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Signaling Pathway that Makes Young Neurons Connect was discovered @ Scripps Research Institute

Posted in Cerebrovascular and Neurodegenerative Diseases, tagged , , , , , on June 26, 2013| 1 Comment »

Reporter: Aviva Lev-Ari, PhD, RN

 

Scripps Research Institute Scientists Discover Key Signaling Pathway that Makes Young Neurons Connect

LA JOLLA, CA – June 20, 2013 – Neuroscientists at The Scripps Research Institute (TSRI) have filled in a significant gap in the scientific understanding of how neurons mature, pointing to a better understanding of some developmental brain disorders.

In the new study, the researchers identified a molecular program that controls an essential step in the fast-growing brains of young mammals. The researchers found that this signaling pathway spurs the growth of neuronal output connections by a mechanism called “mitochondrial capture,” which has never been described before.

“Mutations that may affect this signaling pathway already have been found in some autism cases,” said TSRI Professor Franck Polleux, who led the research, published June 20, 2013 in the journal Cell.

Branching Out

Polleux’s laboratory is focused on identifying the signaling pathways that drive neural development, with special attention to the neocortex—a recently evolved structure that handles the “higher” cognitive functions in the mammalian brain and is highly developed in humans.

In a widely cited study published in 2007, Polleux’s team identified a trigger of an early step in the development of the most important class of neocortical neurons. As these neurons develop following asymmetric division of neural stem cells, they migrate to their proper place in the developing brain. Meanwhile they start to sprout a root-like mesh of input branches called dendrites from one end, and, from the other end, a long output stalk called an axon. Polleux and his colleagues found that the kinase LKB1 provides a key signal for the initiation of axon growth in these immature cortical neurons.

In the new study, Polleux’s team followed up this discovery and found that LKB1 also is crucially important for a later stage of these neurons’ development: the branching of the end of the axon onto the dendrites of other neurons.

“In experiments with mice, we knocked the LKB1 gene out of immature cortical neurons that had already begun growing an axon, and the most striking effect was a drastic reduction in terminal branching,” said Julien Courchet, a research associate in the Polleux laboratory who was a lead co-author of the study. “We saw this also in lab dish experiments, and when we overexpressed the LKB1 gene, the result was a dramatic increase in axon branching.”

Further experiments by Courchet showed that LKB1 drives axonal branching by activating another kinase, NUAK1. The next step was to try to understand how this newly identified LKB1-NUAK1 signaling pathway induced the growth of new axon branches.

Stopping the Train in Its Tracks

Following a thin trail of clues, the researchers decided to look at the dynamics of microtubules. These tiny railway-like tracks are laid down within axons for the efficient transport of molecular cargoes and are altered and extended during axonal branching. Although they could find no major change in microtubule dynamics within immature axons lacking LKB1 or NUAK1, the team did discover one striking abnormality in the transport of cargoes along these microtubules. Tiny oxygen-reactors called mitochondria, which are the principal sources of chemical energy in cells, were transported along axons much more actively—and by contrast, became almost immobile when LKB1 and NUAK1 were overexpressed.

But the LKB1-NUAK1 signals weren’t just immobilizing mitochondria randomly. They were effectively inducing their capture at points on the axons where axons form synaptic connections with other neurons. “When we removed LKB1 or NUAK1 in cortical neurons, the mitochondria were no longer captured at these points,” said Tommy Lewis, Jr., a research associate in the Polleux Laboratory who was co-lead author of the study.

“We argue that there must be an active ‘homing factor’ that specifies where these mitochondria stop moving,” said Polleux. “And we think that this is essentially what the LKB1-NAUK1 signaling pathway does here.”

Looking Ahead

Precisely how the capture of mitochondria at nascent synapses promotes axonal branching is the object of a further line of investigation in the Polleux laboratory. “We think that we have uncovered something very interesting about mitochondrial function at synapses,” Polleux said.

In addition to its basic scientific importance, the work is likely to be highly relevant medically. Developmentally related brain disorders such as epilepsy, autism and schizophrenia typically involve abnormalities in neuronal connectivity. Recent genetic surveys have found NUAK1-related gene mutations in some children with autism, for example. “Our study is the first one to identify that NUAK1 plays a crucial role during the establishment of cortical connectivity and therefore suggests why this gene might play a role in autistic disorder,” Polleux says.

He notes, too, that declines in normal mitochondrial transport within axons have been observed in neurodegenerative disorders such as Alzheimer’s and Parkinson’s diseases. “In the light of our findings, we wonder if the decreased mitochondrial mobility observed in these cases might be due not to a transport defect, but instead to a defect in mitochondrial capture in aging neurons,” he said. “We’re eager to start doing experiments to test such possibilities.”

Other contributors to the study, “Terminal Axon Branching Is Regulated by the LKB1-NUAK1 Kinase Pathway via Presynaptic Mitochondrial Capture,” were Sohyon Lee, Virginie Courchet and Deng-Yuan Liou of TSRI, and Shinichi Aizawa of the RIKEN Institute of Kobe, Japan.

The study was funded in part by the National Institutes of Health (grants R01AG031524 and 5F32NS080464), ADI-Novartis, Fondation pour la Recherche Medicale, and the Philippe Foundation.

About The Scripps Research Institute

The Scripps Research Institute (TSRI) is one of the world’s largest independent, not-for-profit organizations focusing on research in the biomedical sciences. TSRI is internationally recognized for its contributions to science and health, including its role in laying the foundation for new treatments for cancer, rheumatoid arthritis, hemophilia, and other diseases. An institution that evolved from the Scripps Metabolic Clinic founded by philanthropist Ellen Browning Scripps in 1924, the institute now employs about 3,000 people on its campuses in La Jolla, CA, and Jupiter, FL, where its renowned scientists—including three Nobel laureates—work toward their next discoveries. The institute’s graduate program, which awards PhD degrees in biology and chemistry, ranks among the top ten of its kind in the nation. For more information, see www.scripps.edu.

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For information:
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Tel: 858-784-2666
Fax: 858-784-8136
press@scripps.edu

http://www.scripps.edu/news/press/2013/20130620polleux.html?elq=a37dd39263d54de38cea68188c307bf6&elqCampaignId=17

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Cell Transplantation in Brain Repair

Posted in Cerebrovascular and Neurodegenerative Diseases, Genome Biology, Human Immune System in Health and in Disease, Innovations in Neurophysiology & Neuropsychology, Molecular Genetics & Pharmaceutical, Pharmaceutical Industry Competitive Intelligence, Regulated Clinical Trials: Design, Methods, Components and IRB related issues, Stem Cells for Regenerative Medicine, Technology Transfer: Biotech and Pharmaceutical, tagged , , , , , , , on March 9, 2013| Leave a Comment »

Cell Transplantation in Brain Repair

Curator: Larry H Bernstein, MD, FCAP

Cell transplantation: relevance in understanding brain development and prospects in brain repair
M Jaber and A Gaillard
Experimental and Clinical Neurosciences Laboratory, INSERM, Poitiers, France
Front. Cell. Neurosci., 23 Nov 2012 |  http://dx. doi.org/10.3389/fncel.2012.00056
Neurodegenerative disorders such as Parkinson’s diseases (PD) and Huntington’s diseases (HD), neuronal injuries following trauma and neuronal cell death following strokes are major debilitating affections that are often accompanied by motor and cognitive dysfunctions with limited treatment options. Cell transplantation therapies have been considered for the last three decades as a serious avenue to explore with the ultimate aim to replace lost neurons with “new ones” initially originating from fetal neuroblasts and recently deriving from various sources of stem cells.
One of the many factors affecting the success of cell transplantation therapies is

  • host immune response to the graft.

This came as an evidence when attempts of cell therapy was undertaken with the use of human fetal neuroblasts or porcine fetal neuronal tissue for xenotransplantation in the human brain. Bonnamain et al. (2012) describe in this issue how this avenue led to disappointing results which damped this line of research. Pauly et al. (2012) focus on GABAergic striatal neurons with a detailed review on their development and clinical applications in HD. They report that in animal models of HD, the success of cellular transplantation with embryonic striatal transplants is influenced by many parameters. However, recent reports indicate that HD patients that underwent cell transplantation showed motor and cognitive improvements. Given that the use of fetal tissue as a cell source for neural transplantation is not without problems, a significant research activity has been oriented toward finding alternative sources of neural cells. Among these, pluripotent stem cells seem to be an obvious choice as these cells may differentiate into any cell type of any organ. As Benchoua and Onteniente (2012) put it in their review, pluripotent stem cells “hold the potential to revolutionize the field of neurodegenerative medicine by offering a robust and flexible source of allogenic or HLA compatible neuronal precursors.” In their review, the authors focus on

  •  regional and local patterning of these cells
  • to induce their differentiation into specific neural progenitors.

Then, they discuss safety issues regarding these cells,

  • factors that maintain their commitment after transplantation and
  • facilitate their integration within the host brain,
  • mostly in animal models of HD and PD.

The paper of Denham et al. (2012) reviews intra cerebral transplantation of neurons generated from

  •  human embryonic stem (hES) cells in
  • neonatal rats and focus on axonal growth in the host brain and
  • the corresponding electrophysiological properties.

They show that neurons generated from hES cells are capable of

  •  extensive growth within the host brain and
  • display properties consistent with functional integration
  • at the electrophysiological level.

these findings need to be replicated in the context of adult brain repair.

García-Parra et al. (2012) propose a study presenting a new polymeric support

  •  able to induce neuronal differentiation in both PC12 cell line and
  • adult primary skin-derived precursor cells in vitro.

They detail the use of a combined photolithographic technique

  •  to create a topography of micropatterned substrates composed of
  • extracellular matrix providing the cells with
  • appropriate cues for their differentiation.

Such models can set the basis for new avenues to explore the differentiation of stem cells

  •  in vitro after adjustment of the proper microenvironment
  • in order to obtain the requested specific neuronal subtype.

In the in vivo area, de Chevigny et al. (2012) present a very elegant study aimed at

  • characterizing the spatial and temporal expression of two major transcription factors,
  • Pax6 and DIx2 that are implicated in the generation of olfactory bulb (OB) neurons.

OB neurogenesis attracts attention as their

  •  dopamine neurons, or their precursors,
  • are presented as of potential interest in cell replacement or recruitment therapies in PD.

The dynamic expression data presented for these two transcription factors indicate that

  •  while Pax6 is implicated in OB dopaminergic cell fate in a specific and permanent manner,
  • DIx2 expression is more generalized and transient.

This method offers a better explanation of factors involved in the cell lineage of dopamine neurons, but more importantly, is helpful in identifying

  •  molecular mechanisms involved in neuronal subtype specification in the postnatal brain.

Following transplantation, axons derived from transplanted neurons

  •  need to find their way and innervate target areas.

Our own findings showed that embryonic mesencephalic dopamine neurons transplanted in the substantia nigra in an animal model of PD

  •  are able to extend axons toward the striatum (Gaillard et al., 2009; Gaillard and Jaber, 2011).

These results suggest that specific guidance cues exist in the adult brain and that

  •  axons from transplanted embryonic cells

are able to respond to theses cues, guiding them to their final targets.

The review by Prestoz et al. (2012) summarizes the current knowledge on

  •  the identity of cellular and molecular signals thought to be involved in development of the dopamine pathway during embryogenesis in the rodent central nervous system.

The paper also describes the modulation of these factors following lesion and transplantation and their potential implication in restoring damaged pathways.

The review by Saha et al. (2012) is focused on

  •  stimulation,
  • migration of the pools of neural stem or precursor cells,
  • particularly in the subventricular zone following cortical injuries, and
  • details the cellular and molecular mechanisms involved in these processes.

These range from

  •  molecular factors,
  • glial reaction,
  • vasculature
  • physical exercise.

The description is extended to future avenues that

  •  need to be explored in order to better induce these reactions, as
  • their efficiency in brain repair is very limited.

Although cell transplantation in the damaged brain is not likely to be routinely performed in the near future,

  •  the different paths that are evoked in this series of reviews should yield safer, more effective and physiologically relevant transplantation procedures.

References
Benchoua, A., and Onteniente, B. (2012). Intracerebral transplantation for neurological disorders. Lessons from developmental, experimental, and clinical studies.
Front. Cell. Neurosci. 6:2.            http://dx.doi.org/10.3389/fncel.2012.00002
Bonnamain, V., Neveu, I., and Naveilhan, P. (2012). Neural stem/progenitor cells as a promising candidate for regenerative therapy of the central nervous system.
Front. Cell. Neurosci. 6:17.     http://dx.doi.org/10.3389/fncel.2012.00017
de Chevigny, A., Core, N., Follert, P., Wild, S., Bosio, A., Yoshikawa, K., et al. (2012). Dynamic expression of the pro-dopaminergic transcription factors Pax6 and Dlx2 during postnatal olfactory bulb neurogenesis.
Front. Cell. Neurosci. 6:6.       http://dx.doi.org/10.3389/fncel.2012.00006
Denham, M., Parish, C. L., Leaw, B., Wright, J., Reid, C. A., Petrou, S., et al. (2012). Neurons derived from human embryonic stem cells extend long-distance axonal projections through growth along host white matter tracts after intra-cerebral transplantation.
Front. Cell. Neurosci. 6:11.       http://dx.doi.org/10.3389/fncel.2012.00011
Gaillard, A., Decressac, M., Frappé, I., Fernagut, P. O., Prestoz, L., Besnard, S., et al. (2009). Anatomical and functional reconstruction of the nigrostriatal pathway by intranigral transplants. Neurobiol. Dis. 35, 477–488.
Gaillard, A., and Jaber, M. (2011). Rewiring the brain with cell transplantation in Parkinson’s disease. Trends Neurosci. 34, 124–133.
García-Parra, P., Cavaliere, F., Maroto, M., Bilbao, L., Obieta, I., López de Munain, A., et al. (2012). Modeling neural differentiation on micropatterned substrates coated with neural matrix components.
Front. Cell. Neurosci. 6:10.       http://dx.do.org/10.3389/fncel.2012.00010
Pauly, M. C., Piroth, T., Döbrössy, M., and Nikkhah, G. (2012). Restoration of the GABAergic striatal circuitry: from developmental aspects towards clinical applications.
Front. Cell. Neurosci. 6:16.        http://dx.doi.org/10.3389/fncel.2012.00016
Prestoz, L., Jaber, M., and Gaillard, A. (2012). Dopaminergic axon guidance: which makes what? Front. Cell. Neurosci. 6:32.               http://dx.doi.org/10.3389/fncel.2012.00032. 
Saha, B., Jaber, M., and Gaillard, A. (2012). Potentials of endogenous neural stem cells in brain repair. Front. Cell. Neurosci. 6:14.   http://dx.doi.org/10.3389/fncel.2012.00014

Citation: Jaber M and Gaillard A (2012) Cell transplantation: relevance in understanding brain development and prospects in brain repair. Front. Cell. Neurosci. 6:56. http://dx.doi.org/10.3389/fncel.2012.00056

Stem cell diagram illustrates a human fetus st...

Stem cell diagram illustrates a human fetus stem cell and possible uses on the circulatory, nervous, and immune systems. (Photo credit: Wikipedia)

English: Complete neuron cell diagram. Neurons...

English: Complete neuron cell diagram. Neurons (also known as neurones and nerve cells) are electrically excitable cells in the nervous system that process and transmit information. In vertebrate animals, neurons are the core components of the brain, spinal cord and peripheral nerves. (Photo credit: Wikipedia)

B0003894 NMDA receptors in the brain

B0003894 NMDA receptors in the brain (Photo credit: wellcome images)

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