Expression of proneural and neurogenic genes in the zebrafish lateral line primordium correlates with selection of hair cell fate in neuromasts

Expression of a mouse atonal homologue, math1, defines cells with the potential to become sensory hair cells in the mouse inner ear (Science 284 (1999) 1837) and Notch signaling limits the number of cells that are permitted to adopt this fate (Nat. Genet. 21 (1999) 289; J. Neurocytol. 28 (1999) 809). Failure of lateral inhibition mediated by Notch signaling is associated with an overproduction of ear hair cells in the zebrafish mind bomb (mib) and deltaA mutants (Development 125 (1998a) 4637; Development 126 (1999) 5669), suggesting a similar role for these genes in limiting the number of hair cells in the zebrafish ear. This study extends the analysis of proneural and neurogenic gene expression to the lateral line system, which detects movement via clusters of related sensory hair cells in specialized structures called neuromasts. We have compared the expression of a zebrafish atonal homologue, zath1, and neurogenic genes, deltaA, deltaB and notch3, in neuromasts and the posterior lateral line primordium (PLLP) of wild-type and mib mutant embryos. We describe progressive restriction of proneural and neurogenic gene expression in the migrating PLLP that appears to correlate with selection of hair cell fate in maturing neuromasts. In mib mutants there is a failure to restrict expression of zath1 and Delta homologues in the neuromasts revealing similarities with the phenotype previously described in the ear.     

Expression of foreign genes in mammalian cells using an antibody fusion system

An expression system is described whereby a gene product is expressed fused to an antibody Fab fragment to form an antibody-like molecule The antigen binding function of the original antibody is retained and the foreign gene replaces the C_H2 and C_H3 regions of the heavy chain. The fusion protein is secreted as if it were an antibody, and can be purified using the antigen-binding function of the Fab-Iike part of the molecule. In principle any open reading frame can be expressed and it is not necessary to develop an individual purification scheme, or any analytical reagents such as antibodies, for the expressed protein, as both these functions can be performed by the Fab part of the fusion protein. In practice, the nature of the nonantibodv part of the fusion influences the efficiency of expression and secretion, and detailed guidance is given on trouble-shooting and maximizing expression.     

Expression of threonine-biosynthetic genes in mammalian cells and transgenic mice

Threonine is a nutritionally essential amino acid (EAA) for the growth and development of humans and other nonruminant animals and must be provided in diets to sustain life. The aim of this study was to synthesize threonine in mammalian cells through transgenic techniques. To achieve this goal, we combined the genes involved in bacterial threonine biosynthesis pathways into a single open reading frame separated by self-cleaving peptides (2A) and then linked it into a transposon system (piggyBac). The plasmids pEF1a-IRES-GFP-E2F-his and pEF1a-IRES-GFP-M2F-his expressed Escherichia coli homoserine kinase and threonine synthase efficiently in mouse cells and enabled cells to synthesize threonine from homoserine. This biosynthetic pathway occurred with a low level of efficiency in transgenic mice. Three transgenic mice were identified by Southern blot from 72 newborn mice, raising the possibility that a high level of expression of these genes in mouse embryos might be lethal. The results indicated that it is feasible to synthesize threonine in animal cells using genetic engineering technology. Further work is required to improve the efficiency of this method for introducing genes into mammals. We propose that the transgenic technology provides a promising means to enhance the synthesis of nutritionally EAAs in farm animals and to eliminate or reduce supplementation of these nutrients in diets for livestock, poultry and fish.     

Expression of fungal desaturase genes in cultured mammalian cells

Long-chain polyunsaturated fatty acids (LC-PUFA) are important components of cellular structure and function. Most of LC-PUFA are derived from linoleic acid and a-linolenic acid. In plants and fungi, these two acids can be synthesized from oleic acid via the action of two enzymes, 12 and 15-desaturases. Due to lack of these enzymatic activities and the ability to synthesize these two essential fatty acids, animals must obtain them from the diet. In this report, we demonstrated the expression of a fungal 12-desaturase gene in mouse L cells incubated in serum-free medium. The results showed a significant increase in the amount of linoleic acid with a concomitant decrease of oleic acid in cellular lipids. Most of the newly formed linoleic acid was incorporated into cellular phospholipids, particularly phosphatidylcholine. The increase of linoleic acid provided the substrate for the endogenous synthesis of (n-6) LC-PUFA, such as eicosadienoic acid (EDA), dihomo--linoleic acid (DGLA) and arachidonic acid (AA). Prolonged incubation further increased the levels of linoleic acid derived from oleic acid by the action of 12-desaturase, and the levels of 20:2n-6 produced from linoleic acid by the action of the endogenous elongase. However, prolonged incubation suppressed significantly the formation of DGLA and AA. In a separate study, a fungal 6-desaturase gene has also been expressed in the mouse L cells incubated in serum-containing medium. The result shows a significant increase in levels of 20:3n-6 and 20:4n-6. These findings demonstrate that through genetic modification, it is possible to (1) generate cell lines which no longer require dietary 'essential' fatty acids and (2) alter the endogenous fatty acid metabolism to enhance the production of LC-PUFA and their derivatives.     

Expression of bacterial cytotoxin genes in mammalian target cells

We have studied the expression of the gene fragments encoding the enzymatically active portion of three bacterial cytotoxins: exotoxin A (ETA) of Pseudomonas aeruginosa, and pertussis toxin (PT) and adenylate cyclase toxin (CYA) of Bordetella pertussis, in sensitive mammalian target cells. Expression of active ETA and CYA was lethal to the producing cells and stable transfectants of Cos-1 cells containing the corresponding genes could not be obtained. The expression of the PTS1 subunit was tolerated by the producing mammalian cells. Since PT is cytotoxic because of ADP-ribosylation of G-proteins, we assume that the endogenously expressed PTS1 may not find the cellular target G proteins or PTS1 alone may not be sufficient for ADP-ribosylation of these proteins in vivo.     

Neogenin is expressed on neurogenic and gliogenic progenitors in the embryonic and adult central nervous system

The Netrin/RGMa receptor, Neogenin, has recently been identified on neuronal and gliogenic progenitors, including radial glia in the embryonic mouse cortex and ganglionic eminences, respectively [Fitzgerald, D.P., Cole, S.J., Hammond, A., Seaman, C., Cooper, H.M., 2006a. Characterization of Neogenin-expressing neural progenitor populations and migrating neuroblasts in the embryonic mouse forebrain. Neuroscience 142, 703-716]. Here we have undertaken a detailed analysis of Neogenin expression in the embryonic mouse central nervous system at key developmental time points. We demonstrate that Neogenin protein is present on actively dividing neurogenic precursors during peak phases of neurogenesis (embryonic days 12.5-14.5) in the forebrain, midbrain and hindbrain. Furthermore, we show that Neogenin protein is localized to the cell bodies and glial processes of neurogenic radial glial populations in all these regions. We have also observed Neogenin on gliogenic precursors within the subventricular zones of the forebrain late in development (embryonic day 17.5). Adult neural stem cells found in the subventricular zone of the lateral ventricle of the rodent forebrain are direct descendants of the embryonic striatal radial glial population. Here we show that Neogenin expression is maintained in the neural stem cell population of the adult mouse forebrain. In summary, this study demonstrates that Neogenin expression is a hallmark of many neural precursor populations (neurogenic and gliogenic) in both the embryonic and adult mammalian central nervous system.     

Expression and subcellular localization of mammalian formin Fhod3 in the embryonic and adult heart

The formin family proteins play pivotal roles in actin filament assembly via the FH2 domain. The mammalian formin Fhod3 is highly expressed in the heart, and its mRNA in the adult heart contains exons 11, 12, and 25, which are absent from non-muscle Fhod3 isoforms. In cultured neonatal cardiomyocytes, Fhod3 localizes to the middle of the sarcomere and appears to function in its organization, although it is suggested that Fhod3 localizes differently in the adult heart. Here we show, using immunohistochemical analysis with three different antibodies, each recognizing distinct regions of Fhod3, that Fhod3 localizes as two closely spaced bands in middle of the sarcomere in both embryonic and adult hearts. The bands are adjacent to the M-line that crosslinks thick myosin filaments at the center of a sarcomere but distant from the Z-line that forms the boundary of the sarcomere, which localization is the same as that observed in cultured cardiomyocytes. Detailed immunohistochemical and immuno-electron microscopic analyses reveal that Fhod3 localizes not at the pointed ends of thin actin filaments but to a more peripheral zone, where thin filaments overlap with thick myosin filaments. We also demonstrate that the embryonic heart of mice specifically expresses the Fhod3 mRNA isoform harboring the three alternative exons, and that the characteristic localization of Fhod3 in the sarcomere does not require a region encoded by exon 25, in contrast to an essential role of exons 11 and 12. Furthermore, the exon 25-encoded region appears to be dispensable for actin-organizing activities both in vivo and in vitro, albeit it is inserted in the catalytic FH2 domain.     

Expression of epithelial calcium transport system in rat cochlea and vestibular labyrinth

Background  

The low luminal Ca²⁺ concentration of mammalian endolymph in the inner ear is required for normal hearing and balance. We recently reported the expression of mRNA for a Ca²⁺-absorptive transport system in primary cultures of semicircular canal duct (SCCD) epithelium.