Unusual Properties of Regulatory DNA from the Drosophila Engrailed Gene: Three ``pairing-Sensitive'''' Sites within a 1.6-Kb Region

We have previously shown that a 2-kb fragment of engrailed DNA can suppress expression of a linked marker gene, white, in the P element vector CaSpeR. This suppression is dependent on the presence of two copies of engrailed DNA-containing P elements (P[en]) in proximity in the Drosophila genome (either in cis or in trans). In this study, the 2-kb fragment was dissected and found to contain three fragments of DNA which could mediate white suppression [called ``pairing-sensitive sites' (PS)]. A PS site was also identified in regulatory DNA from the Drosophila escargot gene. The eye colors of six different P[en] insertions in the escargot gene suggest an interaction between P[en]-encoded and genome-encoded PS sites. I hypothesize that white gene expression from P[en] is repressed by the formation of a protein complex which is initiated at the engrailed PS sites and also requires interactions with flanking genomic DNA. Genes were sought which influence the function of PS sites. Mutations in some Polycomb and trithorax group genes were found to affect the eye color from some P[en] insertion sites. However, different mutations affected expression from different P[en] insertion sites and no one mutation was found to affect expression from all P[en] insertion sites examined. These results suggest that white expression from P[en] is not directly regulated by members of the Polycomb and trithorax group genes, but in some cases can be influenced by them. I propose that engrailed PS sites normally act to promote interactions between distantly located engrailed regulatory sites and the engrailed promoter.     

The Drosophila zeste protein binds cooperatively to sites in many gene regulatory regions: implications for transvection and gene regulation.

The Drosophila zeste protein binds in vitro to several sites in the white, Ultrabithorax, decapentaplegic, Antennapedia, and engrailed genes and to at least one site in the zeste gene itself. The distribution of these sites corresponds often with that of regulatory elements in these genes as defined by mutations or, in the case of white, by molecular analysis. A zeste binding site is frequently found in the immediate vicinity of the promoter. zeste binding sites are composed of two or more zeste recognition sequences T/CGAGT/CG. Isolated consensus sequences do not bind or footprint. Cooperative interactions are involved both in binding to a given site and between proteins bound at independent sites. zeste bound to one DNA molecule can in fact bind simultaneously to another DNA molecule. These results suggest a general role for zeste in bringing together distant regulatory elements controlling the activity of a target gene. In this model, transvection effects are a by-product of normal intragenic zeste action.     

Effects of a Locus Affecting Floral Pigmentation in Ipomoea Purpurea on Female Fitness Components

A locus influencing floral pigment intensity in the morning glory, Ipomoea purpurea, is polymorphic throughout the southeastern United States. Previous work has suggested that the white allele at this locus has a transmission advantage during mating because of the effect of flower color on pollinator behavior. The experiment described here was designed to determine whether other effects of the W locus may contribute an opposing selective advantage to the dark allele. Dark homozygotes were vegetatively smaller and produced fewer flowers, seed capsules and seeds than either light heterozygotes or white homozygotes. In addition, dark homozygotes produced smaller seeds than heterozygotes, and there is some indication that white homozygotes also produced smaller seeds than heterozygotes. Pleiotropic effects on seed number thus do not seem to contribute to selection opposing the mating advantage associated with the white allele. However, pleiotropic effects on seed size might contribute to overdominance that could stabilize the W locus polymorphism.     

Regulation of white locus expression: the structure of mutant alleles at the white locus of Drosophila melanogaster

We have analyzed the structures of 19 mutant alleles at the white locus of Drosophila melanogaster. Thirteen of the mutant alleles in our selected sample arose spontaneously, and of these, seven are associated with insertions of non-white-region DNA sequence elements. Several lines of evidence strongly suggest that these insertions are responsible for their associated mutant alleles, and further suggest that most or all of these insertions are transposons. Moreover, the white locus DNA sequences can be divided into two nonoverlapping domains on the basis of the properties of the two domains as mutational targets. One of these domains behaves, in this regard, in the manner expected of functional coding sequences, whereas the other does not. We propose a model for the nature and function of the presumptive noncoding white locus genetic elements. The two domains of the white locus defined by our studies are approximately coextensive with the functionally distinct subintervals of the locus defined by previous genetic analysis. Lastly, our results strongly suggest that the dominant, mutable wDZL allele results from the insertion of a transposon outside of, but near, the white locus. This putative transposon apparently carries genetic elements that act at a distance to repress expression of the white locus.     

Identification of Mutations in Three Genes That Interact with Zeste in the Control of White Gene Expression in Drosophila Melanogaster

Three previously described genes, enhancer of yellow, 1, 2 and 3, are shown to cooperate with the zeste gene in the control of white gene expression. The mutations e(y)1(u1), e(y)3(u1), and to a lesser extent e(y)2(u1), enhance the effect of the zeste null allele z(v77h). Different combinations of e(y)1(u1), e(y)2(u1) and e(y)3(u1) mutations with several other z alleles also enhance the white mutant phenotype, but only to levels characteristic of white alleles containing a deletion of the upstream eye enhancer. Loss of zeste protein binding sites from the white locus does not eliminate the effect of e(y)1(u1) and e(y)3(u1) mutations, suggesting that the products of these genes interact with some other nucleotide sequences. Combinations of either e(y)1(u1) or e(y)2(u1) mutations with e(y)3(u1) are lethal. The products of these three genes may represent, together with zeste, a group of proteins involved in the organization of long-distance interactions between DNA sequences.     

Characterization of a Chlamydomonas Transposon, Gulliver, Resembling Those in Higher Plants

While pursuing a chromosomal walk through the mt+ locus of linkage group VI of Chlamydomonas reinhardtii, I encountered a 12-kb sequence that was found to be present in approximately 12 copies in the nuclear genome. Comparison of various C. reinhardtii laboratory strains provided evidence that the sequence was mobile and therefore a transposon. One of two separate natural isolates interfertile with C. reinhardtii, C. smithii (CC-1373), contained the transposon, but at completely different locations in its nuclear genome than C. reinhardtii; and a second, CC-1952 (S1-C5), lacked the transposon altogether. Genetic analysis indicated that the transposon was found at dispersed sites throughout the genome, but had a conserved structure at each location. Sequence homology between the termini was limited to an imperfect 15-bp inverted repeat. An 8-bp target site duplication was created by insertion; transposon sequences were completely removed upon excision leaving behind both copies of the target site duplication, with minor base changes. The transposon contained an internal region of unique repetitive sequence responsible for restriction fragment length heterogeneity among the various copies of the transposon. In several cases it was possible to identify which of the dozen transposons in a given strain served as the donor when a transposition event occurred. The transposon often moved into a site genetically linked to the donor, and transposition appeared to be nonreplicative. Thus the mechanism of transposition and excision of the transposon, which I have named Gulliver, resembles that of certain higher plant transposons, like the Ac transposon of maize.     

Transposition of DNA fragments flanked by two inverted Tn1 sequences: translocation of the plasmid RP4::Tn1 region harboring the Tcr marker

We have demonstrated the possibility of transposition of the plasmid RP4::Tn1 fragment (21.2 kb) carrying the tetracycline resistance (Tcr) gene and flanked by two Tn1 copies. The new transposon, designated Tn1756, bears lethal genes that kill host cells. Therefore, its transposition can only be revealed in the presence of lethality-compensating helper regions of the plasmid RP4. Thus, RP4::Tn1 consists of two transposons, Tn1755 (Tn1-Kmr-Tn1) and Tn1756 (Tn1-Tcr-Tn1), sharing the Tn1 sequences. Both of these transposons are capable of recA-independent translocation to other plasmids. Therefore, transposition of DNA fragments flanked by two inverted Tn1 sequences does not depend on Tn1 orientation.     

Hsmar1 Transposition Is Sensitive to the Topology of the Transposon Donor and the Target

Hsmar1 is a member of the Tc1-mariner superfamily of DNA transposons. These elements mobilize within the genome of their host by a cut-and-paste mechanism. We have exploited the in vitro reaction provided by Hsmar1 to investigate the effect of DNA supercoiling on transposon integration. We found that the topology of both the transposon and the target affect integration. Relaxed transposons have an integration defect that can be partially restored in the presence of elevated levels of negatively supercoiled target DNA. Negatively supercoiled DNA is a better target than nicked or positively supercoiled DNA, suggesting that underwinding of the DNA helix promotes target interactions. Like other Tc1-mariner elements, Hsmar1 integrates into 5′-TA dinucleotides. The direct vicinity of the target TA provides little sequence specificity for target interactions. However, transposition within a plasmid substrate was not random and some TA dinucleotides were targeted preferentially. The distribution of intramolecular target sites was not affected by DNA topology.     

Construction of yeast strains containing genetically marked transposons

Haploid yeast cells contain approximately 35 Ty (transposon yeast) elements. To facilitate the study of these elements, we have constructed yeast strains in which one of these transposons carries a genetic marker. The elements that we have modified are Ty912 and Ty917, elements originally detected at the HIS4 locus in spontaneously occurring his4- mutants. The strain constructions took place in three stages: 1) cloning of the mutant HIS4 genes containing the Ty elements; 2) introduction of a HindIII restriction fragment containing the yeast URA3 gene into the cloned transposons; and 3) replacement of the chromosomal HIS4 gene with the modified genes constructed in vitro. These strains will be extremely useful in the study of Ty transposition and other Ty-promoted DNA rearrangements.     

Structural features of 3C6/C7 interband chromatin organization in Drosophila melanogaster polytene chromosomes

Mechanisms of chromatin decompaction in interbands of Drosophila polytene chromosomes have been studied. Using the example of interband 3C6/C7 of the X chromosome, we investigated the ability of different DNA segments to form an interband in a new genetic environment. We applied site-specific FLP recombination between two transposons with FRT-sites that allows introducing the DNA fragments from the interband 3C6/C7 into pICon(dv) transposon located in cytologically well-characterized 84F region of chromosome 3 followed by electron microscopic analysis of changes in the region caused by insertion of the DNA fragments into the transposon. It was shown that the insertion of a 276-bp DNA fragment from the 3C6/C7 region into the pICon(dv) transposon leads to the formation of a new interband between two thin bands represented by the transposon material. This DNA fragment is the known minimal sequence that is necessary and sufficient for interband generation. In addition, the sequence containing three copies repeated in tandem of 0.9 kb DNA from the interband 3C6/C7, including the 276-bp fragment, were integrated in the transposon. The presence of introduced DNA fragments did not change the morphology of the resulting interband. It was shown that the sites of DNase I hypersensitivity were saved in transposon sequences introduced into a new genetic environment. The data obtained allow analysis to be started of specific factors (proteins, DNA motifs, etc.) that determine the formation of decompacted chromatin in a certain interband region and chromomeric organization of interphase chromosomes in Drosophila as a whole.     

Global mapping of transposon location

Transposable genetic elements are ubiquitous, yet their presence or absence at any given position within a genome can vary between individual cells, tissues, or strains. Transposable elements have profound impacts on host genomes by altering gene expression, assisting in genomic rearrangements, causing insertional mutations, and serving as sources of phenotypic variation. Characterizing a genome's full complement of transposons requires whole genome sequencing, precluding simple studies of the impact of transposition on interindividual variation. Here, we describe a global mapping approach for identifying transposon locations in any genome, using a combination of transposon-specific DNA extraction and microarray-based comparative hybridization analysis. We use this approach to map the repertoire of endogenous transposons in different laboratory strains of Saccharomyces cerevisiae and demonstrate that transposons are a source of extensive genomic variation. We also apply this method to mapping bacterial transposon insertion sites in a yeast genomic library. This unique whole genome view of transposon location will facilitate our exploration of transposon dynamics, as well as defining bases for individual differences and adaptive potential.     

Identification of a hotspot for transformation of Neisseria meningitidis by shuttle mutagenesis using signature-tagged transposons

Shuttle mutagenesis using signature-tagged transposons was employed to generate a library of individually tagged mutants of the Neisseria meningitidis strain B1940, which belongs to serogroup B. The use of tagged transposons allowed us to monitor for enrichment for single mutants during the process of shuttle mutagenesis, by amplification of the tags and subsequent sequence determination. Enrichment of a single clone occurred during the transformation of the meningococci with transposon-containing plasmid DNA. Sequence determination around the site of transposon insertion revealed that the transposon had mutagenized a previously unknown locus, which was designated hrtA (high rate of transformation). hrtA-mediated transformation was independent of TnMax5 and tag sequences, and it most probably involved recombination events. The hrtA locus is restricted to meningococci and gonococci and is present in few apathogenic neisserial species. Chromosomal mapping of hrtA and six further hrt sites revealed a random distribution of highly transforming DNA fragments on the meningococcal chromosome. In conclusion, our data demonstrate that shuttle mutagenesis of naturally competent bacteria using signature-tagged transposons allows the isolation of chromosomal DNA fragments, which exhibit a high transformation efficiency, and which, therefore, are likely to be involved in horizontal gene transfer.     

Application of random amplified polymorphic DNA PCR for genomic analysis of HIV-1-infected individuals

Random amplified polymorphic DNA polymerase chain reaction (RAPD-PCR) is a DNA fingerprinting technique used to detect genomic polymorphisms. We employed sixteen different RAPD-PCR 10-mer primers to amplify DNA from the peripheral blood mononuclear cells (PBMC) of 80 HIV-1-infected individuals. These individuals were previously identified as either heterozygotes (+/Δ32) and homozygotes (+/+) for the CCR5 locus by PCR with gene specific primers. Four of the sixteen randomly selected RAPD primers produced distinguishable banding profiles between CCR5 (+/Δ32) heterozygotes and CCR5 (+/+) homozygotes. Direct sequencing of some RAPD-PCR products obtained with one of the four RAPD primers that were tested yielded clearly readable, but limited sequences, which were similar to portions of the previously published sequences for (+/+) homozygotes (98% similarity) and (+/Δ32) heterozygotes (87% similarity) of the CCR5 alleles. Thus, the RAPD-PCR technique may be useful for the identification of human molecular markers that may correlate with susceptibility to HIV-1-infection, or differences in disease progression among HIV-1-infected individuals.     

Regulatory Regions of the Homeotic Gene Proboscipedia Are Sensitive to Chromosomal Pairing

We have identified regulatory regions of the homeotic gene proboscipedia that are capable of repressing a linked white minigene in a manner that is sensitive to chromosomal pairing. Normally, the eye color of transformants containing white in a P-element vector is affected by the number of copies of the transgene; homozygous flies have darker eyes than heterozygotes. However, we found that flies homozygous for select pb DNA-containing transgenes had lighter eyes than heterozygotes. Several pb DNA fragments are capable of causing this pairing sensitive (PS) negative regulation of white. Two fragments in the upstream DNA of pb, 0.58 and 0.98 kb, are PS; additionally, two PS sites are located in the second intron, including a 0.5-kb region and 49-bp sequence. This phenotype is not observed when two PS sites are located at different chromosomal insertion sites (in trans-heterozygous transgenic animals), indicating that the pb-DNA-mediated repression of white is dependent on the pairing or proximity of the PS regions. The observed phenomenon is similar to transvection in which certain alleles of a gene can complement each other, but only when homologous chromosomes are paired. Interestingly, the intronic PS regions contain positive regulatory sequences for pb, whereas the upstream PS sites contain pb negative regulatory elements.     

NMR solution structure of the RED subdomain of the Sleeping Beauty transposase

DNA transposons can be employed for stable gene transfer in vertebrates. The Sleeping Beauty (SB) DNA transposon has been recently adapted for human application and is being evaluated in clinical trials, however its molecular mechanism is not clear. SB transposition is catalyzed by the transposase enzyme, which is a multi‐domain protein containing the catalytic and the DNA‐binding domains. The DNA‐binding domain of the SB transposase contains two structurally independent subdomains, PAI and RED. Recently, the structures of the catalytic domain and the PAI subdomain have been determined, however no structural information on the RED subdomain and its interactions with DNA has been available. Here, we used NMR spectroscopy to determine the solution structure of the RED subdomain and characterize its interactions with the transposon DNA.     

Somatic cell mutagenesis in Drosophila: recovery of genetic damage in relation to the types of DNA lesions induced in mutationally unstable and stable X-chromosomes

This paper reports the results of a study on the genotoxic activities of 12 mutagens and clastogens of widely differing mode of action in somatic cells in vivo, i.e., in the eye primordia of Drosophila larvae. After emergence, adult flies were monitored for aberrantly colored sectors in the compound eyes of the following genotypes: UZ males and females (zeste) carrying a genetically unstable transposable element, SZ males and females (zeste) carrying a partial duplication of the w+ locus plus a transposon insert, white-coral/white (wco/w) females, w+/w females and w+ males. The UZ and SZ marker sets make it possible to monitor shifts from zeste to red (scored as mosaic red spots, RS) and for loss of the white locus (light spots, LS). wco/w+ females were scored for mosaic twin spots (TS) and LS, w+ genotypes for just LS. The genotoxins analyzed were methyl methanesulfonate (MMS), dimethyl sulfate (DMS) and ethylnitrosourea (ENU) (alkylating), adriamycin (AM) and daunomycin (DM) (intercalating), Trenimon, Thio-TEPA and cisplatin (DDP) (cross-linking), bleomycin (strand-breaking), 7,12-dimethylbenz[a]anthracene (DMBA) and 9,10-dimethylanthracene (DA) (bulky monoadducts) and cytosine arabinofuranoside (inhibition of DNA synthesis). The relative mutabilities with frequencies of mosaic light spots (LS) in w+/w female as the standard (relative mutability = 1) vs. genotypes UZ (RS in male) vs. SZ (RS in male) vs. w+ (LS in male) were 1:0.6:0.2:0.3 for MMS, 1:0.09:0.05:0.7 for DDP, and 1:1.6:0.2:1.0 for ENU, ENU showed exceptional behavior in that it was the only compound for which mutational response, measured by the induction of red spots, was highest with the UZ marker set. Occurrence of large light spots (LS) in male but not in female genotypes was negatively correlated with efficiency of agents for chromosomal damage, suggesting that in the hemizygous condition, as in males, selection of damaged cells and mitotic delay may have played a significant role. In general, the results indicate that there is no association between the ability of an agent to act as a clastogen and the recovery of aberrant (red spots) sectors in either the UZ or the SZ strain, and of single light spots (LS) in w+, UZ and SZ males. The possibility is considered that the process causing the genetic instability in the UZ strain is under genetic control, and that strong point mutagens such as ENU through efficient gene mutation induction can interfere with it.