EVOLUTIONARY GENETICS OF TWO SIBLING SPECIES,DROSOPHILA SIMULANS AND D. SECHELLIA

Drosophila simulans and D. sechellia are sibling species, the former cosmopolitan and the latter restricted to the Seychelles Islands. We used classical genetic analysis to measure the numbers and effects of genes responsible for reproductive isolation and morphological differences in male genitalia between these species. At least five loci are responsible for male sterility in hybrids, with the strongest effects produced by at least two genes on the X chromosome. At least three (and probably four) loci are responsible for the interspecific difference in the size of the posterior process of the male genital arch. These genetic results, as well as the pattern of morphological divergence between the species, show several parallels with the divergence between D. simulans and its other island relative, D. mauritiana. We also present the DNA sequence of a 4.5 kilobase region containing the alcohol dehydrogenase (Adh) locus of D. sechellia, and combine this with previous data to reconstruct the phylogenies of the three species and their more distant relative D. melanogaster. Both D. mauritiana and D. sechellia are very closely related to D. simulans. Although most phylogenies show the two island species to be independent offshoots of the D. simulans lineage (with D. sechellia the more recent), the branch points are too close to make this conclusion unambiguous. The genetic and evolutionary parallels between the simulans/mauritiana and the simulans/sechellia divergences may therefore represent either a striking evolutionary convergence or a close common ancestry of the island species. A comparison of Adh alleles within species shows that the divergence among them may be almost as large as among alleles from different species. We conclude that many of the nucleotide differences among these species actually represent polymorphisms within common ancestors. It may be difficult to build accurate phylogenies using only a single DNA sequence from each species.     

Gradual evolution of a specific satellite DNA family in Drosophila ambigua, D. tristis, and D. obscura

The highly repetitive satellite DNA family "ATOC180" is specific for the three closely related species Drosophila obscura, D. ambigua, and D. tristis but does not occur in their closest relatives D. subsilvestris and D. bifasciata. Approximately 10,000 copies/haploid genome of approximately 180-bp repetition units are tandemly arranged in the centromeric heterochromatin of all chromosomes of all three species. Molecular analysis of 29 cloned repeats shows much intra- and interspecific sequence homogeneity. Single nucleotide changes are the main source of variability and distinguish the sequence-, subfamily- and species-specific ATOC180 repeats from each other. Based on these nucleotide differences, phylogenetic dendrograms were constructed and compared with published trees for other traits. The data indicate that the sequences of the ATOC180 satellite DNA family probably arose in a phylogenetically "short period" during the anagenetic evolution of the common ancestor of D. obscura, D. tristis, and D. ambigua, as a consequence of a process of genome reorganization, followed by a "long period" of entirely gradual sequence evolution. For the latter period, an evolutionary rate of 3 x 10(-8) substitutions/site/year was calculated.      

MITOCHONDRIAL DNA PHYLOGENIES FOR THE DROSOPHILA OBSCURA GROUP

Species belonging to the obscura group of the genus Drosophila have long held a central position in evolutionary studies, especially in experimental population genetics. Despite the considerable amount of accumulated knowledge, many of the phylogenetic relationships of the species in the group remain unclear. Here we present DNA sequence data for the mitochondrial gene cytochrome oxidase I (COI) for 13 species native to both the Old and New Worlds. We combine these data with seven other mitochondrial gene sequences from previous studies, for a total of over 3 kb per species. Strongly supported conclusions include: (1) the two North American subgroups, pseudoobscura and affinis, are each monophyletic; and (2) among Eurasian species two unambiguous clades are identified, one containing D. tristis, D. ambigua, and D. obscura and the other containing D. guanche, D. subobscura, and D. madeirensis. Constructing firm hypotheses connecting these four major clades is problematic with all datasets. Major ambiguities are the number of invasions giving rise to the North American obscura species and the relationships among the Eurasian species. The inadequacy of the mtDNA data to resolve these ambiguities does not reside in lack of changes; the transversions-only parsimony tree has 283 informative characters. Rather, the problems are likely intrinsic to the history of the group: while radiating in temperate Eurasia, North America was colonized once or twice, followed by one or two radiations in the New World.     

The Adh in Drosophila: Chromosomal location and restriction analysis in species with different phylogenetic relationships

Restriction analysis of the genomic region containing the Adh gene and in situ hybridization assays were performed in six Drosophila species belonging to three different subgenera: D. ambigua, D. subobscura, D. madeirensis and D. guanche (sg. Sophophora); D. immigrans (sg. Drosophila); and D. lebanonensis (sg. Pholadoris). In agreement with previous observations, comparison of restriction maps of the Adh region shows that D. subobscura and D. madeirensis are very closely related. Partial homology is also observed with the rest of the obscura group species. Nevertheless, no resemblance at the restriction map level is detected when more distantly related species are compared. In D. ambigua, D. immigrans and D. lebanonensis in situ hybridization assays reveal a single chromosomal location for Adh, which in D. lebanonensis appears to be sex linked. In contrast, in D. subobscura, D. madeirensis and D. guanche multiple sites of hybridization with homologous and heterologous probes are observed. For example, in D. subobscura and D. madeirensis the functional Adh gene is located on the U chromosome and additional homologous retrosequences are found on the E chromosome.by H. Jäckle     

Satellite DNA and speciation: A species specific satellite DNA of Drosophila guanchel

The heterochromatin of the chromosomes of Drosophila gunche consists mainly of a satellite DNA composed of multiple, tandemly arranged copies of a 290 b p basic sequence. Five clones containing one or two copies of the basic unit were sequenced. As expected from CsCl density centrifugation and AT specific staining of mitotic chromosomes the sequence is AT rich. The average nucleotid variability between the cloned sequences is 11.6%. In situ hybridization on the mitotic chromosomes revealed, that this satellite DNA is present in the centromeric regions of all chromosomes but the Y. The nucleotide variability between copies of different tandem clusters seems to be higher than between members of the same cluster. The copy number of the sequence in the haploid genome was estimated to be approximately 80000. The sequence is species specific and is not present in the genome of sibling species D. subobscura and D. madeiren-sis. The evolutionary origin of the satellite DNA and its possible role in species formation is discussed.     

A species specific satellite DNA family of Drosophila subsilvestris appearing predominantly in B chromosomes

This paper describes a species specific satellite DNA family (pSsP216) of Drosophila subsilvestris, a palearctic species of the D. obscura group. The pSsP216 family consists of tandemly arranged 216 bp repetitive units that are predominantly localized on B chromosomes. These chromosomes appear in variable numbers in the karyotype of this species. Some pSsP216 repeats can also be detected in the centromeric heterochromatin of the acrocentric A chromosomes. Two strains, one with and the other without B chromosomes, were investigated for sequence variability and for the location of this satellite DNA on the chromosomes. Among 16 clones of the 216 bp basic repeat unit an overall similarity of about 93% and no strain specific differences were found, indicating that the B chromosomes may have derived from the A chromosomes (probably the dots) by spontaneous amplification of the pSsP216 satellite DNA family.     

TheAdh genomic region ofDrosophila ambigua: Evolutionary trends in different species

Summary The study of individual genes is essential to a comprehensive understanding of genome evolution. The wealth of information on alcohol dehydrogenase (Adh) inDrosophila makes this gene particularly suitable for such analysis. We have characterized more than 4 kb of the genomicAdh region inDrosophila ambigua and compared this region toDrosophila mauritiana andDrosophila pseudoobscura. The presence of two genes,Adh and 3ORF (open reading frame), has been confirmed and some of their essential features have been inferred from primary structural analysis. Inter- and intraspecific comparisons have led us to support that both genes may have diverged from an ancient precursor. They appear to be evolving independently, and show a species-specific pattern. TheAdh in theobscura group species lacks amino acids three and four when compared to the species of themelanogaster group and has accumulated most of its amino acid replacements in the third exon. Neither characteristic is observed when any other group species are compared, which suggests that these may be particular features of the evolution of theobscura group. The 3ORF is highly conserved among the three species analyzed, although variability in the length of the third exon and the nucleotide substitution rate, which is much higher than inAdh, are worth noting. According to our data, both mutation/fixation rates and the distribution of mutations vary over time, which makes it difficult to predict the evolutionary dynamics of specific genome regions.     

Differential homogenization and amplification of two satellite DNAs in the genus Cucurbita (Cucurbitaceae)

Two different satellite DNAs exist in the genus Cucurbita which are different with respect to repeat length (350 by and 170 bp), array size, and sequence homogenization. Whereas the 350-bp satellite DNA is prominent and very homogeneous in all species investigated except for C. maxima and C. lundelliana, the 170-bp satellite is rather evenly distributed in all species. In C. maxima and C. lundelliana the 350-bp satellite is present only in small amounts, but detectable by the sensitive PCR method. These repeats are also very homogeneous, reflecting a silent stage of satellite DNA. In contrast, the 170-bp satellite DNA is intra- and interspecifically heterogeneous. It is striking that the species with no detectable amount of 350-bp satellite contain 170-bp satellite DNA clusters with the highest degree of homogeneity. The evolution of satellite DNA repeats within cultivated and wild species in the genus Cucurbita is elucidated using the sequence data of both satellite DNAs from all species investigated. The value of satellite DNA for phylogenetic analysis between closely related species is discussed. Correspondence to: V. Hemleben     

DNA Barcodes indicate members of the Anopheles fluviatilis (Diptera: Culicidae) species complex to be conspecific in India

Anopheles fluviatilis, a major vector of malaria in India has been described as a complex of three sibling species members, named as S, T and U, based on variations in chromosomal inversions. Also, ribosomal DNA markers (repetitive Internal Transcribed Spacer 2 (ITS2) and 28S D3 region) were described to differentiate these three sibling species members. However, controversies prevail on the genetic isolation status of these cryptic species. Hence, we evaluated this taxonomic incongruence employing DNA barcoding, the well established methodology for species identification, using 60 An. fluviatilis sensu lato specimens, collected from two malaria endemic eastern states of India. These specimens were also subjected to sibling species characterization by ITS2 and D3 DNA markers. The former marker identified 31 specimens among these as An. fluviatilis S and 21 as An. fluviatilis T. Eight specimens amplified DNA fragments specific for both S and T. The D3 marker characterized 39 specimens belonging to species S and 21 to species T. Neither marker identified species U. Neighbor Joining analysis of mitochondrial cytochrome c oxidase gene 1 sequences (the DNA barcode) categorized all the 60 specimens into a single operational taxonomic unit, their Kimura 2 parameter (K2P) genetic variability being only 0.8%. The genetic differentiation (F_ST) and gene flow (N_m) estimates were 0.00799 and 62.07, respectively, indicating these two ‘species’ (S & T) as genetically con‐specific intermixing populations with negligible genetic differentiation. Earlier investigations have refuted the existence of species U. Also, this study demonstrated that An. fluviatilis and the closely related An. minimus could be taxonomically differentiated by the DNA Barcode approach (K2P = 5.0%).     

Adh Nucleotide Variation in Drosophila willistoni: High Replacement Polymorphism in an Electrophoretically Monomorphic Protein

Drosophila willistoni was the subject of intensive allozyme studies and the locus coding for alcohol dehydrogenase (Adh) was found to be virtually monomorphic. DNA sequence analysis of 18 alleles throughout the distribution of the species has revealed six replacement polymorphisms. The ratio of replacement to silent polymorphisms is higher in D. willistoni than in any other Drosophila species studied for Adh nucleotide variation. Also in contrast to other species, the variation in introns and noncoding DNA is about the same as in the coding region. We speculate that both these differences indicate D. willistoni has historically had a small population size possibly related to Pleistocene refugia in the Neotropics. Received: 5 August 1996 / Accepted: 12 April 1997     

A Concertedly Evolving Region in Chironomus, Unique Within the Telomere

Chromosome terminal, complex repeats in the dipteran Chironomus pallidivittatus show rapid concerted evolution during which there is remarkably efficient homogenization of the repeat units within and between chromosome ends. It has been shown previously that gene conversion is likely to be an important component during these changes. The sequence evolution could be a result of different processes—exchanges between repeats in the tandem array as well as information transfer between units in different chromosomes—and is therefore difficult to analyze in detail. In this study the concerted evolution of a region present only once per chromosome, at the junction between the telomeric complex repeats and the subtelomeric DNA was therefore investigated in the two sibling species C. pallidivittatus and C. tentans. Material from individual microdissected chromosome ends was used, as well as clones from bulk genomic DNA. On the telomeric side of the border pronounced species-specific sequence differences were observed, the patterns being similar for clones of different origin within each species. Mutations had been transmitted efficiently between chromosomes also when adjoining, more distally localized DNA showed great differences in sequence, suggesting that gene conversion had taken place. The evolving telomeric region bordered proximally to subtelomeric DNA with high evolutionary constancy. More proximally localized, subtelomeric DNA evolved more rapidly and showed heterogeneity between species and chromosomes. Received: 24 September 1997 / Accepted: 24 November 1997     

Insertion and amplification of a DNA sequence in satellite DNA of Cucumis sativus L. (cucumber)

Summary Another satellite DNA repeat (type IV) in the genome of Cucumis sativus (cucumber) was found and investigated with respect to DNA sequence, methylation, and evolution. This satellite shows a repeat length of 360 bp and a GC-content of 47%. The repeats of type IV are highly conserved among each other. Evidence for CG and CNG methylation is presented. By comparison to the previously described satellites (type I/II and type III) from cucumber, it is evident that this repeat is created by an insertion of a 180 bp DNA sequence similar to type I–III into another DNA sequence (or vice versa), and subsequent amplification forming a new satellite repeat. The different satellites of the type I/II, type III, and the 180 bp insert of type IV show a sequence homology of 60%–70%, indicating that the complex satellite DNA of cucumber is originated from a common progenitor by mutation, additional insertion, and amplification events. Copies of a sequence similar to a part of type IV are present in the genome of the related species Cucumis melo (melon).     

A MOLECULAR PHYLOGENY OF THE DROSOPHILA WILLISTONI GROUP: CONFLICTS BETWEEN SPECIES CONCEPTS?

The six sibling species of the Neotropical Drosophila willistoni group have a long history in studies of evolutionary biology, yet to date only one molecular study, which used allozymes, has been published on the phylogeny of the group. Here we present a phylogeny of the siblings based on the sequences of two nuclear genes, period (per) and Alcohol dehydrogenase (Adh), as well as the mitochondrial gene Cytochrome oxidase I (COI). Taken individually, only per has a strong phylogenetic signal supporting a well-resolved phylogeny of the group, and this phylogeny is different from that obtained using allozymes. The COI dataset by itself produces trees that disagree with per, and neither that data nor the Adh data have a strong phylogenetic signal, as indicated by low bootstrap values for all analyses. Combining the Adh and COI datasets results in the same tree as per alone. Combining all three genes results in the same topology, which is strongly supported. Two problematic taxa, D. pavlovskiana and a “Carmody strain,” which were identified as potentially separate species based on reproductive isolation, clearly cluster in the phylogenetic analyses within D. paulistorum and D. equinoxialis, respectively. Thus, there appears to be a conflict between the biological species concept and the phylogenetic species concept.     

Identification and comparisons of the yolk polypeptides and the genes which code for them in D. melanogaster sibling species

Summary The yolk proteins stored in Drosophila, oocytes for utilisation during embryogenesis are an ideal system for studying the regulation of gene expression during development. The 3 major polypeptides found in yolk in D. melanogaster are synthesised in the fat body and ovarian follicle cells and selectively accumulated by the oocyte during vitellogenesis. In order to understand more about their regulation and the mechanism of uptake, studies on other species are necessary.Three yolk polypeptides have previously been identified in the D. melanogaster sibling species (D. melanogaster, D. simulans, D. mauritiana, D. erecta, D. teissieri, D. orena and D. yakuba). In D. melanogaster three genes located on the X chromosome are known to code for these yolk polypeptides. in this study genomic Southern transfers and in situ hybridisation experiments were carried out on the sibling species. Using the three cloned yolk protein genes from D. melanogaster, homologous sequences could be detected in the sibling species. It is suggested that three yolk protein genes occur in each of these species, all being located on the X chromosome, and that two of the genes are very closely linked in these same species. Yolk protein gene-homologous DNA sequences have also been identified in two more distantly related species D. funebris and D. virilis.     

Allelic variation,fragment length analyses and population genetic models: a case study on Drosophila microsatellites*

The allelic variation of 16 microsatellite loci from selected species of the Drosophila melanogaster and D. obscura group was determined. Intra‐ and interspecific sequence comparisons allowed discrimination of mutations affecting the repetitive microsatellite from those affecting the flanking regions. The hypotheses that slippage needs a minimum number of repeats in order to become efficient with respect to microsatellite variability, and of an increased mutation rate with increased length of the microsatellite are supported by the results of our analyses. There is in particular at the interrupted complex microsatellite locus BICOID in the species of the D. obscura group, extensive variation in the flanking regions in addition to length and sequence variation of the repetitive microsatellite. The allelic variation at this locus can hardly be explained by slippage alone. Estimates of microsatellite variability by fragment length analyses will pick up only a minor fraction of allelic variation at such loci, and conclusions that are based on the stepwise mutation model will not hold.     

Mitochondrial DNA evolution in theobscura species subgroup ofDrosophila

Summary Mitochondrial DNA (mtDNA) restriction site maps for nine species of theDrosophila obscura subgroup and forDrosophila melanogaster were established. Taking into account all restriction enzymes (12) and strains (45) analyzed, a total of 105 different sites were detected, which corresponds to a sample of 3.49% of the mtDNA genome. Based on nucleotide divergences, two phylogenetic trees were constructed assuming either constant or variable rates of evolution. Both methods led to the same relationships. Five differentiated clusters were found for theobscura subgroup species, one Nearctic, represented byDrosophila pseudoobscura, and four Palearctic, two grouping the related triads of speciesDrosophila subobscura, Drosophila madeirensis, Drosophila guanche, andDrosophila ambigua, Drosophila obscura, Drosophila subsilvestris, and two more represented by one species each,Drosophila bifasciata, andDrosophila tristis. The different Palearctic clusters are as distant between themselves as with the Nearctic one. For the related speciesD. subobscura, D. madeirensis, andD. guanche, the pairD. subobscura-D. madeirensis is the closest one. The relationships found by nucleotide divergence were confirmed by differences in mitochondrial genome size, with related species sharing similar genome lengths and differing from the distant ones. The total mtDNA size range for theobscura subgroup species was from 15.5 kb forD. pseudoobscura to 17.1 forD. tristis.     

Evolution of DNA in Heterochromatin: the Drosophila Melanogaster Sibling Species Subgroup as a Resource

The Drosophila melanogasterspecies subgroup is a closely-knit collection of eight sibling species whose relationships are well defined. These species are too close for most evolutionary studies of euchromatic genes but are ideal to investigate the major changes that occur to DNA in heterochromatin over short periods during evolution. For example, it is not known whether the locations of genes in heterochromatin are conserved over this time. The 18S and 28S ribosomal RNA genes can be considered as genuine heterochromatic genes. In D. melanogasterthe rRNA genes are located at two sites, one each on the X and Y chromosome. In the other seven sibling species, rRNA genes are also located on the sex chromosomes but the positions often vary significantly, particularly on the Y. Furthermore, rDNA has been lost from the Y chromosome of both D. simulansand D. sechellia, presumably after separation of the line leading to present-day D. mauritiana.We conclude that changes to chromosomal position and copy number of rDNA arrays occur over much shorter evolutionary timespans than previously thought. In these respects the rDNA behaves more like the tandemly repeated satellite DNAs than euchromatic genes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Detection of satellite DNA in Palorus ratzeburgii: Analysis of curvature profiles and comparison with Tenebrio molitor satellite DNA

Very abundant and homogenous satellite DNA has been found in the flour beetle Palorus ratzeburgii, representing 40% of its genome. Sequencing of 14 randomly cloned satelite monomers revealed a conserved monomer length of 142 bp and an average A+T content of 68%. Sequence variation analysis showed that base substitutions, appearing with a frequency of 2.3%, are predominant differences among satellite monomers. The satellite sequence is unique without significant direct repeats and with only two potentially stable inverted repeats. After electrophoresis of satellite monomers on native polyacrylamide gel retarded mobilities characteristic for curved DNA molecules are observed. The curvature profiles and DNA helix axis trajectory are calculated on the basis of three different algorithms. These calculations predict that P ratzeburgii satellite DNA forms a left-handed solenoid superstructure. Comparison of described features with other satellite DNAs reveals some striking similarities with satellite DNA from related species Tenebrio molitor, which belongs to the same family of Tenebrionidae. Both satellites are very abundant and homogenous with the same, highly conserved monomer length, although there is no homology at the nucleotide level. Their monomers, as well as multimers, exhibit very similar retarded electrophoretic mobilities. The calculated curvature profiles predict two bend centers in monomers of each satellite, resulting in a model of left-handed solenoid superstructures of similar appearance.     

DNA content in nine species of Nematocera with special reference to the sibling species of the Anopheles maculipennis group and the Culex pipiens group

DNA values were determined for the nine species: Telmatoscopus meridionalis (family Psychodidae), Dixa obscura (family Dixidae), and Culiseta litorea, Culex pipiens, Aedes caspius, Anopheles labranchiae, Anopheles atroparvus, Anopheles stephensi, and Anopheles freeborni (family Culicidae). The DNA content indicated that the species could be divided into three categories: The Culex group with Culex pipiens, Culiseta litorea and Aedes caspius containing 1.02, 0.92 and 0.99 pg DNA in the haploid set, the Anopheles group including the four Anopheles species A. labranchiae, A. atroparvus, A. stephensi, A. freeborni and Telmatoscopus meridionalis with 0.23, 0.24, 0.24, 0.29 and 0.24 pg DNA and the third group with Dixa obscura containing 0.16 pg DNA. Within the sibling species of the Anopheles maculipennis group DNA differences were found to be present between the palaearctic and the nearctic populations. No deviations could be found between two Culex pipiens populations which were reproductively isolated.This work was supported by a grant of the Volkswagenstiftung (Germany) and by grant No. 70.1146.04 from C.N.R. (Italian Centre of Researches).