John Locke

Gene transposition as a cause of hybrid sterility in Drosophila.

We describe reproductive isolation caused by a gene transposition. In certain Drosophila melanogaster–D. simulans hybrids, hybrid male sterility is caused by the lack of a single-copy gene essential for male fertility, JYAlpha. This gene is located on the fourth chromosome of D. melanogaster but on the third chromosome of D. simulans. Genomic and molecular analyses show that JYAlpha transposed to the third chromosome during the evolutionary history of the D. simulans lineage. Because of this transposition, a fraction of hybrids completely lack JYAlpha and are sterile, representing reproductive isolation without sequence evolution.

Drosophila Activin-β and the Activin-like product Dawdle function redundantly to regulate proliferation in the larval brain

The Drosophila Activin-like ligands Activin-β and Dawdle control several aspects of neuronal morphogenesis, including mushroom body remodeling, dorsal neuron morphogenesis and motoneuron axon guidance. Here we show that the same two ligands act redundantly through the Activin receptor Babo and its transcriptional mediator Smad2 (Smox), to regulate neuroblast numbers and proliferation rates in the developing larval brain. Blocking this pathway results in the development of larvae with small brains and aberrant photoreceptor axon targeting, and restoring babo function in neuroblasts rescued these mutant phenotypes. These results suggest that the Activin signaling pathway is required for producing the proper number of neurons to enable normal connection of incoming photoreceptor axons to their targets. Furthermore, as the Activin pathway plays a key role in regulating propagation of mouse and human embryonic stem cells, our observation that it also regulates neuroblast numbers and proliferation in Drosophila suggests that involvement of Activins in controlling stem cell propagation may be a common regulatory feature of this family of TGF-β-type ligands.

The characterization of DINE-1, a short, interspersed repetitive element present on chromosome and in the centric heterochromatin of Drosophila melanogaster.

Abstract.The banded portion of chromosome 4 (the ”dot” chromosome) in Drosophila melanogaster displays some properties of β-heterochromatin, which is normally found within the centric domain of the chromosomes. The nature and distribution of repetitive elements on chromosome 4 could play a role in the establishment of this unusual chromatin configuration. We describe here one such element: a short, interspersed repetitive sequence named DINE-1. Determination of a consensus sequence for the element reveals that there are two conserved regions (A and B) separated by a highly variable spacer. The conserved sequences are ∼400 bp long but degenerate at both ends, opening the possibility that a yet-to-be-discovered mother element may be present in the genome. DINE-1 bears few of the properties of the mammalian short interspersed elements (SINEs) to which it bears a superficial resemblance in size. It does not appear to be the product of reverse transcription and lacks any polymerase III promoter consensus. The elements are not flanked by target site duplications and their termini lack direct or inverted repeats, suggesting that they themselves are not transposable. Our analysis of cosmid clones from chromosome 4, and elsewhere in the genome, revealed that the euchromatic locations of DINE-1 are almost exclusively confined to chromosome 4. In situ hybridization of a DINE-1 probe to polytene chromosomes confirmed the preferential distribution along 4, in addition to its presence in the centric heterochromatin. This unusual genomic distribution of bias toward chromosome 4 is also seen in the sibling species, D. simulans, whose dot chromosomes exhibit poorly resolved polytene bands and lack crossing over during meiosis like those of D. melanogaster. However, the dot chromosome of D. virilis, which exhibits a well-defined banded structure on polytene chromosomes and can cross over, has only a single, discrete site of DINE-1 element hybridization. The presence of DINE-1 within these regions suggests a role in the heterochromatic nature of chromosome 4 in D. melanogaster and supports the contention that repeats accumulate in regions of diminished crossing over.

Analysis ofDrosophila chromosome4 using pulsed field gel electrophoresis

Previous estimates of the size ofDrosophila melanogaster chromosome4 have indicated that it is 1% to 4% of the genome or ∼6 Mb. We have used pulsed field gel electrophoresis (PFGE) to separate megabase-sized molecules ofD. melanogaster chromosomal DNA. Southern blots of these gels were probed with DNA fragments from thecubitus interruptus andzfh-2 genes, which are located on chromosome4. They each identify the same-sized distinct band that migrates at approximately 5.2 Mb in DNA preparations from the Kc cell line. We interpret this band to be intact chromosome4. In DNA obtained from embryos of variousD. melanogaster wild-type strains, this chromosome band showed strain-specific size variation that ranged from 4.5 to 5.2 Mb. TheD. melanogaster chromosome4 probes also identified a single, 2.4 Mb band in embryonic DNA fromDrosophila simulans. We conclude thatD. simulans chromosome4 is substantially smaller than that ofD. melanogaster, presumably owing to diffirences in the amount of heterochromatic DNA sequences. Our simple DNA preparation from embryos and PFGE conditions should permit preparative isolation of chromosome4 DNA and will facilitate the molecular mapping of this chromosome.

Characterization of the adenosine deaminase-related growth factor (ADGF) gene family in Drosophila

A novel family of growth factors, with sequence similarity to adenosine deaminase, has been identified in various organisms including flesh fly, tsetse fly, sand fly, mollusk and human. The human homologue, CECR1, is a candidate gene for the genetic disorder cat eye syndrome. Here, we describe six members of this growth factor family in Drosophila and two in vertebrates. The six Drosophila genes, named adenosine deaminase-related growth factors (ADGF), are found at three different chromosomal locations, with one singleton, two in an inverted orientation, and three in a tandem arrangement. These genes show distinct patterns of expression as measured by RT-PCR and Northern blots, indicating gene-specific function. The presence of six ADGF genes in the Drosophila genome suggests that gene duplication and divergence has been important for these growth factors in insect development. Phylogenetic analysis of the 14 extant ADGF-like gene products shows there are at least three major groups, two of which are found in Drosophila. The third appears specific to the vertebrate line. Seven gene duplications are inferred among the ADGF-like genes, most of which occurred long before the origin of Drosophila. Our analysis predicts the existence of several other unsampled ADGF-like genes, both within the species examined here, and in other related invertebrates.

Molecular analysis of cubitus interruptus (ci) mutations suggests an explanation for the unusual ci position effects

The cubitus interruptus (ci) locus of Drosophila melanogaster is located proximally on chromosome 4. In ci mutants cubital wing veins are interrupted or absent. We have cloned this locus using a gypsy element associated with the ci1 mutation. Analysis of all extant ci mutations reveals that they contain conspicuous molecular alterations within a 13.7 kb region. Of the four homozygous viable mutations, three (ci1, ci36l, ciW) have single insertions, while one (ci57g) has a small deletion, all located within a more restricted 1 kb region. The dominant mutations, ciD and Ce2 each contain two insertions within the 13.7 kb region. All these molecular alterations are located upstream of a transcript previously associated with the ciD mutation and thought to derive from a segment polarity gene. We induced revertants of the dominant ci phenotype (wing vein interruption) in ciD and found molecular alterations in this transcript (the ci+ transcript) in two revertant alleles, thereby demonstrating this transcripts involvement in the ci phenotype. The locations of the molecular alterations, together with the results of the ciD reversion experiment, provide a connection between the dominant and recessive ci mutations and argue that all are likely to be alleles of the same complex locus, ci, not two separate loci as previously proposed. The ci phenotype of dominant and recessive mutations can be explained by inappropriate expression of the ci+ transcript in the posterior wing compartment where the cubital vein is affected, while loss of ci+ function generates recessive lethality. Lack of repression of ci+ transcription, through a pairing-dependent, trans-acting silencer element, can explain the unusual position effects associated with ci (the Dubinin effect).

Genomic organization of the rat alpha 2u-globulin gene cluster.

Abstract. The α2u-globulins are a group of similar proteins, belonging to the lipocalin superfamily of proteins, that are synthesized in a subset of secretory tissues in rats. The many α2u-globulin isoforms are encoded by a multigene family that exhibits extensive homology. Despite a high degree of sequence identity, individual family members show diverse expression patterns involving complex hormonal, tissue-specific, and developmental regulation. Analysis suggests that there are approximately 20 α2u-globulin genes in the rat genome. We have used fluorescence in situ hybridization (FISH) to show that the α2u-globulin genes are clustered at a single site on rat Chromosome (Chr) 5 (5q22-24). Southern blots of rat genomic DNA separated by pulsed field gel electrophoresis indicated that the α2u-globulin genes are contained on two NruI fragments with a total size of 880 kbp. Analysis of three P1 clones containing α2u-globulin genes indicated that the α2u-globulin genes are tandemly arranged in a head-to-tail fashion. The organization of the α2u-globulin genes in the rat as a tandem array of single genes differs from the homologous major urinary protein genes in the mouse, which are organized as tandem arrays of divergently oriented gene pairs. The structure of these gene clusters may have consequences for the proposed function, as a pheromone transporter, for the protein products encoded by these genes.

Three subsets of genes whose tissue specific expression is sex and age‐dependent can be identified within the rat α2u‐globulin family

The rat alpha 2u-globulins are encoded by a multigene family whose 20-25 members are subjected to multihormonal regulation that is dependent upon the sex of the animal, the developmental stage and the tissue being examined. Using RT-PCR and diagnostic restriction analysis of the products, we have examined the specificity of the expression of different members of the gene family. All family members can be classified into three subsets, depending on how the amplified cDNA responds to digestion with ApaLI, SstI and VspI. Subset A contains the restriction sites for both ApaLI and SstI but not VspI and typifies the genes expressed in the salivary glands of both mature and juvenile animals of both sexes, where it is the only subset expressed. This subset of genes also accounts for all the transcripts observed in the kidneys and mammary glands of juvenile males. Although subset A was represented in the transcript populations of all the other tissues examined, its proportion relative to the total varied greatly. The two other subsets were subset V, which contains only the restriction site for VspI, and subset N, which lacks all three restriction sites. In all the other tissues examined, two or all three of the subsets were expressed, usually in a manner that was unique to the sex and age of the tissue in question. The proportion of each of the three alpha 2u-globulin subsets in the alpha 2u-globulin gene family was determined by quantitation of the restriction products of amplified genomic DNA. Interestingly, the most prevalent subset in the genome (N) has the most limited tissue expression pattern, but is found in liver and preputial glands, the tissues expressing the most substantial quantities of alpha 2u-globulin. These results indicate the complexity of the regulation of the alpha 2u-globulins and point to the necessity for gene specific analyses if the expression of the family is to be understood in molecular terms.

High-resolution FISH mapping of the rat α2u-globulin multigene family

Abstract. The rat α2u-globulins are a group of similar proteins that are encoded by a family of approximately 20 genes located a single locus of ≤880 kbp on Chromosome (Chr) 5q. Individual members of this gene family demonstrate complex tissue, hormonal, and developmental expression patterns despite a high degree of sequence similarity among the members and consequently provide an interesting system for studying the evolution of differential gene expression. Hybridization analysis indicated that gene classes, similar to those identified at the homologous MUP locus in the mouse, do not exist within the rat α2u-globulin locus. Furthermore, cross-hybridization analysis revealed the presence of conserved sequences in the 5′ and 3′ regions flanking the α2u-globulin genes, some of which were present in an inverted orientation. We have used high-resolution fiber FISH to examine the structural organization of the α2u-globulin locus, and found the genes to be arranged as an array of both direct and inverted repeats. The organization of the rat α2u-globulin genes differs from the MUP genes and suggests different evolutionary events have reorganized these homologous sets of genes.

Examination of DNA sequences undergoing chromatin conformation changes at a variegating breakpoint in Drosophila melanogaster.

Position effect variegation in Drosophila melanogaster is associated with the inability of certain genes to be correctly expressed in a proportion of cells, giving a mosaic phenotype. The lack of expression is thought to be due to alterations in the genes chromatin structure due to its proximity to a region of heterochromatin. Because of the difficulties involved, there is little biochemical data to support the intuitively appealing model of ‘heterochromatin spreading’ used to explain this phenomenon.Differences in restriction fragment length were used to distinguish DNA regions from either normal (non-position affected) or rearranged (position affected) chromosomes so as to examine possible changes in gene copy number and the effects of endogenous nucleases. DNA sequences at the breakpoint of In (1)wm4, which variegates for the white gene, were assayed under conditions where the chromatin conformation was altered using second site modifier mutations (Su(var) or En(var)). No change in the DNA sequerice copy number was observed at either chromosome breakpoint, relative to wild type, when either suppressor or enhancer mutations were present. Therefore copy number change, through differential polyploidization or somatic gene loss, is not affected by Su(var) or En(var) induced changes in the chromatin conformation.Initial experiments showed a gross difference in the sensitivity of DNA to endogenous nucleases that appeared associated with Su(var) and En(var) mutations. En(var) mutation bearing samples appeared delayed in the digestion, relative to Su(var). This differential sensitivity seemed to be genome-wide as there was no detectable difference between either breakpoint of In(1)wm4 or the sequences on the homologous w- chromosome. However, after isogenizing the genetic background, the previously noted difference between the Su(var) and En(var) mutations was eliminated. In studies dealing with nuclease digestion of chromatin, the isogenization of genetic background is essential before meaningful comparisons can be made.