) beginning 24 hr postischemia and continuing for a total of 6 weeks. Neurological function was evaluated over this period using a battery of neurobehavioral tests, and immunostaining for stem-cell markers was performed following animal sacrifice. An in vitro model of oxidative stress was also employed to evaluate the ability of GM1485 to mediate stem-cell-like induction and plasticity. GM1485-treated rats demonstrated improved neurological function as well as increased Sox2(+) cells in the ipsilateral SVZ and striatum relative to vehicle-treated rats. Additionally, GM1485-treated fibroblasts subjected to oxidative stress were reprogrammed to a stem-cell-like phenotype and were able to differentiate down a neuronal lineage. These data demonstrate that GM1485 administration improves neurological function and is consistent with an upregulation of endogenous neurogenesis following stroke in rats. Further experiments are necessary to characterize the molecular pathways involved in these processes.

Fas ligand acts as a counter-receptor in Schwann cells and induces the secretion of bioactive nerve growth factor.

Fas ligand (FasL) is best known for its role in apoptosis. Membrane-bound FasL can signal in FasL-bearing cells, a process known as reverse signalling. The biological and functional consequences of FasL reverse signalling in Schwann cells were studied. FasL engagement induced the secretion of soluble mediator(s) that stimulated neurite growth in PC12 cells, NGF secretion, and NGF mRNA levels. ERK1/2 and Src phosphorylation was rapidly increased and inhibition of their activation affected NGF synthesis and release. FasL can therefore act as a signal-transducing molecule in Schwann cells, leading to the secretion of NGF, and may contribute to peripheral nerve regeneration.

CD81, a cell cycle regulator, is a novel target for histone deacetylase inhibition in glioma cells.

Recent advances in cancer cell biology have focused on histone deacetylase inhibitors (HDACi's) because they target pathways critical to the development and progression of disease. In particular, HDACi's can induce expression of epigenetically silenced genes that promote growth arrest, differentiation and cell death. In glioma cells, one such repressed gene is the tetraspanin CD81, which regulates cytostasis in various cell lines and in astrocytes, the major cellular component of gliomas. Our studies show that HDACi's, trichostatin and sodium butyrate, promote growth arrest and differentiation with negligible cell death in glioma cells and induce expression of CD81 and cyclin-dependent kinase inhibitor 1A (p21(CIP/WAF-1)), another regulator of cytostasis in astrocytes. Interference RNA knock-down of CD81 abrogates cytostasis promoted by HDAC inhibition indicating that HDACi-induced CD81 is responsible for growth arrest. Induction of CD81 expression through HDAC inhibition is a novel strategy to promote growth arrest in glioma cells.

Fas engagement induces neurite growth through ERK activation and p35 upregulation.

Fas (also known as CD95), a member of the tumour-necrosis receptor factor family of 'death receptors', can induce apoptosis or, conversely, can deliver growth stimulatory signals. Here we report that crosslinking Fas on primary sensory neurons induces neurite growth through sustained activation of the extracellular-signal regulated kinase (ERK) pathway and the consequent upregulation of p35, a mediator of neurite outgrowth. In addition, functional recovery after sciatic nerve injury is delayed in Fas-deficient lpr mice and accelerated by local administration of antibodies against Fas, which indicates that Fas engagement may contribute to nerve regeneration in vivo. Our findings define a role for Fas as an inducer of both neurite growth in vitro and accelerated recovery after nerve injury in vivo.