Drosophila CAPS is an essential gene that regulates dense-core vesicle release and synaptic vesicle fusion.

Calcium-activated protein for secretion (CAPS) is proposed to play an essential role in Ca2+-regulated dense-core vesicle exocytosis in vertebrate neuroendocrine cells. Here we report the cloning, mutation, and characterization of the Drosophila ortholog (dCAPS). Null dCAPS mutants display locomotory deficits and complete embryonic lethality. The mutant NMJ reveals a 50% loss in evoked glutamatergic transmission, and an accumulation of synaptic vesicles at active zones. Importantly, dCAPS mutants display a highly specific 3-fold accumulation of dense-core vesicles in synaptic terminals, which was not observed in mutants that completely arrest synaptic vesicle exocytosis. Targeted transgenic CAPS expression in identified motoneurons fails to rescue dCAPS neurotransmission defects, demonstrating a cell nonautonomous role in synaptic vesicle fusion. We conclude that dCAPS is required for dense-core vesicle release and that a dCAPS-dependent mechanism modulates synaptic vesicle release at glutamatergic synapses.

Temperature-sensitive paralytic mutations demonstrate that synaptic exocytosis requires SNARE complex assembly and disassembly.

The neuronal SNARE complex is formed via the interaction of synaptobrevin with syntaxin and SNAP-25. Purified SNARE proteins assemble spontaneously, while disassembly requires the ATPase NSF. Cycles of assembly and disassembly have been proposed to drive lipid bilayer fusion. However, this hypothesis remains to be tested in vivo. We have isolated a Drosophila temperature-sensitive paralytic mutation in syntaxin that rapidly blocks synaptic transmission at nonpermissive temperatures. This paralytic mutation specifically and selectively decreases binding to synaptobrevin and abolishes assembly of the 7S SNARE complex. Temperature-sensitive paralytic mutations in NSF (comatose) also block synaptic transmission, but over a much slower time course and with the accumulation of syntaxin and SNARE complexes on synaptic vesicles. These results provide in vivo evidence that cycles of assembly and disassembly of SNARE complexes drive membrane trafficking at synapses.

Evidence that the Drosophila olfactory mutant smellblind defines a novel class of sodium channel mutation.

The smellblind (sbl) gene of Drosophila is associated with olfactory defects, and the paralytic (para) gene encodes a voltage-gated sodium channel. sbl and para have similar genetic map positions, many combinations of sbl and para mutations fail to complement, and two sbl mutations contain molecular lesions within the para transcription unit. sbl mutations also behave like para mutations in that they are enhanced by the mutation no action potential temperature-sensitive (mlenapts1). The simplest interpretation of these results is that sbl and para are the same gene. Two sbl mutations produce olfactory defects not characteristic of classic sodium channel mutations and do not show typical heat-sensitive paralysis, suggesting that these sbl mutants define a novel class of sodium channel mutation.

The maleless protein associates with the X chromosome to regulate dosage compensation in Drosophila.

The maleless (mle) gene is one of four known regulatory loci required for increased transcription (dosage compensation) of X-linked genes in D. melanogaster males. A predicted mle protein (MLE) contains seven short segments that define a superfamily of known and putative RNA and DNA helicases. MLE, while present in the nuclei of both male and female cells, differs in its association with polytene X chromosomes in the two sexes. MLE is associated with hundreds of discrete sites along the length of the X chromosome in males and not in females. The predominant localization of MLE to the X chromosome in males makes it a strong candidate to be a direct regulator of dosage compensation.

napts, a mutation affecting sodium channel activity in Drosophila, is an allele of mle, a regulator of X chromosome transcription.

napts is a recessive mutation that affects the level of sodium channel activity and, at high temperature, causes paralysis associated with a loss of action potentials. We show, by genetic complementation tests, germline transformation, and analysis of mutations, that napts is a gain-of-function mutation of mle, a gene required for X chromosome dosage compensation and male viability. Molecular analyses of nap and mle mutations indicate that mle+, nap+, and napts activities are encoded by the same open reading frame and suggest that napts is due to a single amino acid substitution. Although napts is known to act via para+, an X-linked sodium channel structural gene, its effect is not due to a simple defect in para+ dosage compensation.

Molecular characterization of eag: a gene affecting potassium channels in Drosophila melanogaster.

Genes encoding proteins involved in the function of the nervous system can be identified via mutations causing behavioral abnormalities. An example is ether à go-go (eag) in Drosophila melanogaster, which was identified originally as an X-linked mutation that displayed ether-induced leg-shaking behavior. Electrophysiological and genetic evidence suggests that the product of the eag locus is intimately involved in the normal functioning of one or more types of voltage-gated potassium channels. To initiate a molecular analysis of eag we first generated a collection of deletions to pinpoint its cytological location. On the basis of this location, we identified an existing inversion, In(1)sc29, with one breakpoint at the eag locus and the other in the scute (sc) complex. A genomic library was prepared from In(1)sc29 and screened with a genomic DNA fragment that spanned the sc breakpoint to isolate DNA from the eag region. Beginning from this starting point over 85 kb of DNA were isolated by chromosome walking. Three additional eag alleles, including two dysgenesis-induced insertion mutations and a gamma-ray-induced insertional translocation, were located on the molecular map of the eag locus by Southern blot analysis. The molecular defects associated with these alleles encompass a total of 27 kb within the chromosome walk. A 10-kb transcript derived from this region, which is expressed most abundantly in heads, was identified on Northern blots. Two different eag mutations separated by over 20 kb interrupt the same transcript identifying it as the likely eag message. cDNAs representing a portion of this transcript have been isolated.(ABSTRACT TRUNCATED AT 250 WORDS)

Dosage effects of a Drosophila sodium channel gene on behavior and axonal excitability.

The effects of para mutations on behavior and axonal excitability in Drosophila suggested that para specifically affects sodium channels. This hypothesis was confirmed by molecular analysis of the para locus, which demonstrates that the encoded para product is a sodium channel polypeptide. Here we characterize the effects of altered para+ dosage on behavior and axonal excitability, both in an otherwise wild-type background and in combination with two other mutations: napts, which also affects sodium channels, and ShKS133, which specifically affects potassium channels. Whereas it was previously shown that decreased dosage of para+ is unconditionally lethal in a napts background, we find that increased dosage of para+ suppresses napts. Similarly, we find that para hypomorphs or decreased dosage of para+ suppresses ShKS133, whereas increased dosage of para+ enhances ShKS133). The electrophysiological basis for these effects is investigated. Other genes in Drosophila that have sequence homology to sodium channels do not show such dosage effects, which suggests that the para+ product has a function distinct from that of other putative Drosophila sodium channel genes. We conclude that the number of sodium channels present in at least some Drosophila neurons can be affected by changes in para+ gene dosage, and that the level of para+ expression can strongly influence neuronal excitability.

Molecular analysis of the para locus, a sodium channel gene in Drosophila.

Previous behavioral, electrophysiological, pharmacological, and genetic studies of mutations of the para locus in Drosophila melanogaster suggested that these mutations alter the structure or function of sodium channels. To identify the protein encoded by this gene and to elucidate the molecular basis of the mutant phenotypes, genomic DNA from the para locus was cloned. Mutational lesions in nine different para alleles were mapped and found to be distributed over a region of 45 kb. Analysis of cDNAs revealed that the para locus comprises a minimum of 26 exons distributed over more than 60 kb of genomic DNA. The nucleotide sequence of the complementary DNA predicts a protein whose structure and amino acid sequence are extremely similar to those of vertebrate sodium channels. The results support the conclusion that para encodes a functionally predominant class of sodium channels in Drosophila neurons. Furthermore, the para transcript appears to undergo alternative splicing to produce several distinct subtypes of this channel.

Site-specific X-chromosome rearrangements from hybrid dysgenesis in Drosophila melanogaster.

When the germ line of Drosophila males is destabilized by a syndrome known as hybrid dysgenesis, X-chromosome rearrangements are found in up to 10 percent of the gametes produced. Some of these aberrations are simple inversions, but many are complex multibreak rearrangements. Furthermore, most of the breakpoints fall into a few highly localized positions on the chromosome. These positions are mostly at points of intercalary heterochromatin and may vary from one strain to the next. the results suggest that they may represent points of insertion of mobile DNA sequences.

Correlation between phosphorylated H1 histones and satellite DNAs in Drosophila virilis.

Drosophila virilis DNA contains satellites I, II, and III. D. novamexicana DNA contains satellite I. D. virilis H1 histone contains subfractions a, b, c, d, and e; D. novamexicana H1 contains subfractions a, b, and c. Therefore, satellites II and III might be correlated with H1d and H1e. To test the validity of this correlation, the H1 histones of polytene nuclei, which contain less than 1% satellite DNA, were analyzed. Polytene nuclei of D. virilis contain substantially decreased levels of H1c and H1e and marginally decreased levels of H1d. Polytene nuclei of D. novamexicana contain decreased levels of H1c.H1c is correlated with satellite I (common to D. virilis and D. novamexicana); H1e is correlated with satellites II and III; H1d is not correlated with any satellite DNA, because its level is virtually unchanged in polytene cells lacking detectable amounts of satellite DNA. Alkaline phosphatase digestion of the H1 histones reveals that H1c is the phosphorylated form of H1b and H1e is the phosphorylated form of H1d. Therefore, the under-replication of satellite DNAs is correlated with the decreased phosphorylation of H1 histones. In vitro, D. virilis H1 histones preferentially bind D. virilis DNAs in the progression III greater than II greater than I greater than main band, whereas D. virilis core histones do not preferentially bind any D. virilis DNA. As an extension of these results, we suggest that phosphorylated H1 histones bind D. virilis satellite DNAs in vivo and are involved in the compaction of heterochromatin.

[Determination of the molecular weight of human ceruloplasmin by hydrodynamic methods and x-ray small-angle scattering]. / Opredelenie molekuliarnogo vesa tseruloplazmina cheloveka pri pomoshchi gidrodinamicheskikh metodov i rentgenovskogo malouglovogo rasseianiia

On the basis of absolute methods of estimation of molecular weight (sedimentation equilibrium method, high speed sedimentation-diffusion and small-angle X-ray scattering) the molecular weight of ceruloplasmin M=130 000+/-5000 was determined.