Generating motor neuron subtype diversity from human pluripotent stem cells

Patani, Rickie

January 2012

No description available.

612.8

Stem cells ; Motor neurons

Synapse formation between identified leech neurons

Merz, David C. (David Christian)

January 1994

The formation of patterns of functionally appropriate chemical synapses is one of the key aspects of nervous system development. I have investigated the cellular interactions that culminate in the formation of an inhibitory synapse between the R and P neurons of the leech. These neurons may be isolated and maintained in culture, where they reform synaptic connections under easily manipulable conditions. An early event in the formation of this synapse is the loss from sites of contact in the postsynaptic P cell of an excitatory response to the transmitter serotonin. The loss of this response was triggered specifically by contact with the presynaptic R neuron, and not by contact with other leech neurons, including other serotonergic neurons. Furthermore, contact with the R neurons of the reproductive ganglia, which do not innervate P cells, was also ineffective in causing the loss of response. This highly specific cellular interaction was prevented by treatment of the R cell surface with the proteolytic enzyme trypsin or with the lectin wheat germ agglutinin (WGA), suggesting involvement of an R cell surface glycoprotein. WGA blocked not only the loss of the excitatory response, but also prevented the formation of the R-P synapse. An antibody library against the R cell generated using a novel phage-display system produced antibodies which bound to subsets of leech neurons, including the R neurons, but none of these was specific for the R cells. I conclude that an early event in the formation of the R-P synapse is the recognition by the P cell of its correct synaptic partner through an R cell-specific surface molecule.

Synapses

Neurons -- Growth

Leeches -- Physiology

The neuroanatomical effect of brain injury during early development in a rat model

Hartle, Kelly D.

10 September 2010

The brain responds to injury during early development with alterations in behaviour and dendritic morphology of motor cortex neurons. Rats were exposed to damage either prenatally or after the first postnatal week, using different models of damage and motor cortex was examined. Prenatal injury resulted in a decrease in length, complexity and volume in layer II neurons, but no differences in layer V neurons or behavioural tasks. Postnatal damage produced increases in length of basilar dendrites, but no differences in spine density at 2 months of age, whereas at 6 months of age, an overall decrease in apical and basilar spine density was observed. Findings demonstrate the maturational status of the brain at the time of injury play a crucial role in response to injury.

Development

Golgi

Injury

Pyramidal Neurons

The role of progesterone in attenuating mitochondrial injury in neural cells in an in vitro model of traumatic brain injury

Malcolm, Shannon Gail

12 1900

No description available.

Progesterone

Brain Wounds and injuries

Neurons

Response of neurons cultured in two-and-three-dimensions to dynamic shear deformation

Cullen, Daniel Kacy

05 1900

No description available.

Shear (Mechanics)

Brain damage

Neurons

Neuropilar synaptogenesis between identified central neurons in vivo

Reese, David R.

January 1998

I explored the relationship between neurite outgrowth and the onset of synaptic activity in the central neuropil of the leech embryo. In order to follow changes in early morphology and the onset of synaptic activity in the same identified neuron, whole cell patch clamp recordings and fluorescent dye fills were obtained from dorsal pressure-sensitive (P) cells, the first neurons that could be reliably identified in the early embryo. I followed the development of the P cell from the first extension of neurites to the elaboration of an adult-like arbour. Following the growth of primary neurites, we observed a profuse outgrowth of transient neurites within the neuropil that retracted to form spurs. Following a dormant period, stable secondary branches grew from the spurs and became tipped with terminals. At this time, neurites of the Retzius (R) cell, a known presynaptic partner in the adult, were observed to contact the terminals. Although voltage-dependent currents were seen in the P cell at the earliest stage, spontaneous synaptic activity was only observed when terminals had formed. Spontaneous release was observed before evoked release could be detected from the R cell. The results suggest that transient neurites are formed during an exploratory phase of development, whereas the more precisely timed outgrowth of stable neurites from the spurs signals functional differentiation during synaptogenesis. As spurs have also been observed in neurons of the mammalian brain, they may constitute a primordial synaptic organizer.

Synapses.

Neurons -- Growth.

Leeches -- Physiology.

The neuroanatomical effect of brain injury during early development in a rat model

Hartle, Kelly D.

10 September 2010

The brain responds to injury during early development with alterations in behaviour and dendritic morphology of motor cortex neurons. Rats were exposed to damage either prenatally or after the first postnatal week, using different models of damage and motor cortex was examined. Prenatal injury resulted in a decrease in length, complexity and volume in layer II neurons, but no differences in layer V neurons or behavioural tasks. Postnatal damage produced increases in length of basilar dendrites, but no differences in spine density at 2 months of age, whereas at 6 months of age, an overall decrease in apical and basilar spine density was observed. Findings demonstrate the maturational status of the brain at the time of injury play a crucial role in response to injury.

Development

Golgi

Injury

Pyramidal Neurons

Neuronal growth cone dynamics are regulated by a nitric oxide-initiated second messenger pathway

Welshhans, Kristy.

January 2007

Thesis (Ph. D.)--Georgia State University, 2007. / Vincent Rehder, committee chair; Sarah Pallas, Walter William Walthall, committee members. Electronic text (248 p. : ill. (some col.)) : digital, PDF file. Description based on contents viewed Jan. 28, 2008; title from file title page. Includes bibliographical references (p. 218-248).

Neurons Brain chemistry. Nitric oxide

Glial hemichannels : a new route for chemical communication in brain /

Stridh, Malin,

January 2008

Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2008. / Härtill 4 uppsatser.

Prolactin modulation of trigeminal sensory neurons : a dissertation /

Diogenes, Anibal.

January 2006

Dissertation (Ph.D.).--University of Texas Graduate School of Biomedical Sciences at San Antonio, 2006. / Vita. Includes bibliographical references.

Pain Prolactin Neurons, Afferent Rats