GENETIC DIFFERENTIATION WITHIN THE MELANOGASTER SPECIES GROUP OF THE GENUS DROSOPHILA (SOPHOPHORA)

THE GENETICS OF ASYMMETRICAL MALE STERILITY IN DROSOPHILA MOJAVENSIS AND DROSOPHILA ARIZONENSIS HYBRIDS: INTERACTIONS BETWEEN THE Y-CHROMOSOME AND AUTOSOMES

Crosses between Drosophila mojavensis and D. arizonensis produce fertile females, but the males from the cross ♂ D. mojavensis × ♀ D. arizonensis are sterile. The chromosomal basis of sperm immotility was studied in these hybrids. Interspecific crossing-over was avoided by crossing hybrid males to pure-species females, and chromosomal identification in backcross progeny was possible by means of electrophoretic markers. The main findings are as follows. The Y-chromosome and two autosomes are involved in the determination of sperm motility. The other autosomes, with the exception of the sixth which was not tested, appear to have no effect. The effect of the D. arizonensis X-chromosome was not examined, but it is established that the D. mojavensis X-chromosome has no effect on sperm motility in males carrying the D. arizonensis Y-chromosome and any combination of autosomes. The Y-chromosome and the two autosomes interact with each other in a simple and predictable way, so that certain combinations of these chromosomes always produce motile sperm and others immotile sperm. Thus, asymmetrical male hybrid sterility may have a simple genetic basis. In contrast to ethological isolation, the genetic basis for this postmating isolating mechanism does not appear to vary among conspecific populations, an observation which suggests that postmating isolation antedates ethological isolation in these species.

THE ASSOCIATION BETWEEN THE POLYMORPHISMS AT THE Adh AND αGpdh LOCI AND THE In(2L)t INVERSION IN DROSOPHILA MELANOGASTER IN RELATION TO TEMPERATURE

Substantial allele-frequency changes were observed at the Adh and αGpdh loci in a seminatural population of Drosophila melanogaster kept in a tropical greenhouse during 1972-1985. Further analysis of the changes at the Adh and αGpdh loci showed that linkage disequilibrium between these loci occurred for a prolonged period due to the presence of In(2L)t, a long inversion on the left arm of the second chromosome. We observed increases in the frequencies of In(2L)t and of short inversions on the left arm of the second chromosome in subpopulations kept at 29.5°C or 33°C. These inversion-frequency increases were accompanied by an increase in Adh^s and a decrease in αGpdh^s frequency. In populations kept at 20°C and 25°C, inversion frequencies decreased, while αGpdh^s allele frequencies decreased at 25°C and increased at 20°C. At 33°C, egg-to-adult survival of individuals possessing In(2L)t, either in the homokaryotypic or the heterokaryotypic state, was higher than that of the other karyotypes of identical allozyme constitution (i.e., Adh^s αGpdh^F ). Thus it seems that In(2L)t has a selective advantage at high temperature. We argue that the observed changes in allele frequencies at the Adh and αGpdh loci are, in part, due to genic selection and are not merely the result of selection acting on the chromosome rearrangements and hitchhiking of the allozymes. The results are discussed with respect to the latitudinal clines found for In(2L)t, Adh, and αGpdh.

Misregulation of sex-lethal and disruption of male-specific lethal complex localization in Drosophila species hybrids

A major model system for the study of evolutionary divergence between closely related species has been the unisexual lethality resulting from reciprocal crosses of Drosophila melanogaster and D. simulans. Sex-lethal (Sxl), a critical gene for sex determination, is misregulated in these hybrids. In hybrid males from D. melanogaster mothers, there is an abnormal expression of Sxl and a failure of localization of the male-specific lethal (MSL) complex to the X chromosome, which causes changes in gene expression. Introduction of a Sxl mutation into this hybrid genotype will allow expression of the MSL complex but there is no sequestration to the X chromosome. Lethal hybrid rescue (Lhr), which allows hybrid males from this cross to survive, corrects the SXL and MSL defects. The reciprocal cross of D. simulans mothers by D. melanogaster males exhibits underexpression of Sxl in embryos.

Widespread discordance of gene trees with species tree in Drosophila: evidence for incomplete lineage sorting

The phylogenetic relationship of the now fully sequenced species Drosophila erecta and D. yakuba with respect to the D. melanogaster species complex has been a subject of controversy. All three possible groupings of the species have been reported in the past, though recent multi-gene studies suggest that D. erecta and D. yakuba are sister species. Using the whole genomes of each of these species as well as the four other fully sequenced species in the subgenus Sophophora, we set out to investigate the placement of D. erecta and D. yakuba in the D. melanogaster species group and to understand the cause of the past incongruence. Though we find that the phylogeny grouping D. erecta and D. yakuba together is the best supported, we also find widespread incongruence in nucleotide and amino acid substitutions, insertions and deletions, and gene trees. The time inferred to span the two key speciation events is short enough that under the coalescent model, the incongruence could be the result of incomplete lineage sorting. Consistent with the lineage-sorting hypothesis, substitutions supporting the same tree were spatially clustered. Support for the different trees was found to be linked to recombination such that adjacent genes support the same tree most often in regions of low recombination and substitutions supporting the same tree are most enriched roughly on the same scale as linkage disequilibrium, also consistent with lineage sorting. The incongruence was found to be statistically significant and robust to model and species choice. No systematic biases were found. We conclude that phylogenetic incongruence in the D. melanogaster species complex is the result, at least in part, of incomplete lineage sorting. Incomplete lineage sorting will likely cause phylogenetic incongruence in many comparative genomics datasets. Methods to infer the correct species tree, the history of every base in the genome, and comparative methods that control for and/or utilize this information will be valuable advancements for the field of comparative genomics.

To take full advantage of the growing number of genome sequences from different organisms, it is necessary to understand the evolutionary relationships (phylogeny) between organisms. Unfortunately, phylogenies inferred from individual genes often conflict, reflecting either poor inferences or real variation in the history of genes. In this study, the authors examine relationships within the Drosophila melanogaster species subgroup, a group of flies with three fully sequenced species in which phylogeny has been a source of controversy. Although the bulk of the data support a phylogeny with Drosophila melanogaster as an outgroup to sister species Drosophila erecta and Drosophila yakuba, large portions of their genes support alternative phylogenies. According to the authors, the most plausible explanation for these observations is that polymorphisms in the ancestral population were maintained during the two rapid speciation events that led to these species. Subsequent to speciation, polymorphisms were randomly fixed in each species, and in some cases non-sister species fixed the same ancestral polymorphisms, while sister species did not. In these cases the genes are correctly inferred to have conflicting phylogenies. The authors note that rapid speciation events will often lead to such conflict, which needs to be accounted for in evolutionary analyses.

Molecular phylogeny of the Drosophila melanogaster species subgroup

Although molecular and phenotypic evolution have been studied extensively in Drosophila melanogaster and its close relatives, phylogenetic relationships within the D. melanogaster species subgroup remain unresolved. In particular, recent molecular studies have not converged on the branching orders of the D. yakuba-D. teissieri and D. erecta-D. orena species pairs relative to the D. melanogaster-D. simulans-D. mauritiana-D. sechellia species complex. Here, we reconstruct the phylogeny of the melanogaster species subgroup using DNA sequence data from four nuclear genes. We have employed "vectorette PCR" to obtain sequence data for orthologous regions of the Alcohol dehydrogenase (Adh), Alcohol dehydrogenase related (Adhr), Glucose dehydrogenase (Gld), and rosy (ry) genes (totaling 7164 bp) from six melanogaster subgroup species (D. melanogaster, D. simulans, D. teissieri, D. yakuba, D. erecta, and D. orena) and three species from subgroups outside the melanogaster species subgroup [D. eugracilis (eugracilis subgroup), D. mimetica (suzukii subgroup), and D. lutescens (takahashii subgroup)]. Relationships within the D. simulans complex are not addressed. Phylogenetic analyses employing maximum parsimony, neighbor-joining, and maximum likelihood methods strongly support a D. yakuba-D. teissieri and D. erecta-D. orena clade within the melanogaster species subgroup. D. eugracilis is grouped closer to the melanogaster subgroup than a D. mimetica-D. lutescens clade. This tree topology is supported by reconstructions employing simple (single parameter) and more complex (nonreversible) substitution models.

The acid phosphatase-1 gene region in the Drosophila species of the subobscura cluster

The acid phosphatase-1 (Acph-1) gene region was sequenced in three species of Drosophila: D. subobscura, D. madeirensis and D. guanche. These three closely related species, which are included in the obscura group, form the subobscura cluster. The different functional regions of the gene were identified by similarity with the sequence of D. melanogaster. The structure of Acph-1 is conserved in the four species. Average divergence at synonymous and nonsynonymous sites between D. melanogaster and the species of the subobscura cluster is Ks = 1.1354 and Ka = 0.1743, respectively. The rather high Ka value confirms that ACPH-1 is a rapidly evolving enzyme in Drosophila, as previously suggested by immunological studies. Amino acid replacements are not randomly distributed along the gene. In fact, an excess of replacements is detected in exon I, indicating that the signal peptide encoded by this exon evolves even faster than the rest of the protein. Divergence at the Acph-1 gene region is further evidence that D. madeirensis and D. subobscura are more closely related than D. guanche is to any of them. In addition, both silent divergence in noncoding regions and synonymous divergence in the coding region indicate that the split of the D. guanche lineage is about twice as old as the split of the lineages leading to D. madeirensis and D. subobscura. These phylogenetic relationships are, however, not supported by divergence at nonsynonymous sites since the lowest Ka estimate is between D. guanche and D. subobscura.

Discrepancy in divergence of the mitochondrial and nuclear genomes of Drosophila teissieri and Drosophila yakuba

Restriction sites were compared in the mitochondrial DNA (mtDNA) molecules from representatives of two closely related species of fruit flies: nine strains of Drosophila teissieri and eight strains of Drosophila yakuba. Nucleotide diversities among D. teissieri strains and among D. yakuba strains were 0.07% and 0.03%, respectively, and the nucleotide distance between the species was 0.22%. Also determined was the nucleotide sequence of a 2305-nucleotide pair (ntp) segment of the mtDNA molecule of D. teissieri that contains the noncoding adenine + thymine (A + T)-rich region (1091 ntp) as well as the genes for the mitochondrial small-subunit rRNA, tRNA(f-met), tRNA(gln), and tRNA(ile), and portions of the ND2 and tRNA(Val) genes. This sequence differs from the corresponding segment of the D. yakuba mtDNA by base substitutions at 0.1% and 0.8% of the positions in the coding and noncoding regions, respectively. The higher divergence due to base substitutions in the A + T-rich region is accompanied by a greater number of insertions/deletions than in the coding regions. From alignment of the D. teissieri A + T-rich sequence with those of D. yakuba and Drosophila virilis, it appears that the 40% of this sequence that lies adjacent to the tRNA(ile) gene has been highly conserved. Divergence between the entire D. teissieri and D. yakuba mtDNA molecules, estimated from the sequences, was 0.3%; this value is close to the value (0.22%) obtained from the restriction analysis, but 10 times lower than the value estimated from published DNA hybridization results.(ABSTRACT TRUNCATED AT 250 WORDS)

Biochemical phylogeny of the eight species in the Drosophila melanogaster subgroup, including D. sechellia and D. orena

The phylogenetic relationships of the eight species of the Drosophila melanogaster subgroup are examined on the basis of genetic variation at 33 putative enzyme loci. Values of Nei's genetic distance (ds) range from 0·28 to 1·74. D. sechellia appears closer to D. simulans than to D. mauritiana, the two former being the most closely related. D. orena is quite distantly related to D. erecta (ds = 1). Genetic differentiation supports the existence of three main lineages within the melanogaster subgroup and the yakuba-teissieri pair appears to be closer to the melanogaster lineage than to the erecta-orena one. Inferences of the times of species divergence from allozyme data are made and their agreement to other estimates is discussed.

Amylase gene duplication: an ancestral trait in the Drosophila melanogaster species subgroup

Electrophoretic polymorphism of amylases was studied in 45 geographic populations of the two cosmopolitan sibling species, D. melanogaster and D. simulans, and in one to three populations or strains of six other species in the D. melanogaster subgroup. Two species, D. erecta and D. orena, for which only a few strains were available were monomorphic. In the other species 2 or 3 amylase variants were identified while in D. melanogaster, 12 electrophoretic variants were characterized. Altogether 17 different amylase isozymes have been observed. The contrast in the level of polymorphism between D. melanogaster and the other species cannot be explained simply by the occurrence of a duplication in the former species. Genetic analysis demonstrated the existence of a duplication in at least 4 other species, namely D. simulans, D. mauritiana, D. yakuba, and D. teissieri. It is therefore suggested that the duplication occurred in a common ancestor and the phylogenetic implications of these observations are discussed.

Contrasting patterns of geographic variation in the cosmopolitan sibling species Drosophila melanogaster and Drosophila simulans

An electrophoretic study was carried out to compare the geographic pattern of genetic variation in Drosophila simulans with that of its sibling species, Drosophila melanogaster. An identical set of 32 gene-protein loci was studied in four geographically distant populations of D. simulans and two populations of D. melanogaster, all originating from Europe and Africa. The comparison yielded the following results: tropical populations of D. simulans were, in terms of the number of unique alleles, average heterozygosity per locus, and percentage of loci polymorphic, more variable than conspecific-temperate populations; some loci in both species showed interpopulation differences in allele frequencies that suggest latitudinal clines; and temperate-tropical genetic differentiation between populations was much less in D. simulans than in D. melanogaster. Similar differences between these two species have previously been shown for chromosomal, quantitative, physiological, and middle-repetitive DNA variation. Estimates of Nm (number of migrants per generation) from the spatial distribution of rare alleles suggest that both species have similar levels of interpopulation gene flow. These observations lead us to propose two competing hypotheses: the low level of geographic differentiation in D. simulans is due to its evolutionarily recent worldwide colonization and, alternatively, D. simulans has a narrower niche than D. melanogaster. Geographic variation data on different genetic elements (e.g., mitochondrial DNA, two-dimensional proteins, etc.) are required before these hypotheses can be adequately tested.

Genomic blot hybridization as a tool of phylogenetic analysis: evolutionary divergence in the genus Drosophila

Comparative, quantitative Southern analysis of genomic DNA, using single-copy sequence probes, potentially is valuable for phylogenetic analysis. We have examined 27 Drosophila species, belonging to two subgenera, seven species groups, and ten subgroups, using a variety of cloned and characterized probes: twelve cloned sequences from D. melanogaster, two from D. pseudoobscura, and two from D. grimshawi. The data are generally congruent with accepted phylogenetic relationships in Drosophila, and confirm or clarify some previously uncertain relationships. The potential and limitations of the method are discussed.

Synthesis patterns of a set of follicle cell proteins in Drosophila melanogaster sibling species

The protein synthesis pattern of a set of stage and tissue specific proteins has previously been described in Drosophila melanogaster. The analysis of this set of follicle cell proteins (Fc proteins) is here extended to cover several sibling species of Drosophila melanogaster, namely D. simulans, D. mauritiana, D. erecta and D. yakuba. Even though a similar set of proteins were synthesized in these species, minor differences in size of the proteins were found between the species. Some of the species exhibited variation within species.

Mitochondrial DNA evolution in the melanogaster species subgroup of Drosophila

Detailed restriction maps (40 cleavage sites on average) of mitochondrial DNAs (mtDNAs) from the eight species of the melanogaster species subgroup of Drosophila were established. Comparison of the cleavage sites allowed us to build a phylogenetic tree based on the matrix of nucleotide distances and to select the most parsimonious network. The two methods led to similar results, which were compared with those in the literature obtained from nuclear characters. The three chromosomally homosequential species D. simulans, D. mauritiana, and D. sechellia are mitochondrially very related, but exhibit complex phylogenetic relationships. D. melanogaster is their closest relative, and the four species form a monophyletic group (the D. melanogaster complex), which is confirmed by the shared unusual length of their mt genomes (18-19 kb). The other four species of the subgroup (D. yakuba, D. teissieri, D. erecta, and D. orena) are characterized by a much shorter mt genome (16-16.5 kb). The monophyletic character of the D. yakuba complex, however, is questionable. Two species of this complex, D. yakuba and D. teissieri, are mitochondrially indistinguishable (at the level of our investigation) in spite of their noticeable allozymic and chromosomal divergence. Finally, mtDNA distances were compared with the nuclear-DNA distances thus far established. These sequences seem to evolve at rather similar rates, the mtDNA rate being barely double that of nuclear DNA.

Conservation and change in the DNA sequences coding for alcohol dehydrogenase in sibling species of Drosophila

The DNA sequences of the alcohol dehydrogenase (Adh) genes of four very closely related species of Drosophila show that the rates of nucleotide change vary greatly in different functional domains of this gene. A phylogeny of these species based on the Adh sequence data is consistent with that based on polytene chromosome banding patterns.

Genetic localization and sequential electrophoresis of glucose-6-phosphate dehydrogenase in Drosophila melanogaster

Studies were undertaken to investigate two critical aspects of the glucose-6-phosphate dehydrogenase polymorphism in Drosophila melanogaster. The first investigation unequivocally maps the genetic site of the G6PD locus to the X chromosome. The second study subjects a set of isochromosomal lines to sequential electrophoresis in an attempt to uncover common molecular heterogeneity within the global polymorphism, assuming that this variation may have gone undetected under conventional electrophoretic conditions. The genetic site was mapped following the segregation of the two common electrophoretic alleles, a so-called null allele, and two rare electrophoretic variants. From the pooled results, the Zw locus mapped to 62.9 on the X chromosome relative to the flanking markers car (at 62.5) and sw (at 64.7). A set of 126 iso-X chromosomal lines of diverse geographic origin was subjected to sequential electrophoresis under three different acrylamide conditions in addition to the conventional starch electrophoretic system. No additional variation beyond the common diallele polymorphism was seen.

Molecular drive: a cohesive mode of species evolution

It is generally accepted that mutations may become fixed in a population by natural selection and genetic drift. In the case of many families of genes and noncoding sequences, however, fixation of mutations within a population may proceed as a consequence of molecular mechanisms of turnover within the genome. These mechanisms can be both random and directional in activity. There are circumstances in which the unusual concerted pattern of fixation permits the establishment of biological novelty and species discontinuities in a manner not predicted by the classical genetics of natural selection and genetic drift.

Critical examination of postulated cladistic relationships among species of flour beetles (genus Tribolium, Tenebrionidae, Coleoptera)

Cytological considerations have led to the hypothesis that Tribolium confusum (CF) evolved from an ancestor similar to T. castaneum (CS) by translocation of an autosome to the X chromosome, and that T. destructor (DEST) was derived from CF. T. brevicornis (BREV) is regarded as the most primitive on morphological grounds. Electrophoretic analyses of 19 strains of CS, 7 of CF, and 1 each of DEST and BREV do not support this postulated evolutionary pathway. CF and CS are much more similar to BREV than they are to each other. (Comparisons of morphological mutations in CS and CF also indicate that the two species are not similar genetically.) DEST and CF are very dissimilar electrophoretically. It is likely that the species evolved independently from an ancestral stock which may be represented by BREV. Recognition of gene homology in different species is the keystone for all attempts at constructing genetically meaningful evolutionary pathways. The difficulties involved in doing so are pointed out.