Drosophila immune deficiency (IMD) is a death domain protein that activates antibacterial defense and can promote apoptosis.

We report the molecular characterization of the immune deficiency (imd) gene, which controls antibacterial defense in Drosophila. imd encodes a protein with a death domain similar to that of mammalian RIP (receptor interacting protein), a protein that plays a role in both NF-kappaB activation and apoptosis. We show that imd functions upstream of the DmIKK signalosome and the caspase DREDD in the control of antibacterial peptide genes. Strikingly, overexpression of imd leads to constitutive transcription of these genes and to apoptosis, and both effects are blocked by coexpression of the caspase inhibitor P35. We also show that imd is involved in the apoptotic response to UV irradiation. These data raise the possibility that antibacterial response and apoptosis share common control elements in Drosophila.

Mutational and structural analysis of the lectin activity in binding domain 2 of ricin B chain.

The study of the lectin binding sites of ricin B chain and of other homologous members of the small gene family that make up ricin-like molecules has revealed a number of key contact residues involved in sugar binding. In particular, on the basis of data generated by the X-ray crystallographic structure of ricin, comparisons of sequence homologies to other ricin-like molecules and substrate binding studies with these molecules, it has been proposed that His248 of Ricinus communis agglutinin (RCA) B chain may interfere with galactose binding in the second binding domain of that lectin. To test that hypothesis, single binding domain 2 (SBD2) of ricin B chain was expressed as a gene 3 fusion protein on the surface of fd phage to measure directly the effect of mutational changes on this binding site. Replacement of tyrosine with histidine at amino acid position 248 of SBD2 of ricin B chain was shown to reduce lectin activity. The sequences of RCA and ricin B chains were aligned and compared with the tertiary structure of ricin B chain to select various mutations that were introduced as controls in the study. One of these controls, Leu247 to Val247, displayed increased affinity for galactosides. The role of sequence changes is discussed in relation to the structural and functional divergence in these molecules.

Positive and negative DNA elements of the Drosophila grimshawi s18 chorion gene assayed in Drosophila melanogaster.

Germ line transformation has been used to map the cis regulatory DNA elements responsible for the precise and evolutionarily stable developmental expression of the s18 chorion gene. Constructs containing chimeric combinations of Drosophila melanogaster and D. grimshawi DNA regions, as well as D. grimshawi sequences alone, can direct expression in the follicular epithelium, in an s18-specific temporal and spatial pattern. The results indicate that both positive and negative regulatory elements can function when transferred from D. grimshawi to D. melanogaster. The first ca. 100 bp of the 5'-flanking DNA region constitute a minimal, developmentally regulated promoter, expression of which is inhibited by the next 100-bp DNA segment and activated by positive elements located further upstream. Expression of the minimal promoter can also be enhanced by more distant chorion regulatory elements, provided the inhibitory DNA segment is absent.

Phage display of ricin B chain and its single binding domains: system for screening galactose-binding mutants.

We demonstrate that the B chain of ricin toxin preserves its lectin activity when expressed as a fusion protein on the surface of fd phage. Moreover, B chain, which folds into two topologically similar globular domains, can be dissected into amino-terminal and carboxyl-terminal domains to form single binding domains (SBDs) of B chain, each of which displays specificity for complex galactosides. The specific binding exhibited by the fusion protein of these SBDs was eliminated when amino acid substitutions Gly-46 in SBD1 or Gly-255 in SBD2 for native asparagine were introduced to alter key residues implicated in hydrogen bonding with substrate. These data demonstrate that it is possible to use a prokaryotic expression system to stably express and screen ricin B chain and its SBDs for sugar-binding mutants. Expression of ricin B chain on the surface of fd phage provides a method that can be used to efficiently select mutants with altered binding activities from a randomly generated library.

Evolution of the autosomal chorion cluster in Drosophila. III. Comparison of the s18 gene in evolutionarily distant species and heterospecific control of chorion gene amplification.

We present a total of 6.1 x 10(3) base-pairs of DNA sequences, encompassing the s18 gene and flanking regions within the autosomal chorion cluster of three Drosophila species. Against a background of extensive divergence in the intron and even in parts of the coding region, islands of strong sequence conservation are evident. These are particularly notable in the 5' flanking DNA where they extend to approximately -600 base-pairs from the transcription start site. The most conserved segment of the entire chorion cluster is 71 base-pairs in the s18 5' flanking DNA, which in D. melanogaster is part of a region defined functionally as containing amplification control elements (ACE3 region). Transformation analysis, using chimeric transposons of D. melanogaster and D. grimshawi DNA, revealed that amplification control elements of D. grimshawi can support amplification in D. melanogaster. The functionally defined ACE3 region of D. grimshawi includes the conserved 71 base-pair segment, but also non-conserved sequences further upstream, which apparently enhance amplification.

The chorion genes of the medfly, Ceratitis capitata, I: Structural and regulatory conservation of the s36 gene relative to two Drosophila species.

We have used low stringency screening with the Drosophila melanogaster s36 chorion gene to recover its homologue from genomic and cDNA libraries of the medfly, Ceratitis capitata. The same gene has also been recovered from a genomic library of D. virilis. The medfly s36 gene shows similar developmental specificity as in Drosophila (early choriogenesis). It is also specifically amplified in ovarian follicles; this is the first report of chorion gene amplification outside the genus Drosophila. Alignments of s36 sequences from three species show that, in addition to its regulatory conservation, the s36 gene is extensively conserved in sequence, in a region corresponding to a central protein domain, and in short regions of 5' flanking DNA that might correspond to cis-regulatory elements.

Amplification-control element ACE-3 is important but not essential for autosomal chorion gene amplification.

We have further characterized the cis-acting elements that control the amplification of the third chromosomal cluster of chorion genes in Drosophila melanogaster; these include the amplification-control element ACE-3 and four amplification-enhancing regions (AER-a to -d). We have used two types of deletions in the chorion cluster: the first was in vitro generated deletions of the ACE-3 region that were subsequently introduced into the germ line, and the second was deletions induced in vivo within a transposon at a preexisting chromosomal location, thus avoiding the complication of position effects. Some of the lines bearing deletions of either type showed amplification, albeit at drastically reduced levels. These unexpected results indicate that, despite its importance, ACE-3 is not essential for low-level amplification and that cis-acting amplification elements are functionally redundant within the autosomal chorion replicon.

Evolution of the autosomal chorion cluster in Drosophila. II. Chorion gene expression and sequence comparisons of the s16 and s19 genes in evolutionarily distant species.

We present a total of 13 kb of DNA sequences, encompassing autosomal chorion genes and their flanking DNA in four species of the genus Drosophila. Against a background of extensive divergence in introns and even in parts of the coding regions, islands of strong conservation are evident in the proximal 5' flanking and 5' untranslated sequences. An extragenic region of strong conservation is seen downstream of the last chorion gene in the autosomal cluster. The conserved DNA elements may be related to the conserved regulatory features of this cluster, including gene amplification and tissue- and temporally regulated transcription.

Evolution of the autosomal chorion locus in Drosophila. I. General organization of the locus and sequence comparisons of genes s15 and s19 in evolutionary distant species.

We have isolated clones corresponding to the autosomal chorion locus of Drosophila melanogaster, from two distantly (D. virilis and D. grimshawi) and one closely (D. subobscura) related species. In all the species the locus is unique within the genome and encompasses the same four chorion genes and an adjacent nonchorion gene, in the same order. In all species the locus specifically amplifies in the ovary, as in D. melanogaster. We present the nucleotide sequences of DNA segments that total 8.3 kb in length and include gene s15-1 from D. subobscura, D. virilis, and D. grimshawi as well as gene s19-1 from D. subobscura and D. grimshawi. They show clearly nonuniform rates of divergence, both within and outside the limits of the genes. Highlighted by a background of extensive sequence divergence elsewhere in the extragenic region, highly conserved elements are observed in the 5' flanking DNA and might represent regulatory elements.

A second domain of simian virus 40 T antigen in which mutations can alter the cellular localization of the antigen.

Previous studies have demonstrated that mutations at amino acid position 128 of the simian virus 40 large T antigen can alter the subcellular localization of the antigen. A second domain in which mutations can alter localization of the nuclear antigen has been identified by mutations at amino acid positions 185, 186, and 199. Mutations in this region cause the polypeptide to accumulate in both the nucleus and cytoplasm of monkey cells. These T-antigen variants accumulate to near normal levels, but they don't bind to the simian virus 40 origin of DNA replication and are unable to mediate DNA replication. Furthermore, the altered tumor antigens can no longer transform secondary rat cells at normal efficiency, but they retain the ability to transform established mouse and rat cell lines.

Selection of sequence elements that substitute for the standard AATAAA motif which signals 3' processing and polyadenylation of late simian virus 40 mRNAs.

A method is described which allows selection of sequences which can substitute for the normal AATAAA hexanucleotide involved in polyadenylation of SV40 late mRNAs. Plaques were generated from viral DNA lacking the motif, forcing acquisition of substitute sequences. Four variants were characterized. All displayed wild-type growth kinetics and produced normal levels of late mRNAs and proteins. Two variants had reacquired AATAAA elements and one acquired an ATTAAA sequence. The last variant carried an ATTTTTTAAA segment, suggesting this novel sequence, or some portion of it, can also signal poly A addition.

A viable simian virus 40 variant that carries a newly generated sequence reiteration in place of the normal duplicated enhancer element.

A segment comprising the transcriptional enhancer elements was deleted from a recombinant plasmid carrying the simian virus 40 genome. The mutated viral chromosome was excised from the plasmid and propagated through several cycles of growth in monkey kidney cells. A variant was obtained that carried reiterations of sequences that span both sides of the deleted enhancer region. The mutant virus, dup1495, displays a lag in its growth kinetics as compared to its parent, but it ultimately generates wild-type yields. The mutant virus expresses early mRNAs at near-normal levels, and the reiterated sequence functioned in cis to enhance transformation of mouse cells by the herpesvirus thymidine kinase gene. Thus dup1495 reiterated segments encode enhancer activity even though their primary sequence is radically different from that of the normal simian virus 40 enhancer.

Homologous nucleotide sequences at the 5' termini of messenger RNAs synthesized from the yeast enolase and glyceraldehyde-3-phosphate dehydrogenase gene families. The primary structure of a third yeast glyceraldehyde-3-phosphate dehydrogenase gene.

Genomic DNA containing a third yeast glyceraldehyde-3-phosphate dehydrogenase structural gene has been isolated on a bacterial plasmid designated pgap11. The complete nucleotide sequence of this structural gene was determined. The gene contains no intervening sequences, codon usage is highly biased, and the nucleotide sequence of the coding portion of this gene is 90% homologous to the other two glyceraldehyde-3-phosphate dehydrogenase genes (Holland, J. P., and Holland, M. J. (1980) J. Biol. Chem. 255, 2596-2605). Based on the extent of nucleotide sequence divergence among the three glyceraldehyde-3-phosphate dehydrogenase genes, it is likely that they arose as a consequence of two duplication events and the gene contained on the hybrid plasmid designated pgap11 is a product of the first duplication event. All three structural genes share extensive nucleotide sequence homology in the 5'-noncoding regions adjacent to the three respective translational initiation codons. The gene contained on pgap11 is not homologous to the others downstream from the respective translational termination codon, however. The 5' termini of messenger RNAs synthesized from the three glyceraldehyde-3-phosphate dehydrogenase and two yeast enolase genes have been mapped to sites ranging from 36 to 82 nucleotides upstream from the respective translational initiation codons. In each case the 5' terminus of the mRNA maps to a region of strong nucleotide sequence homology which is shared by all five structural genes. These latter data confirm that all five structural genes are expressed during vegetative cell growth and further support the hypothesis that a portion of the 5'-noncoding flanking region of the yeast glyceraldehyde-3-phosphate dehydrogenase and enolase genes evolved from a common precursor sequence.