Transcriptional Regulation in the Peripheral Nervous System and the Role of STAT3 in Axon Regeneration

Smith, Robin Patrick

30 September 2008

Several factors contribute to the failure of the central nervous system (CNS) to regenerate after injury. These include inhibition of axonal growth by myelin and glial scar associated molecules, as well as the intrinsic inability of adult CNS neurons to grow long axons in environments that are permissive for younger neurons. Neurons in the peripheral nervous system (PNS) display a much higher capacity to regenerate after injury than CNS neurons, as shown by conditioning lesion experiments and by microtransplantation of dorsal root ganglia neurons into CNS white matter tracts. Our central hypothesis is that neurons of the PNS express specific regeneration associated genes that mediate their enhanced growth response after injury. We have employed a combination of subtractive hybridization, microarray comparison and promoter analysis to probe for genes specific to neurons of the dorsal root ganglia (DRG), using cerebellar granule neurons (CGN) as a reference. We have identified over a thousand different genes, many of whose products form interaction networks and signaling pathways. Moreover, we have identified several dozen transcription factors that may play a role in establishing DRG neuron identity and shape their responses after injury. One of these transcription factors is Signal Transducer and Activator of Transcription 3 (STAT3), previously known to be upregulated in the PNS after a conditioning lesion but not known to be specific to the PNS. Using a real time PCR and immunochemical approaches we have shown that STAT3 is constitutively expressed and selectively active in DRG neurons both in culture and in vivo. We show that the overexpression of wild type STAT3 in cerebellar granule neurons leads to the formation of supernumerary neurites, whereas the overexpression of constitutively active STAT3-C leads to a 20% increase in total neurite outgrowth. It is hoped that the genetic delivery of STAT3-C, potentially combined with co-activators of transcription, will improve functional regeneration of CNS axons in vivo.

Microsystems for In Vitro CNS Neuron Study

Park, Jaewon

2011 December 1900

In vertebrate nervous system, formation of myelin sheaths around axons is essential for rapid nerve impulse conduction. However, the signals that regulate myelination in CNS remain largely unknown partially due to the lack of suitable in vitro models for studying localized cellular and molecular basis of axon-glia signals. We utilize microfabrication technologies to develop series of CNS neuron culture microsystems capable of providing localized physical and biochemical manipulation for studying neuron-glia interaction and neural progenitor development. First, a circular neuron-glia co-culture platform with one soma-compartment and one axon/glia compartment has been developed. The device allows physical and fluidic isolation of axons from neuronal somata for studying localized axon-glia interactions under tightly controlled biochemical environment. Oligodendrocyte (OL) progenitor cells co-cultured on isolated axons developed into mature-OLs, demonstrating the capability of the platform. The device has been further developed into higher-throughput devices that contain six or 24 axon/glia compartments while maintaining axon isolation. Increased number of compartments allowed multiple experimental conditions to be performed simultaneously on a single device. The six-compartment device was further developed to guide axonal growth. The guiding feature greatly facilitated the measurement of axon growth/lengths and enabled quantitative analyses of the effects of localized biomolecular treatment on axonal growth and/or regeneration. We found that laminin, collagen and Matri-gel promoted greater axonal growth when applied to somata than to the isolated axons. In contrast, chondroitin sulfate proteoglycan was found to negatively regulate axon growth only when it was applied to isolated axons. Second, a microsystem for culturing neural progenitor cell aggregates under spatially controlled three-dimensional environment was developed for studies into CNS neural development/myelination. Dense axonal layer was formed and differentiated OLs formed myelin sheaths around axons. To the best to our knowledge, this was the first time to have CNS myelin expressed inside a microfluidic device. In addition, promotion of myelin formation by retinoic acid treatment was confirmed using the device. In conclusion, we have developed series of neuron culture platforms capable of providing physical and biochemical manipulation. We expect they will serve as powerful tools for future mechanistic understanding of CNS axon-glia signaling as well as myelination.

BioMEMS

Microfluidic CNS neuron culture

CNS axon regeneration

PDMS patterning