Key transitions in animal evolution

In order to address this subject further and to assess progressin the examination of animal origins and transitions, an internationalgroup of scientists was convened at the Society for ComparativeBiology meeting in January 2007.     

Rapid concerted evolution in animal mitochondrial DNA

Recombinational genetic processes are thought to be rare in the uniparentally inherited mitochondrial (mt) DNA molecules of vertebrates and other animals. Here, however, we document extremely rapid concerted microevolution, probably mediated by frequent gene conversion events, of duplicated sequences in the mtDNA control region of mangrove killifishes (Kryptolebias marmoratus). In local populations, genetic distances between paralogous loci within an individual were typically smaller (and often zero) than those between orthologous loci in different specimens. These findings call for the recognition of concerted evolution as a microevolutionary process and gene conversion as a likely recombinational force in animal mtDNA. The previously unsuspected power of these molecular phenomena could greatly impact mtDNA dynamics within germ cell lineages and in local animal populations.     

Transition and transversion rate in the evolution of animal mitochondrial DNA

We present a further application of the stochastic model previously described (Lanave et al., 1984, 1985) for measuring the nucleotide substitution rate in the mammalian evolution of the mitochondrial DNA (mtDNA). The applicability of this method depends on the validity of "stationarity conditions" (equal nucleotide frequencies at first, second and third silent codon positions in homologous protein coding genes). In the comparison of homologous sequences satisfying the stationarity condition at the silent sites, only the four codon families (quartets) for which both transitions and transversions are silent at the third position are considered here. This has allowed us to estimate the transition and transversion rates for any pair of species. We have analyzed the third silent codon position of the triplet rat-mouse-cow, of a series of slightly divergent primates and of two Drosophila species. In terms of two external dating input we have then determined the phylogenetic trees for rat, mouse, and cow as well as for a number of primates including man. The phylogenetic tree that we have derived for the triplet rat, mouse and cow agrees with that we had previously determined by analyzing the first, second and third silent codon positions (in both duets and quartets) of mt genes (Lanave et al., 1985). For primates our method leads to the following branching order from the oldest to the most recent: Gibbon, Orangutan, Gorilla, Chimpanzee and Man. In absolute time, fixing the distance Chimpanzee-Man as 5 million years (Myr) we estimate the dating of the divergence nodes as: Gorilla 7 Myr; Orangutan 16 Myr; Gibbon 20 Myr. In all cases analyzed, the transition rate has been found to be substantially higher than the transversion rate. Moreover we have found that the transition/transversion ratio is different in the various lineages. We suggest that this fact is probably related to the nucleotide frequencies at the third silent codon position.     

Replicating animal mitochondrial DNA

The field of mitochondrial DNA (mtDNA) replication has been experiencing incredible progress in recent years, and yet little is certain about the mechanism(s) used by animal cells to replicate this plasmid-like genome. The long-standing strand-displacement model of mammalian mtDNA replication (for which single-stranded DNA intermediates are a hallmark) has been intensively challenged by a new set of data, which suggests that replication proceeds via coupled leading- and lagging-strand synthesis (resembling bacterial genome replication) and/or via long stretches of RNA intermediates laid on the mtDNA lagging-strand (the so called RITOLS). The set of proteins required for mtDNA replication is small and includes the catalytic and accessory subunits of DNA polymerase γ, the mtDNA helicase Twinkle, the mitochondrial single-stranded DNA-binding protein, and the mitochondrial RNA polymerase (which most likely functions as the mtDNA primase). Mutations in the genes coding for the first three proteins are associated with human diseases and premature aging, justifying the research interest in the genetic, biochemical and structural properties of the mtDNA replication machinery. Here we summarize these properties and discuss the current models of mtDNA replication in animal cells.     

Major transitions in the evolution of early land plants: a bryological perspective

Background Molecular phylogeny has resolved the liverworts as the earliest-divergent clade of land plants and mosses as the sister group to hornworts plus tracheophytes, with alternative topologies resolving the hornworts as sister to mosses plus tracheophytes less well supported. The tracheophytes plus fossil plants putatively lacking lignified vascular tissue form the polysporangiophyte clade. Scope This paper reviews phylogenetic, developmental, anatomical, genetic and paleontological data with the aim of reconstructing the succession of events that shaped major land plant lineages. Conclusions Fundamental land plant characters primarily evolved in the bryophyte grade, and hence the key to a better understanding of the early evolution of land plants is in bryophytes. The last common ancestor of land plants was probably a leafless axial gametophyte bearing simple unisporangiate sporophytes. Water-conducting tissue, if present, was restricted to the gametophyte and presumably consisted of perforate cells similar to those in the early-divergent bryophytes Haplomitrium and Takakia. Stomata were a sporophyte innovation with the possible ancestral functions of producing a transpiration-driven flow of water and solutes from the parental gametophyte and facilitating spore separation before release. Stomata in mosses, hornworts and polysporangiophytes are viewed as homologous, and hence these three lineages are collectively referred to as the 'stomatophytes'. An indeterminate sporophyte body (the sporophyte shoot) developing from an apical meristem was the key innovation in polysporangiophytes. Poikilohydry is the ancestral condition in land plants; homoiohydry evolved in the sporophyte of polysporangiophytes. Fungal symbiotic associations ancestral to modern arbuscular mycorrhizas evolved in the gametophytic generation before the separation of major present-living lineages. Hydroids are imperforate water-conducting cells specific to advanced mosses. Xylem vascular cells in polysporangiophytes arose either from perforate cells or de novo. Food-conducting cells were a very early innovation in land plant evolution. The inferences presented here await testing by molecular genetics.     

Structure,function and evolution of the animal mitochondrial replicative DNA helicase

The mitochondrial replicative DNA helicase is essential for animal mitochondrial DNA (mtDNA) maintenance. Deleterious mutations in the gene that encodes it cause mitochondrial dysfunction manifested in developmental delays, defects and arrest, limited life span, and a number of human pathogenic phenotypes that are recapitulated in animals across taxa. In fact, the replicative mtDNA helicase was discovered with the identification of human disease mutations in its nuclear gene, and based upon its deduced amino acid sequence homology with bacteriophage T7 gene 4 protein (T7 gp4), a bi-functional primase-helicase. Since that time, numerous investigations of its structure, mechanism, and physiological relevance have been reported, and human disease alleles have been modeled in the human, mouse, and Drosophila systems. Here, we review this literature and draw evolutionary comparisons that serve to shed light on its divergent features.     

Key transitions during the evolution of animal phototransduction: novelty, "tree-thinking," co-option, and co-duplication

Biologists are amazed by the intricacy and complexity of biologicalinteractions between molecules, cells, organisms, and ecosystems.Yet underlying all this biodiversity is a universal common ancestry.How does evolution proceed from common starting points to generatethe riotous biodiversity we see today? This "novelty problem"—understandinghow novelty and common ancestry relate—has become of criticalimportance, especially since the realization that genes anddevelopmental processes are often conserved across vast phylogeneticdistances. In particular, two processes have emerged as theprimary generators of diversity in organismal form: duplicationplus divergence and co-option. In this article, we first illustratehow phylogenetic methodology and "tree-thinking" can be usedto distinguish duplication plus divergence from co-option. Second,we review two case studies in photoreceptor evolution—onesuggesting a role for duplication plus divergence, the otherexemplifying how co-option can shape evolutionary change. Finally,we discuss how our tree-thinking approach differs from othertreatments of the origin of novelty that utilized a "linear-thinking"approach in which evolution is viewed as a linear and gradualprogression, often from simple to complex phenotype, drivenby natural selection.     

The role of climate in human mitochondrial DNA evolution: a reappraisal

Previous studies have proposed that selection has been involved in the differentiation of human mitochondrial DNA (mtDNA) and climate was the main driving force. This viewpoint, however, gets no support from the subsequent studies and remains controversial thus far. To clarify this issue, a total of 237 complete mtDNA sequences belonging to autochthonous lineages from South Asia, Oceania, and East Asia were collected to seek for the imprint of selection. Based on nonsynonymous (N) and synonymous (S) substitutions analysis, our results confirmed that purifying selection was the predominant force during the evolution of human mtDNA. However, no significant and extensive difference was detected among these three regions, which did not support the climate adaptation hypothesis but preferred random genetic drift to be the main factor in shaping the current landscape of human mtDNA, at least those from Asian and Oceanian regions.     

The evolution of mitochondrial DNA

Although the massive sequencing of mitochondrial DNA from various organisms, together with studies of a different nature, has contributed enormously to the knowledge of the organization and function of this cytoplasmic genome, many issues, mainly the relationships with the nuclear genome, remain unsolved. This review critically evaluates the most recent advances in research on the evolution of the mitochondrial DNA from a qualitative and quantitative point of view, underlining the multiplicity of structures and genetic organization of this genome, which contrasts with its reduced, but rather constant, information content in various organisms. It also highlights the role that mitochondrial DNA is now playing, particularly in metazoans, in different disciplines and application fields. Among these, particular attention is focused on the discovery of the mitochondrial origin of several diseases affecting primarily the neuromuscular system.     

Calibration of mitochondrial DNA evolution in geese

Summary Mitochondrial DNA was purified from five American species of geese representing the generaAnser andBranta, which have fossil records. The results of electrophoretic comparisons of about 75 fragments per individual produced by 14 restriction enzymes imply that the mean extent of sequence divergence between species ofAnser andBranta is about 9%. Fossil evidence suggests that these two groups of geese had a common ancestor 4–5 million years ago. Thus, the mean rate of sequence divergence in goose mitochondiral DNA is not far from 2% per million years, the value in mammals.     

Genetic mapping of bovine mitochondrial DNA from a single animal

Using a physical map of bovine mitochondrial DNA derived from the liver of a single Holstein cow, we have determined the location of the genes specifying the large and small riibosomal RNAs by hybridization analysis and electron microscopic observations of R-loop forms. Also, the position of the origin of DNA replication (D-loop) has been located by electron microscopy. Additionally, the direction of D-loop expansion and the polarity of the large and small ribosomal RNA genes were determined.     

Fragment comparison of hamster mitochondrial DNA: general conclusions about the evolution of mitochondrial DNA

Mitochondrial DNA from heart, liver and kidney of two hamster species, Mesocricetus auratus and Cricetulus griseus has been digested with the restriction endonucleases Bam HI, Bgl I, Eco RI, Hae III, Hind III, Hpa II and Xba I. Cleavage patterns for Hpa II are identical for both species, while only two of seven bands are common with Hae III. All other endonucleases give a species-specific cleavage pattern. The results suggest a fairly high phylogenetic differentiation of the mitochondrial genome between the two hamster species. The large differences in mitochondrial DNA variability between different species is discussed as a function of mutation rate and species-specific generation time.     

Inferring Pongo conservation units: a perspective based on microsatellite and mitochondrial DNA analyses

In order to define evolutionarily significant and management units (ESUs and MUs) among subpopulations of Sumatran (Pongo pygmaeus abelii) and Bornean (P. p. pygmaeus) orangutans we determined their genetic relationships. We analyzed partial sequences of four mitochondrial genes and nine autosomal microsatellite loci of 70 orangutans to test two hypotheses regarding the population structure within Borneo and the genetic distinction between Bornean and Sumatran orangutans. Our data show Bornean orangutans consist of two genetic clusters—the western and eastern clades. Each taxon exhibits relatively distinct mtDNA and nuclear genetic distributions that are likely attributable to genetic drift. These groups, however, do not warrant designations as separate conservation MUs because they demonstrate no demographic independence and only moderate genetic differentiation. Our findings also indicate relatively high levels of overall genetic diversity within Borneo, suggesting that observed habitat fragmentation and erosion during the last three decades had limited influence on genetic variability. Because the mtDNA of Bornean and Sumatran orangutans are not strictly reciprocally monophyletic, we recommend treating these populations as separate MUs and discontinuing inter-island translocation of animals unless absolutely necessary.     

Divergent evolution of life span associated with mitochondrial DNA evolution

Mitochondria play a key role in ageing. The pursuit of genes that regulate variation in life span and ageing have shown that several nuclear‐encoded mitochondrial genes are important. However, the role of mitochondrial encoded genes (mtDNA) is more controversial and our appreciation of the role of mtDNA for the evolution of life span is limited. We use replicated lines of seed beetles that have been artificially selected for long or short life for >190 generations, now showing dramatic phenotypic differences, to test for a possible role of mtDNA in the divergent evolution of ageing and life span. We show that these divergent selection regimes led to the evolution of significantly different mtDNA haplotype frequencies. Selection for a long life and late reproduction generated positive selection for one specific haplotype, which was fixed in most such lines. In contrast, selection for reproduction early in life led to both positive selection as well as negative frequency‐dependent selection on two different haplotypes, which were both present in all such lines. Our findings suggest that the evolution of life span was in part mediated by mtDNA, providing support for the emerging general tenet that adaptive evolution of life‐history syndromes may involve mtDNA.     

Companion animal parasitology: a clinical perspective

In recent years there have been many changes to the ways that clinical veterinary science is conducted and nowhere is this more evident than in companion animal practice. Veterinarians working with pet dogs and cats are facing new challenges associated with the emergence and re-emergence of parasitic diseases. Some, such as Neospora caninum, have been recently recognised; others like Giardia and Cryptosporidium have been reported with increasing frequency, in part as a result of laboratory tests with improved sensitivity and specificity. In many regions, the emergence of parasitic diseases has been a consequence of pet travel and exotic diseases pose a unique diagnostic challenge for the veterinarian, as the index of suspicion for these conditions may be absent. The ranges of certain vector-borne diseases such as babesiosis, hepatozoonosis, ehrlichiosis, leishmaniasis and dirofilariasis are extending due to ecological and climatic changes and enhanced by animals with subclinical infection returning home from endemic areas. In companion animal practice, veterinarians have the additional responsibility of providing accurate information about the zoonotic transmission of parasite infections from pets, especially to those most vulnerable such as children, the elderly and the immunocompromised. Effective education is vital to allay public concerns and promote responsible pet ownership.