Re-emergence of vesicular stomatitis in the western United States is associated with distinct viral genetic lineages.

Phylogenetic analysis of partial phosphoprotein and glycoprotein gene sequences showed that a single genetic lineage of vesicular stomatitis virus (VSV) serotype New Jersey (NJ) caused the 1995 and 1997 outbreaks of vesicular stomatitis (VS) in the western United States. While distinct from VSV-NJ strains causing previous outbreaks in the western United States and those circulating in feral swine in the southeastern United States, this lineage was closely related to viral lineages circulating in the Mexican states of Guerrero, Veracruz, and Oaxaca in 1996, 1989, and 1984 respectively. In 1997 and 1998, VSV serotype Indiana 1 (IN1) re-emerged in the western United States after 30 years. Viruses causing these outbreaks grouped within a single genetic lineage distinct from VSV-IN1 isolates causing outbreaks in the western United States in 1929 and 1956 but closely related to a strain circulating in the state of Colima in central Mexico in 1997. Our data showed that sporadic VS outbreaks in the western United States are caused by genetically distinct viral lineages closer to those circulating in enzootic areas of central and southern Mexico than to those causing previous outbreaks in the United States. The genetic evidence and temporal distribution of outbreaks are not consistent with a pattern of long-term maintenance of VSV in the western United States.

Splice variants of the Drosophila PS2 integrins differentially interact with RGD-containing fragments of the extracellular proteins tiggrin, ten-m, and D-laminin 2.

Two new potential ligands of the Drosophila PS2 integrins have been characterized by functional interaction in cell culture. These potential ligands are a new Drosophila laminin alpha2 chain encoded by the wing blister locus and Ten-m, an extracellular protein known to be involved in embryonic pattern formation. As with previously identified PS2 ligands, both contain RGD sequences, and RGD-containing fragments of these two proteins (DLAM-RGD and TENM-RGD) can support PS2 integrin-mediated cell spreading. In all cases, this spreading is inhibited specifically by short RGD-containing peptides. As previously found for the PS2 ligand tiggrin (and the tiggrin fragment TIG-RGD), TENM-RGD induces maximal spreading of cells expressing integrin containing the alphaPS2C splice variant. This is in contrast to DLAM-RGD, which is the first Drosophila polypeptide shown to interact preferentially with cells expressing the alphaPS2 m8 splice variant. The betaPS integrin subunit also varies in the presumed ligand binding region as a result of alternative splicing. For TIG-RGD and TENM-RGD, the beta splice variant has little effect, but for DLAM-RGD, maximal cell spreading is supported only by the betaPS4A form of the protein. Thus, the diversity in PS2 integrins due to splicing variations, in combination with diversity of matrix ligands, can greatly enhance the functional complexity of PS2-ligand interactions in the developing animal. The data also suggest that the splice variants may alter regions of the subunits that are directly involved in ligand interactions, and this is discussed with respect to models of integrin structure.

The PS2 integrin ligand tiggrin is required for proper muscle function in Drosophila.

Tiggrin is a novel extracellular matrix ligand for the Drosophila PS2 integrins. We have used flanking P elements to generate a precise deletion of tiggrin. Most flies lacking tiggrin die as larvae or pupae. A few adults do emerge and these appear to be relatively normal, displaying only misshapen abdomens and a low frequency of wing defects. Examination of larvae shows that muscle connections, function and morphology are defective in tiggrin mutants. Muscle contraction waves that extend the length of the larvae are much slower in tiggrin mutants. Direct examination of bodywall muscles shows defects in muscle attachment sites, where tiggrin is specifically localized, and muscles appear thinner. Transgenes expressing tiggrin are capable of rescuing tiggrin mutant phenotypes. Transgenes expressing a mutant tiggrin, whose Arg-Gly-Asp (RGD) integrin recognition sequence has been mutated to Leu-Gly-Ala (LGA) show much reduced, but significant, rescuing ability. Cell spreading assays detect no interactions of this mutant tiggrin with PS2 integrins. Therefore, while the RGD sequence is critical for PS2 interactions and full activity in the whole fly, the mutant tiggrin retains some function(s) that are probably mediated by interactions with other ECM molecules or cell surface receptors

Requirements for the cytoplasmic domain of the alphaPS1, alphaPS2 and betaPS integrin subunits during Drosophila development.

The integrins are a family of transmembrane heterodimeric proteins that mediate adhesive interactions and participate in signaling across the plasma membrane. In this study we examine the functional significance of the cytoplasmic domains of the alphaPS1, alphaPS2 and betaPS subunits of the Drosophila Position Specific (PS) integrin family by analyzing the relationship between cytoplasmic domain structure and function in the context of a developing organism. By examining the ability of ssPS molecules lacking the cytoplasmic domain to rescue embryonic abnormalities associated with PS integrin loss, we find that although many embryonic events require the betaPS cytoplasmic domain, this portion of the molecule is not required for at least two processes requiring PS integrins: formation of midgut constrictions and maintaining germband integrity. Furthermore, our studies demonstrate that mutant proteins affecting four highly conserved amino acid residues in the cytoplasmic tail function with different efficiencies during embryonic development, suggesting that interaction of PS integrins with cytoplasmic ligands is developmentally modulated during embryogenesis. We have also examined the ability of alphaPS1 and alphaPS2 to function without their cytoplasmic domains. By analyzing the ability of transgenes producing truncated alphaPS molecules to rescue abnormalities associated with integrin loss, we find that the cytoplasmic tail of alphaPS2 is essential for both embryonic and postembryonic processes, while this portion of alphaPS1 is not required for function in the wing and in the retina. Furthermore, temperature-shift experiments suggest roles for the alphaPS2 cytoplasmic domain in signaling events occurring in the developing wing.

The PS integrins are required for a regulatory event during Drosophila wing morphogenesis.

The PS1 and PS2 integrins are required for morphogenesis of the adult Drosophila wing. Clonal analysis experiments have shown that both integrins are necessary to maintain adhesion between the dorsal and ventral wing epithelia. We have found that early in wing morphogenesis, the integrins are also required for a regulatory event, and this may explain why PS1 and PS2 must be expressed on opposite surfaces of the wing at the onset of pupariation. Overexpression of integrin subunits during this early phase can lead to separation of dorsal and ventral surfaces, and we present evidence here that this dominant phenotype (the Blistermaker phenotype) results from a gain of integrin function, as opposed to negative interference from free integrin subunits. A possible model for an integrin signaling requirement in the wing is discussed.

Distinct spatial and temporal functions for PS integrins during Drosophila wing morphogenesis.

At the onset of pupariation in the Drosophila wing, the PS1 and PS2 integrins are expressed preferentially on the dorsal and ventral wing epithelia, respectively. Clonal analysis experiments have indicated that integrins are required to maintain the tight association of the wing surfaces. Surprisingly, we find that even in clones of cells lacking integrins the wing layers become apposed early in metamorphosis. However, following the normal period of wing separation, large integrin mutant clones do not become re-apposed in the pupa, and integrins are not organized in basal plaques in cells opposite a mutant clone. Paradoxically, our experiments indicate that at least one integrin function requires different integrins on the dorsal and ventral wing surfaces, however in some cases both alphaPS subunits can function to some degree on each wing surface. Finally, overexpression of an alphaPS subunit throughout the wing leads to a dominant wing blister phenotype, and the critical period for this phenotype is the beginning of pupariation. These data indicate that integrin requirements in wing morphogenesis can be separated into early (prepupal) and late (pupal) functions. The late function seems to reflect the traditional view of integrins as cell-matrix adhesion proteins. The early requirement, which probably requires dorsoventral segregation of PS1 and PS2, suggests functions for PS1 and PS2 in signaling events that regulate morphogenesis.

Role of the PS integrins in Drosophila development.

The PS1 and PS2 integrins of Drosophila are heterodimers of alphaPS1betaPS and alphaPS2betaPS subunits, respectively, with very strong structural similarity to vertebrate integrins. Cell transfection experiments indicate that the PS integrins are receptors for extracellular matrix components and are functionally analogous to vertebrate integrins. Matrix ligands from Drosophila tissues have been identified for PS1 and PS2 integrins, using transformed cells and a cell-spreading assay. Mutations in all three subunit genes have been identified, and the phenotypes of mutants indicate that PS integrins are required for the proper morphogenesis of a number of embryonic tissues. Using methods to produce genetic mosaics and transformation of integrin transgenes into whole animals, integrin functions in adult morphogenesis also have been examined. In the pupal wing, integrins are critically required to maintain the connection between dorsal and ventral epithelia, and recent results suggest that in early pupal development, the integrins are acting as specific receptors, as opposed to a non-specific cell-matrix glue.

Nonequivalent requirements for PS1 and PS2 integrin at cell attachments in Drosophila: genetic analysis of the alpha PS1 integrin subunit.

We report on the generation and phenotype of mutant alleles of multiple edematous wings (mew), the gene encoding the alpha PS1 subunit of the PS1 integrin of Drosophila. None of the six alleles examined makes detectable protein, and one allele results from a chromosome break near the middle of the translated sequence, so we are confident that we have described the null phenotype. In contrast to if (alpha PS2) and mys (beta PS) mutants, most mutant mew embryos hatch, to die as larvae. Mutant mew embryos display abnormal gut morphogenesis but, unlike mys or if embryos, there is no evidence of defects in the somatic muscles. Thus, the complementary distributions of PS1 (alpha PS1 beta PS) and PS2 (alpha PS2 beta PS) integrin on tendon cells and muscle, respectively, do not reflect equivalent requirements at the myotendinous junction. Dorsal herniation, characteristic of the mys lethal phenotype, is not observed in mew or in mew if embryos. Clonal analysis experiments indicate that eye morphogenesis is disrupted in mew clones, but if clones in the eye are relatively normal in morphology. Adult wings display blisters around large dorsal but not ventral mew clones. In contrast to dorsal mys clones, small mew patches do not necessarily display morphogenetic abnormalities. Thus, another integrin in addition to PS1 appears to function on the dorsal wing surface.

Tiggrin, a novel Drosophila extracellular matrix protein that functions as a ligand for Drosophila alpha PS2 beta PS integrins.

Genetic and other studies of Drosophila integrins have implicated these extracellular matrix receptors in various morphogenetic events, but identification of their endogenous ligands has been elusive. We report the biochemical purification and cloning of tiggrin, a novel extracellular matrix protein from Drosophila. This 255 x 10(3) M(r) polypeptide contains the potential integrin recognition sequence Arg-Gly-Asp (RGD) and 16 repeats of a novel 73-77 amino acid motif. The tiggrin gene is at chromosome locus 26D1-2 and is expressed by embryonic hemocytes and fat body cells. Tiggrin protein is detected in matrices, especially at muscle attachment sites that also strongly express integrins. Tiggrin-coated surfaces support primary embryo cell culture and provide excellent substrates for alpha PS2 beta PS integrin-mediated cell spreading. Soluble RGD-peptides inhibit this cell spreading.

Functional properties of alternatively spliced forms of the Drosophila PS2 integrin alpha subunit.

The Drosophila alpha PS2 protein is encoded by two alternatively spliced transcripts. The respective alpha PS2 proteins differ by the presence of 25 amino acids in the alpha PS2(C) protein, not found in the alpha PS2(m8) subunit, in a region thought to be important for ligand binding. We examined the functional properties of Drosophila S2 cells transformed with genes expressing either of these proteins, in association with a beta PS subunit. Both PS2 integrins support cell spreading on vertebrate vitronectin or, to a lesser extent, on fibronectin. Interestingly, the PS2(C) form promotes spreading more efficiently on vitronectin than does the PS2(m8) form, with an opposite relative efficiency seen for fibronectin. Also, the two forms of PS2 show different requirements for divalent cations in order to mediate efficient cell spreading. These divalent cations are not required to maintain the association of alpha and beta subunits. Spreading of both cell types is similarly RGD sensitive, and both PS2 integrins appear to associate with the actin cytoskeleton. To our knowledge, this represents the first demonstration of functional differences in integrin subunits resulting from splicing variation to generate different extracellular, ligand binding domains.

Characterization of mutant alleles of myospheroid, the gene encoding the beta subunit of the Drosophila PS integrins.

This paper presents the characterization of nine alleles of myospheroid, which encodes the beta PS subunit of the Drosophila PS integrins. On Southern blots, the mysXB87, mysXN101 and mysXR04 genes yield restriction digest patterns similar to that seen for wild-type chromosomes, however the mys1 and mysXG43 genes contain detectable deletions. mys1, mysXB87 and mysXG43 make little or no stable protein product, and genetically behave as strong lethal alleles. For the mysXN101 mutation, protein product is seen on immunoblots and a reduced amount of beta PS protein is seen at muscle attachment sites of embryos; this mutant protein retains some wild-type function, as revealed by complementation tests with weak alleles. Protein is also seen on immunoblots from mysXR04 embryos, and this allele behaves as an antimorph, being more deleterious in some crosses than the complete deficiency for the locus. mysts2 and mysnj42 are typically lethal in various combinations with other alleles at high temperatures only, but even at high physiological temperatures, neither appears to eliminate gene function completely. The complementation behaviors of mysts1 and mysts3 are quite unusual and suggest that these mutations involve regulatory phenomena. For mysts3, the data are most easily explained by postulating transvection effects at the locus. The results for mysts1 are less straightforward, but point to the possibility of a chromosome pairing-dependent negative interaction.

Drosophila PS2 integrin mediates RGD-dependent cell-matrix interactions.

Integrins are a family of transmembrane glycoproteins that mediate cell-matrix and cell-cell interactions. We have transfected cultured Drosophila cells with genes that express the Drosophila PS2 integrin. We demonstrate that this integrin is expressed on the surface of the cells and can mediate cell spreading on an undefined component of fetal calf serum or on the purified vertebrate matrix molecules vitronectin and fibronectin. Additionally, PS2 integrin can cause cell spreading on RGD peptide. The spreading on matrix components or RGD peptide can be inhibited by soluble RGD peptide and is dependent on divalent cations.

The conditional inhibition of gene expression in cultured Drosophila cells by antisense RNA.

Genes producing antisense RNA are becoming important tools for the selective inhibition of gene expression. Experiments in different biological systems, targeting different mRNAs have yielded diverse results with respect to the success of the technique and its mechanism of action. We have examined the potential of three antisense genes, whose transcription is driven by a Drosophila metallothionein promoter, to inhibit the expression of alcohol dehydrogenase (ADH) or a microtubule associated protein (205K MAP) in cultured Drosophila cells. Expression of ADH was significantly reduced upon induction of the anti-ADH genes. The ADH mRNA does not appear to be destabilized by the presence of antisense RNA but rather exists at similar levels in hybrid form. Hybrids are detected with both spliced and unspliced ADH RNA. In contrast to these results, antisense genes producing antisense RNA in great excess to 205K MAP mRNA, which is itself far less abundant than the ADH mRNA, failed to show any inhibition of 205K MAP expression.

Characterization and use of the Drosophila metallothionein promoter in cultured Drosophila melanogaster cells.

The promoter from the metallothionein gene may be a useful conditional promoter for the construction of chimeric genes to be expressed in Drosophila cells in culture. To explore this possibility the responses of the endogenous metallothionein gene and an in vitro constructed chimeric gene containing the metallothionein promoter were examined. Copper and cadmium, when added to the growth medium of Drosophila Schneider's line 2 cells, can produce a 30-100 fold induction of metallothionein mRNA levels. The level of induction depends on the amount of copper or cadmium added to the medium and these mRNA levels remain high for at least four days. Copper is less toxic than cadmium and does not induce a typical heat-shock response in the cells. Finally, a chimeric gene containing the metallothionein promoter shows a similar induction when transformed into the cells.

Cloning of the luciferase structural genes from Vibrio harveyi and expression of bioluminescence in Escherichia coli.

The DNA encoding the luciferase alpha and beta subunits in the luminous marine bacterium Vibrio harveyi (strain 392) is contained within a 4.0-kilobase HindIII fragment. DNA from V. harveyi was digested with HindIII, and the resulting fragments were inserted into the HindIII site of plasmid pBR322. The recombinant plasmids were introduced by transformation into Escherichia coli RR1. The colonies were supplied with n-decanal, the substrate for the bioluminescence reaction, and 12 colonies (of ca. 6000 total) were observed to luminesce brightly. One of the recombinant plasmids, pTB7, has been studied in detail. The high level of expression of bioluminescence in pTB7 was the result not of native V. harveyi promoters but rather of a promoter in pBR322 which is within the tetracycline resistance gene but oriented in the direction opposite to the transcription of the tetracycline gene. Using antiluciferase antibody to probe proteins transferred from sodium dodecyl sulfate-polyacrylamide gels to nitro-cellulose paper, we have shown that the E. coli transformants produce luciferase that cross-reacts with antiluciferase antibody and is the same molecular weight as V. harveyi luciferase. No alpha subunit could be detected by using antiluciferase antibody in lysates of a subclone, pTB104, which is identical with pTB7 except for deletion of the beta-subunit gene. Thus, the alpha subunit may be unstable and be degraded unless it is associated with beta. The bioluminescence emission spectra of V. harveyi and of E. coli transformants carrying pTB7 are indistinguishable.(ABSTRACT TRUNCATED AT 250 WORDS)