Local adaptation for body color in Drosophila americana.

Pigmentation is one of the most variable traits within and between Drosophila species. Much of this diversity appears to be adaptive, with environmental factors often invoked as selective forces. Here, we describe the geographic structure of pigmentation in Drosophila americana and evaluate the hypothesis that it is a locally adapted trait. Body pigmentation was quantified using digital images and spectrometry in up to 10 flies from each of 93 isofemale lines collected from 17 locations across the United States and found to correlate most strongly with longitude. Sequence variation at putatively neutral loci showed no evidence of population structure and was inconsistent with an isolation-by-distance model, suggesting that the pigmentation cline exists despite extensive gene flow throughout the species range, and is most likely the product of natural selection. In all other Drosophila species examined to date, dark pigmentation is associated with arid habitats; however, in D. americana, the darkest flies were collected from the most humid regions. To investigate this relationship further, we examined desiccation resistance attributable to an allele that darkens pigmentation in D. americana. We found no significant effect of pigmentation on desiccation resistance in this experiment, suggesting that pigmentation and desiccation resistance are not unequivocally linked in all Drosophila species.

Mobile male-killer: similar Wolbachia strains kill males of divergent Drosophila hosts.

Wolbachia are capable of eliciting a variety of reproductive phenotypes from their hosts, including the production of an all-female progeny through embryonic male-killing. To date, phylogenetic analyses indicate six independent acquisitions of the ability to kill male embryos among Wolbachia strains which infect insects. Of these six strains, only one appears to have experienced horizontal transmission between host species while maintaining a male-killing phenotype. The rarity of male-killing Wolbachia and their disjunct phylogenetic relationships is surprising, given the apparently common occurrence of horizontal transfer involving Wolbachia strains causing other phenotypes. A male-killing Wolbachia strain examined here in Drosophila borealis represents a second case of apparent horizontal transmission, based on its close relationship to a male-killing strain in a distantly related Drosophila species. The results reported here show that this Wolbachia has maintained a stable phenotype in D. borealis over a period of at least 50 years, and that a similar strain elicits the same male-killing phenotype in a second Drosophila species, indicating that male-killing may be a stable long-term strategy. Sampling bias and/or a lack of suitable hosts are discussed as possible causes of the low frequency of male-killers identified among Wolbachia strains.

Patterns of microsatellite variation through a transition zone of a chromosomal cline in Drosophila americana.

Chromosomal rearrangements have been considered as important barriers to gene flow and were often used in the delineation of species. The original taxonomic designation of Drosophila americana americana and Drosophila americana texana is based on the presence/absence of a centric fusion between the X- and fourth chromosomes. D. a. americana presents the derived fused state, whereas Drosophila a. texana presents the freely segregating ancestral state. The degree of genetic separation between the two chromosomal forms is still controversial, with different genetic markers yielding contrasting results even when the same populations were analyzed. Using 27 polymorphic microsatellites, we re-evaluated patterns of genetic differentiation between six D. americana populations sampled through a transition zone of both chromosomal forms in the central United States. Our results clearly reject a scenario of two differentiated species forming a hybrid zone in a region of parapatry and indicate that gene flow minimizes genome-wide differentiation associated with the two chromosomal arrangements.

Mapping of paternal-sex-ratio deletion chromosomes localizes multiple regions involved in expression and transmission.

The paternal-sex-ratio (PSR) chromosome in the parasitic wasp Nasonia vitripennis is a submetacentric supernumerary (B chromosome). Males transmit PSR, but after fertilization it causes the loss of the paternal autosomes. Paternal genome loss caused by PSR results in the conversion of a female (diploid) zygote into a male (haploid) under haplodiploid sex determination. In this study, site-specific markers were developed to assay deletion derivatives of PSR. Both polymerase chain reaction and Southern hybridization were used to detect the presence/absence of 16 single-site markers on a set of 20 functional and nine nonfunctional deletion chromosomes. Based on the pattern of marker loss on the deletion chromosomes, the basic organization of PSR was revealed. Two sets of markers were deleted independently, apparently representing the two arms of the submetacentric chromosome. The presence or absence of specific regions was examined in relation to phenotypic characteristics of the deletion chromosomes; ability to cause paternal genome loss, and stability in mitotic cell divisions. Rather than identifying a single region on PSR as being responsible for PSR function, the results suggest that the retention of one of two chromosomal regions is sufficient for causing paternal genome loss. Furthermore, a region was identified that is tightly correlated with mitotic stability, as measured from chromosomal transmission rates. Functional chromosomes with short-arm deletions had high (approximately 100%) transmission rates, whereas functional chromosomes with long-arm deletions had low (approximately 85%) transmission rates.

Evidence for selection at the fused1 locus of Drosophila americana.

We analyze genetic variation at fused1, a locus that is close to the centromere of the X chromosome-autosome (X/4) fusion in Drosophila americana. In contrast to other X-linked and autosomal genes, for which a lack of population subdivision in D. americana has been observed at the DNA level, we find strong haplotype structure associated with the alternative chromosomal arrangements. There are several derived fixed differences at fused1 (including one amino acid replacement) between two haplotype classes of this locus. From these results, we obtain an estimate of an age of approximately 0.61 million years for the origin of the two haplotypes of the fused1 gene. Haplotypes associated with the X/4 fusion have less DNA sequence variation at fused1 than haplotypes associated with the ancestral chromosome arrangement. The X/4 haplotypes also exhibit clinal variation for the allele frequencies of the three most common amino acid replacement polymorphisms, but not for adjacent silent polymorphisms. These patterns of variation are best explained as a result of selection acting on amino acid substitutions, with geographic variation in selection pressures.

Neutral evolution of the sex-determining gene transformer in Drosophila.

The amino acid sequence of the transformer (tra) gene exhibits an extremely rapid rate of evolution among Drosophila species, although the gene performs a critical step in sex determination. These changes in amino acid sequence are the result of either natural selection or neutral evolution. To differentiate between selective and neutral causes of this evolutionary change, analyses of both intraspecific and interspecific patterns of molecular evolution of tra gene sequences are presented. Sequences of 31 tra alleles were obtained from Drosophila americana. Many replacement and silent nucleotide variants are present among the alleles; however, the distribution of this sequence variation is consistent with neutral evolution. Sequence evolution was also examined among six species representative of the genus Drosophila. For most lineages and most regions of the gene, both silent and replacement substitutions have accumulated in a constant, clock-like manner. In exon 3 of D. virilis and D. americana we find evidence for an elevated rate of nonsynonymous substitution, but no statistical support for a greater rate of nonsynonymous relative to synonymous substitutions. Both levels of analysis of the tra sequence suggest that, although the gene is evolving at a rapid pace, these changes are neutral in function.

Reduced sequence variability on the Neo-Y chromosome of Drosophila americana americana.

Sex chromosomes are generally morphologically and functionally distinct, but the evolutionary forces that cause this differentiation are poorly understood. Drosophila americana americana was used in this study to examine one aspect of sex chromosome evolution, the degeneration of nonrecombining Y chromosomes. The primary X chromosome of D. a. americana is fused with a chromosomal element that was ancestrally an autosome, causing this homologous chromosomal pair to segregate with the sex chromosomes. Sequence variation at the Alcohol Dehydrogenase (Adh) gene was used to determine the pattern of nucleotide variation on the neo-sex chromosomes in natural populations. Sequences of Adh were obtained for neo-X and neo-Y chromosomes of D. a. americana, and for Adh of D. a. texana, in which it is autosomal. No significant sequence differentiation is present between the neo-X and neo-Y chromosomes of D. a. americana or the autosomes of D. a. texana. There is a significantly lower level of sequence diversity on the neo-Y chromosome relative to the neo-X in D. a. americana. This reduction in variability on the neo-Y does not appear to have resulted from a selective sweep. Coalescent simulations of the evolutionary transition of an autosome into a Y chromosome indicate there may be a low level of recombination between the neo-X and neo-Y alleles of Adh and that the effective population size of this chromosome may have been reduced below the expected value of 25% of the autosomal effective size, possibly because of the effects of background selection or sexual selection.

Evolution of tandemly repeated sequences: What happens at the end of an array?

Tandemly repeated sequences are a major component of the eukaryotic genome. Although the general characteristics of tandem repeats have been well documented, the processes involved in their origin and maintenance remain unknown. In this study, a region on the paternal sex ratio (PSR) chromosome was analyzed to investigate the mechanisms of tandem repeat evolution. The region contains a junction between a tandem array of PSR2 repeats and a copy of the retrotransposon NATE, with other dispersed repeats (putative mobile elements) on the other side of the element. Little similarity was detected between the sequence of PSR2 and the region of NATE flanking the array, indicating that the PSR2 repeat did not originate from the underlying NATE sequence. However, a short region of sequence similarity (11/15 bp) and an inverted region of sequence identity (8 bp) are present on either side of the junction. These short sequences may have facilitated nonhomologous recombination between NATE and PSR2, resulting in the formation of the junction. Adjacent to the junction, the three most terminal repeats in the PSR2 array exhibited a higher sequence divergence relative to internal repeats, which is consistent with a theoretical prediction of the unequal exchange model for tandem repeat evolution. Other NATE insertion sites were characterized which show proximity to both tandem repeats and complex DNAs containing additional dispersed repeats. An "accretion model" is proposed to account for this association by the accumulation of mobile elements at the ends of tandem arrays and into "islands" within arrays. Mobile elements inserting into arrays will tend to migrate into islands and to array ends, due to the turnover in the number of intervening repeats.

Hybrid origin of a B chromosome (PSR) in the parasitic wasp Nasonia vitripennis.

Little is known about the origin and evolution of supernumerary (B) chromosomes. This study utilizes molecular markers to examine the evolutionary history and microstructural organization of the supernumerary paternal-sex-ratio (PSR) chromosome of the parasitic wasp Nasonia vitripennis. Copies of the retrotransposon NATE were previously isolated from PSR and the genomes of N. vitripennis and related wasp species. A phylogenetic analysis of sequences representing 29 elements from PSR and seven wasp species, coupled with a hybridization analysis of elements in genomic DNA provides evidence that PSR was recently transferred into N. vitripennis from a species in the genus Trichomalopsis. A linear region of the PSR chromosome was compared by Southern blot analysis with genomic DNA from N. vitripennis, Nasonia longicornis, Trichomalopsis americanus, and Trichomalopsis dubius. A region organized similarly to the region on PSR was not evident in any of the species, thus a progenitor region was not identified. However, the hybridizations revealed that this region of PSR is primarily composed of repetitive sequences that appear dispersed in these wasp genomes, and might represent additional mobile elements. At least three different dispersed repeats are present in the 18 kb region of PSR. The abundance of tandem and dispersed repetitive sequences in this relatively small region provides additional evidence for the degenerate structure of the PSR chromosome.

How common are common fragile sites: variation of aphidicolin-induced chromosomal fragile sites in a population of the deer mouse (Peromyscus maniculatus).

Aphidicolin (APC)-induced chromosomal gaps and breaks were analyzed for ten deer mice (Peromyscus maniculatus) from a natural population. The FSM statistical methodology was used to identify fragile sites as chromosomal loci exhibiting significantly non-random numbers of gaps/breaks in each individual and enabled an assessment of variation in fragile sites among the individuals. The individual deer mice exhibited as few as 7 to as many as 19 of the populational total of 34 sites. Two sites were fragile in all individuals and 13 sites were fragile in single individuals only. Defined by populational frequencies of greater than 50%, high-frequency fragile sites constituted 26% of the populational total. Approximately 35% of the total fragile sites were fragile in 20-40% of the population (low-frequency fragile sites) and about 38% were fragile in single individuals only. Analysis of the data pooled over all individuals identified significantly non-random breakage at 80 sites, 47 of which were not identified as fragile in any single individual. It appears, therefore, that fragile site identifications from pooled data have fostered an inflated estimate of the numbers and frequencies of common fragile sites. Comparison of the fragile site and spontaneous breakage (control) data suggest that APC-induced fragile sites represent regions of chromosomes that experience elevated levels of somatic mutation. Additionally, the occurrence of APC-induced fragile sites at or near the interstitial breakpoints of two pericentric-inversion polymorphisms in this population supports the hypothesis that fragile sites experience an increased rate of meiotic chromosomal mutation and are predisposed to undergo phylogenetic rearrangement.

Phylogenetic analysis of a retrotransposon with implications for strong evolutionary constraints on reverse transcriptase.

This study examines the evolutionary dynamics of a retrotransposon in a group of parasitoid wasps. A region containing the reverse transcriptase (RT) domain was sequenced for 43 elements from the genomes of nine different wasp species. Phylogenetic analysis of the elements revealed concordance with taxonomic classification of the host species, and the pattern was consistent with that expected for vertical transmission of a multicopy element during differentiation of the species. Twenty-three of the 43 elements had comparable intact open reading frames in the amplified region, and these were used in an analysis of evolutionary constraint on the amino acid sequence. As previously documented for retroelements, closely related elements exhibited nearly equal substitution rates at nonsynonymous and synonymous sites, but relative nonsynonymous substitution rates decreased as increasingly divergent elements were compared. A statistical test indicated that the decrease was not due to saturation of weakly selected sites. The pattern is most likely caused by a "pseudogene effect." Individual elements are not subject to purifying selection, and therefore, synonymous and nonsynonymous substitutions accumulate at equal rates. Comparisons among closely related elements are influenced strongly by this pseudogene evolution, whereas comparisons among distantly related elements reveal selection on the actively replicating lineages connecting the elements. These distant comparisons more accurately reflect the constraints on the amino acid sequence, and the comparisons among elements in this study indicated strong constraints on RT.

Isolation and characterization of a retroelement from B chromosome (PSR) in the parasitic wasp Nasonia vitripennis.

Molecular characterization of the paternal-sex-ratio (PSR) chromosome in Nasonia vitripennis (Hymenoptera: Pteromalidae) has led to the isolation of a dispersed repetitive element. The element is a LTR-containing retrotransposon which has been named NATE (NAsonia Transposable Element). NATE has direct terminal repeats and has an internal amino acid sequence similar to reverse transcriptases of other retroelements. Phylogenetic analysis indicates NATE is a member of the Gypsy/Ty3 group of retrotransposons, and represents the first isolated from Hymenoptera. Five closely related copies of NATE were isolated from the PSR chromosome, but cross-hybridizing elements were not detected on the autosomes of N. vitripennis. Strongly cross-hybridizing elements were, however, detected in two other Nasonia species. This observed distribution of NATE is interesting, because the supernumerary PSR chromosome may be derived from the genome of a sibling species of N. vitripennis.

Identifying chromosomal fragile sites from individuals: a multinomial statistical model.

The inability to identify fragile sites from data for single individuals remains the major obstacle to determining whether these chromosomal loci are predisposed to cancer-causing and evolutionary rearrangements. We describe a novel statistical model that is amenable to data from single individuals and that establishes site-specific chromosomal breakage as nonrandom with respect to the distribution of total breakage. Our method tests incrementally smaller subsets of the data for homogeneity under a multinomial model that assigns equal probabilities to a maximal set of nonfragile sites and unrestricted probabilities to the remaining fragile sites with significantly higher numbers of breaks. We show how standardized Pearson's chi-square (X2) and likelihood-ratio (G2) statistics can be appropriately used to measure goodness-of-fit for sparse contingency (individual-based) data in this model. A sample application of this approach indicates extensive variation in fragile sites among individuals and marked differences in fragile-site inferences from pooled as opposed to per-individual data.

Cytogenetic nomenclature of deer mice, Peromyscus (Rodentia): revision and review of the standardized karyotype. Report of the Committee for the Standardization of Chromosomes of Peromyscus.

A revision of the standardized karyotype of deer mice (Peromyscus) is presented. This revision addresses short-comings of the original standardization, contains a substantial increase in the number of G-band markers and provides a nomenclature for the G-bands of each autosome and the X chromosome. Using the revised standardized karyotype, we specify the particular G-bands or patterns that identify each chromosome and catalog the more problematic chromosome identifications and likely misidentifications. For each chromosome, we present an overview of previously reported variation in euchromatic arrangement and heterochromatic constitution. We then review previous applications of the standardized karyotype and summarize the predominant findings from cytogenetic and cytosystematic studies of Peromyscus and related taxa.