Cytogenetic Analysis of Two Ecdysone-Regulated Late Puffs 62C and 62E in Drosophila melanogaster

Genetic analysis has been performed to reveal vital genes around two puffs, a late 62C puff and an early-late 62E puff. Their roles in hormonal regulatory mechanisms have been estimated. A locus represented by four lethal mutations has been found in the vicinity of the 62E puff. The mutants display disturbed puffing, which suggests the involvement of this locus in hormonal regulatory mechanisms. In the 62C puff region, 26 mutations have been found that proved to be allelic to mutations in theD-Titin gene. The giant D-Titin gene is essential for the sarcomeric organization of striated muscles. According to the results of in situ hybridization with polytene chromosomes, the D-Titin gene occupies the entire 62C puff. The phenotypic characteristics of the novel mutants suggest that this protein is polyfunctional, and its role is not restricted to processes in the muscular tissue. It may also be involved in the morphogenesis of leg imaginal disks, and it is necessary for condensation and separation of sister chromatids during mitosis. Mutations in the ecdysone-induced BR-C and E74 genes cause disturbances similar to those found in this study. In addition, mutations of these genes can affect the D-Titin gene activity, which suggests that the three genes are involved in similar morphogenetic and myogenetic processes.     

Cytogenetic analysis of the cSOD microregion in Drosophila melanogaster

This report describes the genetic organization of a euchromatic region on the third chromosome of Drosophila melanogaster extending cytologically from 68A2 to C1, an interval comprising 10 or 11 polytene chromosome bands. The gene for cytoplasmic superoxide dismutase (cSOD) maps within this interval, as does low xanthine dehydrogenase (lxd).--Recessive lethal mutations were generated within the region by ethyl methanesulfonate mutagenesis and by hybrid dysgenesis. These lethals fall into 11 functional groups, which were partially ordered by complementation with deletions having breakpoints within the region. The distribution of dysgenesis-induced mutations in the region is highly nonrandom, the majority being within a single group. The mutability of this gene is comparable to that of singed (sn), a documented "hot-spot" for P-element insertion.--One of the EMS-induced lethals, l-108, fulfills biochemical criteria expected of a hypomorphic allele of cSOD. To our knowledge this is the first such allele recovered of this gene, and it should prove very useful in an analysis of the in vivo function of cytoplasmic SOD. Indeed, it has been demonstrated that cSOD is almost certainly a vital gene.     

Modeling dark puffs using P-transposons in Drosophila melanogaster polytene chromosomes

Modeling of morphologically unusual "dark" puffs was conducted using Drosophila melanogaster strains transformed by construct P[ry; Prat:bw], in which gene brown is controlled by the promoter of the housekeeping gene Prat. In polytene chromosomes, insertions of this type were shown to form structures that are morphologically similar to small puffs. By contrast, the Broad-Complex (Br-C) locus, which normally produce a dark puff in the 2B region of the X chromosome, forms a typical light-colored puffs when transferred to the 99B region of chromosome 3R using P[hs-BRC-z1]. A comparison of transposon-induced puffs with those appearing during normal development indicates that these puff types are formed via two different mechanisms. One mechanism involves decompaction of weakly transcribed bands and is characteristic of small puffs. The other mechanism is associated with contacts between bands adjacent to the puffing zone, which leads to mixing of inactive condensed and actively transcribed decondensed material and forming of large dark puffs.     

Cytogenetic analysis of the third chromosome heterochromatin of Drosophila melanogaster

Previous cytological analysis of heterochromatic rearrangements has yielded significant insight into the location and genetic organization of genes mapping to the heterochromatin of chromosomes X, Y, and 2 of Drosophila melanogaster. These studies have greatly facilitated our understanding of the genetic organization of heterochromatic genes. In contrast, the 12 essential genes known to exist within the mitotic heterochromatin of chromosome 3 have remained only imprecisely mapped. As a further step toward establishing a complete map of the heterochomatic genetic functions in Drosophila, we have characterized several rearrangements of chromosome 3 by using banding techniques at the level of mitotic chromosome. Most of the rearrangement breakpoints were located in the dull fluorescent regions h49, h51, and h58, suggesting that these regions correspond to heterochromatic hotspots for rearrangements. We were able to construct a detailed cytogenetic map of chromosome 3 heterochromatin that includes all of the known vital genes. At least 7 genes of the left arm (from l(3)80Fd to l(3)80Fj) map to segment h49-h51, while the most distal genes (from l(3)80Fa to l(3)80Fc) lie within the h47-h49 portion. The two right arm essential genes, l(3)81Fa and l(3)81Fb, are both located within the distal h58 segment. Intriguingly, a major part of chromosome 3 heterochromatin was found to be empty, in that it did not contain either known genes or known satellite DNAs.     

Two-step regulation of ecdysone-inducible late puffs in salivary glands of Drosophila melanogaster

Our previous study showed that some ecdysone-inducible late puffs could also be induced by a mild detergent (digitonin) in Drosophila salivary glands. However, they could only be induced at the stage immediately prior to when developmentally programmed puffing occurred, suggesting that these late puff loci were under two-step regulation. Using an in vitro culture of salivary glands, we have examined whether ecdysone or the protein products of early puff genes participate in either of the two steps of late puff regulation. This study has revealed that (i) the acquisition of digitonin-responsiveness (the first step) could be induced in vitro by incubating salivary glands with ecdysone; (ii) the first step could also be induced by protein synthesis inhibition even in the absence of ecdysone; (iii) the second step required both ecdysone and protein synthesis unless treated with digitonin; and (iv) the first step, rather than the second step, determines the timing of normal puff formation in the loci. These results suggest that, during normal development, ecdysone controls both steps by activating two types of early genes; the first type, whose function can be mimicked by cycloheximide, renders the loci responsive to digitonin and the second type, whose function can be mimicked by digitonin, activates the loci to form puffs.     

Cytogenetic and molecular aspects of position-effect variegation in Drosophila melanogaster

Position-effect variegation in Drosophila melanogaster is accompanied by compaction of the corresponding chromosomal regions. The compaction can be continuous, so that bands and interbands located distal to the eu-heterochromatic junction fuse into one dense block, or discontinuous, when two or more zones of compaction are separated by morphologically and functionally normal regions. In this work it was found that in both continuous and discontinuous compaction the blocks of dense material contain the immunochemically detectable protein HP1, which has previously been characterized as specific for heterochromatin. The regions undergoing compaction do not contain HP1 when they have a normal banding pattern. Thus, it may be proposed that HP1 is one of the factors involved in compaction. If two different or two identical rearrangements are combined in the same nucleus, they variegate independently. The frequency of compaction of the two rearrangements in the same nucleus corresponds to the product of the frequencies of the compact state of the individual elements. The extent of compaction (i.e. the number of bands involved in heterochromatization) of each rearrangement does not depend on the compaction pattern of the other rearranged element.     

Protein synthesis in salivary glands of Drosophila melanogaster: relation to chromosome puffs

The salivary glands and other tissues from Drosophila melanogaster were dissected at various times throughout the prepupal period, as well as after heat shocks and ecdysterone treatments, and the proteins labelled by incubating the isolated tissues with [³⁵S]methionine were separated by electrophoresis on sodium dodecyl sulphate-polyacrylamide gel. The labelled band patterns from salivary gland, as seen on the autoradiograph of the gel, showed striking variations, in a manner remarkably similar to variations in puff patterns during the same prepupal period. In proteins from Malpighian tubes, the pattern of bands varied to a lesser extent and in brain only a few components were modified.Heat shock brought about the appearance of a number of new bands, while others were reduced in intensity. This effect was observed with all the tissues examined, salivary glands, brain and Malpighian tubes, as well as wing imaginal discs, tissue lacking polytene chromosomes. The six most heavily labelled bands induced by heat shock represent about 30%, and one component alone represents over 15%, of the total label in the sample, as seen in salivary glands, brain and Malpighian tubes. The synthesis of RNA at puff sites was investigated after heat shock by [³H]uridine labelling. By correlating the amount of [³H]uridine in some puffs with the level of [³⁵S]methionine in some bands a tentative relation is suggested in a few instances.The effect of ecdysterone treatment was also studied in the salivary glands. Changes in a number of protein bands were noticed, though they were much less pronounced than those following heat shock.     

Cytogenetic and molecular aspects of position effect variegation in Drosophila melanogaster

A chromosomal region subjected to position effect variegation was analysed for possible DNA under-replication. DNA clones from the vicinity of the euheterochromatin junction and from a distance of hundreds of kilobase pairs were used as probes. Formation of compact blocks of chromatin is regarded as a characteristic feature of position effect variegation. It was shown that in T (1;2) dor^var7 males undergoing position effect variegation clones representing the DNA nearest to the breakpoint in 2B7 hybridized normally in situ to the compact blocks, providing evidence against DNA underreplication. In females the same clones did not hybridize to the compact blocks. These variations in hybridization may be related to different degrees of compaction of chromosome regions in males and females. A correlation between the degree of underreplication and the level of cell polyteny was shown by Southern-blot hybridization of a DNA probe from the 2B region to DNA from an X/O strain carrying Dp (1;1)pn2b displaying position effect variegation and compaction in 94% of salivary gland cells. Almost complete underreplication of the DNA of this region was found in salivary gland cells (with a maximal degree of polyteny), intermediate underreplication was found in fat body cells (with an intermediate degree of polyteny), and replication was not disturbed in diploid cells of the larval cephalic complex.by W. Beermann     

Cytogenetic and molecular aspects of position effect variegation in Drosophila melanogaster

A new genetic model system for studying position effect variegation in Drosophila melanogaster was found. It allows the analysis of genetic inactivation and changes in chromosome morphology in the same cells. In T(1;2)dor ^var7 strains the 2B5 early ecdysone puff, and the ecs locus which maps in this puff are translocated into the vicinity of centromeric heterochromatin. The ecs locus plays a key role in the system of ecdysone puffs: genetic damage to this locus results in loss of sensitivity of cells to the hormone and, as a consequence, ecdysone-induced puffs do not develop. In the T(1;2)dor ^var7 chromosome the ecs and at least five adjoining loci are inactivated in a variegated fashion. In the salivary gland cells of T(1;2)dor ^var7/ ecs^lt435 0 h prepupae which do not show the ecdysone puffs, the morphology of the 2B region was analysed. In all cases where the ecs locus was inactivated, a dense block of chromatin reminiscent of a solid band was found in the 2B region instead of the four bands 2B1–2, 3–4, 5 and 6. Sometimes compaction of the chromatin reached the 2A1–2 or even 1E1–4 bands. Formation of the compact block of chromatin coincided with late replication in this region. In situ hybridization of polytene chromosomes with a DNA clone from the ecs locus showed that when the dense chromatin block was present, no DNA was accessible for hybridization in 2B5. Hybridization of DNA of another clone located in the region of the translocation breakpoint (2B7–8) was found only in polytene chromosomes of larvae grown at 25° C, and never in those grown at 18° C, independently of the morphology of the 2B5 puff. The possibility that in the case of block formation both late replication and, as a consequence, underreplication of chromosome DNA take place, is discussed.Dedicated to Professor W. Beermann on the occasion of his 65th birthday     

Cytogenetic and molecular characterization of heterochromatin gene models in Drosophila melanogaster

In the past decade, genome-sequencing projects have yielded a great amount of information on DNA sequences in several organisms. The release of the Drosophila melanogaster heterochromatin sequence by the Drosophila Heterochromatin Genome Project (DHGP) has greatly facilitated studies of mapping, molecular organization, and function of genes located in pericentromeric heterochromatin. Surprisingly, genome annotation has predicted at least 450 heterochromatic gene models, a figure 10-fold above that defined by genetic analysis. To gain further insight into the locations and functions of D. melanogaster heterochromatic genes and genome organization, we have FISH mapped 41 gene models relative to the stained bands of mitotic chromosomes and the proximal divisions of polytene chromosomes. These genes are contained in eight large scaffolds, which together account for approximately 1.4 Mb of heterochromatic DNA sequence. Moreover, developmental Northern analysis showed that the expression of 15 heterochromatic gene models tested is similar to that of the vital heterochromatic gene Nipped-A, in that it is not limited to specific stages, but is present throughout all development, despite its location in a supposedly "silent" region of the genome. This result is consistent with the idea that genes resident in heterochromatin can encode essential functions.     

Larval saliva in Drosophila melanogaster: production, composition, and relationship to chromosome puffs.

Drosophila melanogaster salivary glands produce a mucoprotein-containing saliva in the third larval instar. At the time of prepupa formation, the protein component of the saliva is more than 30% of the total gland protein. Electrophoresis of reduced and alkylated saliva proteins in acrylamide gels yields four saliva-specific fractions. Two protein fractions contain strongly linked sugar. The molecular weights of the proteins were ascertained in SDS-acrylamide gels. Molecular weights for two sugar-free fractions were found to be 12 × 10³ and 23 × 10³ and, for one fraction containing little sugar, it probably lies below 100 × 10³. The variability of saliva proteins in 67 wild types of D. melanogaster were investigated. With the help of transplantation experiments, it was shown that the salivary glands synthesize saliva autonomously. Saliva proteins could be electrophoretically demonstrated earliest in the salivary glands of 86- to 88-hr-old larvae. After saliva is discharged from the gland lumen at the beginning of prepupa formation, the glands produce another type of saliva during the entire prepupal stage and also secrete it into the gland lumen. The chromosome puffs in section 3C of the X chromosome and in section 68C in the third chromosome show a behavior that is positively correlated with larval saliva synthesis.     

Developmental analysis of two mutations affecting chemotactic behavior in Drosophila melanogaster.

InDrosophila melanogaster, gusA^Q1, a cold-sensitive mutation, affects the behavior of larvae and adults tested with quinine sulfate. The temperature-sensitive period ofgusA^Q1 occurs during embryogenesis. Another cold-sensitive mutation,gusE^N13, alters the response of adults to quinine sulfate without affecting larval behavior. The temperature-sensitive period of this mutation is during the third larval instar.     

Clonal analysis in hybrids between Drosophila melanogaster and Drosophila simulans

We have analysed the viability of cellular clones induced by mitotic recombination in Drosophila melanogaster/D. simulans hybrid females during larval growth. These clones contain a portion of either melanogaster or simulans genomes in homozygosity. Analysis has been carried out for the X and the second chromosomes, as well as for the 3L chromosome arm. Clones were not found in certain structures, and in others they appeared in a very low frequency. Only in abdominal tergites was a significant number of clones observed, although their frequency was lower than in melanogaster abdomens. The bigger the portion of the genome that is homozygous, the less viable is the recombinant melano-gaster/simulans hybrid clone. The few clones that appeared may represent cases in which mitotic recombination took place in distal chromosome intervals, so that the clones contained a small portion of either melanogaster or simulans chromosomes in homozygosity. Moreover, Lhr, a gene of D. simulans that suppresses the lethality of male and female melanogaster/simulans hybrids, does not suppress the lethality of the recombinant melanogaster/simulans clones. Thus, it appears that there is not just a single gene, but at least one per tested chromosome arm (and maybe more) that cause hybrid lethality. Therefore, the two species, D. melanogaster and D. simulans, have diverged to such a degree that the absence of part of the genome of one species cannot be substituted by the corresponding part of the genome of the other, probably due to the formation of co-adapted gene complexes in both species following their divergent evolution after speciation. The disruption of those coadapted gene complexes would cause the lethality of the recombinant hybrid clones.