Using DNA microarrays to study gene expression in closely related species

MOTIVATION: Comparisons of gene expression levels within and between species have become a central tool in the study of the genetic basis for phenotypic variation, as well as in the study of the evolution of gene regulation. DNA microarrays are a key technology that enables these studies. Currently, however, microarrays are only available for a small number of species. Thus, in order to study gene expression levels in species for which microarrays are not available, researchers face three sets of choices: (i) use a microarray designed for another species, but only compare gene expression levels within species, (ii) construct a new microarray for every species whose gene expression profiles will be compared or (iii) build a multi-species microarray with probes from each species of interest. Here, we use data collected using a multi-primate cDNA array to evaluate the reliability of each approach. RESULTS: We find that, for inter-species comparisons, estimates of expression differences based on multi-species microarrays are more accurate than those based on multiple species-specific arrays. We also demonstrate that within-species expression differences can be estimated using a microarray for a closely related species, without discernible loss of information. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.     

Inferring species relationships among Camellia chrysanthoides and its closely related species for developing conservation strategies

Accurate species classification is important for developing conservation strategies for endangered species. Camellia chrysanthoides and its closely related species are currently threatened. However, the taxonomy of these species is complex and contentious. A total of 87 individuals from nine populations of C. chrysanthoides and its close relatives were collected and analyzed using two nuclear genes (PAL and waxy) and a chloroplast DNA fragment. Molecular and morphological evidence demonstrates that C. chrysanthoides and C. micrantha share floral traits and nuclear and chloroplast haplotypes, suggesting that they should be treated as a single species. Our nuclear results indicated that C. parvipetala is genetically close to C. chrysanthoides and C. micrantha. A barrier to gene flow between C. chrysanthoides and C. micrantha populations and the high number of private nuclear haplotypes in C. parvipetala suggest that C. chrysanthoides, C. micrantha and C. parvipetala should be recognized as three independent conservation units.     

Using high-density exon arrays to profile gene expression in closely related species

Global comparisons of gene expression profiles between species provide significant insight into gene regulation, evolutionary processes and disease mechanisms. In this work, we describe a flexible and intuitive approach for global expression profiling of closely related species, using high-density exon arrays designed for a single reference genome. The high-density probe coverage of exon arrays allows us to select identical sets of perfect-match probes to measure expression levels of orthologous genes. This eliminates a serious confounding factor in probe affinity effects of species-specific microarray probes, and enables direct comparisons of estimated expression indexes across species. Using a newly designed Affymetrix exon array, with eight probes per exon for approximately 315 000 exons in the human genome, we conducted expression profiling in corresponding tissues from humans, chimpanzees and rhesus macaques. Quantitative real-time PCR analysis of differentially expressed candidate genes is highly concordant with microarray data, yielding a validation rate of 21/22 for human versus chimpanzee differences, and 11/11 for human versus rhesus differences. This method has the potential to greatly facilitate biomedical and evolutionary studies of gene expression in nonhuman primates and can be easily extended to expression array design and comparative analysis of other animals and plants.     

Evolution of prokaryotic gene order: genome rearrangements in closely related species

Conservation of gene order in prokaryotes has become important in predicting protein function because, over the evolutionary timescale, genomes are shuffled so that local gene-order conservation reflects the functional constraints within the protein. Here, we compare closely related genomes to identify the rate with which gene order is disrupted and to infer the genes involved in the genome rearrangement.     

Investigation of nuclear and mitochondrial DNA polymorphism in closely related species of endemic Baikal sponges

In order to investigate the phylogenetic relationships among endemic Baikal sponges of the family Lubomirskiidae and to clarify their taxonomy, the sequence variation at the silicatein-encoding gene and the mtDNA intergenic region was examined. Phylogenetic analysis of the silicatein α1 gene exonic regions in six freshwater sponge species revealed considerable interspecific variability of this region. The analysis performed did not support the monophyly of the genera Lubomirskia and Baikalospongia. The mtDNA region between the COX2 and ATP6 genes was examined in five species from the Lubomirskiidae family, including multiple samples for analyzing intraspecific variations. According to the data obtained, the genus Baikalospongia was paraphyletic with respect to Lubomirskia, while B. bacilifera and B. recta did not form monophyletic groups. Molecular data indicate that taxonomy of Lubomirskiidae should be revised. It was demonstrated that, in endemic Baikal sponges, the accelerated evolution was accompanied by an increase in the length of the non-coding regions in both mitochondrial and nuclear genes.     

Genetic basis of hybrid male sterility among three closely related species of Drosophila

The genetic basis of hybrid male sterility among three closely related species, Drosophila bipectinata, D. parabipectinata and D. malerkotliana has been investigated by using backcross analysis methods. The role of Y chromosome, major hybrid sterility (MHS) genes (genetic factors) and cytoplasm (non-genetic factor) have been studied in the hybrids of these three species. In the species pair, bipectinata--parabipectinata, Y chromosome introgression of parabipectinata in the genomic background of bipectinata and the reciprocal Y chromosome introgression were unsuccessful as all males in second backcross generation were sterile. Neither MHS genes nor cytoplasm was found important for sterility. This suggests the involvement of X-Y, X-autosomes or polygenic interactions in hybrid male sterility. In bipectinata--malerkotliana and parabipectinata--malerkotliana species pairs, Y chromosome substitution in reciprocal crosses did not affect male fertility. Backcross analyses also show no involvement of MHS genes or cytoplasm in hybrid male sterility in these two species pairs. Therefore, X- autosome interaction or polygenic interaction is supposed to be involved in hybrid male sterility in these two species pairs. These findings also provide evidence that even in closely related species, genetic interactions underlying hybrid male sterility may vary.     

Biogeography of the chaetodontidae: an analysis of allopatry among closely related species

Synopsis A recent survey of chaetodontid osteology has produced a hypothesis of relationships among 22 osteologically distinct genera and subgenera. Fourteen supra-specific taxa have distributions that are Indo-Pacific or larger. Most sister taxa inferred by osteology are broadly sympatric. The basal dichotomy within the large genusChaetodon contrasts monophyletic groups centered in the Atlantic and Indo-Pacific with little overlap. Divergence of Atlantic and Indo-Pacific distributions is correlated with the closing of the Tethys seaway 18–13 million years ago. Distributional data of Burgess (1978) and Allen (1980) are reevaluated in the context of putative species pairs and complexes. Species in nearly two thirds of these complexes (18 of 31) are distributed allopatrically. Eight complexes are examined in more detail. Five of these eight contain at least one peripherically isolated species. Distributions of species in four complexes indicate that previously wide-spread species were cleaved more symmetrically. Sympatric distributions within two species pairs indicate that the more narrowly distributed species in each pair arose through central isolation within a broadly distributed ancestor. The area of central isolation corresponds to the classical center of origin. A new hypothesis of vicariance followed by dispersal may partially explain the diversity gradient so prominently featured in dispersal-oriented tropical marine biogeography.     

A chromosomal investigation of two closely related species of Spodoptera

This paper reports the first cytogenetic study of the two closely related species of noctuid moths, Spodoptera latifascia and S. descoinsi. Chromosomes were prepared using a spreading technique on warm slides. Both gonads and larval brains, which are innovating in the Lepidoptera, were used. Out of 100 specimens observed, 35 showed mitotic metaphases, which allowed chromosomes to be counted. For both species and F1 hybrids, the diploid chromosome number was 2n = 62. The chromosomes of the two species appeared dot-shaped, more rarely rod-shaped, showing little variation in size or morphology. The preparations from larval brains also suggested the existence of two levels of ploidy (haploidy and diploidy) in some nuclei. This result will need further investigation. For the first time in the Lepidoptera, in situ hybridization with Drosophila rDNA as a probe was carried out on S. latifascia and S. descoinsi. It revealed the presence of nucleolar organizing regions located at the distal part of one chromosome pair. Though no sophisticated characterization of S. latifascia and S. descoinsi was possible, it seemed that there was no major chromosomal difference. No karyotypic element could be identified as being involved in reproductive isolation between the two species.     

DNA reassociation kinetics of closely related species

The kinetics of reassociation of the DNA of three groups of closely related organisms were examined. The laboratory mouse was compared to an Asiatic mouse, whose chromosome number is the same but whose chromosome organization is different. Chinese hamster (2N=22) was compared to Syrian hamster (2N=44), and Haplopappus gracilis (2N=4) was compared to H. ravenit (2N=8). It was found that the most highly repeated DNA fractions of the three comparative sets of organisms differ in their reaction rates. However, these fractions of the related hamsters, haplopappi, and probably the mice, do not differ in the amount of DNA composing the fractions. The intermediately fast reassociating DNA and the unique DNA do not differ between members of related pairs of organisms. The implication of these results is that a short sequence of DNA may be highly copied in one organism, while in a related organism a longer DNA sequence is repeated a fewer number of times, and the total amount of repeated DNA may be the same in both related organisms.     

Recombination rate variation in closely related species

Despite their importance to successful meiosis and various evolutionary processes, meiotic recombination rates sometimes vary within species or between closely related species. For example, humans and chimpanzees share virtually no recombination hotspot locations in the surveyed portion of the genomes. However, conservation of recombination rates between closely related species has also been documented, raising an apparent contradiction. Here, we evaluate how and why conflicting patterns of recombination rate conservation and divergence may be observed, with particular emphasis on features that affect recombination, and the scale and method with which recombination is surveyed. Additionally, we review recent studies identifying features influencing fine-scale and broad-scale recombination patterns and informing how quickly recombination rates evolve, how changes in recombination impact selection and evolution in natural populations, and more broadly, which forces influence genome evolution.     

Barcoding animal life: cytochrome c oxidase subunit 1 divergences among closely related species

With millions of species and their life-stage transformations, the animal kingdom provides a challenging target for taxonomy. Recent work has suggested that a DNA-based identification system, founded on the mitochondrial gene, cytochrome c oxidase subunit 1 (COI), can aid the resolution of this diversity. While past work has validated the ability of COI sequences to diagnose species in certain taxonomic groups, the present study extends these analyses across the animal kingdom. The results indicate that sequence divergences at COI regularly enable the discrimination of closely allied species in all animal phyla except the Cnidaria. This success in species diagnosis reflects both the high rates of sequence change at COI in most animal groups and constraints on intraspecific mitochondrial DNA divergence arising, at least in part, through selective sweeps mediated via interactions with the nuclear genome.     

Typing of four genetic loci discriminates among closely related species of New World Leishmania

All New World Leishmania species can cause cutaneous lesions, while only Leishmania (Viannia) braziliensis has been associated with mucosal metastases. Multilocus enzyme electrophoresis (MLEE) is the optimal standard for species identification but is slow and costly. New methods for species identification are needed to ensure proper identification and therapy. The coding regions of four metabolic enzyme markers in the MLEE typing method: mannose phosphate isomerase (MPI), malate dehydrogenase (MDH), glucose-6-phosphate isomerase (GPI), and 6-phosphogluconate dehydrogenase (6PGD), were analysed from seven species of New World Leishmania isolated from patients with either cutaneous or mucosal lesions to identify specific genetic polymorphisms responsible for the phenotypic variations observed in the MLEE typing scheme. We identified species-specific polymorphisms and determined that a combination of sequencing of the mpi and 6pgd genes was sufficient to differentiate among seven closely related species of New World Leishmania and among isolates of L. braziliensis shown previously to have atypical MLEE patterns. When DNA isolated from 10 cutaneous lesion biopsies were evaluated, the sequence typing method was 100% concordant with the published MLEE/monoclonal antibody identification methods. The identification of species-specific polymorphisms can be used to design a DNA-based test with greater discriminatory power that requires shorter identification times. When the causative agent of the disease is L. braziliensis, this method ensures correct species identification, even when the agent is a genetic variant. Proper identification could facilitate adequate treatment, preventing the onset of the disfiguring mucosal form of the disease.     

Evidence for nonallopatric speciation among closely related sympatric Heliotropium species in the Atacama Desert

The genetic structure of populations of closely related, sympatric species may hold the signature of the geographical mode of the speciation process. In fully allopatric speciation, it is expected that genetic differentiation between species is homogeneously distributed across the genome. In nonallopatric speciation, the genomes may remain undifferentiated to a large extent. In this article, we analyzed the genetic structure of five sympatric species from the plant genus Heliotropium in the Atacama Desert. We used amplified fragment length polymorphisms (AFLPs) to characterize the genetic structure of these species and evaluate their genetic differentiation as well as the number of loci subject to positive selection using divergence outlier analysis (DOA). The five species form distinguishable groups in the genetic space, with zones of overlap, indicating that they are possibly not completely isolated. Among‐species differentiation accounts for 35% of the total genetic differentiation (F_ST = 0.35), and F_ST between species pairs is positively correlated with phylogenetic distance. DOA suggests that few loci are subject to positive selection, which is in line with a scenario of nonallopatric speciation. These results support the idea that sympatric species of Heliotropium sect. Cochranea are under an ongoing speciation process, characterized by a fluctuation of population ranges in response to pulses of arid and humid periods during Quaternary times.