Endothelin-1 regulates the dorsoventral branchial arch patterning in mice

Endothelin-1 (ET-1), a 21-amino acid peptide secreted by the epithelium and core mesenchyme in the branchial arches as well as vascular endothelium, is involved in craniofacial and cardiovascular development through endothelin receptor type-A (EdnrA) expressed in the neural crest-derived ectomesenchyme. Here we show that ET-1(-/-) mutant mice exhibit a homeotic-like transformation of the lower jaw to an upper jaw. Most of the maxillary arch-derived components are duplicated and replaced mandibular arch-derived structures, resulting in a mirror image of the upper and lower jaws in the ET-1(-/-) mutant. As for hyoid arch-derivatives, the ventral structures are severely affected in comparison to the dorsal ones in the ET-1(-/-) mutant. Correspondingly, the expression of Dlx5 and Dlx6, Distalless-related homeobox genes determining the ventral identity of the anterior branchial arches, and of the mandibular marker gene Pitx1 is significantly downregulated in the ET-1(-/-) mutant, whereas the expression of Dlx2 and the maxillary marker gene Prx2 is unaffected or rather upregulated. These findings indicate that the ET-1/EdnrA signaling may contribute to the dorsoventral axis patterning of the branchial arch system as a mediator of the regional intercellular interactions.     

Computer control of pH and DO in a laboratory fermenter using a neural network technique

In this contribution, the advantages of the artificial neural network approach to the identification and control of a laboratory-scale biochemical reactor are demonstrated. It is very important to be able to maintain the levels of two process variables, pH and dissolved oxygen (DO) concentration, over the course of fermentation in biosystems control. A PC-supported, fully automated, multi-task control system has been designed and built by the authors. Forward and inverse neural process models are used to identify and control both the pH and the DO concentration in a fermenter containing a Saccharomyces cerevisiae based-culture. The models are trained off-line, using a modified back-propagation algorithm based on conjugate gradients. The inverse neural controller is augmented by a new adaptive term that results in a system with robust performance. Experimental results have confirmed that the regulatory and tracking performances of the control system proposed are good.     

Tra2betal regulates P19 neuronal differentiation and the splicing of FGF-2R and GluR-B minigenes

The present study demonstrates that the expression of Tra2beta1 (Transformer 2-beta1) proteins, an SR (serine/arginine rich) protein, is developmentally up-regulated in a neural-specific pattern. The up-regulation is also observed in RA (retinoic acid) induced neural differentiation of P19 cells. Tra2betal proteins are located in the nuclei of P19 cells, which are consistent with its functional site as an SR protein. The over-expression of Tra2betal proteins promotes RA induced neuronal differentiation of P19 cells. In P19 cells, the splicing of FGF-2R (fibroblast growth factor receptor 2) minigene produces the BEK form, while the alternative splicing of GluR-B (glutamate receptor subunit B) minigene generates two products, the Flop and the Truncated isoforms. Tra2betal inhibits the BEK splicing, but it promotes the Flop splicing. The results therefore suggest that Tra2betal is involved in the regulation of alternative splicing processes during neural development, peculiarly the splicing of FGF-2R and GluR-B genes. Both FGF-2R and GluR-B genes are known to play important roles in neural differentiation.     

GDNF augments survival and differentiation of TH-positive neurons in neural progenitor cells

GDNF plays an important role in the survival and differentiation of primary dopaminergic neurons, but it requires multiple factors for its entire range of activities. This study investigated the effects of GDNF and its cofactors on the development of bFGF-responsive neural progenitor cells (NPCs), mesencephalic and cortical progenitor cells (MP and CP). Various factors were found to have significant inductive effects on the survival and maintenance of these cells in late developmental stages. MP had greater potential than CP to differentiate into dopaminergic neurons. Treatment of NPCs with GDNF and its cofactors enhanced MAP-2 and TH expression, particularly the latter. These findings suggest that NPCs, particularly MP, could develop into more specific neurons if the appropriate factors were applied during the final cell fate specification. They might thus become beneficial sources of donor cells in the treatment of neurological disorders.     

Interpretation and Optimization of Absorbance and Fluorescence Signals from Voltage-sensitive Dyes

Voltage-sensitive dyes produce absorbance and fluorescence changes that can be used to image voltage. The present study develops a systematic approach to the optimization of these signals. A mathematical analysis assesses the dye optical density (OD) that optimizes the signal-to-noise ratio in absorbance and fluorescence measurements. The signal-to-noise ratio is maximal for a dye OD of 2 (natural logarithm) in absorbance and ~1 in fluorescence. The fluorescence result is approximate because, in contrast to absorbance, the optimal dye OD varies with the amount of scattering and intrinsic absorbance of the tissue. The signal-to-noise ratio of absorbance is higher in thick preparations such as brain slices; fluorescence is superior in thin preparations such as cell culture. The optimal OD for absorbance and fluorescence, as well as the superiority of absorbance, were confirmed experimentally on hippocampal slices. This analysis also provided insight into the interpretation of signals normalized to resting light intensities. With both absorbance and fluorescence, the normalized signal (I/I) varies with OD, and does not reflect the change in dye absorbance. In absorbance this problem is remedied by dividing I/I by the dye OD to obtain the absorbance change. For fluorescence a correction is possible, but is more complicated. Because this analysis indicates that high levels of stain optimize the signal-to-noise, dyes were tested for pharmacological actions and phototoxicity. The absorbance dye RH155 was found to have pharmacological action at high staining levels. The fluorescent dye RH414 was phototoxic. Adverse effects could not be detected with the absorbance dye RH482.     

Effects of prolonged delivery of brain-derived neurotrophic factor on the fate of neural stem cells transplanted into the developing rat retina

One of the major roles of brain-derived neurotrophic factor (BDNF) is to promote the differentiation and support the survival of neurons in the central nervous system. The objective of the present study was to evaluate the effect of BDNF on the fate of adult rat hippocampus-derived neural stem cells (AHPCs) transplanted into the developing rat retina. Immunohistochemical analysis showed a significant increase in the ratio of grafted AHPCs stained for MAP2ab (P<0.05) and a marked decrease in the ratio of nestin-positive grafted cells in the slow-releasing BDNF group compared with the control group. The respective changes in the ratios of MAP5 and GFAP-positive grafted cells were comparable for the two groups. The results reported here suggest a potentially beneficial role for extended delivery of BDNF in the differentiation of grafted neural stem cells, which may lead to a novel modification of stem cell transplantation.     

Neural progenitor genes. Germinal zone expression and analysis of genetic overlap in stem cell populations

The identification of the genes regulating neural progenitor cell (NPC) functions is of great importance to developmental neuroscience and neural repair. Previously, we combined genetic subtraction and microarray analysis to identify genes enriched in neural progenitor cultures. Here, we apply a strategy to further stratify the neural progenitor genes. In situ hybridization demonstrates expression in the central nervous system germinal zones of 54 clones so identified, making them highly relevant for study in brain and neural progenitor development. Using microarray analysis we find 73 genes enriched in three neural stem cell (NSC)-containing populations generated under different conditions. We use the custom microarray to identify 38 "stemness" genes, with enriched expression in the three NSC conditions and present in both embryonic stem cells and hematopoietic stem cells. However, comparison of expression profiles from these stem cell populations indicates that while there is shared gene expression, the amount of genetic overlap is no more than what would be expected by chance, indicating that different stem cells have largely different gene expression patterns. Taken together, these studies identify many genes not previously associated with neural progenitor cell biology and also provide a rational scheme for stratification of microarray data for functional analysis.