Functional analysis of the white + gene of Drosophila by P-factor-mediated transformation

Current Perspectives of Telomerase Structure and Function in Eukaryotes with Emerging Views on Telomerase in Human Parasites

Replicative capacity of a cell is strongly correlated with telomere length regulation. Aberrant lengthening or reduction in the length of telomeres can lead to health anomalies, such as cancer or premature aging. Telomerase is a master regulator for maintaining replicative potential in most eukaryotic cells. It does so by controlling telomere length at chromosome ends. Akin to cancer cells, most single-cell eukaryotic pathogens are highly proliferative and require persistent telomerase activity to maintain constant length of telomere and propagation within their host. Although telomerase is key to unlimited cellular proliferation in both cases, not much was known about the role of telomerase in human parasites (malaria, Trypanosoma, etc.) until recently. Since telomerase regulation is mediated via its own structural components, interactions with catalytic reverse transcriptase and several factors that can recruit and assemble telomerase to telomeres in a cell cycle-dependent manner, we compare and discuss here recent findings in telomerase biology in cancer, aging and parasitic diseases to give a broader perspective of telomerase function in human diseases.

The "Mendelian Gene" and the "Molecular Gene": Two Relevant Concepts of Genetic Units

We focus here on two prevalent meanings of the word gene in research articles. On one hand, the gene, named here "molecular gene," is a stretch of DNA that is transcribed and codes for an RNA or a polypeptide with a known or presumed function (as in "gene network"), whose exact spatial delimitation on the chromosome remains a matter of debate, especially in cases with alternative splicing, antisense transcripts, etc. On the other hand, the gene, called here "Mendelian gene," is a segregating genetic unit which is detected through phenotypic differences associated with different alleles at the same locus (as in "gene flow"). We show that the "Mendelian gene" concept is still extensively used today in biology research and is sometimes confused with the "molecular gene." We try here to clarify the distinction between both concepts. Efforts to delineate the beginning and the end of the DNA sequence corresponding to the "Mendelian gene" and the "molecular gene" reveal that both entities do not always match. We argue that both concepts are part of two relevant frameworks for explaining the biological world.

Loss of Pol32 in Drosophila melanogaster causes chromosome instability and suppresses variegation

Pol32 is an accessory subunit of the replicative DNA Polymerase δ and of the translesion Polymerase ζ. Pol32 is involved in DNA replication, recombination and repair. Pol32’s participation in high- and low-fidelity processes, together with the phenotypes arising from its disruption, imply multiple roles for this subunit within eukaryotic cells, not all of which have been fully elucidated. Using pol32 null mutants and two partial loss-of-function alleles pol32^rd1 and pol32^rds in Drosophila melanogaster, we show that Pol32 plays an essential role in promoting genome stability. Pol32 is essential to ensure DNA replication in early embryogenesis and it participates in the repair of mitotic chromosome breakage. In addition we found that pol32 mutantssuppress position effect variegation, suggesting a role for Pol32 in chromatin architecture.

[The telomere position effect: silence in the back row!]

Heterochromatin displays repressive histone marks that down-regulate transcription. In the absence of specialized barriers, these repressive marks spread onto nearby nucleosomes and induce transcriptional silencing of these regions. Accordingly, in various species, transgenes that are experimentally inserted directly next to telomeric repeats are silenced. Transcriptional repression induced by the spreading of telomeric heterochromatin is known as the "telomere position effect". Although it is attenuated by the presence of natural subtelomeric barriers acting against the spreading of telomeric heterochromatin, telomere-induced silencing is also observed at the level of endogenous loci where it was initially proposed to provide a mean to regulate gene expression during senescence. This, however, remains to be formally demonstrated. Here, I review the current evidences for a telomere position effect, from yeast to human.

Effete, a Drosophila chromatin-associated ubiquitin-conjugating enzyme that affects telomeric and heterochromatic position effect variegation

Drosophila telomeres are elongated by the transposition of telomere-specific retrotransposons rather than telomerase activity. Proximal to the terminal transposon array, Drosophila chromosomes contain several kilobases of a complex satellite DNA termed telomere-associated sequences (TASs). Reporter genes inserted into or next to the TAS are silenced through a mechanism called telomere position effect (TPE). TPE is reminiscent of the position effect variegation (PEV) induced by Drosophila constitutive heterochromatin. However, most genes that modulate PEV have no effect on TPE, and systematic searches for TPE modifiers have so far identified only a few dominant suppressors. Surprisingly, only a few of the genes required to prevent telomere fusion have been tested for their effect on TPE. Here, we show that with the exception of the effete (eff; also called UbcD1) mutant alleles, none of the tested mutations at the other telomere fusion genes affects TPE. We also found that mutations in eff, which encodes a class I ubiquitin-conjugating enzyme, act as suppressors of PEV. Thus, eff is one of the rare genes that can modulate both TPE and PEV. Immunolocalization experiments showed that Eff is a major constituent of polytene chromosomes. Eff is enriched at several euchromatic bands and interbands, the TAS regions, and the chromocenter. Our results suggest that Eff associates with different types of chromatin affecting their abilities to regulate gene expression.

Heterochromatin and gene positioning: inside, outside, any side?

All cellular processes depend on the expression and repression of the right sets of genes at the right time. As each cell contains the same DNA, transcriptional and epigenetic factors have to maintain tight control over gene expression. Even a small divergence from the correct transcriptional program can lead to severe defects and even death. Having deciphered the complete linear genetic information, we need to clarify how this information is organized into the dynamic and highly heterogeneous three-dimensional space of the eukaryotic cell nucleus. Observations on the higher order organization of DNA into differentiated condensation levels date back to the early twentieth century, and potential implications of these structural features to gene expression were postulated shortly after. In particular, proximity of genes to condensed regions of heterochromatin was proposed to negatively influence their expression and, henceforward, the concept of heterochromatin as subnuclear silencing compartment emerged. Methodological advances fueled a flurry of recent studies, which only, in part, led support to this concept. In this review, we address how (hetero)chromatin structure and proximity might influence gene expression and discuss the challenges and means to unravel this fundamental biological question.

Telomere length regulates TERRA levels through increased trimethylation of telomeric H3K9 and HP1α

Gene silencing by the repressive telomeric chromatin environment, referred to as telomere position effect (TPE), has been well characterized in yeast and depends on telomere length. However, proof of its existence at native human chromosome ends has remained elusive, mainly owing to the paucity of genes near telomeres. The discovery of TERRAs, the telomeric noncoding RNAs transcribed from subtelomeric promoters, paved the way to probing for telomere-length impact on physiological TPE. Using cell lines of various origins, we show that telomere elongation consistently represses TERRA expression. Repression is mediated by increased trimethylated H3K9 density at telomeres and by heterochromatin protein HP1α, with no detectable spreading of the marks beyond the telomeric tract, restricting human TPE to telomere transcription. Our data further support the existence of a negative-feedback mechanism in which longer TERRA molecules repress their own transcription upon telomere elongation.

HP1 is distributed within distinct chromatin domains at Drosophila telomeres

Telomeric regions in Drosophila are composed of three subdomains. A chromosome cap distinguishes the chromosome end from a DNA double-strand break; an array of retrotransposons, HeT-A, TART, and TAHRE (HTT), maintains telomere length by targeted transposition to chromosome ends; and telomere-associated sequence (TAS), which consists of a mosaic of complex repeated sequences, has been identified as a source of gene silencing. Heterochromatin protein 1 (HP1) and HP1-ORC-associated protein (HOAP) are major protein components of the telomere cap in Drosophila and are required for telomere stability. Besides the chromosome cap, HP1 is also localized along the HTT array and in TAS. Mutants for Su(var)205, the gene encoding HP1, have decreased the HP1 level in the HTT array and increased transcription of individual HeT-A elements. This suggests that HP1 levels directly affect HeT-A activity along the HTT array, although they have little or no effect on transcription of a white reporter gene in the HTT. Chromatin immunoprecipitation to identify other heterochromatic proteins indicates that TAS and the HTT array may be distinct from either heterochromatin or euchromatin.

Telomeric chromatin: roles in aging, cancer and hereditary disease

Over the last several years there has been an explosion in our understanding of the organization of telomeric chromatin in mammals. As in other regions of the genome, chromatin composition at the telomere regulates structure, which defines function. Mammalian telomeres, similar to what has been demonstrated for telomeres of other eukaryotes, carry marks of heterochromatin and alteration in this underlying epigenetic code has effects on telomere replication and recombination. Experiments aimed at determining links between changes in telomeric chromatin and possible roles in aging and disease are beginning to emerge. The rapid refinement of our knowledge of the structure and alterations in telomeric chromatin over the last several years makes it likely that we are just seeing the tip of the iceberg.

Telomeric position effect: from the yeast paradigm to human pathologies?

Alteration of the epigenome is associated with a wide range of human diseases. Therefore, deciphering the pathways that regulate the epigenetic modulation of gene expression is a major milestone for the understanding of diverse biological mechanisms and subsequently human pathologies. Although often evoked, little is known on the implication of telomeric position effect, a silencing mechanism combining telomere architecture and classical heterochromatin features, in human cells. Nevertheless, this particular silencing mechanism has been investigated in different organisms and several ingredients are likely conserved during evolution. Subtelomeres are highly dynamic regions near the end of the chromosomes that are prone to recombination and may buffer or facilitate the spreading of silencing that emanates from the telomere. Therefore, the composition and integrity of these regions also concur to the propensity of telomeres to regulate the expression, replication and recombination of adjacent regions. Here we describe the similarities and disparities that exist among the different species at chromosome ends with regard to telomeric silencing regulation with a special accent on its implication in numerous human pathologies.

Transcriptional activity of the telomeric retrotransposon HeT-A in Drosophila melanogaster is stimulated as a consequence of subterminal deficiencies at homologous and nonhomologous telomeres

Drosophila melanogaster telomeres have two DNA domains: a terminal array of retrotransposons and a subterminal repetitive telomere-associated sequence (TAS), a source of telomere position effect (TPE). We reported previously that deletion of the 2L TAS array leads to dominant suppression of TPE by stimulating in trans expression of a telomeric transgene. Here, we compared the transcript activities of a w transgene inserted between the retrotransposon and TAS arrays at the 2L telomere in genotypes with different lengths of the 2L TAS. In contrast to individuals bearing a wild-type 2L homologue, flies with a TAS deficiency showed a significant increase in the level of telomeric w transcript during development, especially in pupae. Moreover, we identified a read-through w transcript initiated from a retrotransposon promoter in the terminal array. Read-through transcript levels also significantly increased with the presence of a 2L TAS deficiency in trans, indicating a stimulating force of the TAS deficiency on retrotransposon promoter activity. The read-through transcript contributes to total w transcript, although most w transcript originates at the w promoter. While silencing of transgenes in nonhomologous telomeres is suppressed by 2L TAS deficiencies, suggesting a global effect, the overall level of HeT-A transcripts is not increased under similar conditions.

Engineered telomeres in transgenic Xenopus laevis

The expanding roles of telomeres in epigenetic gene regulation, nuclear organization, and human disease have necessitated the establishment of model organisms in which to study telomere function under normal developmental conditions. We present an efficient system for generating numerous vertebrate animals containing engineered telomeres using a Xenopus laevis transgenesis technique. Our results indicate Xenopus zygotes efficiently recognize telomeric repeats at chromosome break points and form telomeric complexes thus generating a new telomere. The resulting transgenic animals progress through normal development and successfully metamorphose into froglets despite the chromosome breakage. Overall, this presents an efficient mechanism for generating engineered telomeres in a vertebrate system and provides an opportunity to investigate epigenetic aspects of telomere function during normal vertebrate development.

An FB-NOF mediated duplication of the white gene is responsible for the zeste1 phenotype in some Drosophila melanogaster unstable strains

The males of the Drosophila melanogaster M115 mutant strain and of its spontaneous revertant strain RM115 are phenotypically similar to those carrying the w(+UZ) and w(+UR) alleles. The molecular description of these mutant strains could be extended to the unstable-zeste system, which has been used as a genotoxicity test, and could be of use for a better understanding of the assay. An FB element in the 3' vicinity of the white gene, actually into the second intron of the newly predicted CG32795 gene, was found and precisely located in our M115 and RM115 strains, and also in w(+UZ) as expected. We demonstrate the presence of NOF sequences in the M115 and w(+UZ) insertions. However, we found that the z1 phenotype in these males might not be due to the FB-NOF interference on the zeste-white interaction but to a duplication of the white gene unnoticed in previous studies. The reversion of RM115 correlates with the loss of the duplication, probably by a complex recombination event. Furthermore, a FISH experiment suggests that the two copies of white are nearby or tandemly duplicated.

Euchromatic and heterochromatic domains at Drosophila telomeres

Noncoding repetitive sequences make up a large portion of eukaryotic genomes, but their function is not well understood. Large blocks of repetitive DNA-forming heterochromatin around the centromeres are required for this region to function properly, but are difficult to analyze. The smaller regions of heterochromatin at the telomeres provide an opportunity to study their DNA and protein composition. Drosophila telomere length is maintained through the targeted transposition of specific non-long terminal repeat retrotransposons to chromosome ends, where they form long tandem arrays. A subterminal telomere-associated sequence (TAS) lies immediately proximal to the terminal-retrotransposon array. Here, we review the experimental support for the heterochromatic features of Drosophila telomeres, and provide evidence that telomeric regions contain 2 distinct chromatin subdomains: TAS, which exhibits features that resemble beta heterochromatin; and the terminal array of retrotransposons, which appears euchromatic. This organization is significantly different from the telomeric organization of other eukaryotes, where the terminal telomerase-generated repeats are often folded in a t-loop structure and become part of the heterochromatin protein complex.

A deficiency screen for dominant suppressors of telomeric silencing in Drosophila

Heterochromatin is a specialized chromatin structure in chromosomal regions associated with repeated DNA sequences and low concentrations of genes. Formation of heterochromatin is determined in large part by enzymes that modify histones and structural proteins that bind to these modified histones in a cooperative fashion. In Drosophila, mutations in genes that encode heterochromatic proteins are often dominant and increase expression of genes placed into heterochromatic positions. To find components of telomeric heterochromatin in Drosophila, we screened a collection of autosomal deficiencies for dominant suppressors of silencing of a transgene at the telomere of chromosome 2L. While many deficiency chromosomes are associated with dominant suppressors, in the cases tested on chromosome 2 the suppressor mapped to the 2L telomere, rather than the deficiency. We infer that background effects may hamper the search for genes that play a role in telomeric heterochromatin formation and that either very few genes participate in this pathway or mutations in these genes are not dominant suppressors of telomeric position effect. The data also suggest that the 2L telomere region plays a major role in telomeric silencing.

Cis- and trans-acting influences on telomeric position effect in Drosophila melanogaster detected with a subterminal transgene

One model of telomeric position effect (TPE) in Drosophila melanogaster proposes that reporter genes in the vicinity of telomeres are repressed by subterminal telomere-associated sequences (TAS) and that variegation of these genes is the result of competition between the repressive effects of TAS and the stimulating effects of promoters in the terminal HeT-A transposon array. The data presented here support this model, but also suggest that TPE is more complex. Activity of a telomeric white reporter gene increases in response to deletion of some or all of the TAS on the homolog. Only transgenes next to fairly long HeT-A arrays respond to this trans-interaction. HeT-A arrays of 6-18 kb respond by increasing the number of dark spots on the eye, while longer arrays increase the background eye color or increase the number of spots sufficiently to cause them to merge. Thus, expression of a subtelomeric reporter gene is influenced by the telomere structure in cis and trans. We propose that the forces involved in telomere length regulation in Drosophila are the underlying forces that manifest themselves as TPE. In the wild-type telomere TAS may play an important role in controlling telomere elongation by repressing HeT-A promoter activity. Modulation of this repression by the homolog may thus regulate telomere elongation.

Terminal retrotransposons activate a subtelomeric white transgene at the 2L telomere in Drosophila

Genetically marked P elements inserted into the subtelomeric satellites of Drosophila show repression and variegation of the reporter gene. One such white+ reporter, inserted between the subtelomeric satellite and the terminal HeT-A array in the left arm of chromosome 2 (2L), is sensitive to its context; changes in the structure of the telomere region can be identified by changes in eye color. Addition of HeT-A or TART elements to the 2L terminus increases w+ expression, and loss of sequence from the end decreases expression. This indicates that the telomeric retrotransposons in Drosophila have an activating influence on the repressed subterminal reporter gene. Changes in eye color due to altered expression of the transgene also allow the detection of interactions between homologous telomeres. The 2L arms that terminate in long HeT-A/TART arrays showed increased expression of the subterminal w+ transgene when the terminal repeats on the homologue are absent or markedly shorter. We propose that the chromatin structure of the terminal HeT-A/TART array and the activity of a putative promoter/enhancer element on HeT-A are affected by telomeric interactions. Such trans-activation may reflect control over HeT-A transcription and, thus, transposition activity.

Molecular screening for P-element insertions in a large genomic region of Drosophila melanogaster using polymerase chain reaction mediated by the vectorette

As an alternative to existing methods for the detection of new insertions during a transposon mutagenesis, we adapted the method of vectorette ligation to genomic restriction fragments followed by PCR to obtain genomic sequences flanking the transposon. By combining flies containing a defined genomic transposon with an excess of flies containing unrelated insertion sites, we demonstrate the specificity and sensitivity of the procedure in the detection of integration events. This method was applied in a transposon-tagging screen for BJ1, the Drosophila homolog of the vertebrate gene Regulator of Chromosome Condensation (RCCI). Genetic mobilization of a single genomic P element was used to generate preferentially new local insertions from which integrations into a genomic region surrounding the BJ1 gene were screened. Flies harboring new insertions were phenotypically selected on the basis of the zeste1-dependent transvection of white. We detected a single transposition to a 13-kb region close to the BJ1 gene among 6650 progeny that were analyzed. Southern analysis of the homozygous line confirmed the integration 3 kb downstream of BJ1.

The regulatory properties of autonomous subtelomeric P elements are sensitive to a Suppressor of variegation in Drosophila melanogaster

Genetic recombination was used in Drosophila melanogaster to isolate P elements, inserted at the telomeres of X chromosomes (cytological site IA) from natural populations, in a genetic background devoid of other P elements. We show that complete maternally inherited P repression in the germline (P cytotype) can be elicited by only two autonomous P elements at 1A and that a single element at this site has partial regulatory properties. The analysis of the surrounding chromosomal regions of the P elements at 1A shows that in all cases these elements are flanked by Telomeric Associated Sequences, tandemly repetitive noncoding sequences that have properties of heterochromatin. In addition, we show that the regulatory properties of P elements at 1A can be inhibited by some of the mutant alleles of the Su(var)205 gene and by a deficiency of this gene. However, the regulatory properties of reference P strains (Harwich and Texas 007) are not impaired by Su(var)205 mutations. Su(var)205 encodes Heterochromatin Protein 1 (HP1). These results suggest that the HP1 dosage effect on the P element properties is site-dependent and could involve the structure of the chromatin.

Molecular characterization of the Anopheles gambiae 2L telomeric region via an integrated transgene

A Drosophila P-element derivative (pUChsneo) integrated into the telomeric region of the left arm of the second chromosome of Anopheles gambiae was used to clone the proximally flanking An. gambiae sequences. Molecular analyses revealed that the pUChsneo construct was partially duplicated and had integrated into a subterminal minisatellite. This satellite has a repeat unit of 820 bp and is located exclusively at the tip of 2L. No sequence similarity to subterminal minisatellites from other dipterans was detected, but some structural features such as tandem subrepeats are shared. The end of the chromosome was mapped with respect to restriction sites in pUChsneo at approximately generation 100 after the integration event. Considering inevitable terminal nucleotide loss due to incomplete DNA replication, we conclude that the chromosome end must have undergone a dramatic elongation process since it was mapped in generation 23.

DNA organization and polymorphism of a wild-type Drosophila telomere region

Telomeres at the ends of linear chromosomes of eukaryotes protect the chromosome termini from degradation and fusion. While telomeric replication/elongation mechanisms have been studied extensively, the functions of subterminal sequences are less well understood. In general, subterminal regions can be quite polymorphic, varying in size from organism to organism, and differing among chromosomes within an organism. The subterminal regions of Drosophila melanogaster are not well characterized today, and it is not known which and how many different components they contain. Here we present the molecular characterization of DNA components and their organization in the subterminal region of the left arm of chromosome 2 of the Oregon RC wild-type strain of D. melanogaster, including a minisatellite with a 457bp repeat length. Two distinct polymorphic arrangements at 2L were found and analyzed, supporting the Drosophila telomere elongation model by retrotransposition. The high incidence of terminal chromosome deficiencies occurring in natural Drosophila populations is discussed in view of the telomere structure at 2L.

White as a reporter gene to detect transcriptional silencers specifying position-specific gene expression during Drosophila melanogaster eye development

The white+ gene was used as a reporter to detect transcriptional silencer activity in the Drosophila genome. Changes in the spatial expression pattern of white were scored in the adult eye as nonuniform patterns of pigmentation. Thirty-six independent P[lacW] transposant lines were collected. These represent 12 distinct pigmentation patterns and probably 21 loci. The spatial pigmentation pattern is due to cis-acting suppression of white+ expression, and the suppression probably depends on cell position rather than cell type. The mechanism of suppression differs from inactivation by heterochromatin. In addition, activation of lacZ in P[lacW] occurs also in specific patterns in imaginal discs and embryos in many of the lines. The expression patterns of white+ and lacZ may reflect the activity of regulatory elements belonging to an endogenous gene near each P[lacW] insertion site. We speculate that these putative POSE (position-specific expression) genes may have a role in pattern formation of the eye as well as other imaginal structures. Three of the loci identified are optomotor-blind, engrailed and invected. teashirt is also implicated as a candidate gene. We propose that this "silencer trap"' may be an efficient way of identifying genes involved in imaginal pattern formation.

An unusual mosaic protein with a protease domain, encoded by the nudel gene, is involved in defining embryonic dorsoventral polarity in Drosophila

Dorsoventral polarity of the Drosophila embryo is induced by a ventral extracellular signal, which is produced by a locally activated protease cascade within the extraembryonic perivitelline compartment. Local activation of the protease cascade depends on a positional cue that is laid down during oogenesis outside the oocyte. Here we present evidence that the nudel gene encodes an essential component of this cue. The nudel gene, which is expressed in follicle cells covering the oocyte, encodes an unusual mosaic protein resembling an extracellular matrix protein with a central serine protease domain. Our findings suggest that embryonic dorsoventral polarity is defined by a positional cue that requires the nudel protein to anchor and to trigger the protease cascade producing the polarity-inducing signal.

The unusual telomeres of Drosophila

The telomeres of most eukaryotes contain short, simple repeats that are highly conserved. Drosophila, on the other hand, does not have such sequences, but carries at the ends of its chromosomes one or more LINE-like retrotransposable elements. Instead of elongation by telomerase, incomplete DNA replication at the termini of Drosophila chromosomes is counterbalanced by transposition of these elements at high frequency specifically to the termini. These transposable elements are not responsible for distinguishing telomeric ends in Drosophila from broken chromosome ends; the structure performing this function is not yet known. Proximal to the terminal array of transposable elements are regions of tandem repeats that are structurally, and probably functionally, analogous to the subterminal regions in other eukaryotes.

Induced expression of a Drosophila hsp70 promoter-fusion transgene is reduced after repeated heat shocks

Levels of transcripts produced by a heat shock protein 70 (hsp70)-antisense white transgene in Drosophila were measured after single and multiple heat shocks to determine whether the hsp70 promoter could produce sustained high levels of transgene transcripts. A single heat shock resulted in typical highly inducible levels of RNA, but the amount of antisense RNA was substantially reduced after multiple heat shocks. Endogenous hsp70 mRNA levels were also less abundant after multiple heat shocks as compared to a single heat shock. The hsp70 promoter is unsuitable for use in fusion gene constructs for long term expression studies where repeated heat shocks are required.

Tissue-specific position effects on alcohol dehydrogenase expression in Drosophila melanogaster

Twenty transformed lines have been isolated as a result of the germ line insertion of a 3.2 kb alcohol dehydrogenase (Adh) gene fragment into an Adh negative strain of Drosophila melanogaster by P element-mediated transformation. More than half of these lines exhibited abnormal ADH expression. The level of ADH expression ranges from zero in some lines to near normal levels in others, and the pattern of ADH expression in the larval gut is also abnormal in many of these lines. Each of the abnormal tissue-specific patterns is stable and characterized by the absence or reduction of ADH expression in certain tissues. High levels of ectopic expression were not observed. In two of these lines, the pattern of ADH staining is highly restricted: it is limited to the medial midgut in line MM-50, and to the gastric caecae and the proventriculus in line GC-1. In heterozygotes between these two lines ADH is expressed in both of these tissues. To test the hypothesis that this abnormal expression is due to position effects, inserts were mobilized to new locations. The mobilized inserts exhibited new patterns of tissue-specific expression associated with new cytological insert locations, showing that the abnormal expression in lines MM-50 and GC-1 is due to tissue-specific position effects and not to mutations. The results are discussed in the context of chromatin structure as a possible cause of these position effects.

P-transposable vectors expressing a constitutive and thermoinducible hsp82-neo fusion gene for Drosophila germline transformation and tissue-culture transfection

Three P-transposable vectors (approx. 16, 12, and 9 kb) were constructed containing a hsp82-neo fusion gene encoding a truncated heat-shock protein 82 of Drosophila pseudoobscura and the bacterial neomycin phosphotransferase (NPT). In transgenic Drosophila melanogaster, hsp82-neo exhibits high levels of housekeeping gene promoter and NPT activities in all cells in the absence of heat-shock and is further induced (fivefold) by elevated temperatures (35 degrees-36 degrees C). The hsp82-neo selection of transformants is possible from embryo to adulthood. The hsp82-neo insertion in a P-element plasmid carrying an alcohol-dehydrogenase-encoding gene (Adh) produced plasmids pHS22 (approx. 16 kb) and pHS24 (approx. 12 kb), in which both genes were expressed, as observed in 13 transgenic strains. Cloning of DNA fragments up to at least 16 kb in a third vector, pHS85 (approx. 9 kb), lacking the Adh cointegrate is facilitated by a 104-bp multiple cloning site (MCS) positioned downstream (3') from hsp82-neo. To accept inserts of nonselectable foreign genes, MCS provides 20 restriction sites, eight of them unique. The hsp82-neo-expressing vectors also function in cell-culture transfection assays. The hsp82-neo fusion gene (3.73 kb) may be of wide application as a dominant selection marker in other animal systems and plants.

Cloning and characterization of the white and topaz eye color genes from the sheep blowfly Lucilia cuprina

Clones carrying the white and topaz eye color genes have been isolated from genomic DNA libraries of the blowfly Lucilia cuprina using cloned DNA from the homologous white and scarlet genes, respectively, of Drosophila melanogaster as probes. On the basis of hybridization studies using adjacent restriction fragments, homologous fragments were found to be colinear between the genes from the two species. The nucleotide sequence of a short region of the white gene of L. cuprina has been determined, and the homology to the corresponding region of D. melanogaster is 72%; at the derived amino acid level the homology is greater (84%) due to a marked difference in codon usage between the species. A major difference in genome organization between the two species is that whereas the DNA encompassing the D. melanogaster genes is free of repeated sequences, that encompassing their L. cuprina counterparts contains substantial amounts of repeated sequences. This suggests that the genome of L. cuprina is organized on the short period interspersion pattern. Repeated sequence DNA elements, which appear generally to be short (less than 1 kb) and which vary in repetitive frequency in the genome from greater than 10(4) copies to less than 10(2) copies, are found in at least two different locations in the clones carrying these genes. One type of repeat structure, found by sequencing, consists of tandemly repeating short sequences. Restriction site and restriction fragment length polymorphisms involving both the white and topaz gene regions are found within and between populations of L. cuprina.

Molecular and phenotypic variation of the white locus region in Drosophila melanogaster

Restriction site and insertion/deletion polymorphism in a 45-kb region of the white locus on the X chromosome in Drosophila melanogaster was investigated for 64 X chromosome lines with six 6-cutter and ten 4-cutter restriction enzymes. A total of 109 polymorphisms were detected (54 restriction sites and 55 insertions/deletions). Estimated heterozygosity per nucleotide for this region (0.004-0.008) was similar to those of the Adh and 87A heat-shock locus regions located on the autosomes in D. melanogaster. This is contrary to a simple prediction based on the theory of mutation selection-balance of partially recessive deleterious mutants which predicts less variation on X chromosomes. Large linkage disequilibria between pairs of polymorphisms (including insertions and deletions) within the transcriptional unit (especially the 3' end of the 1st intron) were observed. As expected from population genetics theory, linkage disequilibria between these polymorphisms were greater for those pairs that are physically closer on the restriction map. Linkage equilibrium was typically observed when the pairs of sites were separated by 2 kb or more. Although significant between-line variation in eye pigment was observed (P less than 0.05), there is little evidence for strong associations between this phenotype and the polymorphisms at the DNA level.

The underlying bases of gene expression differences in stable transformants of the rosy locus in Drosophila melanogaster

This report represents a continuation of our laboratory's effort to understand the major phenomena associated with P-M dysgenesis-mediated transformation in Drosophila. A group of stable transformants are characterized with respect to rosy gene expression. Stable, true-breeding, line-specific variants in gene expression are described. These are shown to be associated with single transposons present in each line, and the lines are free of functional P elements. The effects on expression are cis-acting, and there are no identifiable rosy DNA sequence lesions associated with these transposons. Evidence is presented that demonstrates that two features of the transformation experimental system are responsible for such variation. The first relates to the fact that the transposons insert at numerous genomic sites. Both heterochromatic and euchromatic position effects are characterized. The second relates to the fact that transformation involves dysgenic mobilization of a P-element transposon. This process is mutagenic, and such a mutation is characterized.

Spatial and temporal pattern of hsp26 expression during normal development

The tissue-specific patterns of developmental expression of hsp26-lacZ fusion genes inserted into Drosophila melanogaster by germline transformation were analyzed in several transformant lines utilizing a histochemical assay for beta-galactosidase activity on whole animals. We compared this pattern to the tissue-specific distribution of endogenous hsp26 RNA determined using hybridization of probes to RNA in situ in tissue sections. Both assays reveal that hsp26 is expressed in numerous tissues during development including spermatocytes, nurse cells, epithelium, imaginal discs, proventriculus and neurocytes. The ease and resolution of the whole-animal beta-galactosidase assay makes it particularly attractive for the elucidation of sequences involved in such complex regulation. The original hsp26-lacZ fusion gene contained 2 kb of sequence upstream of the transcription start. A construct containing only 278 bp upstream was still expressed in spermatocytes but no longer in nurse cells. In a few instances, the fusion genes were expressed in tissues for which there was no evidence for expression of the endogenous hsp26 gene. These novel patterns appear to be a result of chromosomal position since they were observed in only one or a subset of transformant lines containing identical inserts.

Developmentally regulated expression of Drosophila chorion genes introduced at diverse chromosomal positions

Drosophila chorion genes are organized into two clusters that are selectively amplified in the ovarian follicle cells. During oogenesis the transcription of individual genes is temporally regulated, resulting in distinct, stage-specific profiles of chorion mRNA accumulation. P element-mediated gene transfer was used to study the regulation of genes encoding the major chorion proteins s15-1 and s38-1. Transformed chorion genes integrated at diverse chromosomal locations exhibited proper tissue-specific and stage-specific expression, despite separation from the gene clusters. Qualitatively normal expression was not dependent on the ability of the inserted DNA to undergo amplification. However, chromosome position quantitatively influenced the RNA produced by the transformed genes. The level of RNA per gene copy produced by individual transformed genes varied approximately tenfold, after correction for differences in gene dosage due to the amplification of some inserted sequences. Transformation experiments with an s38-1-lacZ fusion gene demonstrated that cis-regulatory sequences sufficient for the stage-specific program of s38-1 expression were confined to a 1.3 X 10(3) base-pair segment between -748 and +573 relative to the s38-1 initiation site. Finally, egg chamber-specific amplification was induced at the site of two s38-1 insertions, suggesting that an amplification control element resides near this gene.

Effects of genomic position on the expression of transduced copies of the white gene of Drosophila

The white gene of Drosophila is expressed normally when introduced at many different sites in the genome by P-element-mediated DNA transformation, but is expressed abnormally when inserted at two particular genomic positions. It is now demonstrated that the mutant expression in these two cases is caused by the surrounding chromosomal region into which the white gene has been inserted. The white gene could be moved from these two positions, where it confers a mutant phenotype, to other positions in the genome where it confers a wild-type phenotype. However, flies in which white has been moved to one new location have an unusual mosaic phenotype.