Adsorbate-driven morphological changes on Cu(111) nano-pits.

Adsorbate-driven morphological changes of pitted-Cu(111) surfaces have been investigated following the adsorption and desorption of CO and H. The morphology of the pitted-Cu(111) surfaces, prepared by Ar(+) sputtering, exposed a few atomic layers deep nested hexagonal pits of diameters from 8 to 38 nm with steep step bundles. The roughness of pitted-Cu(111) surfaces can be healed by heating to 450-500 K in vacuum. Adsorption of CO on the pitted-Cu(111) surface leads to two infrared peaks at 2089-2090 and 2101-2105 cm(-1) for CO adsorbed on under-coordinated sites in addition to the peak at 2071 cm(-1) for CO adsorbed on atop sites of the close-packed Cu(111) surface. CO adsorbed on under-coordinated sites is thermally more stable than that of atop Cu(111) sites. Annealing of the CO-covered surface from 100 to 300 K leads to minor changes of the surface morphology. In contrast, annealing of a H covered surface to 300 K creates a smooth Cu(111) surface as deduced from infrared data of adsorbed CO and scanning tunnelling microscopy (STM) imaging. The observation of significant adsorbate-driven morphological changes with H is attributed to its stronger modification of the Cu(111) surface by the formation of a sub-surface hydride with a hexagonal structure, which relaxes into the healed Cu(111) surface upon hydrogen desorption. These morphological changes occur ∼150 K below the temperature required for healing of the pitted-Cu(111) surface by annealing in vacuum. In contrast, the adsorption of CO, which only interacts with the top-most Cu layer and desorbs by 200 K, does not significantly change the morphology of the pitted-Cu(111) surface.

Transforming growth factor-beta-related genes in Drosophila and vertebrate development.

The Drosophila decapentaplegic gene, the Xenopus activin genes and the genes encoding the mouse bone morphogenetic proteins are transforming growth factor-beta-related genes whose roles in development are the focus of current studies. They exhibit elaborate patterns of expression during development, and the protein products have potent effects on the differentiation of specific cell types.

Regulation of cell cycle synchronization by decapentaplegic during Drosophila eye development.

In the developing Drosophila eye, differentiation is coordinated with synchronized progression through the cell cycle. Signaling mediated by the transforming growth factor-beta-related gene decapentaplegic (dpp) was required for the synchronization of the cell cycle but not for cell fate specification. DPP may affect cell cycle synchronization by promoting cell cycle progression through the G2-M phases. This synchronization is critical for the precise assembly of the eye.

Genetic suppression of mutations in the Drosophila abl proto-oncogene homolog.

The Drosophila abelson (abl) gene encodes the homolog of the mammalian c-abl cytoplasmic tyrosine kinase and is an essential gene for the development of viable adult flies. Three second-site mutations that suppress the lethality caused by the absence of abl function have been isolated, and all three map to the gene enabled (ena). The mutations are recessive embryonic lethal mutations but act as dominant mutations to compensate for the neural defects of abl mutants. Thus, mutations in a specific gene can compensate for the absence of a tyrosine kinase.

Learning about cancer genes through invertebrate genetics.

Genetic studies in yeast, nematodes and Drosophila are revealing the signal transduction pathways that regulate differentiation and cell proliferation. Some of the critical molecules involved are homologous to proto-oncogenes and others are likely to be analogous to the products of tumor suppressor genes.

Drosophila abl and genetic redundancy in signal transduction.

Genetic studies on Drosophila Abl and, more recently, on mouse c-Abl and c-Src indicate that the functions of these non-receptor tyrosine kinases may duplicate activities of other molecules within signal transduction pathways. In Drosophila, second-site mutations have been recovered that disrupt the redundant functions so that the Abl tyrosine kinase is essential to the formation of axonal connections in the embryonic central nervous system and for attachment of embryonic muscles to the body wall. Molecular isolation and analysis of the genes identified by these second-site mutations should define the molecular basis for the genetic redundancy.

Identification of a fibroblast growth factor-binding protein in Drosophila melanogaster.

As assessed by competitive binding and protein-crosslinking experiments, Drosophila melanogaster cells possess basic fibroblast growth factor (bFGF)-specific binding proteins that are similar to FGF receptors on vertebrate cells in molecular weight and binding affinity; these D. melanogaster cells, however, have no detectable binding proteins for acidic fibroblast growth factor (aFGF). Consistent with the presence of bFGF-specific binding proteins, D. melanogaster cells degrade bFGF but not aFGF. These results indicate the conservation of heparin-binding growth factors and receptors between vertebrates and D. melanogaster.

DNA sequence, structure, and tyrosine kinase activity of the Drosophila melanogaster Abelson proto-oncogene homolog.

We report our molecular characterization of the Drosophila melanogaster Abelson gene (abl), a gene in which recessive loss-of-function mutations result in lethality at the pupal stage of development. This essential gene consists of 10 exons extending over 26 kilobase pairs of genomic DNA. The DNA sequence encodes a protein of 1,520 amino acids with strong sequence similarity to the human c-abl proto-oncogene beginning in the type lb 5' exon and extending through the region essential for tyrosine kinase activity. When the tyrosine kinase homologous region was expressed in Escherichia coli, phosphorylation of proteins on tyrosine residues was observed with an antiphosphotyrosine antibody. These results show that the abl gene is highly conserved through evolution and encodes a functional tyrosine protein kinase required for Drosophila development.

Biochemical characterization of the Drosophila dpp protein, a member of the transforming growth factor beta family of growth factors.

The decapentaplegic (dpp) gene of Drosophila melanogaster is required for pattern formation in the embryo and for viability of the epithelial cells in the imaginal disks. The dpp protein product predicted from the DNA sequence is similar to members of a family of growth factors that includes transforming growth factor beta (TGF-beta). We have produced polyclonal antibodies to a recombinant dpp protein made in bacteria and used a metallothionein promoter to express a dpp cDNA in Drosophila S2 cells. Similar to other proteins in the TGF-beta family, the dpp protein produced by the Drosophila cells was proteolytically cleaved, and both portions of the protein were secreted from the cells. The amino-terminal 47-kilodalton (kDa) peptide was found in the medium and in the proteins adhering to the plastic petri dish. The carboxy-terminal peptide, the region with sequence similarity to the active ligand portion of TGF-beta, was found extracellularly as a 30-kDa homodimer. Most of the 30-kDa homodimer was in the S2 cell protein adsorbed onto the surface of the plastic dish. The dpp protein could be released into solution by increased salt concentration and nonionic detergent. Under these conditions, the amino-terminal and carboxy-terminal portions of dpp were not associated in a stable complex.

Phosphorylation of Enabled by the Drosophila Abelson tyrosine kinase regulates the in vivo function and protein-protein interactions of Enabled.

Drosophila Enabled (Ena) is a member of a family of cytoskeleton-associated proteins including mammalian vasodilator-stimulated phosphoprotein and murine Enabled that regulate actin cytoskeleton assembly. Mutations in Drosophila ena were discovered as dominant genetic suppressors of mutations in the Abelson tyrosine kinase (Abl), suggesting that Ena and Abl function in the same pathway or process. We have identified six tyrosine residues on Ena that are phosphorylated by Abl in vitro and in vivo. Mutation of these phosphorylation sites to phenylalanine partially impaired the ability of Ena to restore viability to ena mutant animals, indicating that phosphorylation is required for optimal Ena function. Phosphorylation of Ena by Abl inhibited the binding of Ena to SH3 domains in vitro, suggesting that one effect of Ena phosphorylation may be to modulate its association with other proteins.

Mutations in Drosophila enabled and rescue by human vasodilator-stimulated phosphoprotein (VASP) indicate important functional roles for Ena/VASP homology domain 1 (EVH1) and EVH2 domains.

Drosophila Enabled (Ena) was initially identified as a dominant genetic suppressor of mutations in the Abelson tyrosine kinase and, more recently, as a member of the Ena/human vasodilator-stimulated phosphoprotein (VASP) family of proteins. We have used genetic, biochemical, and cell biological approaches to demonstrate the functional relationship between Ena and human VASP. In addition, we have defined the roles of Ena domains identified as essential for its activity in vivo. We have demonstrated that VASP rescues the embryonic lethality associated with loss of Ena function in Drosophila and have shown that Ena, like VASP, is associated with actin filaments and focal adhesions when expressed in cultured cells. To define sequences that are central to Ena function, we have characterized the molecular lesions present in two lethal ena mutant alleles that affected the Ena/VASP homology domain 1 (EVH1) and EVH2. A missense mutation that resulted in an amino acid substitution in the EVH1 domain eliminated in vitro binding of Ena to the cytoskeletal protein zyxin, a previously reported binding partner of VASP. A nonsense mutation that resulted in a C-terminally truncated Ena protein lacking the EVH2 domain failed to form multimeric complexes and exhibited reduced binding to zyxin and the Abelson Src homology 3 domain. Our analysis demonstrates that Ena and VASP are functionally homologous and defines the conserved EVH1 and EVH2 domains as central to the physiological activity of Ena.

Drosophila abelson interacting protein (dAbi) is a positive regulator of abelson tyrosine kinase activity.

Human and mouse Abelson interacting proteins (Abi) are SH3-domain containing proteins that bind to the proline-rich motifs of the Abelson protein tyrosine kinase. We report a new member of this gene family, a Drosophila Abi (dAbi) that is a substrate for Abl kinase and that co-immunoprecipitates with Abl if the Abi SH3 domain is intact. We have identified a new function for both dAbi and human Abi-2 (hAbi-2). Both proteins activate the kinase activity of Abl as assayed by phosphorylation of the Drosophila Enabled (Ena) protein. Removal of the dAbi SH3 domain eliminates dAbi's activation of Abl kinase activity. dAbi is an unstable protein in cells and is present at low steady state levels but its protein level is increased coincident with phosphorylation by Abl kinase. Expression of the antisense strand of dAbi reduces dAbi protein levels and abolishes activation of Abl kinase activity. Modulation of Abi protein levels may be an important mechanism for regulating the level of Abl kinase activity in the cell.

Dominant effects of the bcr-abl oncogene on Drosophila morphogenesis.

We targeted expression of human/fly chimeric Bcr-Abl proteins to the developing central nervous system (CNS) and eye imaginal disc of Drosophila melanogaster. Neural expression of human/fly chimeric P210 Bcr-Abl or P185 Bcr-Abl rescued abl mutant flies from pupal lethality, indicating that P210 and P185 Bcr-Abl can substitute functionally for Drosophila Abl during axonogenesis. However, increased levels of neurally expressed P210 or P185 Bcr-Abl but not Drosophila Abl produced CNS defects and lethality. Expression of P210 or P185 in the eye imaginal disc produced a dominant rough eye phenotype that was dependent on dosage of the transgene. Drosophila Enabled, previously identified as a suppressor of the abl mutant phenotype and substrate for Drosophila Abl kinase, had markedly increased phosphotyrosine levels in Bcr-Abl expressing Drosophila, indicating that it is a substrate for Bcr-Abl as well. Drosophila, therefore, is a suitable model system to identify Bcr-Abl interactions important for signal transduction and oncogenesis.

Genetic interactions between the Drosophila Abelson (Abl) tyrosine kinase and failed axon connections (fax), a novel protein in axon bundles.

Mutations in the failed axon connections (fax) gene have been identified as dominant genetic enhancers of the Abl mutant phenotype. These mutations in fax all result in defective or absent protein product. In a genetic background with wild-type Abl function, the fax loss-of-function alleles are homozygous viable, demonstrating that fax is not an essential gene unless the animal is also mutant for Abl. The fax gene encodes a novel 47-kD protein expressed in a developmental pattern similar to that of Abl in the embryonic mesoderm and axons of the central nervous system. The conditional, extragenic noncomplementation between fax and another Abl modifier gene, disabled, reveal that the two proteins are likely to function together in a process downstream or parallel to the Abl protein tyrosine kinase.

Cytogenetic analysis of chromosome region 73AD of Drosophila melanogaster.

The 73AD salivary chromosome region of Drosophila melanogaster was subjected to mutational analysis in order to (1) generate a collection of chromosome breakpoints that would allow a correlation between the genetic, cytological and molecular maps of the region and (2) define the number and gross organization of complementation groups within this interval. Eighteen complementation groups were defined and mapped to the 73A2-73B7 region, which is comprised of 17 polytene bands. These complementation groups include the previously known scarlet (st), transformer (tra) and Dominant temperature-sensitive lethal-5 (DTS-5) genes, as well as 13 new recessive lethal complementation groups and one male and female sterile locus. One of the newly identified lethal complementation groups corresponds to the molecularly identified abl locus, and another gene is defined by mutant alleles that exhibit an interaction with the abl mutants. We also recovered several mutations in the 73C1-D1.2 interval, representing two lethal complementation groups, one new visible mutant, plucked (plk), and a previously known visible, dark body (db). There is no evidence of a complex of sex determination genes in the region near tra.

Solubilization and reconstitution of dopamine-sensitive adenylate cyclase from bovine caudate nucleus.

Dopamine-sensitive adenylate cyclase was reconstituted from the cholate-soluble components of caudate nucleus homogenate. Biological function was restored by precipitating the components from cholate and phospholipid with ammonium sulfate, dialyzing the resuspended precipitate, and activating the particulate complex with phospholipid in the assay. The reconstituted adenylate cyclase was stimulated 3- to 4-fold by dopamine and 8- to 12-fold by guanyl-5'-yl imidodiphosphate. The catecholamine stimulation was specific for dopamine and required the addition of GTP. The cholate-soluble component(s) of the basal adenylate cyclase were separated from the component(s) that conferred dopamine sensitivity by gel filtration chromatography. Dopamine-sensitive adenylate cyclase was also reconstituted from digitonin-soluble components. These were resolved into two fractions by DEAE-cellulose chromatography: one fraction contained adenylate cyclase, but both fractions were required for reconstitution of dopamine-sensitive adenylate cyclase.

TGF-beta family factors in Drosophila morphogenesis.

Many Drosophila genes have now been identified with substantial sequence similarity to vertebrate protooncogenes and growth factors. Some of these have been isolated directly by cross-hybridization with vertebrate probes and some have been recognized in the sequences of genes cloned because of their intiguing mutant phenotypes. An example of a gene isolated for its interesting development functions but with homology to a vertebrate growth factor is the Drosophila decapentaplegic gene (dpp). An example of a Drosophila gene isolated by virtue of its sequence conservation is the vgr/60A gene. Both dpp and vgr/60A are members of the transforming growth factor-beta family and are most similar to the human bone morphogenetic proteins. The regulation of the dpp gene by several different groups of pattern formation genes including the dorsal/ventral group, the terminal group, the segment polarity genes, and the homeotic genes indicates that many events in embryogenesis require the cell to cell communication mediated by the secreted dpp protein. The temporal and spatial pattern of vgr/60A expression differs from that of dpp indicating that it may be regulated by different pattern information genes. The experimental advantages of the Drosophila system should permit a better understanding of the importance of growth factor homologs in specific developmental events, aid in establishing the functional interactions between these regulatory molecules, and identify new genes that are important for the biological functions of growth factors. It is likely that some of the newly identified genes will have vertebrate homologs and the analysis of these may be helpful in studies on vertebrate development and tumor biology.

Homologs of vertebrate growth factors in Drosophila melanogaster and other invertebrates.

The molecular characterization of a number of loci that control developmental processes in invertebrates has revealed that a subset of these genes encode products that are homologous to vertebrate growth factors. Genetic analyses of the autonomy of action and molecular analysis of the patterns of expression of these genes have demonstrated that products of some of these loci (e.g., the EGF homologs, Notch, Delta, lin-12, and glp-1) appear to act in a cell-autonomous manner, while the products of other such loci (e.g., the TGF-beta homolog decapentaplegic and the murine int-1 homolog wingless) act in a nonautonomous manner. Studies of a number of invertebrate EGF homologs, including Notch, Delta, lin-12, and glp-1, for which we are beginning to achieve some reasonable understanding, reveal three common themes. First, each of these loci had been implicated in the determination of cell fates. The products of these loci appear to act at the level of single cells (i.e., they are required for the local choice between alternative determined states). The action of each of these loci within the context of determinative processes is clearly pleiotropic; mutations in each of these genes are correlated with multiple developmental defects. Second, the preponderance of evidence indicates that products of each of these loci function in a cell-autonomous manner during development. This shared character implies that these loci do not encode precursors of EGF-like molecules that act, in turn, as diffusible effectors in determinative decisions. It appears, rather, that these molecules function in association with the membranes of the cells in which they are produced and may constitute components of a class of receptors required for sensing diverse cues that specify particular cell fates during development. Third, we propose that EGF-like sequences found within each of these products function as protein-protein contact motifs that are essential for intermolecular interactions that involve membrane-bound molecules and are central to determinative decisions during development. Assignment of such a function to these sequences is consistent with recent findings indicating that EGF-homologous sequences found in urokinase (Apella et al., 1987) and blood coagulation factor IX (Rees et al., 1988) constitute sites that are required for binding to appropriate interacting proteins and are distinct from the respective "active" sites of each molecule. Within the context of this proposal, products of the EGF-homologous invertebrate genes noted above would participate in the transfer of information required for the specification of cell fate from the extracellular compartment to the cell interior.(ABSTRACT TRUNCATED AT 400 WORDS)

Increased levels of the Drosophila Abelson tyrosine kinase in nerves and muscles: subcellular localization and mutant phenotypes imply a role in cell-cell interactions.

Mutations in the Drosophila Abelson tyrosine kinase have pleiotropic effects late in development that lead to pupal lethality or adults with a reduced life span, reduced fecundity and rough eyes. We have examined the expression of the abl protein throughout embryonic and pupal development and analyzed mutant phenotypes in some of the tissues expressing abl. abl protein, present in all cells of the early embryo as the product of maternally contributed mRNA, transiently localizes to the region below the plasma membrane cleavage furrows as cellularization initiates. The function of this expression is not yet known. Zygotic expression of abl is first detected in the post-mitotic cells of the developing muscles and nervous system midway through embryogenesis. In later larval and pupal stages, abl protein levels are also highest in differentiating muscle and neural tissue including the photoreceptor cells of the eye. abl protein is localized subcellularly to the axons of the central nervous system, the embryonic somatic muscle attachment sites and the apical cell junctions of the imaginal disk epithelium. Evidence for abl function was obtained by analysis of mutant phenotypes in the embryonic somatic muscles and the eye imaginal disk. The expression patterns and mutant phenotypes indicate a role for abl in establishing and maintaining cell-cell interactions.