Functions of the ventral striatum

Stern, C. E.

January 1987

No description available.

611

Ventral striatum functions

Projection Neurons of the Nucleus Accumbens: An Intracellular Labeling Study

Chang, H. T., Kitai, S. T.

11 November 1985

Projection neurons of nucleus accumbens (NAC) of the rat were identified by either antidromic activation from stimulation of midbrain ventral tegmental area-substantia nigra (VTA-SN) regions, or by tracing axons of intracellularly labeled NAC neurons into the ventral pallidum. The morphology of these NAC projection neurons were determined to be medium spiny neurons similar to those identified in the caudate-putamen.

intracellular labeling

nucleus accumbens

ventral striatum

ventral tegmental area (VTA)

Biochemical studies of the signal transduction pathway mediated by the Drosophila Toll receptor

Kubota, Ken

January 1994

No description available.

572

Dorso-ventral polarity; Embryology

A 'cell-free' system to study regulation of focal adhesions and of the connected actin cytoskeleton

Cattelino, Anna

January 1999

No description available.

572

Ventral plasma membranes; Fibroblasts

Embryonic roles for the slug regulatory gene in hindbrain regulation and limb patterning

Buxton, Paul Graeme

January 1997

No description available.

572.8

Dorsal-ventral patterning; Chick

Functional analysis of a homeobox-containing gene expressed during early Xenopus development

Trindade, Margarida

January 2000

No description available.

572.8

Role of transcription factor Pax6 in the development of the ventral lateral geniculate nucleus

Li, Ziwen

January 2018

The development of the diencephalon can be summarised as a process in which cells that initially appear similar give rise to a complex structure that contains a variety of cell groups called nuclei. It involves two stages: the early patterning of the diencephalic prosomeres and the later formation of the individual nuclei. It has been shown that transcription factors and morphogens regulate the first stage but their further effects on the second stage remain unclear. The ventral lateral geniculate nucleus (vLGN) is involved in the visual system and is shown to have complex origins from the thalamus, the zona limitans intrathalamica (ZLI) and the prethalamus. The transcription factor Pax6 is involved in the development of brain structures including the cortex, the diencephalon and the major axonal tracts in the forebrain by playing a multifaceted role in patterning, proliferation, differentiation, migration and axon guidance. It is known that Pax6 is essential in setting up the prosomeric boundaries in the developing diencephalon but its role in the formation of individual nuclei has not yet been explored. By using a conditional Pax6 knock-out mouse driven by Zic4Cre with a green fluorescent protein (GFP) reporter showing the Cre activity, the formation of the thalamic nuclei vLGN, dorsal lateral geniculate nucleus (dLGN) and VP (ventral posterior nuclei) was examined in postnatal day 0 (P0) Pax6+/+, Pax6fl/+ and Pax6fl/fl pups. Using this mouse model, I found an increase in nuclear volume at the rostral level and a global decrease in cell density in the P0 Pax6fl/fl vLGN, whereas in the dLGN an increase of GFP+ve cell proportion was observed. In Pax6fl/+, I found an increase in GFP+ve cell proportion in the caudal part of the vLGN and across the dLGN. No significant change was observed in the VP in either the Pax6fl/+ or the Pax6fl/fl. The defects in the vLGN and dLGN could be caused by: 1. disruption of the expression of patterning factors such as Shh and Nkx2.2; 2. cell proliferation defcts and abnormal apoptosis; 3. ocular developmental defects; 4. failure in cell sorting/migration; 5. cell fate change. During my PhD, I tested the first three theories and explored the fourth but was not able to pursue the last due to the time limit of the project. To test the hypothesized mechanisms underlying those defects seen in the vLGN and dLGN, I performed BrdU labelling to study the time origin of cells that contribute to these two nuclei and discovered that E11.5 and E12.5 are the main ages when these cells and the GFP+ve subpopulation are born. Then I carried out experiments to examine the cell proliferation and cell apoptosis in the thalamus (pTH-R, rostral part of the progenitor zone of the thalamus, and pTH-C, caudal part of the progenitor zone of the thalamus) and the prethalamus (Pth) from E11.5 to E13.5 and found: 1. the proliferation rate decreased in the pTH-R in Pax6fl/+ at E11.5; 2. the growth fraction decreased in both pTH-C and pTH-R in E12.5 Pax6fl/fl; 3. there is no change in cell proliferation in the GFP+ve subpopulation; 4. no abnormal apoptosis is observed in either the whole cell population or the GFP+ve subpopulation. Judging by the amplitude of the change in proliferation in the pTH-R and pTH-C at E11.5 and E12.5, it is unlikely that these changes alone are responsible for the phenotypes seen in P0 vLGN and dLGN. Then I examined the expression patterns of Shh and Nkx2.2 and the expansion of both was observed in Pax6fl/fl at both E12.5 and E13.5, which could explain the volume change of the vLGN but not the change in the proportion of GFP+ve subpopulation in both the vLGN and dLGN. Then I continued to examine if the ocular input from the retinal ganglionic cells are severely affected by the deletion of Pax6 and found no gross change in the conditional mutants, which rejected the ocular developmental defects theory. At the end of my PhD, I performed a BrdU short-term survival experiment and a brain slice culture combined with live imaging experiment to explore the possibility of abnormal cell migration causing the vLGN and dLGN phenotypes and found that the cells moving along the border of the thalamus and prethalamus move faster in the Pax6fl/fl than in the Pax6fl/+, but rather than moving directly toward the lateral surface of the diencephalon, they take a detour. These findings indicate that the deletion of Pax6 causes minor changes in the proliferation of E11.5 to E13.5 diencephalon and expansion of regional marker expression such as Shh and Nkx2.2, which could potenially affect the volume and change the proportion of GFP+ve cells in P0 vLGN and dLGN. Migration defects caused by Pax6 could also contribute to the phenotype observed in those two nuclei. Potential cell fate change caused by Pax6 deletion could be another factor that contributes to the defects in the conditional mutants. More work needs to be done to test the migration defect and cell fate change hypotheses in future.

Ventral Tegmental Area GABAA Receptors Mediate the Change from a Drug-naive to an Opiate- or Ethanol-deprived Motivational State

Ting-A-Kee, Ryan Anthony

31 August 2012

A crucial question in drug addiction research concerns whether the varying reports of dopamine-independent and dopamine-dependent motivation can be integrated. According to one theory, the prior drug history of a subject — that is to say, whether they have received minimal or chronic drug exposure — determines whether opiate motivation is dependent upon the brainstem tegmental pedunculopontine nucleus (TPP) or dopamine neurotransmission. The biological analogue of this change is thought to be a switch in the signalling properties (from hyperpolarizing to depolarizing) of ventral tegmental area (VTA) gamma-aminobutyric acid subtype-A (GABAA) receptors. In this thesis, I demonstrate that the mechanisms underlying opiate motivation can be selected artificially by manipulating the signalling properties of VTA GABAA receptors, irrespective of the past drug history of the subject. Furthermore, I suggest that these same VTA GABAA receptors also play a similar role in controlling ethanol motivation. Indeed, the mechanisms underlying ethanol motivation can be doubly dissociated in a manner similar to that observed with opiates. However, whereas opiate motivation is TPP-dependent in the drug-naive state, I found that ethanol motivation was dependent on dopamine neurotransmission (via the D2 receptor) in drug-naive animals. Conversely, ethanol motivation was TPP-dependent in ethanol-deprived mice (as opposed to opiate motivation being dopamine-dependent in opiate-deprived animals). These effects are consistent with a VTA GABAA receptor switching mechanism identical to the one seen in the case of opiate motivation.

motivation

morphine

ethanol

ventral tegmental area

0384

Ventral Tegmental Area GABAA Receptors Mediate the Change from a Drug-naive to an Opiate- or Ethanol-deprived Motivational State

Ting-A-Kee, Ryan Anthony

31 August 2012

A crucial question in drug addiction research concerns whether the varying reports of dopamine-independent and dopamine-dependent motivation can be integrated. According to one theory, the prior drug history of a subject — that is to say, whether they have received minimal or chronic drug exposure — determines whether opiate motivation is dependent upon the brainstem tegmental pedunculopontine nucleus (TPP) or dopamine neurotransmission. The biological analogue of this change is thought to be a switch in the signalling properties (from hyperpolarizing to depolarizing) of ventral tegmental area (VTA) gamma-aminobutyric acid subtype-A (GABAA) receptors. In this thesis, I demonstrate that the mechanisms underlying opiate motivation can be selected artificially by manipulating the signalling properties of VTA GABAA receptors, irrespective of the past drug history of the subject. Furthermore, I suggest that these same VTA GABAA receptors also play a similar role in controlling ethanol motivation. Indeed, the mechanisms underlying ethanol motivation can be doubly dissociated in a manner similar to that observed with opiates. However, whereas opiate motivation is TPP-dependent in the drug-naive state, I found that ethanol motivation was dependent on dopamine neurotransmission (via the D2 receptor) in drug-naive animals. Conversely, ethanol motivation was TPP-dependent in ethanol-deprived mice (as opposed to opiate motivation being dopamine-dependent in opiate-deprived animals). These effects are consistent with a VTA GABAA receptor switching mechanism identical to the one seen in the case of opiate motivation.

motivation

morphine

ethanol

ventral tegmental area

0384

Leaf Morphology of Selaginella P. Beauv. and its Taxonomic Significance in Taiwan

Chao, Shu-chih

29 July 2008

Microphyll morphology of 16 Taiwanese species of Selagienlla was observed under light microscopy and scanning electron microscopy. Features studied include microphyll arrangement, epidermal cell morphology, stomal distribution, shape arrangement and distribution silica body on microphyll surface. Microphyll are dimorphic and 4-ranked arrangement, with ventral microphylls larger than the dorsal microphylls. The epidermal cells at dorsal side of dorsal microphylls and at ventral side of ventral microphylls are similar, which are tetragonal or oblong in shape and sinuolate or sinuate in anticlinal cell walls. The epidermis at ventral side of dorsal microphylls and dorsal side of ventral microphylls are similar, which are sub-square or rectangular in shape and straight or sinuolate in anticlinal walls. Stomata are mainly distributed on dorsal side of dorsal microphylls and ventral side of ventral microphylls. Four distribution patterns of are found on microphyll silica body, which are microphyll margin, midrib, homogeneity and nil patterns. Four types of arrangement of silica body on epidermal cells were recognized, namely single row, multi-row, mixed and globulate types. In Taiwan, the characters appeared in epidermal cell morphology and stomal distribution of microphyll are useful for species identification in Selaginella, while those of distribution at patterns and arrangement types of silica bodies on epidermal cells are valuable for the species identification under subgenus.

Taiwan

ventral

dorsal

silica body

Selaginella