Speciation and DNA barcodes: testing the effects of dispersal on the formation of discrete sequence clusters

Large-scale sequencing of short mtDNA fragments for biodiversity inventories ('DNA barcoding') indicates that sequence variation in animal mtDNA is highly structured and partitioned into discrete genetic clusters that correspond broadly to species-level entities. Here we explore how the migration rate, an important demographic parameter that is directly related to population isolation, might affect variation in the strength of mtDNA clustering among taxa. Patterns of mtDNA variation were investigated in two groups of beetles that both contain lineages occupying habitats predicted to select for different dispersal abilities: predacious diving beetles (Dytiscidae) in the genus Bidessus from lotic and lentic habitats across Europe and darkling beetles (Tenebrionidae) in the genus Eutagenia from sand and other soil types in the Aegean Islands. The degree of genetic clustering was determined using the recently developed 'mixed Yule coalescent' (MYC) model that detects the transition from between-species to within-population branching patterns. Lineages from presumed stable habitats, and therefore displaying lower dispersal ability and migration rates, showed greater levels of mtDNA clustering and geographical subdivision than their close relatives inhabiting ephemeral habitats. Simulations of expected patterns of mtDNA variation under island models showed that MYC clusters are only detected when the migration rates are much lower than the value of Nm=1 typically used to define the threshold for neutral genetic divergence. Therefore, discrete mtDNA clusters provide strong evidence for independently evolving populations or species, but their formation is suppressed even under very low levels of dispersal.     

Phylogenetics of pond and lake lifestyles in Chaoborus midge larvae

Abstract . Aquatic invertebrates experience strong trade-offs between habitats due to the selective effects of different predators. Diel vertical migration and small body size are thought to be effective strategies against fish predation in lakes. In the absence of fish in small ponds, migration is ineffective against invertebrate predators and large body size is an advantage. Although widely discussed, this phenomenon has never been tested in a phylogenetic context. We reconstructed a mitochondrial DNA (mtDNA) tree to investigate the phylogenetic distribution of pond and lake lifestyles among 10 species of northern temperate Chaoborus midge larvae. The mtDNA tree is similar to previous morphological trees for Chaoborus , the only difference being the disruption of the subgenus Chaoborus sensu stricto. At least three shifts have occurred between pond and lake lifestyles, each time associated with evolution of diel vertical migration in the lake taxon. The trend in larval body size with habitat type is sensitive to tree and character reconstruction methods, only weakly consistent with the effects of fish predation. Despite long time periods over which adaptation to each habitat type could have occurred, there remains significant phylogenetic heritability in larval body size. The tree provides a framework for comparative studies of the metapopulation genetic consequences of pond and lake lifestyles.     

Using exon and intron sequences of the gene Mp20 to resolve basal relationships in Cicindela (Coleoptera:Cicindelidae)

The genus Cicindela (Coleoptera: Cicindelidae) is a species-rich cosmopolitan group of tiger beetles useful for comparing clade diversification worldwide. Knowledge about relationships of major groups is important for this analysis but basal nodes in Cicindela have been difficult to resolve with standard mtDNA markers. Here we developed the Mp20 gene, a single-copy nuclear marker coding for a muscle-associated protein in insects, for phylogenetic analysis of basal groups of Cicindela. Nearly full-length sequences were obtained for 51 cicindelids, including major taxonomic groups from all continents. Sequences of Mp20 were between 1.2 and 1.7 kb and spanning three introns. Phylogenetic signal of exon and intron sequences was compared with that from four gene regions of mtDNA (COI, COIII, Cytb, 16S rRNA; 2.4 kb total). Because introns differed in length, sequence alignment was conducted using various procedures of phenetic and parsimony-based character coding of indels to assess their phylogenetic information content, but major nodes were recovered consistently. Mp20 sequences contributed two thirds of the total support of the combined analysis, with most signal from the introns. We found major clades of Cicindela to be geographically largely coincident with continental regions, confined to Australasia, the Holarctic, the Indian subcontinent, Africa, and South and Central America. Clock estimates using various maximum-likelihood (ML) branch length calculations resulted in roughly similar divergence times whether Mp20 exon, introns, or mtDNA were used, and they were not greatly affected by different procedures for coding and optimizing indel characters. Based on existing clock calibrations in Cicindela, basal splits of continental lineages occurred in the mid-Miocene, placing the radiation of basal groups of Cicindela to a period when their open-vegetation habitats expanded globally.     

The crystal structure at 2A resolution of the Ca2+ -binding protein S100P

S100P is a small calcium-binding protein of the S100 EF-hand-containing family of proteins. Elevated levels of its mRNA are reported to be associated with the progression to hormone independence and metastasis of prostate cancer and to be associated with loss of senescence in human breast epithelial cells in vitro. The first structure of human recombinant S100P in calcium-bound form is now reported at 2.0A resolution by X-ray diffraction. A flexible linker connects the two EF-hand motifs. The protein exists as a homodimer formed by non-covalent interactions between large hydrophobic areas on monomeric S100P. Experiments with an optical biosensor to study binding parameters of the S100P monomer interaction showed that the association rate constant was faster in the presence of calcium than in their absence, whereas the dissociation rate constant was independent of calcium. The K(d) values were 64(+/-24)nM and 2.5(+/-0.8) microM in the presence and in the absence of calcium ions, respectively. Dimerization of S100P is demonstrated in vivo using the yeast two-hybrid system. The effect of mutation of specific amino acids suggests that dimerization in vivo can be affected by amino acids on the dimer interface and in the hydrophobic core.     

Saturating effects of species diversity on life-history evolution in bacteria

Species interactions can play a major role in shaping evolution in new environments. In theory, species interactions can either stimulate evolution by promoting coevolution or inhibit evolution by constraining ecological opportunity. The relative strength of these effects should vary as species richness increases, and yet there has been little evidence for evolution of component species in communities. We evolved bacterial microcosms containing between 1 and 12 species in three different environments. Growth rates and yields of isolates that evolved in communities were lower than those that evolved in monocultures, consistent with recent theory that competition constrains species to specialize on narrower sets of resources. This effect saturated or reversed at higher levels of richness, consistent with theory that directional effects of species interactions should weaken in more diverse communities. Species varied considerably, however, in their responses to both environment and richness levels. Mechanistic models and experiments are now needed to understand and predict joint evolutionary dynamics of species in diverse communities.     

Difluoro analogue of UCS15A triggers activation of exogenously expressed c-Src in HCT 116 human colorectal carcinoma cells

UCS 15A, an antibiotic produced by Streptomyces sp., has been reported to specifically disrupt SH3 domain-mediated interactions in eukaryotic cells. Interestingly, in the case of the non-receptor tyrosine kinase Src, UCS15A was effective in suppressing the SH3 domain-mediated intermolecular rather than intramolecular interactions, and thus prevented Src interactions with certain downstream effectors without affecting Src kinase activity. Here the synthesis of a novel difluoro analogue of UCS15A is described. The effects of this compound (8) on Src activity were tested in HCT 116 colorectal carcinoma cells engineered for inducible expression of c-Src. The presence of compound (8) resulted in the increased activity of the induced c-Src implicating that (8) acts as a c-Src activator in vivo. These observations are supported by computer modelling studies which suggest that the aldehyde group of (8) may covalently bind to a lysine residue in the SH2-kinase linker region situated in the proximity of the SH3 domain, which could promote a conformational change resulting in increased Src activity.     

Quantifying the effects of the break up of Pangaea on global terrestrial diversification with neutral theory

The historic richness of most taxonomic groups increases substantially over geological time. Explanations for this fall broadly into two categories: bias in the fossil record and elevated net rates of diversification in recent periods. For example, the break up of Pangaea and isolation between continents might have increased net diversification rates. In this study, we investigate the effect on terrestrial diversification rates of the increased isolation between land masses brought about by continental drift. We use ecological neutral theory as a means to study geologically complex scenarios tractably. Our models show the effects of simulated geological events that affect all species equally, without the added complexity of further ecological processes. We find that continental drift leads to an increase in diversity only where isolation between continents leads to additional speciation through vicariance, and where higher taxa with very low global diversity are considered. We conclude that continental drift by itself is not sufficient to account for the increase in terrestrial species richness observed in the fossil record.     

Critical plant K concentrations for growth and problems in the diagnosis of nutrient deficiencies by plant analysis

Ryegrass was grown in a glasshouse in pots of soil at a range of available K, either with or without added Na. Critical plant K concentrations for growth were related to different functions of K in plants. Critical K concentrations were 126 mM (1.9% in DM) for biophysical functions in low-Na soils 82 mM (1.3% in DM), for biophysical functions in high-Na soils, and 46 mM (0.8% in DM) for biochemical functions. The implications of the findings for plant testing and the benefits of expressing plant K concentrations on a tissue water basis are discussed.