Recent events dominate interdomain lateral gene transfers between prokaryotes and eukaryotes and, with the exception of endosymbiotic gene transfers, few ancient transfer events persist

While there is compelling evidence for the impact of endosymbiotic gene transfer (EGT; transfer from either mitochondrion or chloroplast to the nucleus) on genome evolution in eukaryotes, the role of interdomain transfer from bacteria and/or archaea (i.e. prokaryotes) is less clear. Lateral gene transfers (LGTs) have been argued to be potential sources of phylogenetic information, particularly for reconstructing deep nodes that are difficult to recover with traditional phylogenetic methods. We sought to identify interdomain LGTs by using a phylogenomic pipeline that generated 13 465 single gene trees and included up to 487 eukaryotes, 303 bacteria and 118 archaea. Our goals include searching for LGTs that unite major eukaryotic clades, and describing the relative contributions of LGT and EGT across the eukaryotic tree of life. Given the difficulties in interpreting single gene trees that aim to capture the approximately 1.8 billion years of eukaryotic evolution, we focus on presence-absence data to identify interdomain transfer events. Specifically, we identify 1138 genes found only in prokaryotes and representatives of three or fewer major clades of eukaryotes (e.g. Amoebozoa, Archaeplastida, Excavata, Opisthokonta, SAR and orphan lineages). The majority of these genes have phylogenetic patterns that are consistent with recent interdomain LGTs and, with the notable exception of EGTs involving photosynthetic eukaryotes, we detect few ancient interdomain LGTs. These analyses suggest that LGTs have probably occurred throughout the history of eukaryotes, but that ancient events are not maintained unless they are associated with endosymbiotic gene transfer among photosynthetic lineages.

Inter- and intra-domain horizontal gene transfer, gain-loss asymmetry and positive selection mark the evolutionary history of the CBM14 family

Protein-carbohydrate interactions are ubiquitous in nature and at the core of many physiological processes of profound importance to health and disease. Specificity in protein-carbohydrate interactions is conferred by carbohydrate-binding modules (CBMs) that can accurately discriminate among the multitude of saccharides found in nature, thus targeting proteins to their particular substrates. Family 14 carbohydrate-binding modules (CBM14s), more specifically, are short modules that bind explicitly to chitin, the second most abundant carbohydrate in nature. Although considerable effort has been placed in elucidating protein-carbohydrate interactions at the molecular level for biological and biotechnological applications, in contrast the evolutionary relationships among these modules are minimally understood. Using the CBM14 family as an example, here we describe one of the first global molecular evolutionary analyses of a CBM family across all domains of life, with an emphasis on its origin, taxonomic distribution and pattern of diversification as a result of gene and module duplication, and positive selection. Our genome-wide searches recovered an impressive number of CBM14s from diverse lineages across nearly all domains of life. However, their highly disseminated distribution in taxa outside the Opisthokonta group strongly suggests a later evolutionary origin and elevated rates of inter- and intra-domain horizontal gene transfer. Moreover, accelerated rates of asymmetric gains and losses reveal a dynamic mode of birth-and-death evolution, whereas positive selection acting on paralogous CBM14-containing proteins suggest changes in substrate specificity and an increase in the functional promiscuity of this ancient CBM family. The importance of these results is discussed.

Evolutionary dynamics of Polynucelotide phosphorylases

Polynucleotide phosphorylase (PNPase) is an evolutionarily conserved 3'→5' phosphate-dependent exoribonucease belonging to the PDX family of proteins. It consists of two catalytic RNase PH domains (PNP1 and PNP2), an α-helical domain and two RNA-binding domains. The PNP1 and PNP2 domains share substantial sequence and structural homology with RNase PH (RPH), which is another PDX family member found in all the three major kingdoms of life, suggesting that these three domains originated from a common ancestor. Phylogenetic analysis (based on the PNPase/RNase PH sequence information for 43 vertebrate taxa) shows that PNP2 and RPH are sister taxa which arose through duplication of the ancestral PNP1 domain. Also, all three domains (PNP1, PNP2 and RPH), along with the KH and S1 domains have undergone significant and directional sequence change, as determined by branch and site-specific dN/dS analyses. In general, codons that show dN/dS ratios that are significantly greater than 1.0 are outside the ordered regions (α-helices and β-sheets) of these protein domains. In addition, sites that have been selected for mutagenesis in these proteins lie embedded in regions where there is a preponderance of codons with dN/dS values that are not significantly different from 0.0. Overall, this report is an attempt to further our understanding of the evolutionary history of these three protein domains, and define the evolutionary events that led to their refinement in the vertebrate lineage leading to mammals.

Phylogenetic relationships and selective pressure on gene families related to iron homeostasis in land plants

Iron is involved in many metabolic processes, such as respiration and photosynthesis, and therefore an essential element for plant development. Comparative analysis of gene copies between crops and lower plant groups can shed light on the evolution of genes important to iron homeostasis. A phylogenetic analysis of five metal homeostasis gene families (NAS, NRAMP, YSL, FRO, and IRT) selected in monocots, dicots, gymnosperms, and bryophytes was performed. The homologous genes were found using known iron homeostasis gene sequences of Oryza sativa, Arabidopsis thaliana, and Physcomitrella patens as queries. The phylogeny was constructed using bioinfomatics tools. A total of 243 gene sequences for 30 plant species were found. The evolutionary fingerprint analysis suggested a purifying selective pressure of iron homeostasis genes for most of the plant gene homologues. The NAS and YSL genes appear to accumulate more negative selection sites, suggesting a strong selective pressure on these two gene families. The divergence time analysis indicates IRT as the most ancient gene family and FRO as the most recent. NRAMP and YSL genes appear to share a close relationship in the evolution of iron homeostasis gene families.

Human polynucleotide phosphorylase (hPNPase(old-35)): an evolutionary conserved gene with an expanding repertoire of RNA degradation functions

Human polynucleotide phosphorylase (hPNPase(old-35)) is an evolutionary conserved RNA-processing enzyme with expanding roles in regulating cellular physiology. hPNPase(old-35) was cloned using an innovative 'overlapping pathway screening' strategy designed to identify genes coordinately regulated during the processes of cellular differentiation and senescence. Although hPNPase(old-35) structurally and biochemically resembles PNPase of other species, overexpression and inhibition studies reveal that hPNPase(old-35) has evolved to serve more specialized and diversified functions in humans. Targeting specific mRNA or non-coding small microRNA, hPNPase(old-35) modulates gene expression that in turn has a pivotal role in regulating normal physiological and pathological processes. In these contexts, targeted overexpression of hPNPase(old-35) represents a novel strategy to selectively downregulate RNA expression and consequently intervene in a variety of pathophysiological conditions.

Horizontal gene transfer in evolution: facts and challenges

The contribution of horizontal gene transfer to evolution has been controversial since it was suggested to be a force driving evolution in the microbial world. In this paper, I review the current standpoint on horizontal gene transfer in evolutionary thinking and discuss how important horizontal gene transfer is in evolution in the broad sense, and particularly in prokaryotic evolution. I review recent literature, asking, first, which processes are involved in the evolutionary success of transferred genes and, secondly, about the extent of horizontal gene transfer towards different evolutionary times. Moreover, I discuss the feasibility of reconstructing ancient phylogenetic relationships in the face of horizontal gene transfer. Finally, I discuss how horizontal gene transfer fits in the current neo-Darwinian evolutionary paradigm and conclude there is a need for a new evolutionary paradigm that includes horizontal gene transfer as well as other mechanisms in the explanation of evolution.

Horizontal gene transfer: sustaining pathogenicity and optimizing host-pathogen interactions

Successful host-pathogen interactions require the presence, maintenance and expression of gene cassettes called 'pathogenicity islands' (PAIs) and 'metabolic islands' (MAIs) in the respective pathogen. The products of these genes confer on the pathogen the means to recognize their host(s) and to efficiently evade host defences in order to colonize, propagate within the host and eventually disseminate from the host. Virulence effectors secreted by type III and type IV secretion systems, among others, play vital roles in sustaining pathogenicity and optimizing host-pathogen interactions. Complete genome sequences of plant pathogenic bacteria have revealed the presence of PAIs and MAIs. The genes of these islands possess mosaic structures with regions displaying differences in nucleotide composition and codon usage in relation to adjacent genome structures, features that are highly suggestive of their acquisition from a foreign donor. These donors can be other bacteria, as well as lower members of the Archaea and Eukarya. Genes that have moved from the domains Archaea and Eukarya to the domain Bacteria are true cases of horizontal gene transfer. They represent interdomain genetic transfer. Genetic exchange between distinct members of the domain Bacteria, however, represents lateral gene transfer, an intradomain event. Both horizontal and lateral gene transfer events have been used to facilitate survival fitness of the pathogen.