Molecular and iridescent feather reflectance data reveal recent genetic diversification and phenotypic differentiation in a cloud forest hummingbird

The present day distribution and spatial genetic diversity of Mesoamerican biota reflects a long history of responses to habitat change. The hummingbird Lampornis amethystinus is distributed in northern Mesoamerica, with geographically disjunct populations. Based on sampling across the species range using mitochondrial DNA (mtDNA) sequences and nuclear microsatellites jointly analysed with phenotypic and climatic data, we (1) test whether the fragmented distribution is correlated with main evolutionary lineages, (2) assess body size and plumage color differentiation of populations in geographic isolation, and (3) evaluate a set of divergence scenarios and demographic patterns of the hummingbird populations. Analysis of genetic variation revealed four main groups: blue‐throated populations (Sierra Madre del Sur); two groups of amethyst‐throated populations (Trans‐Mexican Volcanic Belt and Sierra Madre Oriental); and populations east of the Isthmus of Tehuantepec (IT) with males showing an amethyst throat. The most basal split is estimated to have originated in the Pleistocene, 2.39–0.57 million years ago (MYA), and corresponded to groups of populations separated by the IT. However, the estimated recent divergence time between blue‐ and amethyst‐throated populations does not correspond to the 2‐MY needed to be in isolation for substantial plumage divergence, likely because structurally iridescent colors are more malleable than others. Results of species distribution modeling and Approximate Bayesian Computation analysis fit a model of lineage divergence west of the Isthmus after the Last Glacial Maximum (LGM), and that the species’ suitable habitat was disjunct during past and current conditions. These results challenge the generality of the contraction/expansion glacial model to cloud forest‐interior species and urges management of cloud forest, a highly vulnerable ecosystem to climate change and currently facing destruction, to prevent further loss of genetic diversity or extinction.     

Angiotensin II induces focal adhesion kinase/paxillin phosphorylation and cell migration in human umbilical vein endothelial cells

In the present study, we demonstrated that Ang II provokes a transitory enhancement of focal adhesion kinase (FAK) and paxillin phosphorylation in human umbilical endothelial cells (HUVEC). Moreover, Ang II induces a time- and dose-dependent augmentation in cell migration, but does not affect HUVEC proliferation. The effect of Ang II on FAK and paxillin phosphorylation was markedly attenuated in cells pretreated with wortmannin and LY294002, indicating that phosphoinositide 3-kinase (PI3K) plays an important role in regulating FAK activation. Similar results were observed when HUVEC were pretreated with genistein, a non-selective tyrosine kinases inhibitor, or with the specific inhibitor PP2 for Src family kinases, demonstrating the involvement of protein tyrosine kinases, and particularly Src family of tyrosine kinases, in the downstream signalling pathway of Ang II receptors. Furthermore, FAK and paxillin phosphorylation was markedly blocked after treatment of HUVEC with AG1478, a selective inhibitor of epidermal growth factor receptor (EGFR) phosphorylation. Pretreatment of cells with inhibitors of PI3K, Src family tyrosine kinases, and EGFR also decreased HUVEC migration. In conclusion, these results suggest that Ang II mediates an increase in FAK and paxillin phosphorylation and induces HUVEC migration through signal transduction pathways dependent on PI3K and Src tyrosine kinase activation and EGFR transactivation.     

New insights into the signaling pathways controlling defense gene expression in rice roots during the arbuscular mycorrhizal symbiosis

Mycorrhizal fungi form a mutualistic relationship with the roots of most plant species. This association provides the arbuscular mycorrhizal (AM) fungus with sugars while the fungus improves the uptake of water and mineral nutrients in the host plant. Moreover, the induction of defense gene expression in mycorrhizal roots has been described. While salicylic acid (SA)-regulated Pathogenesis-Related (PR) proteins accumulate in rice roots colonized by the AM fungus G. intraradices , the SA content is not significantly altered in the mycorrhizal roots. Sugars, in addition to being a source of carbon for the fungus, might act as signals for the control of defense gene expression. We hypothesize that increased demands for sugars by the fungus might be responsible for the activation of the host defense responses which will then contribute to the stabilization of root colonization by the AM fungus. An excessive root colonization might change a mutualistic association into a parasitic association.Key words: Glomus intraradices, glucose, fructose, Oryza sativa, pathogenesis-related (PR), salicylic acid (SA), sucrose, sugarsThe arbuscular mycorrhizal (AM) fungi are obligate biotrophs that establish mutualistic associations with the roots of over 90% of all plant species. AM fungi improve the uptake of water and mineral nutrients in the host plant, mainly phosphorus and nitrogen, in exchange for sugars generated from photosynthesis. The benefits of the AM symbiosis on plant fitness are largely known, including increased ability to cope with biotic and abiotic stresses.^1,2 In fact, the amount of carbon allocated to mycorrhizal roots might be up 20% of the total photosynthate income.³ During root colonization, the AM fungus penetrates into the root through the epidermal cells and colonizes the cortex. In the root cortical cells, the fungus forms highly branched structures, called arbuscules, which are the site of the major nutrient exchange between the two symbionts.^4,5 The legumes Medicago truncatula and Lotus japonicus have been widely adopted as the reference species for studies of the AM symbiosis. Cereal crops and rice in particular are also able to establish symbiotic associations with AM fungi.^6,7 Arabidopsis thaliana, the model system for functional genomics in plants, has no mycorrhization ability.It is also well known that plants have evolved inducible defense systems to protect themselves from pathogen invasion. Challenge with a pathogen activates a complex variety of defense reactions that includes the rapid generation of reactive oxygen species (ROS), changes in ion fluxes across the plasma membrane, cell wall reinforcement and production of antimicrobial compounds (e.g., phytoalexins).⁸ One of the most frequently observed biochemical events following pathogen infection is the accumulation of pathogenesis-related (PR) proteins.⁹ For some PR proteins antimicrobial activities have been described (e.g., chitinases, β-1,3-glucanases, thionins or defensins). The plant responses to pathogen attack are activated both locally and systemically. The phytohormones salicyclic acid (SA), jasmonic acid (JA), ethylene (ET) and abscisic acid (ABA) act as defense signaling molecules for the activation of defense responses.¹⁰ Whereas SA-dependent signaling often provides resistance to biotrophic pathogens, JA/ET-dependent signaling is effective against necrotrophic pathogens.¹¹ During plant-pathogen interactions, cross-talk between SA and JA/ET signaling pathways provides the plant with the opportunity to prioritize one pathway over another to efficiently fine-tune its defense response to the invading pathogen. Contrary to biotrophic pathogens which exhibit a high degree of host specificity, the AM fungi manage to colonize a broad range of plant species.Evidence also exists on the existence of common mechanisms and signaling pathways governing responses to AM and pathogenic fungi.^2,12,13 Alterations in the content of hormones acting as defense signals also appear to occur during the AM symbiosis. As an example, JA and its derivatives (jasmonates) are believed to play an important role during the AM symbiosis in M. truncatula or tomato plants.^14,15 However, controversial data exists in the literature concerning the involvement of the various defense-related hormones during AM functioning. In particular, our current understanding of SA signaling during AM symbiosis is not clear.We recently documented the symbiotic proteome of the rice roots during their interaction with the AM fungus Glomus intraradices.⁶ A majority of the proteins identified in the rice symbiotic proteome are proteins with a function in defense responses or sugar metabolism. Among the proteins that accumulated at high levels in mycorrhizal rice roots compared to non mycorrhizal roots were PR proteins belonging to different PR families, such as PR1, chitinases (PR3), PR5 and several PR10 proteins. The PR1 and PBZ1 (a member of the PR10 family of PR proteins) genes are considered markers of the activation of defense responses in rice plants.^16,17 Of interest, the expression of many of the AM-regulated PR genes was previously reported to be induced by SA.^16,18–20 Proteins acting as oxidative stress protectors, such as ascorbate peroxidases, peroxidases and glutathione-S-transferases, also accumulated in mycorrhizal rice roots. Together, these observations support that the plant''s immune system is activated in the mycorrhizal rice root.To gain further insights into the molecular mechanisms governing PR gene expression in mycorrhizal roots, the SA and sugar contents of mycorrhizal roots were determined. Towards this end, rice (Oryza sativa ssp. japonica cv. Senia) plants were inoculated with the AM fungus G. intraradices.⁶ At 42 days post-inoculation (dpi), the overall colonization of the rice roots ranged from 25 to 30% as judged by microscopical observations of trypan blue-stained roots (results not shown; similar results were reported previously in reference ⁶). By this time, all the events related to fungal development, namely intraradical hyphae, arbuscules at different morphological stages of formation and vesicles, were present in G. intraradices-inoculated roots, thus confirming the establishment of the symbiotic association in the rice roots.Knowing that many AM-regulated proteins are also regulated by SA in rice roots, it was of interest to determine whether the level of endogenous SA increases in mycorrhizal roots compared to non mycorrhizal roots. In plants, intracellular SA is found predominantly as free SA and its sugar conjugate SA-glucoside (SAG). Root samples were analyzed for SA content, by measuring the level of both free SA and SAG as previously described in reference ²¹. This analysis revealed no significant differences, neither in free nor in SAG, between mycorrhizal and non mycorrhizal roots (Fig. 1). Then, it appears that although the expression of PR genes (functioning in a SA-dependent manner) is activated during the AM symbiosis, the fungus G. intraradices do not exploit the SA-mediated signaling pathway for induction of PR genes.Open in a separate windowFigure 1SA content, free SA and SA-glucoside (SAG) conjugate, in roots of mock-inoculated (−Gi) and G. intraradices-inoculated (+Gi) rice plants. SA determination was carried out at 42 days post-inoculation with G. intraradices. Three independent biological samples and three replicates per biological sample were used for quantification of SA. Two out of the three samples were the same ones used for the characterization of the symbiotic proteome in which the accumulation of SA-regulated PR genes was observed in reference ⁶. FW, fresh weight. Bars represent the means ± standard error.On the other hand, a direct link between sugar metabolism and the plant defense response has been established, including the phenomenon of high sugarmediated resistance and the finding that various key PR genes are induced by sugars. Transgenic approaches that lead to alterations in photoassimilate partitioning, either sucrose or hexoses, also alter PR gene expression.^22,23 In other studies, a SA-independent induction of PR genes by soluble sugars, sucrose, glucose and fructose, was reported in reference ²⁴.Sucrose, the main form of assimilated carbon during photosynthesis, is transported to the root tissues via the phloem where it becomes available to the root cells. As previously mentioned, characterization of the rice symbiotic proteome revealed alterations in the accumulation of proteins involved in sugar metabolism, such as enzymes involved in glucolysis/gluconeogenesis (e.g., fructose-1,6-bisphophate aldolase, enolase) or in pentose interconversions (e.g., UDP-glucose dehydrogenase).⁶ Because the plant provides sugars to the fungus, it is not surprising to find alterations in enzymes involved in sugar metabolism in the mycorrhizal roots. Evidence also supports that AM fungi acquire hexoses from the host cell and transform it into trehalose and glycogen, the typical sugars in the fungus.²⁵ Utilization of sucrose then requires hydrolysis in the plant cell which can be performed by sucrose synthase, producing UDP-glucose and fructose or invertases, producing glucose and fructose. Along with this, increased activities of invertases and sucrose synthases or increased expression of their corresponding genes, have been described during AM symbiotic interactions.^26,27 Very recently, the MtSucS1 sucrose synthase gene was reported to be essential for the establishment and maintenance of the AM symbiosis in Medicago truncatula.²⁸ In this context, we decided to explore whether colonization by G. intraradices has an effect on the accumulation of soluble sugars in rice roots.Sucrose, glucose and fructose content were measured enzymatically²³ in the rice roots at 42 days post-inoculation with G. intraradices . A tendency to a higher sucrose level was observed in mycorrhizal roots compared to non-mycorrhizal roots (Fig. 2). Concerning the hexose content, the mycorrhizal roots had a significantly lower hexose, both glucose and fructose levels, compared to non-mycorrhizal roots (p ≤ 0.05, Fig. 2). This finding is in agreement with results reported by other authors indicating that the fungal symbiont takes up and uses hexoses within the root.^29,30 The observation that the sucrose content is not significantly affected by mycorrhiza functioning, indicates that the host cell is able to sense sucrose concentration in order to maintain it at sufficient but constant levels to satisfy the demand for sugars by the fungal symbiont.Open in a separate windowFigure 2Sugar content in roots of rice plants inoculated with G. intraradices (+Gi) or mock-inoculated (−Gi). (A) Sucrose content. (B) Glucose content. (C) Fructose content. Measurements were made at 42 days post-inoculation with G. intraradices. Bars represent the means ± standard error.Clearly, the outcome of the AM symbiosis is an overall improvement of the fitness of both partners: the plant supplies the fungus with photosynthates whereas the fungus delivers nutrients from the soil to the host plant. Variations in the extent of colonization of the AM fungi will impose different carbon demands on the plants. However, a high demand of photosynthates by the mycorrhizal root might result in increased mycorrhization which, in turn, might be detrimental for the host plant. The rate of colonization and the amount of fungal biomass must then be tightly controlled by the host plant. We postulate that an increased sink strength by AM colonization might result in transient and/or localized increases in sugar concentrations in the root cell which might be the signal for the activation of defense gene expression. A schematic representation of plant responses associated with increased demands for sugars and deployment of defense responses is shown in Figure 3. According to this model, sugars might play a dual role during the AM symbiosis: (1) sugars are transferred from the plant to the fungus in exchange of mineral nutrients and (2) sugars alter host gene expression, leading to the activation of defense-related genes. This will allow the host plant to avoid an excessive root colonization by the AM fungus that might cause negative effects on the plant''s fitness. A complex exchange and interplay of signals between plant roots and AM fungi must then operate during functioning of the AM symbiosis for coordination of joint nutrient resource explotation strategies and control of the plant''s immune system. During evolution, co-adaptation between the two symbionts, the AM fungi and the host plant, must have occurred for stabilization of mycorrhizal cooperation and optimal functioning of mycorrhizal associations along the mutualism-parasitism continuum.Open in a separate windowFigure 3Proposed model for a sugar mediated-activation of defense-related genes in mycorrhizal roots. In the arbuscular mycorrhizal symbiosis, the fungal symbiont colonizes root cortical cells, where it establishes differentiated hyphae called arbuscules. Arbuscules are the site of mineral nutrient transfer to the plant and the site of carbon acquisition by the fungus. Although arbuscules form within the root cortical cells, they remain separated from the plant cell cytoplasm by a plant-derived membrane, the periarbuscular membrane. In this way, an interface is created between the plant and fungal cells which appears to be optimal for nutrient transfer. Sucrose is transported through the phloem into the root. In the root cell, sucrose is hydrolyzed by host invertase and sucrose synthase activities before uptake by the AM fungus. Hexose uptake at the plant-fungus interfase might be passive with a concentration gradient maintained by rapid conversion of hexoses taken up by the fungus to trehalose and glycogen. Active mechanisms might also operate for hexose transport processes between the host cell and the symbiont. Under conditions of a high demand for sugars by the AM fungus, transient increases in sugar content will occur in the root cells which would be the signal for the activation of the host defense responses. The host-produced defense compounds would stabilize the level of root colonization by the AM fungus. An excessive root colonization might change the mutualistic association into a parasitic one.     

Cyr61 activates retinal cells and prolongs photoreceptor survival in rd1 mouse model of retinitis pigmentosa

Subretinal injections with glial cell line‐derived neurotrophic factor (GDNF) rescue morphology as well as function of rod cells in mouse and rat animal models of retinitis pigmentosa. At the same time, it is postulated that this effect is indirect, mediated by activation of retinal Müller glial (RMG) cells. Here, we show that Cyr61/CCN1, one of the secreted proteins up‐regulated in primary RMG after glial cell line‐derived neurotrophic factor stimulation, provides neuroprotective and pro‐survival capacities: Recombinant Cyr61 significantly reduced photoreceptor (PR) cells death in organotypic cultures of Pde6b^rd1 retinas. To identify stimulated pathways in the retina, we treated Pde6b^rd1 retinal explants with Cyr61 and observed an overall increase in activated Erk1/2 and Stat3 signalling molecules characterized by activation‐site‐specific phosphorylation. To identify Cyr61 retinal target cells, we isolated primary porcine PR, RMG and retinal pigment epithelium (RPE) cells and exposed them separately to Cyr61. Here, RMG as well as RPE cells responded with induced phosphorylation of Erk1/2, Stat3 and Akt. In PR, no increase in phosphorylation in any of the studied proteins was detected, suggesting an indirect neuroprotective effect of Cyr61. Cyr61 may thus act as an endogenous pro‐survival factor for PR, contributing to the complex repertoire of neuroprotective activities generated by RMG and RPE cells.

     

Identification of a Common Non-Apoptotic Cell Death Mechanism in Hereditary Retinal Degeneration

Cell death in neurodegenerative diseases is often thought to be governed by apoptosis; however, an increasing body of evidence suggests the involvement of alternative cell death mechanisms in neuronal degeneration. We studied retinal neurodegeneration using 10 different animal models, covering all major groups of hereditary human blindness (rd1, rd2, rd10, Cngb1 KO, Rho KO, S334ter, P23H, Cnga3 KO, cpfl1, Rpe65 KO), by investigating metabolic processes relevant for different forms of cell death. We show that apoptosis plays only a minor role in the inherited forms of retinal neurodegeneration studied, where instead, a non-apoptotic degenerative mechanism common to all mutants is of major importance. Hallmark features of this pathway are activation of histone deacetylase, poly-ADP-ribose-polymerase, and calpain, as well as accumulation of cyclic guanosine monophosphate and poly-ADP-ribose. Our work thus demonstrates the prevalence of alternative cell death mechanisms in inherited retinal degeneration and provides a rational basis for the design of mutation-independent treatments.     

Multilocus Bayesian Estimates of Intra-Oceanic Genetic Differentiation,Connectivity, and Admixture in Atlantic Swordfish (Xiphias gladius L.)

Previous genetic studies of Atlantic swordfish (Xiphias gladius L.) revealed significant differentiation among Mediterranean, North Atlantic and South Atlantic populations using both mitochondrial and nuclear DNA data. However, limitations in geographic sampling coverage, and the use of single loci, precluded an accurate placement of boundaries and of estimates of admixture. In this study, we present multilocus analyses of 26 single nucleotide polymorphisms (SNPs) within 10 nuclear genes to estimate population differentiation and admixture based on the characterization of 774 individuals representing North Atlantic, South Atlantic, and Mediterranean swordfish populations. Pairwise F _ST values, AMOVA, PCoA, and Bayesian individual assignments support the differentiation of swordfish inhabiting these three basins, but not the current placement of the boundaries that separate them. Specifically, the range of the South Atlantic population extends beyond 5°N management boundary to 20°N-25°N from 45°W. Likewise the Mediterranean population extends beyond the current management boundary at the Strait of Gibraltar to approximately 10°W. Further, admixture zones, characterized by asymmetric contributions of adjacent populations within samples, are confined to the Northeast Atlantic. While South Atlantic and Mediterranean migrants were identified within these Northeast Atlantic admixture zones no North Atlantic migrants were identified respectively in these two neighboring basins. Owing to both, the characterization of larger number of loci and a more ample spatial sampling coverage, it was possible to provide a finer resolution of the boundaries separating Atlantic swordfish populations than previous studies. Finally, the patterns of population structure and admixture are discussed in the light of the reproductive biology, the known patterns of dispersal, and oceanographic features that may act as barriers to gene flow to Atlantic swordfish.     

Human DNA polymerases lambda and beta show different efficiencies of translesion DNA synthesis past abasic sites and alternative mechanisms for frameshift generation

Human DNA polymerases (pols) beta and lambda could promote template slippage and generate -1 frameshifts on defined heteropolymeric DNA substrates containing a single abasic site. Kinetic data demonstrated that pol lambda was more efficient than pol beta in catalyzing translesion DNA synthesis past an abasic site, particularly in the presence of low nucleotide concentrations. Moreover, pol lambda was found to generate frameshifts in two ways: first, by using a nucleotide-stabilized primer misalignment mechanism, or second, by promoting primer reannealing using microhomology regions between the terminal primer sequence and the template strand. Our results suggest a molecular mechanism for the observed high in vivo rate of frameshifts generation by pol lambda and highlight the remarkable ability of pol lambda to promote microhomology pairing between two DNA strands, further supporting its proposed role in the nonhomologous end joining process.     

Methodological Deficits in Diagnostic Research Using ‘-Omics’ Technologies: Evaluation of the QUADOMICS Tool and Quality of Recently Published Studies

Background

QUADOMICS is an adaptation of QUADAS (a quality assessment tool for use in systematic reviews of diagnostic accuracy studies), which takes into account the particular challenges presented by ‘-omics’ based technologies. Our primary objective was to evaluate the applicability and consistency of QUADOMICS. Subsequently we evaluated and describe the methodological quality of a sample of recently published studies using the tool.

Methodology/Principal Findings

45‘-omics’- based diagnostic studies were identified by systematic search of Pubmed using suitable MeSH terms (“Genomics”, “Sensitivity and specificity”, “Diagnosis”). Three investigators independently assessed the quality of the articles using QUADOMICS and met to compare observations and generate a consensus. Consistency and applicability was assessed by comparing each reviewer''s original rating with the consensus. Methodological quality was described using the consensus rating. Agreement was above 80% for all three reviewers. Four items presented difficulties with application, mostly due to the lack of a clearly defined gold standard. Methodological quality of our sample was poor; studies met roughly half of the applied criteria (mean ± sd, 54.7±18.4%). Few studies were carried out in a population that mirrored the clinical situation in which the test would be used in practice, (6, 13.3%); none described patient recruitment sufficiently; and less than half described clinical and physiological factors that might influence the biomarker profile (20, 44.4%).

Conclusions

The QUADOMICS tool can consistently be applied to diagnostic ‘-omics’ studies presently published in biomedical journals. A substantial proportion of reports in this research field fail to address design issues that are fundamental to make inferences relevant for patient care.