AMP-activated kinase mediates adipose stem cell-stimulated neuritogenesis of PC12 cells.

Adipose tissue stroma contains a population of mesenchymal stem cells, which support repair of damaged tissues through the protective effects of secreted trophic factors. Neurotrophic factors, including nerve growth factor (NGF) have been identified in media collected from cultured adipose-derived stem cells (ASC). We previously demonstrated that administration of cell-free ASC conditioned medium (ASC-CM) at 24 h after injury reduced lesion volume and promoted functional recovery in a rat model of neonatal brain hypoxic-ischemic (HI) injury. The timing of administration well after the peak in neural cell apoptosis in the affected region suggests that regeneration of lost neurons is promoted by factors in ASC-CM. In this study, we determined which of the factors in ASC-CM could induce neurogenesis by testing the ability of the mixture, either whole or after inactivating specific components, to stimulate neurite outgrowth in vitro using the neurogenic cell line PC12. Neuritogenesis in PC12 cells treated with ASC-CM was observed at a level comparable to that observed with purified recombinant NGF. It was observed that NGF in ASC-CM was mainly responsible for inducing PC12 cell neuritogenesis. Interestingly, both ASC-CM and NGF induced PC12 cell neuritogenesis through activation of the AMP-activated kinase (AMPK) pathway which is the central protein involved in controlling many critical functions in response to changes in the cellular energy status. Pharmacological and genetic inhibition of AMPK activity greatly reduced neuritogenesis in PC12 cells. These results suggest that, in addition to possessing neuroprotective properties, ASC-CM mediates repair of damaged tissues through inducing neuronal differentiation via NGF-induced AMPK activation.

Adipose stromal cells-secreted neuroprotective media against neuronal apoptosis.

Transplantation of pluripotent adipose stem/stromal cells (ASC) alleviates tissue damage and improves functional deficits in both stroke and cardiovascular disease animal models. Recent studies indicate that the primary mechanism of ASC-induced repair may not be directly related to tissue regeneration through differentiation, but rather through paracrine mechanisms provided by secreted pro-survival and repair-inducing trophic factors. In this study, we have found that ASC-conditioned medium (ASC-CM) potently protected cerebellar granule neurons (CGN) from apoptosis induced by serum and potassium deprivation. Neural cell protection was mostly attributable to activated caspase-3 and Akt-mediated neuroprotective pathway signaling. Specific neutralization of neurotrophic factor activity demonstrated that serum and potassium deprivation-induced Akt-mediated neuroprotection and caspase-3-dependent apoptosis were mainly modulated by IGF-1. These data suggest that of the many neuroprotective factors secreted by ASC, IGF-1 is the major factor that mediates protection against serum and potassium deprivation-induced CGN apoptosis. This study establishes a mechanistic basis supporting the therapeutic application of ASC for neurological disorders, specifically through paracrine support provided by trophic factor secretion.

Adipose stromal cells-conditional medium protected glutamate-induced CGNs neuronal death by BDNF.

The delivery of factors secreted by adipose stromal cells (ASC) to the brain may be a viable neuroprotective therapeutic option. In this study, we investigated the bioactivity of ASC-conditioned medium (ASC-CM) in glutamate-induced neurotoxicity and found that the ASC-CM significantly blocked glutamate neurotoxicity. We identified the brain-derived neurotrophic factor (BDNF) in the ASC-CM by using Western blot and demonstrated that this activity was critical for the neuroprotective effect of ASC-CM in excytotoxicity models. Furthermore, inactivating BDNF also attenuated the suppression by ASC-CM of glutamate-induced caspase-3 activity, but not p38 phosphorylation. These findings suggest that among ASC secrete a potent combination of factors, BDNF play a major role in neuroprotection against excytotoxicity.

Caffeic acid phenethyl ester prevents cerebellar granule neurons (CGNs) against glutamate-induced neurotoxicity.

Caffeic acid phenethyl ester (CAPE) is an active component of propolis obtained from honeybee hives and is found to have the following properties: anti-mitogenic, anti-carcinogenic, anti-inflammatory, immunomodulatory, and antioxidant. Recent reports suggest that CAPE also has a neuronal protective property against ischemic injury. Since excitotoxicity may play an important role in ischemia, in this study, we investigated whether CAPE could directly protect neurons against excitotoxic insult. We treated cultured rat cerebellar granule neurons (CGNs) with excitotoxic concentrations of glutamate in the presence or absence of CAPE and found that CAPE markedly protected neurons against glutamate-induced neuronal death in a concentration-dependent fashion. Glutamate-induced CGNs death is associated with time-dependent activation of caspase-3 and phosphorylation of p38, both events of which can be blocked by CAPE. Treating CGNs with specific inhibitors of these two enzymes together exerts a synergistic neuroprotective effect, similar to the neuroprotective effect of CAPE exposure. These results suggest that CAPE is able to block glutamate-induced excitotoxicity by inhibiting phosphorylation of p38 and caspase-3 activation. This finding may further help understanding of the mechanism of glutamate-induced neuronal death and CAPE-induced neuroprotection against excitotoxicity.

The widely conserved Era G-protein contains an RNA-binding domain required for Era function in vivo.

Era is a small G-protein widely conserved in eubacteria and eukaryotes. Although essential for bacterial growth and implicated in diverse cellular processes, its actual function remains unclear. Several lines of evidence suggest that Era may be involved in some aspect of RNA biology. The GTPase domain contains features in common with all G-proteins and is required for Era function in vivo. The C-terminal domain (EraCTD) bears scant similarity to proteins outside the Era subfamily. On the basis of sequence comparisons, we argue that the EraCTD is similar to, but distinct from, the KH RNA-binding domain. Although both contain the consensus VIGxxGxxI RNA-binding motif, the protein folds are probably different. We show that bacterial Era binds RNA in vitro and can form higher-order RNA-protein complexes. Mutations in the VIGxxGxxI motif and other conserved residues of the Escherichia coli EraCTD decrease RNA binding in vitro and have corresponding effects on Era function in vivo, including previously described effects on cell division and chromosome partitioning. Importantly, mutations in L-66, located in the predicted switch II region of the E. coli Era GTPase domain, also perturb binding, leading us to propose that the GTPase domain regulates RNA binding in response to unknown cellular cues. The possible biological significance of Era RNA binding is discussed.

A Study on the lack of [methyl-(3)H] thymidine uptake and incorporation by chemolithotrophic bacteria.

Five chemolithotrophic bacteria were tested for their ability to incorporate [methyl-(3)H] thymidine. None of the bacteria incorporated the label, even after incubation for 24 hours. The inability of these bacteria to incorporate thymidine appears to be due to an absence of transport mechanisms for exogenous nucleosides. As a result of these findings, it is concluded that activities deduced from labeled thymidine incorporation measurements probably do not include the activity of chemolithotrophic bacteria.

Effects of Light and CO on the Survival of a Marine Ammonium-Oxidizing Bacterium during Energy Source Deprivation.

The chemolithotrophic ammonium-oxidizing bacterium Nitrosomonas cryotolerans responds uniquely to nutrient deprivation by lowering its endogenous respiration and anabolic processes to undetectable levels during starvation, thus appearing to enter a dormant state. To ascertain whether this state protects the cells from further stresses (as seen with endospore-forming bacteria), the starved cells were subjected to two known inhibitors, CO and light. It was found that long-term-starved cells were less resistant than freshly starved cells to light inhibition. Both long-term-starved cells and freshly starved cells were unaffected by CO.