Modelling human CNS injury with human neural stem cells in 2- and 3-Dimensional cultures.

The adult human central nervous system (CNS) has very limited regenerative capability, and injury at the cellular and molecular level cannot be studied in vivo. Modelling neural damage in human systems is crucial to identifying species-specific responses to injury and potentially neurotoxic compounds leading to development of more effective neuroprotective agents. Hence we developed human neural stem cell (hNSC) 3-dimensional (3D) cultures and tested their potential for modelling neural insults, including hypoxic-ischaemic and Ca2+-dependent injury. Standard 3D conditions for rodent cells support neuroblastoma lines used as human CNS models, but not hNSCs, but in all cases changes in culture architecture alter gene expression. Importantly, response to damage differs in 2D and 3D cultures and this is not due to reduced drug accessibility. Together, this study highlights the impact of culture cytoarchitecture on hNSC phenotype and damage response, indicating that 3D models may be better predictors of in vivo response to damage and compound toxicity.

Emerging potential of exosomes and noncoding microRNAs for the treatment of neurological injury/diseases.

Recent discoveries of cellular generation of exosomes, small (∼ 30 - 100 nm) complex lipid membrane structures which encapsulate and transport proteins, RNAs, including microRNAs (miRNAs) have provided new insight in how cells within organisms communicate. These discoveries will likely have a major impact on the treatment of disease, with cancers and neurological diseases as evident targets. Exosomes provide a major medium of intercellular communications and thereby, there being a potential by altering communications and instructions for protein production, we can employ exosomes to treat diseases. We now have an opportunity to treat neurological disease by modifying intercellular communication networks. Recent work demonstrating that the therapeutic benefit provided by stem cells for the treatments of stroke and traumatic brain injury depend on their generation and release of exosomes provides a foundation for exosome-based therapy. Cell-free exosomes have also been recently employed to effectively treat stroke and brain trauma. The content of exosomes, particularly their miRNA cargo which can concurrently impact the post-transcriptional regulation of many genes, can be regulated. We are at the cusp of capitalizing on this important means of intercellular communications for the treatment of diseases, such as cancers and neurological diseases, among many others.

The role of the Gadd45 family in the nervous system: a focus on neurodevelopment, neuronal injury, and cognitive neuroepigenetics.

The growth arrest and DNA damage-inducible (Gadd)45 proteins have been associated with numerous cellular mechanisms including cell-cycle control, DNA damage sensation and repair, genotoxic stress, neoplasia, and molecular epigenetics. The genes were originally identified in in vitro screens of irradiation- and interleukin-induced transcription and have since been implicated in a host of normal and aberrant central nervous system processes. These include early and postnatal development, injury, cancer, memory, aging, and neurodegenerative and psychiatric disease states. The proteins act through a variety of molecular signaling cascades including the MAPK cascade, cell-cycle control mechanisms, histone regulation, and epigenetic DNA demethylation. In this review, we provide a comprehensive discussion of the literature implicating each of the three members of the Gadd45 family in these processes.

Deficiency of the complement regulator CD59a exacerbates Wallerian degeneration.

The complement system is implicated in Wallerian degeneration (WD). We have previously shown that the membrane attack complex (MAC), the terminal activation product of the complement cascade, mediates rapid axonal degradation and myelin clearance during WD after peripheral nerve injury. In this study we analyzed the contribution of CD59a, a cell membrane negative regulator of the MAC, to WD. Following injury, the level of MAC deposition was higher in the CD59a deficient mice than wildtypes whereas the residual axonal content was lower in CD59a deficient mice than wildtypes, strongly implicating MAC as a determinant of axonal damage during WD. The number of endoneurial macrophages was significantly higher in CD59a deficient mice compared to wildtypes at 1 day post-injury. These findings are relevant to the understanding of the mechanisms of axon loss in injury and disease.