Characterization of an invertebrate nicotinic acetylcholine receptor gene: The ard gene of Drosophila melanogaster

AbstractThe ard gene encodes a neuronal nicotinic acetylcholine receptor (AChR) protein from Drosophila (ARD protein). Cytogenetically this gene maps at position 64B/C on the left arm of the 3rd chromosome. Five introns interrupt the protein coding region of the gene, and one is found upstream of the translation start site. The ard gene thus contains less introns than vertebrate muscle AChR genes, but, with one exception, the positions of the resident introns are precisely conserved. Implications for the evolution of AChR genes are discussed

The intramembrane protease SPPL2a promotes B cell development and controls endosomal traffic by cleavage of the invariant chain

Peer reviewe

Chronic stress induces opposite changes in the mRNA expression of the cell adhesion molecules NCAM and L1

The effects of 21-day exposure to restraint stress on mRNA levels of the cell adhesion molecules NCAM and L1 were evaluated in different hippocampal regions (CA1, CA3, and dentate gyrus) and other structures (thalamus, prefrontal and frontal cortices, and striatum) of the rat brain. A general decrease in gene expression of the neural cell adhesion molecule (NCAM) was found throughout the brain, particularly in all hippocampal subregions. On the contrary, transcripts for the adhesion molecule L1 were specifically increased at the level of the hippocampus, especially in the dorsal dentate gyrus and area CA3. mRNA for the NCAM180 isoform was detected unchanged in all brain areas examined after chronic stress. A second experiment explored whether there would be cognitive alterations associated with this stress procedure and molecular regulation. Thus, after exposure to the same restraint regimen, performance in the water maze was evaluated. Although stressed rats displayed the ability to learn the task throughout the training session, they showed a transient deficit in the initial phase of the acquisition. In conclusion, our findings indicate that chronic stress interferes with the mechanisms involved in the synthesis of cell adhesion molecules of the immunoglobulin superfamily. Furthermore, they suggest that these effects might be involved in the mechanisms by which stress induces structural and functional alterations in the central nervous system and, particularly, in the hippocampus

Water maze learning and forebrain mRNA expression of the neural cell adhesion molecule L1

L1 and NCAM, two cell adhesion molecules of the immunoglobulin superfamily, have been implicated in the formation of neural circuits, synaptic plasticity, and cognitive function. In this study, we sought to investigate whether differences in the steady-state levels of L1 and NCAM expression in specific brain regions could account for individual differences in learning abilities. Using adult male Wistar rats, we evaluated mRNA levels of L1, NCAM, and the NCAM180 isoform in different brain regions (hippocampus, thalamus, striatum, prefrontal and frontal cortices) immediately after submitting rats to a massed training protocol in the water maze. The results showed that untrained and trained rats exhibited similar levels of mRNA for these molecules, which supports the view that training did not influence their immediate level of expression. However, in most of the brain regions we investigated (with the exception of prefrontal and frontal cortices), L1 mRNA levels were positively correlated with the latency to find the hidden platform in the water maze task and with posttraining plasma corticosterone levels. However, no correlations were observed for total NCAM or NCAM180 mRNA in the brain regions examined in this study. Given that animals with a slower spatial acquisition curve exhibited more anxiety-like responses, including thigmotactic behavior in the water maze and increased corticosterone levels, and that recent genetic studies indicate a role for L1 in anxiety, the current findings suggest a relationship among L1, anxiety, and cognitive processes

Sequence of a Drosophila Ligand-Gated Ion-Channel Polypeptide with an Unusual Amino-Terminal Extracellular Domain

Abstract: We report the isolation of a full-length clone from a Drosophila melanogaster head cDNA library that encodes a 614-residue polypeptide that exhibits all of the features of a ligand-gated chloride-channel/receptor subunit. This polypeptide, which has been named GRD (denoting that the polypeptide is a GABAA and glycine receptor-like subunit of Drosophila), displays between 33 and 44% identity to vertebrate GABAA and glycine receptor subunits and 32–37% identity to the GABAA receptor-like polypeptides from Drosophila and Lymnaea. It is interesting that the large amino-terminal, presumed extracellular domain of the GRD protein contains an insertion, between the dicysteine loop and the first putative membrane-spanning domain, of 75 amino acids that is not found in any other ligand-gated chloride-channel subunit. Analysis of cDNA and genomic DMA reveals that these residues are encoded by an extension of an exon that is equivalent to exon 6 of vertebrate GABAA and glycine receptor genes. The gene (named Grd) that encodes the Drosophila polypeptide has been mapped, by in situ hybridization, to position 75A on the left arm of chromosome 3

Sox9 overexpression exerts multiple stage‐dependent effects on mouse spinal cord development

Abstract The high‐mobility‐group (HMG)‐domain protein Sox9 is one of few transcription factors implicated in gliogenesis in the vertebrate central nervous system. To further study the role of Sox9 in early spinal cord development, we generated a mouse that allows expression of Sox9 in a temporally and spatially controlled manner. Using this mouse, we show that premature Sox9 expression in neural precursor cells disrupted the neuroepithelium of the ventricular zone. Sox9 also compromised development and survival of neuronal precursors and neurons. Additionally, we observed in these mice substantial increases in oligodendroglial and astroglial cells. Reversing the normal order of appearance of essential transcriptional regulators during oligodendrogenesis, Sox10 preceded Olig2. Our study reinforces the notion that Sox9 has a strong gliogenic activity. It also argues that Sox9 expression has to be tightly controlled to prevent negative effects on early spinal cord structure and neuronal development

Mutation of the Sry-related Sox10 gene in Dominant megacolon, a mouse model for human Hirschsprung disease

The spontaneous mouse mutant Dominant megacolon (Dom) is a valuable model for the study of human congenital megacolon (Hirschsprung disease). Here we report that the defect in the Dom mouse is caused by mutation of the gene encoding the Sry-related transcription factor Sox10. This assignment is based on (i) colocalization of the Sox10 gene with the Dom mutation on chromosome 15; (ii) altered Sox10 expression in the gut and in neural-crest derived structures of cranial ganglia of Dom mice; (iii) presence of a frameshift in the Sox10 coding region, and (iv) functional inactivation of the resulting truncated protein. These results identify the transcriptional regulator Sox10 as an essential factor in mouse neural crest development and as a further candidate gene for human Hirschsprung disease, especially in cases where it is associated with features of Waardenburg syndrome

A mouse model for fucosidosis recapitulates storage pathology and neurological features of the milder form of the human disease

Fucosidosis is a rare lysosomal storage disorder caused by the inherited deficiency of the lysosomal hydrolase α-L-fucosidase, which leads to an impaired degradation of fucosylated glycoconjugates. Here, we report the generation of a fucosidosis mouse model, in which the gene for lysosomal α-L-fucosidase (Fuca1) was disrupted by gene targeting. Homozygous knockout mice completely lack α-L-fucosidase activity in all tested organs leading to highly elevated amounts of the core-fucosylated glycoasparagine Fuc(α1,6)-GlcNAc(β1-N)-Asn and, to a lesser extent, other fucosylated glycoasparagines, which all were also partially excreted in urine. Lysosomal storage pathology was observed in many visceral organs, such as in the liver, kidney, spleen and bladder, as well as in the central nervous system (CNS). On the cellular level, storage was characterized by membrane-limited cytoplasmic vacuoles primarily containing water-soluble storage material. In the CNS, cellular alterations included enlargement of the lysosomal compartment in various cell types, accumulation of secondary storage material and neuroinflammation, as well as a progressive loss of Purkinje cells combined with astrogliosis leading to psychomotor and memory deficits. Our results demonstrate that this new fucosidosis mouse model resembles the human disease and thus will help to unravel underlying pathological processes. Moreover, this model could be utilized to establish diagnostic and therapeutic strategies for fucosidosis.status: publishe