Structural organization of the Amy locus in seven strains of Drosophila melanogaster.

Restriction maps were made by Southern blot analysis of the Amy (alpha-amylase) region in 7 strains of D. melanogaster using endonucleases SalI, XhoI and EcoRI. These were compared to the map of lambda Dm65 which contains the cloned Amy region. Strains used produce either two amylase variants, a single variant, or no amylase, yet all 7 strains carry two Amy genes as inverted repeats at the Amy locus. This and the orientation of the repeats resembles the situation in lambda Dm65. Most restriction sites mapped are conserved but two strains contain a large insertion which differs in size and position between strains. A complex anomaly, probably an inversion, exists at the Amy locus in a null strain. Maps for our Amy1,3 strain and the lambda Dm65 clone are identical, the DNA of each having been derived from a Canton-S wild stock. Restriction and genetic maps of the Amy region were aligned and alleles assigned to the proximal and distal genes, Amy-p and Amy-d.     

Tissue-specific and dietary control of alpha-amylase gene expression in the adult midgut of Drosophila melanogaster.

The regulatory effects of allelic substitution at the trans-acting mapP locus and of dietary glucose on the expression of the duplicate genes for alpha-amylase (Amy) in Drosophila melanogaster were examined in the anterior midgut and posterior midgut regions of mature flies. The levels of amylase activity and amylase protein, as well as the abundance of amylase-specific RNA, were quantified. All 3 parameters of Amy expression were concordant. Results indicate that the effects of both mapP and dietary glucose are exerted at the level of amylase RNA. However, the tissue-specific effects of mapP are restricted to the posterior midgut and can therefore be distinguished from the effects of glucose in food medium, which influences amylase RNA levels in both the anterior and posterior midgut regions. Our data suggest that, in large part, strain-specific effects of dietary glucose can be explained on the basis of alternate alleles at the mapP locus in different homozygous strains of flies. Levels of amylase RNA in tissue extracts of flies from an amylase-null strain were also measured. Low levels were observed in both anterior and posterior midgut extracts. These were unresponsive to dietary conditions.     

DNA rearrangement causes multiple changes in gene expression at the amylase locus inDrosophila melanogaster

A spontaneous null mutation at the alpha-amylase locus in Drosophila melanogaster was recovered from a laboratory population. The mutant strain was found to lack amylase enzyme production and to produce low, but detectable, levels of amylase mRNA. Moreover, the null strain is also lacking the glucose repression of amylase mRNA production which is seen in wild-type strains. The mutant phenotype correlates with a rearrangement in genomic DNA which, in turn, corresponds to a simple inversion in the arrangement observed most frequently in North American populations of D. melanogaster, including the common laboratory strain, Oregon-R. These results have implications for our understanding of both the evolution of the duplicated amylase gene structure and the regulation of amylase gene expression.     

DNA Sequence Evolution of the Amylase Multigene Family in Drosophila Pseudoobscura

The alpha-Amylase locus in Drosophila pseudoobscura is a multigene family of one, two or three copies on the third chromosome. The nucleotide sequences of the three Amylase genes from a single chromosome of D. pseudoobscura are presented. The three Amylase genes differ at about 0.5% of their nucleotides. Each gene has a putative intron of 71 (Amy1) or 81 (Amy2 and Amy3) bp. In contrast, Drosophila melanogaster Amylase genes do not have an intron. The functional Amy1 gene of D. pseudoobscura differs from the Amy-p1 gene of D. melanogaster at an estimated 13.3% of the 1482 nucleotides in the coding region. The estimated rate of synonymous substitutions is 0.398 +/- 0.043, and the estimated rate of nonsynonymous substitutions is 0.068 +/- 0.008. From the sequence data we infer that Amy2 and Amy3 are more closely related to each other than either is to Amy1. From the pattern of nucleotide substitutions we reason that there is selection against synonymous substitutions within the Amy1 sequence; that there is selection against nonsynonymous substitutions within the Amy2 sequence, or that Amy2 has recently undergone a gene conversion with Amy1; and that Amy3 is nonfunctional and subject to random genetic drift.     

Dosage compensation and dietary glucose repression of larval amylase activity inDrosophila miranda

The functional locus for alpha-amylase (Amy) in Drosophila miranda is in the evolutionarily new X2 chromosome. X2 evolved from an autosome in response to an ancestral autosome-Y translocation that gave rise to the "neo-Y" chromosome of this species. Y-linked Amy, if still present in the ancestrally translocated element, is unexpressed. Dosage compensation for amylase activity was examined in larvae of the S 204 strain. Since dietary glucose is known to repress Amy expression in Drosophila melanogaster, dosage compensation of amylase activity in male larvae of D. miranda was tested by rearing larvae of both sexes on yeast diets with or without a glucose supplement. The WT 10 strain of Drosophila persimilis, a sibling species in which Amy is autosomally linked, was used as a reference for tests of amylase activity differences between the sexes. On the diet with glucose, Amy expression was repressed in both WT 10 and S 204 larvae and male larvae of S 204 displayed dosage compensation for amylase activity. On the nonrepressing diet consisting of yeast alone, S 204 continued to display dosage compensation.     

The Amylase gene cluster on the evolving sex chromosomes of Drosophila miranda.

On the basis of chromosomal homology, the Amylase gene cluster in Drosophila miranda must be located on the secondary sex chromosome pair, neo-X (X2) and neo-Y, but is autosomally inherited in all other Drosophila species. Genetic evidence indicates no active amylase on the neo-Y chromosome and the X2-chromosomal locus already shows dosage compensation. Several lines of evidence strongly suggest that the Amy gene cluster has been lost already from the evolving neo-Y chromosome. This finding shows that a relatively new neo-Y chromosome can start to lose genes and hence gradually lose homology with the neo-X. The X2-chromosomal Amy1 is intact and Amy2 contains a complete coding sequence, but has a deletion in the 3''-flanking region. Amy3 is structurally eroded and hampered by missing regulatory motifs. Functional analysis of the X2-chromosomal Amy1 and Amy2 regions from D. miranda in transgenic D. melanogaster flies reveals ectopic AMY1 expression. AMY1 shows the same electrophoretic mobility as the single amylase band in D. miranda, while ectopic AMY2 expression is characterized by a different mobility. Therefore, only the Amy1 gene of the resident Amy cluster remains functional and hence Amy1 is the dosage compensated gene.     

Transposition of the hobo element in Drosophila melanogaster somatic cells

Somatic mutation and recombination test on wing cells of Drosophila melanogaster showed that the recombination frequency in the somatic tissues of strains studied correlated with the presence of a full-length copy of the hobo transposable element in the genome. Transposition of hobo in somatic tissue cells at a frequency 3.5 x 10-2 per site per X chromosome was shown by fluorescence in situ hybridization with salivary gland polytene chromosomes of larvae of one of the D. melanogaster strains having a full-length hobo copy.     

Evidence for Regulatory Variants of the Dopa Decarboxylase and Alpha-Methyldopa Hypersensitive Loci in Drosophila

We have analyzed two variants of Drosophila melanogaster (RS and RE) which lead to the dual phenotype of elevated DDC activity and increased resistance to dietary alpha-methyldopa relative to Oregon-R controls. Both phenotypes show tight genetic linkage to the dopa decarboxylase, Ddc, and l(2)amd genes (i.e., less than 0.05 cM distant). We find that low (Oregon-R), medium (RS) and high (RE and Canton-S) levels of DDC activity seen at both pupariation and eclosion in these strains are completely accounted for by differences in accumulation of DDC protein as measured by immunoprecipitation. Genetic reconstruction experiments in which Ddc+ and amd+ gene doses are varied show that increasing DDC activity does not lead to a measurable increase in resistance to dietary alpha-methyldopa. This suggests that the increased resistance to dietary alpha-methyldopa is not the result of increased DDC activity but, rather, results from increased l(2)amd+ activity. Both cytogenetic and molecular analyses indicate that these overproduction variants are not the result of small duplications of the Ddc and amd genes, nor are they associated with small (greater than or equal to 100 bp) insertions or deletions. Measurements of DDC activity in wild-type strains of Drosophila reveal a unimodal distribution of activity levels with the Canton-S and RE strains at the high end of the scale, the Oregon-R control at the low end and RS near the modal value. We conclude that accumulated changes in a genetic element (or elements) in close proximity to the Ddc+ and amd+ genes lead to the coordinated changes in the expression of the Ddc and amd genes in these strains.     

Thymidylate Synthetase in Mutants of DROSOPHILA MELANOGASTER

Thymidylate synthetase has been examined with respect to the normal pattern of activity throughout the development of the Oregon-R strain of Drosophila melanogaster. Large amounts of the enzyme are present in both the unfertilized and the fertilized eggs. A comparison of the ovarian thymidylate synthetase activity of the Oregon-R strain and the female sterility mutants, fs(2)B, fu, and fs(1)N, indicates variations in the activity of this enzyme in each strain. At four days of age, the ovarian-specific activity of the female sterility mutants is comparable to or less than that of the Oregon-R strain, but it is reduced at fifteen days of age. The enzyme activity per ovary is low in the fs(2)B strain but is similar in the Oregon-R, fu, and fs(1)N strains. When expressed as activity per organism, thymidylate synthetase declines after six to eight hours of development until the minimal level is reached in the late embryonic stage. Enzyme activity rises throughout the larval instars, reaching a maximum immediately after puparium formation. The activity decreases during pupation, but rises again during the first four days of adult life.     

Molecular cloning of alpha-amylase genes fromDrosophila melanogaster. III. An inversion at theAmy locus in an amylase-null strain

Overlapping clones of the structural gene region for alpha-amylase,Amy, were isolated from a lambda EMBL4 library containing genomic DNA fragments from an amylase-null strain ofDrosophila melanogaster. Southern blot analysis and restriction endonuclease mapping of the cloned region indicate that it contains anAmy gene duplication within an inverted repeat sequence as is characteristic of the genomic arrangement for this species. Spacing between the cloned gene copies is similar to that commonly found in other strains. Evidence is presented for the presence of an inversion 4 to 9 kb in length within the clonedAmy region of the null strain. We postulate a causal relationship between the presence of the inversion and the failure of individuals from the null strain to express amylase. A model is proposed that suggests the inversion may have arisen through intramolecular (or sister-strand) recombination mediated by homologous pairing of the inverted repeat sequences at theAmy locus.This research was supported by NIH Grant GM25255.     

Evolution of nucleotide substitutions and gene regulation in the amylase multigenes in Drosophila kikkawai and its sibling species

In order to determine evolutionary changes in gene regulation and the nucleotide substitution pattern in a multigene family, the amylase multigenes were characterized in Drosophila kikkawai and its sibling species. The nucleotide substitution pattern was investigated. Drosophila kikkawai has four amylase genes. The Amy1 and Amy2 genes are a head-to-head duplication in the middle of the B arm of the second chromosome, while the Amy3 and Amy4 genes are a tail-to-tail duplication near the centromere of the same chromosome. In the sibling species of D. kikkawai (Drosophila bocki, Drosophila leontia, and Drosophila lini), sequencing of the Amy1, Amy2, Amy3, and Amy4 genes revealed that the Amy1 and Amy2 gene group diverged from Amy3 and Amy4 after duplication. In the Amy1 and Amy2 genes, the divergent evolution occurred in the flanking regions; in contrast, the coding regions have evolved in concerted fashion. The electrophoretic pattern of AMY isozymes was also examined. In D. kikkawai and its siblings, two or three electrophoretically different isozymes are encoded by the Amy1 and Amy2 genes (S isozyme) and by the Amy3 and Amy4 genes (F (M) isozymes). The S and F (M) isozymes show different patterns of band intensity when larvae and flies were fed in different media. Amy1 and Amy2, which encode the S isozyme, are more strikingly regulated than Amy3 and Amy4, which encode the F (M) isozyme. The GC content and codon usage bias were higher for the Amy1 and Amy2 genes than for the Amy3 and Amy4 genes. Although the ratio of synonymous and replacement substitutions within the Amy1 and Amy2 gene group was not significantly different from that within the Amy3 and Amy4 gene group, the synonymous substitution rate in the lineage of Amy1 and Amy2 was lower than that of Amy3 and Amy4. In conclusion, after the first duplication but before speciation of four species, the synonymous substitution rate between the two lineages and the electrophoretic pattern of the isozymes encoded by them changed, although we do not know whether there was any evolutionary relationship between the two.     

Molecular Cloning of α-Amylase Genes from DROSOPHILA MELANOGASTER. I. Clone Isolation by Use of a Mouse Probe

A cloned alpha-amylase cDNA sequence from the mouse is homologous to a small set of DNA sequences from Drosophila melanogaster under appropriate conditions of hybridization. A number of recombinant lambda phage that carry homologous Drosophila genomic DNA sequences were isolated using the mouse clone as a hybridization probe. Putative amylase clones hybridized in situ to one or the other of two distinct sites in polytene chromosome 2R and were assigned to one of two classes, A and B. Clone lambda Dm32, representing class A, hybridizes within chromosome section 53CD. Clone lambda Dm65 of class B hybridizes within section 54A1-B1. Clone lambda Dm65 is homologous to a 1450- to 1500-nucleotide RNA species, which is sufficiently long to code for alpha-amylase. No RNA homologous to lambda Dm32 was detected. We suggest that the class B clone, lambda Dm65, contains the functional Amy structural gene(s) and that class A clones contain an amylase pseudogene.     

P transposable element in Drosophila melanogaster: horizontal transfer]

The P transposable element family in Drosophila melanogaster is responsible for the syndrome of hybrid dysgenesis which includes chromosomal rearrangements, male recombination, high mutability and temperature sensitive agametic sterility (called gonadal dysgenesis sterility). P element activity is controlled by a complex regulation system, encoded by the elements themselves, which keeps their transposition rate low within the strain bearing P elements and limits copy number by genome. A second regulatory mechanism, which acts on the level of RNA processing, prevents P mobility to somatic cells. The oldest available strains, representing most major geographical regions of the world, exhibited no detectable hybridization to the P-element. In contrast, all recently collected natural populations that were tested carried P-element sequences. The available evidence is consistent with the hypothesis of a worldwide P-element invasion of D. melanogaster during the past 30 years. Timing and direction of the invasion are discussed. The lack of P-element in older strains of Drosophila melanogaster as well as in the species must closely related to Drosophila melanogaster, suggests that P entered the Drosophila melanogaster genome recently, probably by horizontal transfer from an other species. The analysis of P-element elsewhere in the genus Drosophila reveals that several more distantly related species carried transposable elements with sequences quite similar to P. The species with the best-matching P-element is D. willistoni. A P-element from this species was found to match all but one of the 2907 nucleotides of the Drosophila melanogaster P-element. The phylogenic distributions and the likely horizontal transfers of the two other Drosophila transposable elements are discussed.     

Population Genetics of Drosophila Amylase. I. Genetic Control of Tissue-Specific Expression in D. PSEUDOOBSCURA

Drosophila pseudoobscura is polymorphic for tissue-specific expression of alpha-amylase in adult midguts. This enzyme is encoded by a single locus, Amy, on the third chromosome. In this paper we show: (1) Up to about 12 days post-eclosion, the midgut activity patterns remain stable; after 12 days areas not showing activity previously begin to show activity. Thus, the genes controlling the expression of Amy are temporally acting. (2) Diet affects the quantitative, but not the qualitative, expression of Amy. (3) The expression of Amy in adult midguts is under genetic control. Selection for different frequencies of patterns is possible; realized heritabilities are 0.20 to 0.50. Partial linkage with third chromosome inversions has been demonstrated; the genes or elements controlling Amy expression are not, however, confined to the third chromosome. (4) The genetic elements controlling tissue-specific expression of amylase do not coordinately control the expression of five other "digestive-type" enzymes that were studied.--This polymorphism appears to be analogous to that studied by Abraham and Doane (1978) in D. melanogaster, wherein they have mapped regulatory genes.     

Effects of genotype and age on mixed-function oxidase activities in adult Drosophila melanogaster

The mixed-function oxidases that metabolize dimethylnitrosamine, aminopyrine, benzphetamine, 7-ethoxycoumarin and benzo[alpha]pyrene were measured in adults of the Canton-S, Oregon-R and Hikone-R strains of Drosophila melanogaster. The expression of these activities is both genotype and age dependent.     

Molecular evolution of the 5'-flanking regions of the duplicated Amy genes in Drosophila melanogaster species subgroup

The nucleotide sequences of the 5'-flanking regions of the duplicated Amy genes in eight sibling species belonging to the melanogaster species subgroup are analyzed. In Drosophila melanogaster, a region of about 450 bp immediately upstream of the translation initiation site of the two paralogous genes (the proximal and distal genes) has sequence similarities. However, we could not detect any significant sequence similarity in the region more upstream than -450. This result indicates that the coding regions of the ancestral Amy gene were duplicated together with 450 bp of the 5'-flanking region as one unit. Multiple alignment of these 450-bp sequences in the proximal and distal genes of all eight species revealed a mosaic pattern of highly conserved and divergent regions. The conserved regions included almost all the putative regulatory elements identified in previous analyses of the sequences. A phylogenetic analysis of the aligned sequences shows that these 450-bp sequences are clustered into the proximal and the distal groups. As a whole, the divergence between groups in this region is very large in contrast to that in the coding regions. Based on the divergence between groups, the 450-bp region is divided into two subregions. We found that the ratios of the divergence between groups to that within groups differ in the two subregions. From these observations, we discuss a possibility of positive selection acting on the subregion immediately upstream of the Amy coding region to cause divergence of regulatory elements of the paralogous genes.      

Short 5'-flanking regions of the Amy gene of Drosophila kikkawai affect amylase gene expression and respond to food environments

Evolution of the duplicated genes and regulation in gene expression is of great interest, especially in terms of adaptation. Molecular population genetic and evolutionary studies on the duplicated amylase genes of Drosophila species have suggested that their 5'-flanking (cis-regulatory) regions play an important role in evolution of these genes. For better understanding of evolution of the duplicated amylase genes and gene expression, we studied functional significance of the Amy1 gene of Drosophila kikkawai using in vitro deletion mutagenesis followed by P-element-mediated germline transformation. We found that a 1.6-kb of the 5'-flanking region can produce strikingly higher level of larval amylase activity on starch food compared with that on glucose food. We found two cis-regulatory elements, which increase larval amylase activity on starch food. We also found a larval cis-regulatory element, which responds to the food difference. This food-response element is necessary for the function of the element increasing larval activity on starch food. A 5-bp deletion in a putative GRE caused high amylase activity, indicating a cis-regulatory element decreasing amylase activity. These cis-regulatory elements identified in the 5'-flanking region could be the targets of natural selection.     

Complex interactions among members of an essential subfamily of hsp70 genes in Saccharomyces cerevisiae.

Saccharomyces cerevisiae contains a large family of genes related to hsp70, the major heat shock-inducible gene of Drosophila melanogaster. One subfamily, identified by sequence homology, contains four genes, SSA1, SSA2, SSA3, and SSA4 (formerly YG100, YG102, YG106, and YG107, respectively). Previous studies showed that strains containing mutations in SSA1 and SSA2 are temperature sensitive for growth. SSA4, which is normally heat inducible and not expressed during vegetative growth, is expressed at high levels in ssa1 ssa2 strains at 23 degrees C. We constructed mutations in SSA3 and SSA4 and analyzed strains carrying mutations in the four genes. Strains carrying mutations in SSA3 SSA4 or SSA3 and SSA4 were indistinguishable from the wild type. However, ssa1 ssa2 ssa4 strains were inviable. SSA3, like SSA4, is a heat-inducible gene that is not normally expressed at 23 degrees C. Nevertheless, an intact copy of SSA3 regulated by the constitutive SSA2 promoter was capable of rescuing a ssa1 ssa2 ssa4 strain. This indicates that SSA3 encodes a functional protein and that the SSA1, SSA2, SSA3, and SSA4 gene products are functionally similar.