Effective expression of the green fluorescent fusion proteins in cultured Aplysia neurons.

The green fluorescent fusion protein and its isoforms are extensively used to monitor gene expression, protein localisation and their dynamics in relations to fundamental cellular processes. However, it has not yet been effectively applied to Aplysia neurons that serve as a powerful model to study the mechanisms underlying neuroplasticity. We report here the development of a procedure combining in vitro transcription of mRNA encoding fluorescent-tagged proteins and its subsequent injection into the cytoplasm to image, in real-time, protein dynamics in cultured Aplysia neurones. To illustrate the efficiency of the procedure we report here the visualisation of actin, microtubules and vesicle trafficking. The results presented here introduce a reliable and effective method to express green fluorescent protein (GFP) fusion proteins in cultured Aplysia neurons.

The zebrafish eya1 gene and its expression pattern during embryogenesis.

The eyes absent-like genes encode a group of putative transcriptional coactivators with a sole representative in Drosophila and several members in mammals. Haploinsufficiency of the human EYA1 gene results in branchio-oto-renal syndrome characterized by developmental anomalies of the branchial arches, the three compartments of the ear and the kidney. As a first step towards a functional analysis of this gene in lower vertebrates, we isolated its zebrafish homologue, eya1, and studied its expression pattern during embryogenesis. The eya1 cDNA predicts a protein with 84.7% identity with the human homologue. Transcripts are first detected at the tailbud stage in presumptive cranial placodal precursor cells. Thereafter, eya1 expression continues in anterior pituitary, olfactory, otic, and lateral line placodes. Aside from these placodal sites of expression, eya1 transcripts were observed in the somites, developing pectoral fins, and branchial arches. No expression was found in pronephros or Wolffian duct of the zebrafish renal system. Within the developing ear, eya1 expression becomes confined to the ventral part of the otic vesicle from where the acoustic ganglion precursor cells arise and the sensory patches differentiate. In the lateral line, eya1 is expressed in the placodes, ganglia, migrating primordia, and receptive organs at all developmental stages, including both the differentiating hair and supporting cells. Taken together, these results indicate a remarkable similarity in both the structure and expression pattern of eya1 between higher and lower vertebrates, suggesting that the function of this gene has been conserved throughout vertebrate evolution.

Eya1 expression in the developing ear and kidney: towards the understanding of the pathogenesis of Branchio-Oto-Renal (BOR) syndrome.

Branchio-Oto-Renal (BOR) syndrome is an autosomal dominant, early developmental defect characterised by varying combinations of branchial (fistulas, sinuses, and cysts), outer, middle and inner ear, and renal anomalies. The gene underlying this syndrome, EYA1, is homologous to the Drosophila developmental gene eyes absent which encodes a transcriptional co-activator required for eye specification. We report here the temporal and spatial pattern of expression of the murine homologue, Eya1, throughout ear and kidney development in relation to the anomalies of BOR syndrome. The expression of Eya1 in the branchial arch apparatus (namely in the 2nd, 3rd, and 4th branchial clefts and pharyngeal pouches) at embryonic day (E)10.5, can be correlated with the branchial fistulas, sinuses, and cysts but not with the outer and middle ear anomalies. In contrast, Eya1 is expressed during the slightly more advanced stage of outer and middle ear morphogenesis at E13.5, in the mesenchyme adjacent to the first branchial cleft (the cleft will give rise to the external auditory canal and the surrounding mesenchyme to the auricular hillocks) and surrounding the primordia of the middle ear ossicles, and in the epithelium of the tubotympanic recess (the future tympanic cavity). During early inner ear development, Eya1 is expressed in the ventromedial wall of the otic vesicle (the site of the future sensory epithelia), in the statoacoustic ganglion, and in the periotic mesenchyme, consistent with the cochlear anomalies and sensorineural hearing loss of BOR syndrome. Subsequently, Eya1 expression is observed in the differentiating hair and supporting cells of the sensory epithelia, as well as in the associated ganglia, and persists after differentiation has taken place. This suggests that, in addition to a role in the morphogenetic process, Eya1 could also be implicated in the differentiation and/or survival of these inner ear cell populations. Finally, Eya1 expression in the condensing mesenchymal cells of the kidney is consistent with the excretory and collecting system anomalies of BOR syndrome. From the comparison of the Eya1 and Pax2 expression patterns during ear and kidney development, a contribution of these two genes to the same regulatory pathway can only be suggested in the mesenchymal-epithelial transition directing renal tubule formation.

Prominent neuronal-specific tub gene expression in cellular targets of tubby mice mutation.

The tubby strain of mice exhibits maturity-onset obesity and sensory deficits in vision and hearing. The mutated gene, tub , responsible for this phenotype was identified recently, but the function of the TUB protein has not been deduced from its amino acid sequence. This prompted us to undertake expression mapping studies with the hope that they might help to elucidate the biological role of the TUB protein. We report the tub gene expression pattern in embryonic, fetal and adult mice tissues as determined by northern blots and in situ hybridization, using antisense oligonucleotidic probes. In mouse embryos, tub is expressed selectively in differentiating neurons of the ensemble of central and peripheral nervous systems, starting at 9.5 days after conception. In adult mice, tub is transcribed in several major brain areas, including cerebral cortex, hippocampus, several nuclei of the hypothalamus controlling feeding behavior, in the spiral ganglion of the inner ear and in the photoreceptor cells of the retina. These structures contain potential cellular targets of the tubby mutation-induced pathogenesis. The neuronal-specific tub gene distribution allows the establishment of a genotype-phenotype correlation in the tubby mice. This correlation is reminiscent of that observed in fat/fat mice, whose phenotype, also characterized by obesity, is caused by a null mutation in the carboxypeptidase E (CPE) gene. Our observations highlight similarities between CPE, prohormone convertases, several neuropeptides and tub gene expression patterns during embryogenesis, and may narrow down the avenues to explore in order to determine ultimately the function of the TUB protein.

Identification of novel PAX6 mutations in two families with bilateral aniridia. Mutations in brief no. 167. Online.

We report two novel PAX6 mutations in aniridia patients of two Swiss pedigrees (We, Sc) which give rise to different phenotypes. An SSCP analysis of the PAX6 14 exons reveals electrophoretic mobility shifts exclusively in exons 5 and 12 of aniridia patients. As determined by bidirectional sequencing and restriction digest analysis, these shifts are caused by mono-allelic base transitions in exon 5 (c.547C-->T; R44X; We) and intron 12 (IVS12+5G-->A; Sc). Each mutation co-segregates with the trait in the affected family with complete penetrance. The Sc mutation in the splicing donor site of intron 12 may result in either intron inclusion or exon skipping, both giving rise to a truncated PAX6 protein which may retain a residual transactivating activity. In contrast, the We genetic alteration is a loss-of-function mutation leading to a more severe phenotype than that observed in the Sc pedigree.

Expression of myosin VIIA during mouse embryogenesis.

The gene encoding myosin VIIA is responsible for the mouse shaker-1 phenotype, which consists of deafness and balance deficiency related to cochlear and vestibular neuroepithelial defects. In humans, a defective myosin VIIA gene is responsible for Usher syndrome type IB, which associates congenital deafness, vestibular dysfunction and retinitis pigmentosa. In an attempt to progress in the understanding of the function(s) of myosin VIIA, we studied the expression of the myosin VIIA gene during mouse embryonic development. Embryos from day 9 (E9) to E18 were analyzed by in situ hybridization and immunohistofluorescence. The myosin VIIA mRNA and protein were consistently detected in the same embryonic tissues throughout development. Myosin VIIA was first observed in the otic vesicle at E9, and later in a variety of tissues. The olfactory epithelium and the liver express it as early as E10. In the retinal pigment epithelium, choroid plexus, adrenal gland and tongue, expression begins at E12 and in the testis and the adenohypophysis at E13. In the small intestine, kidney and hair follicles of the vibrissae, expression of myosin VIIA starts only at E15. Myosin VIIA expression was observed only in epithelial cell types, most of which possess microvilli or cilia. Interestingly, myosin VIIA expression seems to be concomitant with the appearance of these structures in the epithelial cells, suggesting a role for this myosin in their morphogenesis. The cellular location of myosin VIIA within sensory hair cells and olfactory receptor neurons also argues for a role of this protein in the synaptic vesicle trafficking.

SOX22 is a new member of the SOX gene family, mainly expressed in human nervous tissue.

SOX (SRY box-containing) genes share a particular DNA-binding domain, called HMG, with the mammalian testis-determining gene SRY Several SOX genes have already been shown to be transcription factors involved in the decision of important cell fates during development. Here we report the cloning of a new human member of the SOX gene family, SOX22. The corresponding protein contains several domains that are also present in other paralogous SOX proteins. The SOX22 gene maps to chromosome 20 on band p13 and does not appear to be clustered with any other SOX gene mapped to date. SOX22 mRNA is expressed in various fetal and adult organs and tissues, suggesting that this gene plays roles in both differentiation and maintenance of several cell types.

A human homologue of the Drosophila eyes absent gene underlies branchio-oto-renal (BOR) syndrome and identifies a novel gene family.

A candidate gene for Branchio-Oto-Renal (BOR) syndrome was identified at chromosome 8q13.3 by positional cloning and shown to underlie the disease. This gene is a human homologue of the Drosophila eyes absent gene (eya), and was therefore called EYA1. A highly conserved 271-amino acid C-terminal region was also found in the products of two other human genes (EYA2 and EYA3), demonstrating the existence of a novel gene family. The expression pattern of the murine EYA1 orthologue, Eya1, suggests a role in the development of all components of the inner ear, from the emergence of the otic placode. In the developing kidney, the expression pattern is indicative of a role for Eya1 in the metanephric cells surrounding the 'just-divided' ureteric branches.

Human Usher 1B/mouse shaker-1: the retinal phenotype discrepancy explained by the presence/absence of myosin VIIA in the photoreceptor cells.

Usher syndrome type 1 (USH1) associates severe congenital deafness, vestibular dysfunction and progressive retinitis pigmentosa leading to blindness. The gene encoding myosin VIIA is responsible for USH1B. Mutations in the murine orthologous gene lead to the shaker-1 phenotype, which manifests cochlear and vestibular dysfunction, without any retinal defect. To address this phenotypic discrepancy, the expression of myosin VIIA in retinal cells was analyzed in human and mouse during embryonic development and adult life. In the human embryo, myosin VIIA was present first in the pigment epithelium cells, and later in these cells as well as in the photoreceptor cells. In the adult human retina, myosin VIIA was present in both cell types. In contrast, in mouse, only pigment epithelium cells expressed the protein throughout development and adult life. Myosin VIIA was also found to be absent in the photoreceptor cells of other rodents (rat and guinea-pig), whereas these cells expressed the protein in amphibians, avians and primates. These observations suggest that retinitis pigmentosa of USH1B results from a primary rod and cone defect. The USH1B/shaker-1 paradigm illustrates a species-specific cell pattern of gene expression as a possible cause for the discrepancy between phenotypes involving defective orthologous genes in man and mouse. Interestingly, in the photoreceptor cells, myosin VIIA is mainly localized in the inner and base of outer segments as well as in the synaptic ending region where it is co-localized with the synaptic vesicles. Therefore, we suggest that myosin VIIA might play a role in the trafficking of ribbon-synaptic vesicle complexes and the renewal processes of the outer photoreceptor disks.

Human myosin VIIA responsible for the Usher 1B syndrome: a predicted membrane-associated motor protein expressed in developing sensory epithelia.

The gene encoding human myosin VIIA is responsible for Usher syndrome type III (USH1B), a disease which associates profound congenital sensorineural deafness, vestibular dysfunction, and retinitis pigmentosa. The reconstituted cDNA sequence presented here predicts a 2215 amino acid protein with a typical unconventional myosin structure. This protein is expected to dimerize into a two-headed molecule. The C terminus of its tail shares homology with the membrane-binding domain of the band 4.1 protein superfamily. The gene consists of 48 coding exons. It encodes several alternatively spliced forms. In situ hybridization analysis in human embryos demonstrates that the myosin VIIA gene is expressed in the pigment epithelium and the photoreceptor cells of the retina, thus indicating that both cell types may be involved in the USH1B retinal degenerative process. In addition, the gene is expressed in the human embryonic cochlear and vestibular neuroepithelia. We suggest that deafness and vestibular dysfunction in USH1B patients result from a defect in the morphogenesis of the inner ear sensory cell stereocilia.

Accumulation of calcium in degenerating photoreceptors of several Drosophila mutants.

The hypothesis that a large, possibly toxic, increase in cellular calcium accompanies photoreceptor cell degeneration in several different Drosophila mutants was tested. The calcium content of wild type and mutant photoreceptors of Drosophila was measured using rapid freezing of the eyes and energy-dispersive x-ray analysis (e.d.x.) of cryosections and semithin sections of cryosubstituted material. Light- and dark-raised mutants of the following strains were studied: retinal degeneration B (rdgB); retinal degeneration C (rdgC); neither inactivation nor afterpotential C (ninaC), and no receptor potential A (norpA). These are light-dependent retinal degeneration mutants in which the affected gene products had been previously shown as myosin-kinase (ninaC), calcium-dependent phosphoprotein phosphatase (rdgC), phosphoinositide transfer protein (rdgB), and phospholipase C (norpA). In light-raised mutants, ommatidia of variable degrees of degeneration were observed. Mass-dense globular bodies of 200-500 nm diameter in relatively large quantities were found in the degenerating photoreceptor of all the mutants tested. These subcellular globules were found to have a very high calcium content, which was not found in wild type or in nondegenerating photoreceptors of the mutants. Nondegenerating photoreceptors were found not only in dark-raised mutants, but in smaller quantities also in light-raised mutants. Usually these globular structures contained high levels of phosphorus, indicating that at least part of the calcium in the mutant photoreceptors is precipitated as calcium phosphate. The results indicate that a large increase in cellular calcium accompanies light-induced photoreceptor degeneration in degenerating Drosophila mutants even when induced by very different mutations, suggesting that the calcium accumulation is a secondary rather than a primary effect in the degeneration process.

Calcium channel blockers inhibit retinal degeneration in the retinal-degeneration-B mutant of Drosophila.

Light accelerates degeneration of photoreceptor cells of the retinal degeneration B (rdgB) mutant of Drosophila. During early stages of degeneration, light stimuli evoke spikes from photoreceptors of the mutant fly; no spikes can be recorded from photoreceptors of the wild-type fly. Production of spike potentials from mutant photoreceptors was blocked by diltiazem, verapamil hydrochloride, and cadmium. Little, if any, effect of the (-)-cis isomer or (+)-cis isomer of diltiazem on the light response was seen. Further, the (+)-cis isomer was approximately 50 times more effective than the (-)-cis isomer in blocking the Ca2+ spikes, indicating that diltiazem action on the rdgB eye is mediated by means of blocking voltage-sensitive Ca2+ channels, rather than by blocking the light-sensitive channels. Application of the Ca(2+)-channel blockers (+)-cis-diltiazem and verapamil hydrochloride to the eyes of rdgB flies over a 7-day period largely inhibited light-dependent degeneration of the photoreceptor cells. Pulse labeling with [32P]phosphate showed much greater incorporation into eye proteins of [32P]phosphate in rdgB flies than in wild-type flies. Retarding the light-induced photoreceptor degeneration in the mutant by Ca(2+)-channel blockers, thus, suggests that toxic increase in intracellular Ca2+ by means of voltage-gated Ca2+ channels, possibly secondary to excessive phosphorylation, leads to photoreceptor degeneration in the rdgB mutant.

Phorbol ester induces photoreceptor-specific degeneration in a Drosophila mutant.

In the retinal degeneration B (rdgB) mutant of Drosophila, the major class of photoreceptors degenerate when the fly is raised in the light for several days; raising the fly in the dark largely prevents the degeneration. Thus, the rdgB is a conditional mutant that requires the operation of some stages of the phototransduction cascade to express its characteristic phenotype. We report here experiments that examine the ability of chemical agents to mimic light by causing photoreceptor-specific degeneration in the dark. Application of a specific activator of protein kinase C, phorbol ester, to eyes of rdgB flies led to a degeneration of the photoreceptors that was indistinguishable from that caused by light: both light and phorbol ester-induced degeneration were characterized by (i) selective degeneration of one class of photoreceptors; (ii) a unique pattern of degeneration; and (iii) the appearance of light-induced regenerative spikes at early stages of degeneration. Application of phorbol ester to the eyes of wild-type flies had no effect. We suggest that light or phorbol ester activates a protein kinase C and results in a sustained or excessive phosphorylation of proteins in the rdgB mutant, leading to photoreceptor degeneration. Furthermore, the results are consistent with identification of the rdgB gene product as a phosphoprotein phosphatase that is nonfunctional or absent in the mutant.