A Fragment of Engrailed Regulatory DNA Can Mediate Transvection of the White Gene in Drosophila

We have found a fragment of engrailed regulatory DNA that has an unusual effect on expression of a linked marker gene, white, in the P element transposon CaSpeR. Normally, flies homozygous for a given CaSpeR insertion have darker eyes than heterozygotes. However, when a particular engrailed DNA fragment is included in that transposon, homozygotes often have lighter eyes than heterozygotes. Thus, engrailed DNA appears to cause white expression to be repressed in homozygotes. The suppression of white is dependent on the proximity of the two transposons in the genome-either in cis (i.e., on the same chromosome) or in trans (i.e., on homologous chromosomes). Thus, the engrailed fragment is mediating a phenomenon similar to that mediated by the zeste gene at the white locus. However, the interactions we observe do not require, nor are influenced by, mutations of zeste. We suggest that the engrailed DNA contains one or more binding sites for a protein that facilitates interactions between transposons. The normal function of these sites may be to mediate interactions between distant cis-regulatory regions of engrailed, a large locus that extends over 70 kilobases.     

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 white gene as a marker in a new P-element vector for gene transfer in Drosophila.

We describe new vectors suitable for P-element mediated germ line transformation of Drosophila melanogaster using passenger genes whose expression does not result in a readily detectable phenotypic change of the transformed flies. The P-element vectors contain the white gene fused to the heat shock protein 70 (hsp70) gene promoter. Expression of the white gene rescues the white phenotype of recipient flies partly or completely even without heat treatment. Transformed descendents of most founder animals (GO) fall into two classes which are distinguishable by their orange and red eye colours. The different levels of white expression are presumably due to position effects associated with different chromosomal sites of insertion. Doubling of the gene dose in orange eyed fly stocks results in an easily visible darkening of the eye colour. Consequently, the generation of homozygous transformants is easily possible by simple inbreeding due to the phenotypic distinction of homo- and heterozygous transformants. Cloning into these P-element vectors is facilitated by the presence of polylinkers with 8 and 12 unique restriction sites.     

Independence between modification of genetic position effects and formation of lampbrush loops by the Y chromosome of Drosophila hydei

Summary The phenotype of the variegation position effect white-mottled-2 in Drosophila hydei is modified by supernumerary Y chromosomes and by fractions thereof. Different translocated Y fragments have varying degrees of effectiveness in suppressing the mutant phenotype in the mottled eyes. In fragments derived from similar regions of the Y chromosome the suppressive ability is related to their cytological lengths. In contrast, fragments derived from distinctive regions of the Y chromosome differ markedly in their effectiveness, and these differences are not necessarily correlated with the cytological length. In particular, fragments of the distal region of Y^L are more effective in enhancing the wild phenotype than are proximal fragments of similar size.The mutation white-mottled-2 is accompanied by a complex rearrangement of the X chromosome. This inhibits crossing over between large regions of the X chromosome in structural heterozygotes; it causes also a delay of development and a considerable reduction of viability in homozygous females and hemizygous males. XO males are inviable. The inviability of these males is partially covered by Y fragments. With respect to viability, the fragments show similar regional differences in effectiveness as in the modification of the mottled phenotype.There is also a parental effect on the modulation of the white-mottled-2 phenotype.There is no correlation between the activity of Y chromosomal factors on spermiogenesis and the activity of Y factors on the modification of the variegation position effect. Suppression of Y chromosomal sites which normally unfold lampbrush loops during the spermatocyte stage and whose activity has previously been shown to be indispensible for normal differentiation of the male germ line cells does not result in any visible alterations of the effectiveness on the mottling. So there is obviously independence between these two different genetic activities of Y chromosomal factors.     

Meiotic Nondisjunction and Recombination of Chromosome III and Homologous Fragments in Saccharomyces Cerevisiae

A yeast strain, in which nondisjunction of chromosome III at the first-meiotic division could be assayed, was constructed. Using chromosome fragmentation plasmids, chromosomal fragments (CFs) were derived in isogenic strains from six sites along chromosome III and one site on chromosome VII. Whereas the presence of the CFs derived from chromosome III increased considerably the meiosis I nondisjunction of that chromosome, the CF derived from chromosome VII had no effect on chromosome III segregation. The effects of the chromosome III-derived fragments were not linearly related to fragment length. Two regions, one of 12 kb in size located at the left end of the chromosome, and the other of 5 kb, located at the center of the right arm, were found to have profound effects on chromosome III nondisjunction. Most disomics arising from meioses in strains containing chromosome III CFs did not contain the CF; thus it appears that the two chromosome III homologs had segregated away from the CF. Among the disomics, recombination between the homologous chromosomes III was lower than expected from the genetic distance, while recombination between one of the chromosomes III and the fragment was frequent. We suggest that there are sites along the chromosome that are more involved than others in the pairing of homologous chromosomes and that the pairing between fragment and homologs involves recombination among these latter elements.     

Sequences required for enhancer blocking activity of scs are located within two nuclease-hypersensitive regions.

The Drosophila 87A7 heat shock locus is bordered, on the proximal and distal sides, by two special chromatin structures, scs and scs'. Each structure is characterized by two sets of nuclease-hypersensitive sites, located within moderately G/C-rich DNA, flanking an A/T-rich nuclease-resistant region. scs and scs' have been shown to insulate a white reporter gene from position effects and to prevent enhancer-promoter interactions. These and other properties suggest scs and scs' might function as chromatin domain boundaries. To identify the DNA sequences which are essential for the insulating activity of scs we used an enhancer blocking assay based on the white gene. Sequences capable of suppressing activation of white by its upstream enhancer elements reside within a 900 bp DNA fragment corresponding to the scs chromatin structure. Within this region, DNA fragments associated with the two nuclease-hypersensitive regions are essential for full enhancer blocking activity, while the central A/T-rich region is dispensable. Deletions which remove part of the hypersensitive regions result in intermediate levels of white activity. Insulating activity can, however, be reconstituted by multimerizing DNA fragments from either hypersensitive region. Our results suggest that the scs boundary is assembled from a discrete number of functionally redundant DNA sequences located within both hypersensitive regions and that boundaries act by decreasing the frequency of enhancer-promoter interactions. We also show that certain types of position effects, like those involved in dosage compensation, are not efficiently blocked by scs.     

Dissection of the locus control function located on the chicken lysozyme gene domain in transgenic mice.

The entire chicken lysozyme gene locus including all known cis-regulatory sequences and the 5' and 3' matrix attachment sites defining the borders of the DNase I sensitive chromatin domain, is expressed at a high level and independent of its chromosomal position in macrophages of transgenic mice. It was concluded that the lysozyme gene locus carries a locus control function. We analysed several cis-regulatory deletion mutants to investigate their influence on tissue specificity and level of expression. Position independent expression of the gene is lost whenever one of the upstream tissue specific enhancer regions is deleted, although tissue specific expression is usually retained. Deletion of the domain border fragments has no influence on copy number dependency of expression. However, without these regions an increased incidence of ectopic expression is observed. This suggests that the domain border fragments may help to suppress transgene expression in inappropriate tissues. We conclude, that position independent expression of the lysozyme gene is not controlled by a single specific region of the locus but is the result of the concerted action of several tissue specific upstream regulatory DNA elements with the promoter.     

Meiotic recombination in Drosophila females depends on chromosome continuity between genetically defined boundaries

In the pairing-site model, specialized regions on each chromosome function to establish meiotic homolog pairing. Analysis of these sites could provide insights into the mechanism used by Drosophila females to form a synaptonemal complex (SC) in the absence of meiotic recombination. These specialized sites were first established on the X chromosome by noting that there were barriers to crossover suppression caused by translocation heterozygotes. These sites were genetically mapped and proposed to be pairing sites. By comparing the cytological breakpoints of third chromosome translocations to their patterns of crossover suppression, we have mapped two sites on chromosome 3R. We have performed experiments to determine if these sites have a role in meiotic homolog pairing and the initiation of recombination. Translocation heterozygotes exhibit reduced gene conversion within the crossover-suppressed region, consistent with an effect on the initiation of meiotic recombination. To determine if homolog pairing is disrupted in translocation heterozygotes, we used fluorescent in situ hybridization to measure the extent of homolog pairing. In wild-type oocytes, homologs are paired along their entire lengths prior to accumulation of the SC protein C(3)G. Surprisingly, translocation heterozygotes exhibited homolog pairing similar to wild type within the crossover-suppressed regions. This result contrasted with our observations of c(3)G mutant females, which were found to be defective in pairing. We propose that each Drosophila chromosome is divided into several domains by specialized sites. These sites are not required for homolog pairing. Instead, the initiation of meiotic recombination requires continuity of the meiotic chromosome structure within each of these domains.     

Topological Constraints on Transvection between White Genes within the Transposing Element Te35b in Drosophila Melanogaster

The transposable element TE35B carries two copies of the white (w) gene at 35B1.2 on the second chromosome. These w genes are suppressed in a zeste-1 (z(1)) mutant background in a synapsis-dependent manner. Single-copy derivatives of the original TE35B stock give red eyes when heterozygous, but zeste eyes when homozygous. TE35B derivatives carrying single, double or triple copies of w were crossed to generate flies carrying from two to five ectopic w genes. Within this range, z(1)-mediated suppression is insensitive to copynumber and does not distinguish between w genes that are in cis or in trans. Suppression does not require the juxtaposition of even numbers of w genes, but is extremely sensitive to chromosomal topology. When arranged in a tight cluster, in triple-copy TE derivatives, w genes are nonsuppressible. Breakpoints falling within TE35B and separating two functional w genes act as partial suppressors of z(1). Similarly, breakpoints immediately proximal or distal to both w genes give partial suppression. This transvection-dependent downregulation of w genes may result from mis-activation of the X-chromosome dosage compensation mechanism.     

Genetic alterations by human papillomaviruses in oncogenesis.

The integration sites in the cellular genome of human papillomavirus are located in chromosomal regions always associated with oncogenes or other known tumor phenotypes. Two regions, 8q24 and 12q13, are common to several cases of cervical carcinoma and can have integrated more than one type of papillomavirus DNA. These two chromosomal regions contain several genes implicated in oncogenesis. These observations strongly imply that viral integration sites of DNA tumor viruses can be used as the access point to chromosomal regions where genes implicated in the tumor phenotype are located, a situation similar to that of non-transforming retroviruses.