Atelinae phylogenetic relationships: The trichotomy revived?

This research examines phylogenetic relationships between members of the Atelinae subfamily (Alouatta, Ateles, Brachyteles, and Lagothrix), based on analysis of three genetic regions. Two loci, cytochrome c oxidase subunit II (COII) and the hypervariable I portion of the control region, are part of the mitochondrial genome. The other is a single-copy nuclear gene, Aldolase A Intron V. Analysis of these genetic regions provides support for tribe Alouattini containing the Alouatta species, while tribe Atelini contains the other three genera. However, these three genetic regions produce conflicting results for relationships among tribe Atelini members. Previous genetic studies supported grouping Brachyteles with Lagothrix, leaving Ateles in a separate subclade. The present data sets vary based on the genetic region analyzed and method of analysis suggesting all possible cladistic relationships. These results are more consistent with investigations of morphology and behavior among these primates. The primary cause of discrepancy between this study and previous genetic studies is postulated to reside in increased sampling in the present study of genetic variation among members of the Atelinae, specifically Ateles. The present study utilized samples of Ateles from all postulated species for this genetically variable primate, while previous studies used only one or two species of Ateles. This paper demonstrates that shifting relationships are produced when different species of Ateles are used to reconstruct phylogenies. This research concludes that a trichotomy should still be supported between members of tribe Atelini until further analyses, which include additional Atelinae haplotypes are conducted.     

Phylogeny of the genus Arenavirus

The family Arenaviridae consists of a unique genus (Arenavirus) that currently comprises 22 viral species, as recognized by the International Committee for Taxonomy of Viruses. Seven newly discovered represent putative new species. Here, our aims were to provide the most comprehensive phylogenetic analysis of members and putative members of the family Arenaviridae to date, and to investigate the genetic diversity observed within and between recognized species of New world arenaviruses to determine whether the genetic criteria previously proposed to define arenavirus species for Old world arenaviruses should be retained or are more widely applicable to the whole genus.     

Strengths and potential pitfalls of hay transfer for ecological restoration revealed by RAD‐seq analysis in floodplain Arabis species

Achieving high intraspecific genetic diversity is a critical goal in ecological restoration as it increases the adaptive potential and long‐term resilience of populations. Thus, we investigated genetic diversity within and between pristine sites in a fossil floodplain and compared it to sites restored by hay transfer between 1997 and 2014. RAD‐seq genotyping revealed that the stenoecious floodplain species Arabis nemorensis is co‐occurring with individuals that, based on ploidy, ITS‐sequencing and morphology, probably belong to the close relative Arabis sagittata, which has a documented preference for dry calcareous grasslands but has not been reported in floodplain meadows. We show that hay transfer maintains genetic diversity for both species. Additionally, in A. sagittata, transfer from multiple genetically isolated pristine sites resulted in restored sites with increased diversity and admixed local genotypes. In A. nemorensis, transfer did not create novel admixture dynamics because genetic diversity between pristine sites was less differentiated. Thus, the effects of hay transfer on genetic diversity also depend on the genetic make‐up of the donor communities of each species, especially when local material is mixed. Our results demonstrate the efficiency of hay transfer for habitat restoration and emphasize the importance of prerestoration characterization of microgeographic patterns of intraspecific diversity of the community to guarantee that restoration practices reach their goal, that is maximize the adaptive potential of the entire restored plant community. Overlooking these patterns may alter the balance between species in the community. Additionally, our comparison of summary statistics obtained from de novo‐ and reference‐based RAD‐seq pipelines shows that the genomic impact of restoration can be reliably monitored in species lacking prior genomic knowledge.     

Electrophoretic evidence concerning the relationship between Haplometrana and Glypthelmins (Digenea: Plagiorchiiformes)

Analysis of genetic data from a multilocus allozyme study, using cellulose acetate gel electrophoresis, of 2 trematode species, Glypthelmins californiensis Stafford, 1905, and Haplometrana intestinalis Lucker, 1931, from Rana aurora and Rana pretiosa, yielded a Nei's genetic distance coefficient between parasites of 0.70 +/- 0.10. This amount of genetic divergence is characteristic of comparisons between congeneric rather than intergeneric trematode species and supports the conclusion, corroborated by morphology and life history, that H. intestinalis is more closely related to some members of Glypthelmins than to any other species.     

Cross-species amplification of Eucalyptus microsatellite loci

This study examined the interspecific amplification of nuclear microsatellite loci developed mainly for eucalypts in the subgenus Symphyomyrtus across five species within the second most speciose subgenus, subgenus Eucalyptus. A set of eight to 10 loci, depending on taxon, have been identified that are highly variable and easily scored. The successful transfer of microsatellite loci to these eucalypt species sidesteps the expensive and time-consuming development of species-specific microsatellite libraries. This primer set will enable the examination and cross-species comparison of the genetic resources of commercially and ecologically important members of the subgenus Eucalyptus.     

LC-MS/MS with 2D mass mapping of skin secretions' peptides as a reliable tool for interspecies identification inside Rana esculenta complex

Identification of species constituting Rana esculenta complex represents a certain problem as two parental species Rana ridibunda and Rana lessonae form their hybrid R. esculenta, while external signs and sizes of the members of this complex are intersected. However the composition of skin secretion consisting mainly of peptides is different for the species of the complex. LC-MS/MS is an ideal analytical tool for the quantitative and qualitative analysis of these peptides. The results covering elemental composition of these peptides, their levels in the secretion, as well as their belonging to a certain family of peptides may be visualized by means of 2D mass maps. The proposed approach proved itself to be a perspective tool for the reliable identification of all 3 species constituting R. esculenta complex. Easy distinguishing between the species may be achieved using 2D maps as fingerprints. Besides this approach may be used to study hybridogenesis and mechanisms of hemiclonal transfer of genetic information, when rapid and reliable identification of species involved in the process is required.     

Phylogeny and form in fishes: Genetic and morphometric characteristics of dragonets (Foetorepus sp.) do not align

Measures of biodiversity are often hindered by a lack of methodological practices that distinguish cryptic or morphologically similar cohabiting species. This is particularly difficult for marine fishes where direct observations of the ecology and demography of populations are difficult. Dragonets (Foetorepus c.f. calauropomus) were collected as bycatch from research trawls deployed in waters off north-eastern Tasmania, Australia. Morphometric and genetic analyses were conducted on the 43 specimens recovered. Sequence analysis of two mitochondrial loci distinguished three genetic clusters, each having levels of dissimilarity consistent with species-level distinctions between other members of the Callionymidae. While clear morphological distinctions were observed between male and female fish, limited morphometric analyses could not differentiate between members of the three genetic groups. This finding highlights questions about the ability of genetically distinct but morphologically similar groups to occupy the same ecological niche, and points to additional and undescribed hidden biodiversity amongst cryptic species of fish.     

Millets genetic engineering: the progress made and prospects for the future

Millets comprise a highly variable small-seeded group of Poaceae members that can grow in extreme environmental conditions of drought, high temperature and low soil fertility hence, recognized as climate-resilient. Among millets, the phylogenetic closeness of Setaria with other agronomically important grasses like maize, sugarcane, and sorghum helped in its adoption as a translational model plant. Established efficient gene transfer methodology is a prerequisite for embracing plant species as models. However, genetic engineering of some of the economically important millets has been started in the 1990s, but inadequate progress made this group lag behind other members of Poaceae as rice, maize and wheat. Genetic transformation in millets has generally been achieved by a physical method of microprojectile bombardment, recently Agrobacterium-mediated gene transfer technique has also established in some of the millets but with very few reports. The central hindrance in millet transformation is its recalcitrant nature to regeneration through tissue culture techniques. Optimization of highly efficient regeneration procedure for each millet species is thus, necessary to establish advanced transformation system for them. The possibility of alternative transformation approaches is also discussed. The establishment of robust gene transfer methods whether it’s conventional in-vitro tissue culture dependent or in-planta are important for functional validation studies and would enable development of crop improvement strategies. This review presents the progress made on millet genetic transformation, discussing the major challenges that need to be overcome and future opportunities of transgenic techniques in various millets.

     

Molecular characterization of five medicinally important species of Typhonium (Araceae) through random amplified polymorphic DNA (RAPD)

The interrelationship of five medicinally important species of Typhonium (Araceae) including T. venosum, which was previously placed under the genus Sauromatum, was inferred by analysis of random amplified polymorphic DNA (RAPD). DNA from pooled leaf samples was isolated and RAPD analysis was performed using 20 decamer oligonucleotide primers. Out of a total of 245 bands amplified, 12 were found to be monomorphic while 233 bands were polymorphic including 86 species-specific bands. The genetic similarities were analyzed from the dendrogram constructed by the pooled RAPD data using a similarity index. The dendrogram showed two distinct clades, one containing T. roxburghii, T. trilobatum and T. venosum and the other containing the remainder two species, i.e. T. diversifolium and T. flagelliforme. Both the clusters shared a common node approx. at 23.7% level of similarity. The maximum similarity of 31.2% was observed between T. venosum and T. trilobatum. In view of its close genetic similarity with other members of Typhonium, transfer of Sauromatum venosum to the genus Typhonium and merger of the two genera was supported.     

Restoration of species‐rich grasslands by transfer of local plant material and its impact on species diversity and genetic variation—Findings of a practical restoration project in southeastern Germany

Restoration of species‐rich grasslands is a key issue of conservation. The transfer of seed‐containing local plant material is a proven technique to restore species‐rich grassland, since it potentially allows to establish genetically variable and locally adapted populations. In our study, we tested how the transfer of local plant material affected the species diversity and composition of restored grasslands and the genetic variation of the typical grassland plant species Knautia arvensis and Plantago lanceolata.For our study, we selected fifteen study sites in southeastern Germany. We analyzed species diversity and composition and used molecular markers to investigate genetic variation within and among populations of the study species from grasslands that served as source sites for restoration and grasslands, which were restored by transfer of green hay and threshed local plant material.The results revealed no significant differences in species diversity and composition between grasslands at source and restoration sites. Levels of genetic variation within populations of the study species Knautia arvensis and Plantago lanceolata were comparable at source and restoration sites and genetic variation among populations at source and their corresponding restoration sites were only marginal different.Our study suggests that the transfer of local plant material is a restoration approach highly suited to preserve the composition of species‐rich grasslands and the natural genetic pattern of typical grassland plant species.     

Sex differences in the influence of mothers on the sociosexual preferences of their offspring

The extent to which "nurture" as opposed to "nature" determines behavior and sociosexual preferences in mammalian species is controversial although most recent interest has focused on genetic determinants. We report here that if sheep and goats are cross-fostered at birth, but raised in mixed-species groups, their play and grooming behavior resembles that of their foster rather than genetic species. There are no sex differences in effects on these behaviors, and other species-specific behavior patterns such as aggression, browsing, climbing, and vocalizations are unaffected. In adulthood, cross-fostered males strongly prefer to socialize and mate with females of their foster mother's species, even if raised with a conspecific of their own species. Castration within 2 days of birth slightly reduces the level of this altered social preference but mating preference following short-term testosterone treatment is the same as for gonadally intact animals. Cross-fostered females also show significant preference for socializing with females and mating with males of their foster mother's species, although this effect is weaker than that in both gonadally intact and castrated males. When cross-fostered animals are placed in flocks containing members of only their genetic species for 3 years, male social and mating preferences for females of their mother's species remain virtually unaffected. Females change to display an exclusive mating preference for members of their genetic species in 1-2 years although they still retain some social interest in female members of their foster species. Thus, there are clear sex differences in the impact of the emotional bond between a mother and her offspring in these mammals. Effects on males are strongest and irreversibly maintained even after altering their social environment, whereas those on females are weaker and mating preferences are clearly adaptable in the face of altered social priorities. These sex differences are presumably caused by pre-, or early postnatal, organizational effects of sex hormones on the brain.     

DNA polymorphism in the genus Brucella

The genus Brucella has been described as consisting of six species, three of them including several biovars, which display a high degree of DNA homology by DNA-DNA hybridization. However, DNA polymorphism able to differentiate the six Brucella species and some of their biovars has been shown to exist. This work reviews the DNA variability in the genus Brucella and discusses the relationships between its members according to this genetic variability and a proposal for their evolution based on genetic diversity of the omp2 locus.     

History of the international embryo transfer society Part II

During 1979, service to members, including publication of abstracts of articles pertinent to interests of members, publication of bibliographies covering topics of embryo transfer, publication of the proceedings of the owners-managers workshop, service as a source of information and contacts for members, and updating members through publication of a newsletter, has been maintained and increased in scope. Membership has been growing steadily throughout the year and, at this writing, the membership has exceeded 200 from 22 countries. Thus, as the Society approaches the 1980 decade, it can do so with an optimism of not just survival but of continued growth in size, breadth of service to members, and range of species and topic interests. There is a good mix in the Society between the commercial and university research sectors interested in embryo transfer. Also, there is a good mix between animal scientists, veterinarians, physiologists, and others interested in this specialty interest area. It is expected that these factors will contributeto a healthy future for the Society.     

The genus Amycolatopsis: Indigenous plasmids, cloning vectors and gene transfer systems

The genus Amycolatopsis is a member of the phylogenetic group nocardioform actinomycetes. Most of the members of the genus Amycolatopsis are known to produce antibiotics. Additionally, members of this genus have been reported to metabolize aromatic compounds as the sole sources of carbon and energy. Development of genetic manipulation in Amycolatopsis has progressed slowly due to paucity of genetic tools and methods. The occurrence of indigenous plasmids in different species of Amycolatopsis is not very common. Till date, only three indigenous plasmids viz., pMEA100, pMEA300 and pA387 have been reported in Amycolatopsis species. Various vectors based on the indigenous plasmids, pMEA100, pMEA300 and pA387, have been constructed. These vectors have proved useful for molecular genetics studies of actinomycetes. Molecular genetic work with Amycolatopsis strains is not easy, since transformation methods have to be developed, or at least optimized, for each particular strain. Nonetheless, methods for efficient transformation (polyethyleneglycol (PEG) induced protoplast transformation, transformation by electroporation and direct transformation) have been developed and used successfully for the introduction of DNA into several Amycolatopsis species. The construction of plasmid cloning vectors and the development of gene transfer systems has opened up possibilities for studying the molecular genetics of these bacteria.     

Species Delimitation--a Geneious plugin for the exploration of species boundaries

Species Delimitation is a plugin to the Geneious software to support the exploration of species boundaries in a gene tree. The user assigns taxa to putative species and the plugin computes statistics relating to the probability of the observed monophyly or exclusivity having occurred by chance in a coalescent process. It also assesses the within and between species genetic distances to infer the probability with which members of a putative species might be identified successfully with tree-based methods.     

Contribution of horizontally acquired genomic islands to the evolution of the tubercle bacilli

The contribution of horizontal gene transfer (HGT) to the evolution of Mycobacterium tuberculosis -- the main causal agent of tuberculosis in humans -- and closely related members of the M. tuberculosis complex remains poorly understood. Using a combination of genome-wide parametric analyses, we have identified 48 M. tuberculosis chromosomal regions with atypical characteristics, potentially due to HGT. These specific regions account for 4.5% of the genome (199 kb) and include 256 genes. Many display features typical of the genomic islands found in other bacteria, including residual material from mobile genetic elements, flanking direct repeats, insertion in the vicinity of tRNA sequences, and genes with putative or documented virulence functions. Southern blotting analysis of nine of these 48 regions confirmed their presence in "Mycobacterium prototuberculosis," the ancestral species of the M. tuberculosis complex. Finally, our results strongly suggest that the ancestor of the tubercle bacilli was an environmental bacillus that exchanged genetic material with other bacterial species, including Proteobacteria in particular, present in its surroundings. This study describes a rational approach to searching for mycobacterial virulence genes, and highlights the importance of dissecting gene transfer networks to improve our understanding of mycobacterial pathogenicity and evolution.     

Genetic differentiation in the molluscan species Littorina rudis and Littorina arcana (Prosobranchia: Littorinidae)

Six populations of Littorina rudis and ihree of L. arcana were screened for elcctrophorctically dctci table variation at 21 enzyme loci. These species reproduce by ovoviviparity and oviparily respectively, and both are members of the L. saxatilis species complex. The mean coefficient of genetic identity between the two species was high (0.957) and no diagnostic loci were observed. Allele frequency differences are maintained in sympatric populations of the two species. Intraspecific values of/ ranged from 0.944 to 0.995 and both species showed marked inter-population genetic heterogeneity, a feature consistent with their limited powers of dispersal. Heterozygosity is high in all populations of both species. Populations of I. rudis have higher mean heterozygosities (= 0.153) then L. arcane ( H = 0.132).     

Mobilizable narrow host range plasmids as natural suicide vectors enabling horizontal gene transfer among distantly related bacterial species

Klebsiella pneumoniae 287-w carries three small narrow host range (NHR) plasmids (pIGMS31, pIGMS32, and pIGRK), which could be maintained in several closely related species of Gammaproteobacteria, but not in Alphaproteobacteria. The plasmids contain different mobilization systems (MOB), whose activity in Escherichia coli was demonstrated in the presence of the helper transfer system originating from plasmid RK2. The MOBs of pIGMS31 and pIGMS32 are highly conserved in many bacterial plasmids (members of the MOB family), while the predicted MOB of pIGRK has a unique structure, encoding a protein similar to phage-related integrases. The MOBs of pIGMS31 and pIGMS32 enabled the transfer of heterologous replicons from E. coli into both gammaproteobacterial and alphaproteobacterial hosts, which suggests that these NHR plasmids contain broad host range MOB systems. Such plasmids therefore represent efficient carrier molecules, which may act as natural suicide vectors promoting the spread of diverse genetic information (including other types of mobile elements, e.g. resistance transposons) among evolutionarily distinct bacterial species. Thus, mobilizable NHR plasmids may play a much more important role in horizontal gene transfer than previously thought.     

Allozymic variation and divergence in three species of Antirrhinum L. (Scrophulariaceae-Antirrhineae)

An allozymic study of three wild species of Antirrhinum L. A. lopesiamum Rothm., A. mollissimum Roihni. and A. microphyllum Rothm. is described. All are members of subsection Kickiella Rothm., and are narrow-range endemics of the Iberian Peninsula. The variability of the different loci, as well as the number and mobility of the alleles, differ among the three species, a demonstration of the usefulness of allozymes for the systematics of the genus. The finding of alleles unique to each species indicates high divergence among species suggesting ancient diversification, and supports the hypothesis of a geographical model of speciation. All three species show high levels of within-species variability, mainly partitioned within populations, while between populations genetic differentiation is low. Correlations between population size, sample size and genetic variability, and the usefulness of allozymic data for conservation purposes, are discussed.     

Low species barriers in halophilic archaea and the formation of recombinant hybrids

Speciation of sexually reproducing organisms requires reproductive barriers. Prokaryotes reproduce asexually but?often exchange DNA by lateral gene transfer mechanisms and recombination [1], yet distinct lineages are still observed. Thus, barriers to gene flow such as geographic isolation, genetic incompatibility or a physiological inability to transfer DNA represent potential underlying mechanisms behind preferred exchange groups observed in prokaryotes [2-6]. In Bacteria, experimental evidence showed that sequence divergence impedes homologous recombination between bacterial species [7-11]. Here we study interspecies gene exchange in halophilic archaea that possess a parasexual mechanism of genetic exchange that is functional between species [12, 13]. In this process, cells fuse forming a diploid state containing the full genetic repertoire of both parental cells, which facilitates genetic exchange and recombination. Later, cells separate, occasionally resulting in hybrids of the parental strains [14]. We show high recombination frequencies between Haloferax volcanii and Haloferax mediterranei, two species that have an average nucleotide sequence identity of 86.6%. Whole genome sequencing of Haloferax interspecies hybrids revealed the exchange of chromosomal fragments ranging from 310Kb to 530Kb. These results show that recombination barriers may be more permissive in halophilic archaea than they are in bacteria.