CORREDORES ECOLÓGICOS URBANOS: UM ESTUDO PARA CONECTAR PLANTAS, ANIMAIS E PESSOAS NA CIDADE DE VITÓRIA – ES

Ecological corridors are territorial strips that aim to reduce the impacts of fragmentation of ecosystems, restoring the interconnection between them, in order to facilitate the movement of species, enabling seed dispersal and gene exchange between isolated populations. The relevance of the theme lies in the contribution to sustainable urbanism, aligning with biophilia, with benefits for living beings, including humans, with better walking conditions, thermal and psychological comfort. The general objective of the work was to delineate an urban ecological corridor in the continental portion of the city of Vitória/ES, in order to connect three isolated Environmental Protection Zones and benefit their essential occupants: the human species, the flora and the fauna. Exploratory studies and field visits were conducted, supported by Urbanism and Ecology literature, based on the definition of the connection axes and the recomposition of road profiles. The result achieved is an ecological corridor adapted to the existing roads, from the intensification of forestation and the implementation of gantries and elevated walkways for animal crossings. The insertion of aerial crossings and biodiversity corridors will bring a differential to the quality of life and ecological diversity for the local population.

Horizontal gene transfer in 44 early diverging fungi favors short, metabolic, extracellular proteins from associated bacteria

Numerous studies have been devoted to individual cases of horizontally acquired genes in fungi. It has been shown that such genes expand their metabolic capabilities and contribute to their adaptations as parasites or symbionts. Some studies have provided a more extensive characterization of the horizontal gene transfer (HGT) in Dikarya. However, in the early diverging fungi (EDF), the overall influence of HGT on the ecological adaptation and evolution is largely unknown. In order to fill this gap, we have designed a computational pipeline to obtain a sample of over 600 phylogenetic trees with evidence for recent to moderately old HGT across multiple EDF genomes ranging from Chytridiomycota and Blastocladiomycota to Mucoromycota. Our pipeline is designed to obtain a small sample of reliable HGT events with a possibly minimal number of false detections that distort the overall statistical patterns. We show that transfer rates differ greatly between closely related species and strains, but the ancestrally aquatic fungi are generally more likely to acquire foreign genetic material than terrestrial ones. A close ecological relationship with another organism is a predisposing condition, but does not always result in an extensive gene exchange, with some fungal lineages showing a preference for HGT from loosely associated soil bacteria.ImportanceAlthough it is now recognized that horizontal gene exchange is a factor influencing the adaptation and evolution of eukaryotic organisms, the so far described cases in early diverging fungi (EDF) are fragmentary, and a large-scale comprehensive study is lacking. We have designed a methodology to obtain a reliable, statistical sample of inter-kingdom xenologs across the tree of life of EDF to give a preliminary characterization of their general properties and patterns. We study how different fungal lineages vary in terms of the number of xenologs, what are their ecological associations, and the molecular properties of proteins encoded by the acquired genes. Our results help to better understand to what extent and in what way the incorporation of foreign genetic material shaped the present biodiversity of fungi.

Why do plasmids manipulate the expression of bacterial phenotypes?

Conjugative plasmids play an important role in bacterial evolution by transferring niche-adaptive traits between lineages, thus driving adaptation and genome diversification. It is increasingly clear, however, that in addition to this evolutionary role, plasmids also manipulate the expression of a broad range of bacterial phenotypes. In this review, we argue that the effects that plasmids have on the expression of bacterial phenotypes may often represent plasmid adaptations, rather than mere deleterious side effects. We begin by summarizing findings from untargeted omics analyses, which give a picture of the global effects of plasmid acquisition on host cells. Thereafter, because many plasmids are capable of both vertical and horizontal transmission, we distinguish plasmid-mediated phenotypic effects into two main classes based upon their potential fitness benefit to plasmids: (i) those that promote the competitiveness of the host cell in a given niche and thereby increase plasmid vertical transmission, and (ii) those that promote plasmid conjugation and thereby increase plasmid horizontal transmission. Far from being mere vehicles for gene exchange, we propose that plasmids often act as sophisticated genetic parasites capable of manipulating their bacterial hosts for their own benefit. This article is part of the theme issue ‘The secret lives of microbial mobile genetic elements’.

Pseudomonas Phage MD8: Genetic Mosaicism and Challenges of Taxonomic Classification of Lambdoid Bacteriophages

Pseudomonas phage MD8 is a temperate phage isolated from the freshwater lake Baikal. The organisation of the MD8 genome resembles the genomes of lambdoid bacteriophages. However, MD8 gene and protein sequences have little in common with classified representatives of lambda-like phages. Analysis of phage genomes revealed a group of other Pseudomonas phages related to phage MD8 and the genomic layout of MD8-like phages indicated extensive gene exchange involving even the most conservative proteins and leading to a high degree of genomic mosaicism. Multiple horizontal transfers and mosaicism of the genome of MD8, related phages and other λ-like phages raise questions about the principles of taxonomic classification of the representatives of this voluminous phage group. Comparison and analysis of various bioinformatic approaches applied to λ-like phage genomes demonstrated different efficiency and contradictory results in the estimation of genomic similarity and relatedness. However, we were able to make suggestions for the possible origin of the MD8 genome and the basic principles for the taxonomic classification of lambdoid phages. The group comprising 26 MD8-related phages was proposed to classify as two close genera belonging to a big family of λ-like phages.

Morphological ghosts of introgression in Darwin’s finch populations

Many species of plants, animals, and microorganisms exchange genes well after the point of evolutionary divergence at which taxonomists recognize them as species. Genomes contain signatures of past gene exchange and, in some cases, they reveal a legacy of lineages that no longer exist. But genomic data are not available for many organisms, and particularly problematic for reconstructing and interpreting evolutionary history are communities that have been depleted by extinctions. For these, morphology may substitute for genes, as exemplified by the history of Darwin’s finches on the Galápagos islands of Floreana and San Cristóbal. Darwin and companions collected seven specimens of a uniquely large form of Geospiza magnirostris in 1835. The populations became extinct in the next few decades, partly due to destruction of Opuntia cactus by introduced goats, whereas Geospiza fortis has persisted to the present. We used measurements of large samples of G. fortis collected for museums in the period 1891 to 1906 to test for unusually large variances and skewed distributions of beak and body size resulting from introgression. We found strong evidence of hybridization on Floreana but not on San Cristóbal. The skew is in the direction of the absent G. magnirostris. We estimate introgression influenced 6% of the frequency distribution that was eroded by selection after G. magnirostris became extinct on these islands. The genetic residuum of an extinct species in an extant one has implications for its future evolution, as well as for a conservation program of reintroductions in extinction-depleted communities.

Genetic structure of the water frog (Pelophylax esculentus complex) populations in the south of the Central Russian Upland

BACKGROUND: The water frog (Pelophylax esculentus complex) is hybrid in composition. In view of the fact that a large number of data on the species composition of the water frog and very scarce material on the genetic structure of populations are available in the literature, we aimed to analyze the genetic structure of populations of the water frog in the southern part of the Middle Russian upland, which was one of the refugia for many species during the glacial epoch and the center of dispersion in the postglacial time, based on DNA microsatellite markers. MATERIALS AND METHODS: The study involved 36 local populations. DNA variability was analyzed by multiplex SSR-PCR. Seven loci (Res 14, Res 15, Res 17, Res 22, Rrid059A, Rrid082A, and Rrid171A) were used for amplification. Fragment analysis of PCR products was performed on an ABI PRISM 3500 automated capillary DNA sequencer (Applied Biosystems, USA). RESULTS: The total number of alleles detected ranged from 13 to 41. The effective number of alleles (Ae) averaged 4.569 0.219, the Chenon index (I) 1.567 0.04, level of expected heterozygosity (Не) 0.68 0.01. According to Wrights model, the greatest contribution to genetic variability is made by the heterogeneity of individuals within populations, some of which are of a hybrid nature (Fis = 0.281 0.069, Fit = 0.413 0.053, Fst = 0.180 0.017). The average indicator of the intensity of gene exchange between populations (Nm) was 1.212 0.142 individuals per generation. The calculation of the effective abundance using the LD method indicates a high level of viability of the studied groups of the frogs. CONCLUSION: The results demonstrated a high level of genetic diversity and viability of most of the studied groups, which, due to the intense gene exchange between them, can represent a single panmictic population. The data of the genetic analysis support the active adaptation of P. esculentus complex to living in an urbanized environment.

Viral-eukaryotic gene exchange drives infection mode and cellular evolution

Gene exchange between viruses and their hosts acts as a key facilitator of horizontal gene transfer and is thought to be a major driver of evolutionary change 1–3. Our understanding of this process comes primarily from bacteria and phage co-evolution4, but the mode and functional significance of gene transfers between eukaryotes and their viruses remains more anecdotal. Here we show that viral-eukaryotic gene exchange can define infection strategies and has recurrently influenced eukaryotic evolution. Using a systematic, phylogenetically-informed approach, we characterized viral-eukaryotic gene exchange across diverse taxa, identifying thousands of transfers, and revealing their frequency, taxonomic distribution, and projected functions, across the eukaryotic tree of life. Eukaryote-derived viral genes revealed common viral host-manipulation strategies, including the key cellular pathways and compartments targeted during infection, identifying potential targets for broad-spectrum host-targeted antiviral therapeutics. Furthermore, viral-derived eukaryotic genes exposed a recurring role for viral glycosyltransferases in the diversification of eukaryotic morphology, as viral-derived genes have impacted the evolution of structures as diverse as algal cell walls, trypanosome mitochondria, and animal tissues. These findings illuminate the nature of viral-eukaryotic gene exchange and its impact on the biology of viruses and their eukaryotic hosts, providing novel perspectives for understanding viral infection mechanisms and revealing the influence of viruses on eukaryotic evolution.

Causes and consequences of bacteriophage diversification via genetic exchanges across lifestyles and bacterial taxa

Bacteriophages (phages) evolve rapidly by acquiring genes from other phages leading to mosaic genomes. Here, we identify numerous genetic transfers between distantly related phages and aim at understanding their frequency, consequences and the conditions favoring them. Gene flow tends to occur between phages that are enriched for recombinases, transposases and non-homologous end joining, suggesting that both homologous and illegitimate recombination contribute to gene flow. Phage family and host phyla are strong barriers to gene exchange, but phage lifestyle is not. Even if we observe four times more recent transfers between temperate phages than between other pairs, there is extensive gene flow between temperate and virulent phages, and between the latter. These predominantly involve virulent phages with large genomes previously classed as low gene flux, and lead to the preferential transfer of genes encoding functions involved in cell energetics, nucleotide metabolism, DNA packaging and injection, and virion assembly. Such exchanges may contribute to the observed twice larger genomes of virulent phages. We used genetic transfers, which occur upon co-infection of a host, to compare phage host range. We found that virulent phages have broader host ranges and can mediate genetic exchanges between narrow host range temperate phages infecting distant bacterial hosts, thus contributing to gene flow between virulent phages, as well as between temperate phages. This gene flow drastically expands the gene repertoires available for phage and bacterial evolution, including the transfer of functional innovations across taxa.

Who put the film in biofilm? The migration of a term from wastewater engineering to medicine and beyond

Sessile microorganisms were described as early as the seventeenth century. However, the term biofilm arose only in the 1960s in wastewater treatment research and was adopted later in marine fouling and in medical and dental microbiology. The sessile mode of microbial life was gradually recognized to be predominant on Earth, and the term biofilm became established for the growth of microorganisms in aggregates, frequently associated with interfaces, although many, if not the majority, of them not being continuous “films” in the strict sense. In this sessile form of life, microorganisms live in close proximity in a matrix of extracellular polymeric substances (EPS). They share emerging properties, clearly distinct from solitary free floating planktonic microbial cells. Common characteristics include the formation of synergistic microconsortia, using the EPS matrix as an external digestion system, the formation of gradients and high biodiversity over microscopically small distances, resource capture and retention, facilitated gene exchange as well as intercellular communication, and enhanced tolerance to antimicrobials. Thus, biofilms belong to the class of collective systems in biology, like forests, beehives, or coral reefs, although the term film addresses only one form of the various manifestations of microbial aggregates. The uncertainty of this term is discussed, and it is acknowledged that it will not likely be replaced soon, but it is recommended to understand these communities in the broader sense of microbial aggregates.

Paracoccidioides Genomes Reflect High Levels of Species Divergence and Little Interspecific Gene Flow

ABSTRACTThe fungus Paracoccidioides is a prevalent human pathogen endemic to South America. The genus is composed of five species. In this report, we use 37 whole-genome sequences to study the allocation of genetic variation in Paracoccidioides. We tested three genome-wide predictions of advanced speciation, namely, that all species should be reciprocally monophyletic, that species pairs should be highly differentiated along the whole genome, and that there should be low rates of interspecific gene exchange. We find support for these three hypotheses. Species pairs with older divergences show no evidence of gene exchange, while more recently diverged species pairs show evidence of modest rates of introgression. Our results indicate that as divergence progresses, species boundaries become less porous among Paracoccidioides species. Our results suggest that species in Paracoccidioides are at different stages along the divergence continuum.IMPORTANCEParacoccidioides is the causal agent of a systemic mycosis in Latin America. Most of the inference of the evolutionary history of Paracoccidioides has used only a few molecular markers. In this report, we evaluate the extent of genome divergence among Paracoccidioides species and study the possibility of interspecific gene exchange. We find that all species are highly differentiated. We also find that the amount of gene flow between species is low and in some cases is even completely absent in spite of geographic overlap. Our study constitutes a systematic effort to identify species boundaries in fungal pathogens and to determine the extent of gene exchange among fungal species.