Different levels of human intervention in domestic rabbits: effects on genetic diversity.

The effects of human interaction on domestic rabbits were evaluated through the analysis of animals (up to 267) belonging to fancy breeds (22), a commercial breed (1), and selected strains (2). Microsatellite loci and mtDNA polymorphism revealed that the genetic pool of domestic rabbits studied only originated from that available in France. The good conservation of the original diversity was probably ensured through the multiplicity of samplings from wild populations. Selected strains, because of the breeding strategy, keep a fairly high level of diversity compared to other breeds.

Stationary distributions of microsatellite loci between divergent population groups of the European rabbit (Oryctolagus cuniculus).

Previous analysis of mitochondrial DNA polymorphism in the native range of the European rabbit (Oryctolagus cuniculus) demonstrated the occurrence of two highly divergent (2 Myr) maternal lineages with a well-defined geographical distribution. Analysis of both protein and immunoglobulin polymorphisms are highly concordant with this pattern of differentiation. However, the present analysis of nine polymorphic microsatellite loci (with a total of 169 alleles) in 24 wild populations reveals severe allele-size homoplasy which vastly underestimates divergence between the main groups of populations in Iberia. Nonetheless, when applied to more recent historical phenomena, this same data set not only confirms the occurrence of a strong bottleneck associated with the colonization of Mediterranean France but also suggests a two-step dispersal scenario that began with gene flow from northern Spain through the Pyrenean barrier and subsequent range expansion into northern France. The strength and appropriateness of applying microsatellites to more recent evolutionary questions is highlighted by the fact that both mtDNA and protein markers lacked the allelic diversity necessary to properly evaluate the colonization of France. The well-documented natural history of European rabbit populations provides an unusually comprehensive framework within which one can appraise the advantages and limitations of microsatellite markers in revealing patterns of genetic differentiation that have occurred across varying degrees of evolutionary time. The degree of size homoplasy presented in our data should serve as a warning to those drawing conclusions from microsatellite data sets which lack a set of complementary comparative markers, or involve long periods of evolutionary history, even within a single species.

Rate matrices for analyzing large families of protein sequences.

We propose and study a new approach for the analysis of families of protein sequences. This method is related to the LogDet distances used in phylogenetic reconstructions; it can be viewed as an attempt to embed these distances into a multidimensional framework. The proposed method starts by associating a Markov matrix to each pairwise alignment deduced from a given multiple alignment. The central objects under consideration here are matrix-valued logarithms L of these Markov matrices, which exist under conditions that are compatible with fairly large divergence between the sequences. These logarithms allow us to compare data from a family of aligned proteins with simple models (in particular, continuous reversible Markov models) and to test the adequacy of such models. If one neglects fluctuations arising from the finite length of sequences, any continuous reversible Markov model with a single rate matrix Q over an arbitrary tree predicts that all the observed matrices L are multiples of Q. Our method exploits this fact, without relying on any tree estimation. We test this prediction on a family of proteins encoded by the mitochondrial genome of 26 multicellular animals, which include vertebrates, arthropods, echinoderms, molluscs, and nematodes. A principal component analysis of the observed matrices L shows that a single rate model can be used as a rough approximation to the data, but that systematic deviations from any such model are unmistakable and related to the evolutionary history of the species under consideration.

Cytochrome b sequences reveal Acomys minous (Rodentia, Muridae) paraphyly and answer the question about the ancestral karyotype of Acomys dimidiatus.

Sequences of the cytochrome b (cyt b) mitochondrial gene show that the spiny mouse Acomys from Crete, known as the endemic species A. minous, is composed of two distinct maternal lineages ("A" and "B"). Group "A" sequences cluster with A. nesiotes (Cyprus) and group "B" sequences cluster with A. cilicicus (Turkey), which is evidence of paraphyly of A. minous in regard to these two species. From cyt b sequences, the three taxa are very closely related to A. cahirinus (Egypt): the maximum divergence found among these sequences is 1.6%, which is equivalent to the intraspecific diversity observed in other Acomys species. Paleozoology evidenced that man unintentionally introduced Acomys into Crete and Cyprus during antiquity. The divergence time between Acomys cyt b sequences found in Crete was estimated at 0.4 Myr, which means that the diversity observed did not appear after the introduction but reflects a much more ancient polymorphism. Cytochrome b phylogeny and cytogenetic data together comprise evidence that, within the species A. dimidiatus (Saudi Arabia, Israel, Egypt), it is the karyotypic form with 36 chromosomes that derives from the form with 38 chromosomes, due to a single acrocentric fusion.

Phylogeography of the European rabbit (Oryctolagus cuniculus) in the Iberian Peninsula inferred from RFLP analysis of the cytochrome b gene.

We studied mitochondrial DNA variation in the European rabbit through the examination of restriction fragment length polymorphism in 526 individuals from 20 locations spread across the Iberian Peninsula. Digestion with eight enzymes of a 1120-bp fragment comprising most of the cytochrome b gene resolved 38 different haplotypes. These haplotypes were distributed in two highly divergent clades, with different but overlapping geographical distributions, and with comparable levels of within-clade variation. The overall phylogeographical pattern suggests a history of long-term regional isolation of two groups of rabbit populations, compatible with the recognition of two subspecies within the Iberian Peninsula, followed by recent contact and admixture. The underlying cause is sought in the alternation of glacial and interglacial periods in the late Pleistocene.

Absence of a genetic bottleneck in a wild rabbit (Oryctolagus cuniculus) population exposed to a severe viral epizootic.

Infectious diseases and their demographic consequences are thought to influence the genetic diversity of populations. In Europe, during the last 50 years, the European rabbit (Oryctolagus cuniculus) has suffered two important viral epizootics: myxomatosis and rabbit viral haemorraghic disease (RVHD). Although mortality rates were very high, the impact of these diseases on genetic diversity has never been assessed directly. The subject of this paper is a wild rabbit population in France, which has been studied since the beginning of the 1980s. The first outbreak of RVHD occurred in 1995 and provoked a demographic crash. The population, sampled for the first time in 1982 and 1994, was sampled again at the end of 1996 to examine the impact of the epizootic on genetic diversity. In spite of the observed high mortality rate ( approximately 90%), analysis of 14 polymorphic loci (allozymes and microsatellites) showed no loss in genetic diversity after the epizootic. Determination of temporal changes in allele frequencies indicated that the population evolved under genetic drift. The temporal method of Waples demonstrated a significant decrease in the effective population size (Ne) correlated with the demographic crash due to the epizootic. However, the population had only been studied for two generations after the epizootic and the remnant population size probably stayed high enough ( approximately 50 individuals) to keep its genetic diversity at the precrash level. These results suggest that, contrary to what is usually thought and in spite of the subsequent high mortality rates, past epizootics (especially myxomatosis) may have had little effect on the genetic diversity of wild rabbit populations in Europe.

MitBASE : a comprehensive and integrated mitochondrial DNA database. The present status.

MitBASE is an integrated and comprehensive database of mitochondrial DNA data which collects, under a single interface, databases for Plant, Vertebrate, Invertebrate, Human, Protist and Fungal mtDNA and a Pilot database on nuclear genes involved in mitochondrial biogenesis in Saccharomyces cerevisiae. MitBASE reports all available information from different organisms and from intraspecies variants and mutants. Data have been drawn from the primary databases and from the literature; value adding information has been structured, e.g., editing information on protist mtDNA genomes, pathological information for human mtDNA variants, etc. The different databases, some of which are structured using commercial packages (Microsoft Access, File Maker Pro) while others use a flat-file format, have been integrated under ORACLE. Ad hoc retrieval systems have been devised for some of the above listed databases keeping into account their peculiarities. The database is resident at the EBI and is available at the following site: http://www3.ebi.ac.uk/Research/Mitbase/mitbas e.pl. The impact of this project is intended for both basic and applied research. The study of mitochondrial genetic diseases and mitochondrial DNA intraspecies diversity are key topics in several biotechnological fields. The database has been funded within the EU Biotechnology programme.

Mitochondrial genes collectively suggest the paraphyly of Crustacea with respect to Insecta.

Complete sequences of seven protein coding genes from Penaeus notialis mitochondrial DNA were compared in base composition and codon usage with homologous genes from Artemia franciscana and four insects. The crustacean genes are significantly less A + T-rich than their counterpart in insects and the pattern of codon usage (ratio of G + C-rich versus A + T-rich codon) is less biased. A phylogenetic analysis using amino acid sequences of the seven corresponding polypeptides supports a sister-taxon status for mollusks-annelid and arthropods. Furthermore, a distance matrix-based tree and two most-parsimonious trees both suggest that crustaceans are paraphyletic with respect to insects. This is also supported by the inclusion of Panulirus argus COII (complete) and COI and COIII (partial) sequence data. From analysis of single and combined genes to infer phylogenies, it is observed that obtained from single genes are not well supported in most topologies cases and notably differ from that of the tree based on all seven genes.

Cytonuclear disequilibria in wild populations of rabbit (Oryctolagus cuniculus L.) suggest unequal allele turnover rates at the b locus (IGKC1).

DNA sequence comparisons suggest that evolutionary rates at the rabbit IGKC1 locus can differ among allelic lineages. Here we address the question of whether population turnover rates can vary among IGKC1 alleles. We studied the distribution of sixteen IGKC1 (or b-locus) allotypes in areas comprising the aboriginal species range (Iberian peninsula). Rabbits in this area belong to one of two distantly related mitochondrial lineages (mtDNA types) A and B. In the more recent distribution area of the species, all rabbits belong to the mtDNA type B lineage, and IGKC1 alleles b4 and b5 comprise over 90% of the gene pool. These two alleles are also predominant in areas of mtDNA type B prevalence within the Iberian range. However, in areas of mtDNA type A prevalence, the b4 and b5 allotypes are rare or absent; they apparently have been replaced by serologically related, but distinct, 'endemic' variants. The cytonuclear disequilibria were highly significant, also within the subsample consisting of populations from Spain. These observations suggest that allelic persistence times for the predominant IGKC1 lineages could be shorter than the divergence time of the major mtDNA lineages A and B. In contrast, the relative gene frequencies of the IGKC1 allele b9 were similar among the type A and type B rabbits; it was present in most populations at low frequency. In consequence, persistence times of the b9 allele appear to be longer than the divergence time of lineages A and B. The data reported here are in agreement with the DNA sequence data, providing further proof that the molecular clock can run at different rates among allelic lineages at the rabbit IGKC1 locus.

The allotypic patchwork pattern of the rabbit IGKC1 allele b5wf: genic exchange or common ancestry?

The protein sequences of different alleles of the rabbit immunoglobulin IGKC1 gene can differ at more than 40% of the amino acid positions. This exceptional degree of allelic divergence raises questions concerning the causal underlying mechanisms. We report the DNA sequence of the coding region of an allotype which is associated with the mitochondrial lineage A (Southwestern Spain). At the serological level, this b5wf allotype presents a patchwork of antigenic determinants which in domestic breeds are characteristic of the b4, b5, and b6 allotypes. The inferred protein sequence of the b5wf allotype was found to differ from that of the b4, b5, and b6 allotypes at 25, 10, and 15% of the amino acid positions, respectively. Sequence comparisons show that the b4-specific epitopes of the b5wf allotype are probably due to a shared ThrThrGlnThr motif at Kabat positions 153-156. Similarly, the shared b5-specific determinants should relate to the motifs 161ThrSerLys163 and/or 182LysSerAspGlu185. A monoclonal antibody binding epitope shared among the b5wf, b5, and b6 sequences appeared to be correlated with the presence of Asp190. Although there is evidence of interallelic genic exchange, sequence comparisons suggest that the apparent mosaic structure of the b5wf allotype is better explained by common ancestry and point mutation.

MitBASE: a comprehensive and integrated mitochondrial DNA database.

MitBASE is an integrated and comprehensive database of mitochondrial DNA data which collects all available information from different organisms and from intraspecie variants and mutants. Research institutions from different countries are involved, each in charge of developing, collecting and annotating data for the organisms they are specialised in. The design of the actual structure of the database and its implementation in a user-friendly format are the care of the European Bioinformatics Institute. The database can be accessed on the Web at the following address: http://www.ebi.ac. uk/htbin/Mitbase/mitbase.pl. The impact of this project is intended for both basic and applied research. The study of mitochondrial genetic diseases and mitochondrial DNA intraspecie diversity are key topics in several biotechnological fields. The database has been funded within the EU Biotechnology programme.

Intrageneric phylogeny of Acomys (rodentia, muridae) using mitochondrial gene cytochrome b.

This paper investigates interspecies relationships within the genus Acomys (spiny mice) by analyzing entire mitochondrial cytochrome b gene (1141 bp). This gene provides strong phylogenetic signal, as shown by high support of the topology obtained (bootstrap value and RNA support number). The phylogeny is congruent with inferences from allozymes for the species considered. Controversial taxonomy of Acomys cahirinus, dimidiatus, airensis, and ignitus is clarified, with their specific ranks confirmed on the basis of tree topology and nucleotide distances. Phylogenetic relationship between the undescribed species Acomys sp. from west Africa and A. airensis argue in favor of two distinct colonization events in this zone.

Nonneutral evolution of tandem repeats in the mitochondrial DNA control region of lagomorphs.

The mitochondrial DNA of the European rabbit (Oryctolagus cuniculus) contains a tandem array of 153-bp repeats in the vicinity of the replication origin of the H-stand. Variation among molecules in the number of these repeats results in inter- and intraindividual length polymorphism (heteroplasmy). Generally, in an individual, one predominant molecular type is observed, the others representing a low percentage of the mtDNA content. At the tissue level, we observe a particular distribution of this polymorphism in the gonads compared with liver, kidneys, or brain, implying a relationship between the differentiation status of the cells and the types of new mtDNA molecules which appear and accumulate during lifetime. Similar tandem repeats were also found in the mtDNA noncoding region of European hares (Lepus europaeus), a cottontail (Sylvilagus floridanus), and a pika (Ochotona rufescens). The lengths and the sequences of these units evolve rapidly and in a concerted way, but the number of repeats is maintained in a narrow range, and an internal 20-bp segment is highly conserved. Constraints restrict the evolution of the primary sequence of these repeated units, the number of which is probably controlled by a stabilizing selection.

Taxonomic status and phylogenetic relationships of some species of the genus Gammarus (Crustacea, Amphipoda) deduced from mitochondrial DNA sequences.

Mitochondrial DNA nucleotide sequence analysis was used to determine the extent of genetic differentiation among six species of the genus Gammarus (Crustacea, Amphipoda) common in France (G. fossarum, G. pulex, G. lacustris, G. wautieri, G. roeseli, G. marinus). From 23 different populations, 104 specimens were compared to examine their taxonomic status and their phylogenetic relationships. Nucleotide sequences for a 376-base segment of the cytochrome c oxidase subunit I (COI) gene were obtained through direct sequencing of amplified DNA. The strong sequence variability found at the interspecific level, generally masked by morphological or ecological similarities, is consistent with that observed for other crustaceans and supports existing species classifications. A high level of genetic variation was observed at the intraspecific level, suggesting that the COI gene will be a powerful marker for amphipod population biology. Based on the mitochondrial population biology. Based on the mitochondrial DNA results, we propose a phylogenetic hypothesis of the relationships among the six studied species, which is discussed in biogeographic and evolutionary terms.

Phylogeny of cephalopods inferred from mitochondrial DNA sequences.

Sequences of partial mitochondrial cytochrome oxidase III gene (533 bp) were obtained for 17 species of cephalopods, 14 decapods, 2 octopods, and 1 vampyromorph. This study aimed to: (1) compare partial COII and COIII amino acid sequences of three species of cephalopods with other invertebrates in terms of base composition and phylogenetic relationships. Cephalopod sequences are closer to Katharina tunicata sequences than to Mytilus edulis (marine bivalve) and Albinaria turrita (terrestrial gastropod); (2) investigate the phylogenetic relationships among cephalopods. Nucleotides as well as amino acid sequence variations of a COIII fragment were examined with parsimony and distance methods. Our data confirm the monophyly of the Decapoda and of each family. A high hierarchical rank for sepiolids, already suggested by other authors, appears justified. The order Sepioidea comprising five families should be abandoned, with Spirula being excluded. The surprising position of Idiosepius as the sister group of some oegopsids and not of sepioids or sepiolids is confirmed. Vampyroteuthis is the sister group of octopods. However, the data do not allow resolution of the phylogenetic relationships between the orders of Decapoda; consequently we suspect a rapid radiation.

[History of the rabbit and ancient DNA]. / Histoire des lapins et ADN ancien.

Present populations of Rabbits (Oryctolagus cuniculus) are organized into two well defined groups A and B according to their mitochondrial DNA sequences. Group A is restricted to the South Western part of the Iberian Peninsula while group B is found everywhere else. Domestic breeds belong to the latter. As evidenced from data on ancient bones (up to 12,000 years BP) the mitochondrial type B1, predominant in domestic animals, originated from Spain. B1 animals were introduced in France by man between late Roman times and Middle Ages.

Partial sequence of the shrimp Penaeus notialis mitochondrial genome.

About half of the mitochondrial DNA of the shrimp Penaeus notialis (Crustacea: Decapoda) has been cloned (in 2 overlapping fragments of 7.9 kb and 1 kb) and partially sequenced. The gene content and arrangement are identical to that of the homologous domain in Drosophila yakuba. Intergenic nucleotides are scarce and a 982 bp non-coding sequence exhibit features similar to that of mtDNA control regions. The gene organization and the tRNA structures differentiate the Penaeus notialis mitochondrial genome from that of Artemia franciscana. Paraphyletism of crustacean mtDNA with respect to Insecta is discussed. A secondary structure of s-rRNA is proposed.

Molecular cloning and complete nucleotide sequence of the repeated unit and flanking gene of the scallop Pecten maximus mitochondrial DNA: putative replication origin features.

In the bivalve mollusc Pecten maximus, the size of the mitochondrial DNA molecules ranges from 20 to 25.8 kbp. This variability is mainly correlated with the occurrence of a variable domain composed with two to five 1.6-kbp repeated units tandemly arrayed in the genome. DNA fragments spanning the 1,586-base-pair-long repeated element and the nearest flanking gene have been cloned and sequenced. This sequence was analyzed regarding its base composition and potential secondary structures. The repeated unit domain was positioned and oriented with regard to the known flanking gene. It ends 2 base pairs upstream relative to the beginning of the tRNAgly gene. The peculiar properties of the repeated unit were compared with those of the 1,442-bp repeated element found in the mitochondrial genome of the deep sea scallop Placopecten magellanicus. This comparison provided evidence for the absence of nucleotide conservation, except for a small sequence engaged in a secondary structure, but argued for a strong pressure maintaining domains with specific nucleotide content. A possible role for the conserved sequence is discussed.

Rabbit mitochondrial DNA diversity from prehistoric to modern times.

The mitochondrial genetic variability in European rabbit (Oryctolagus cuniculus) populations present in Europe and North Africa from 11,000 years ago to the present day has been analyzed using ancient DNA techniques. DNA was extracted from 90 rabbit bones found in 22 archaeological sites dated between the Mesolithic and recent times. Nucleotide sequences present in a variable 233-bp domain of the cytochrome b gene were compared to those present in modern-day rabbits. The results show that the structure of ancient populations of wild rabbit exhibited remarkable stability over time until the Middle Ages. At this time, a novel type of mtDNA molecule abruptly appears into most wild populations studied from France. This mtDNA type corresponds to that currently present in the domestic breeds of rabbit examined so far. The relative rapidity by which this mtDNA type established and its absence in all sites examined before 1,700 years ago lend support to the hypothesis that between 2,000 and 1,000 years ago, man may have favored the development, into all regions of France, of animals carrying this particular mtDNA molecule. The origin of such animals has still to be found: animals previously living outside of France or within France but in very restricted areas? This event was concomitant with the documented establishment of warrens after the tenth century A.D. in Europe.