Novel Extended-spectrum β-Lactamase in Shigella sonnei

International audienc

The complete genome sequence of Corynebacterium pseudotuberculosis FRC41 isolated from a 12-year-old girl with necrotizing lymphadenitis reveals insights into gene-regulatory networks contributing to virulence

Trost E, Ott L, Schneider J, et al. The complete genome sequence of Corynebacterium pseudotuberculosis FRC41 isolated from a 12-year-old girl with necrotizing lymphadenitis reveals insights into gene-regulatory networks contributing to virulence. BMC Genomics. 2010;11(1): 728

Invasion of the Placenta during Murine Listeriosis

Feto-placental infections due to Listeria monocytogenes represent a major threat during pregnancy, and the underlying mechanisms of placental invasion remain poorly understood. Here we used a murine model of listeriosis (pregnant mice, infected at day 14 of gestation) to investigate how this pathogen invades and grows within the placenta to ultimately infect the fetus. When L. monocytogenes is injected intravenously, the invasion of the placenta occurs early after the initial bacteremia, allowing the placental growth of the bacteria, which is an absolute requirement for vertical transmission to the fetus. Kinetically, bacteria first target the cells lining the central arterial canal of the placenta, which stain positively with cytokeratin, demonstrating their fetal trophoblast origin. Bacteria then disseminate rapidly to the other trophoblastic structures, like syncytiotrophoblast cells lining the villous core in the labyrinthine zone of placenta. Additionally, we found that an inflammatory reaction predominantly constituted of polymorphonuclear cells occurs in the villous placenta and participates in the control of infection. Altogether, our results suggest that the infection of murine placenta is dependent, at the early phase, on circulating bacteria and their interaction with endovascular trophoblastic cells. Subsequently, the bacteria spread to the other trophoblastic cells before crossing the placental barrier

ActA Is Required for Crossing of the Fetoplacental Barrier by Listeria monocytogenes

The facultative intracellular bacterial pathogen Listeria monocytogenes induces severe fetal infection during pregnancy. Little is known about the molecular mechanisms allowing the maternofetal transmission of bacteria. In this work, we studied fetoplacental invasion by infecting mice with various mutants lacking virulence factors involved in the intracellular life cycle of L. monocytogenes. We found that the placenta was highly susceptible to bacteria, including avirulent bacteria, such as an L. monocytogenes mutant with an hly deletion (ΔLLO) and a nonpathogenic species, Listeria innocua, suggesting that permissive trophoblastic cells, trapping bacteria, provide a protective niche for bacterial survival. The ΔLLO mutant, which is unable to escape the phagosomal compartment of infected cells, failed to grow in the trophoblast tissue and to invade the fetus. Mutant bacteria with inlA and inlB deletion (ΔInlAB) grew in the placenta and fetus as well as did the wild-type virulent stain (EGDwt), indicating that in the murine model, internalins A and B are not involved in fetoplacental invasion by L. monocytogenes. Pregnant mice were then infected with an actA deletion (ΔActA) strain, a virulence-attenuated mutant that is unable to polymerize actin and to spread from cell to cell. With the ΔActA mutant, fetal infection occurs, but with a significant delay and restriction, and it requires a placental bacterial load 2 log units higher than that for the wild-type virulent strain. Definitive evidence for the role of ActA was provided by showing that a actA-complemented ΔActA mutant was restored in its capacity to invade fetuses. ActA-mediated cell-to-cell spreading plays a major role in the vertical transmission of L. monocytogenes to the fetus in the murine model

Modelling the response of fresh groundwater to climate and vegetation changes in coral islands

Writing up of the manuscript was partially supported by the Griffith Geoscience Research Award, Ireland. We are grateful to Météo France for access to the temperature and precipitation records, provided through the Climathèque agreement between Météo France and the University of Reunion Island. We are also grateful to P. Bauer-Gottwein for kindly providing the source code of the modified version of SEAWAT that was applied to carry out the phytotoxicity simulations in the last model scenario as well as our colleague R. Cassidy for assistance in code implementation. We thank the associate editor K. Hinsby as well as A. Vandenbohede and two anonymous reviewers for their valuable comments on the manuscript.International audienceIn coral islands, groundwater is a crucial freshwater resource for terrestrial life, including human water supply. Response of the freshwater lens to expected climate changes and subsequent vegetation alterations is quantified for Grande Glorieuse, a low-lying coral island in the Western Indian Ocean. Distributed models of recharge, evapotranspiration and saltwater phytotoxicity are integrated into a variable-density groundwater model to simulate the evolution of groundwater salinity. Model results are assessed against field observations including groundwater and geophys-ical measurements. Simulations show the major control currently exerted by the vegetation with regards to the lens morphology and the high sensitivity of the lens to climate alterations, impacting both quantity and salin-ity. Long-term changes in mean sea level and climatic conditions (rainfall and evapotranspiration) are predicted to be responsible for an average increase in salinity approaching 140 % (+8 kg m −3) when combined. In low-lying areas with high vegetation density, these changes top +300 % (+10 kg m −3). However, due to salinity increase and its phytotoxicity, it is shown that a corollary drop in vegetation activity can buffer the alteration of fresh groundwater. This illustrates the importance of accounting for vegetation dynamics to study groundwater in coral islands

OZCAR : The French Network of Critical Zone Observatories

[Departement_IRSTEA]Eaux [TR1_IRSTEA]ARCEAU [ADD1_IRSTEA]Hydrosystèmes et risques naturels [Departement_IRSTEA]Eaux [TR1_IRSTEA]ARCEAU [ADD1_IRSTEA]Hydrosystèmes et risques naturelsSpecial Section: Hydrological ObservatoriesInternational audienceThe French critical zone initiative, called OZCAR (Observatoires de la Zone Critique-Application et Recherche or Critical Zone Observatories-Application and Research) is a National Research Infrastructure (RI). OZCAR-RI is a network of instrumented sites, bringing together 21 pre-existing research observatories monitoring different compartments of the zone situated between "the rock and the sky," the Earth's skin or critical zone (CZ), over the long term. These observatories are regionally based and have specific initial scientific questions, monitoring strategies, databases, and modeling activities. The diversity of OZCAR-RI observatories and sites is well representative of the heterogeneity of the CZ and of the scientific communities studying it. Despite this diversity, all OZCAR-RI sites share a main overarching mandate, which is to monitor, understand, and predict ("earthcast") the fluxes of water and matter of the Earth's near surface and how they will change in response to the "new climatic regime." The vision for OZCAR strategic development aims at designing an open infrastructure, building a national CZ community able to share a systemic representation of the CZ , and educating a new generation of scientists more apt to tackle the wicked problem of the Anthropocene. OZCAR articulates around: (i) a set of common scientific questions and cross-cutting scientific activities using the wealth of OZCAR-RI observatories, (ii) an ambitious instrumental development program, and (iii) a better interaction between data and models to integrate the different time and spatial scales. Internationally, OZCAR-RI aims at strengthening the CZ community by providing a model of organization for pre-existing observatories and by offering CZ instrumented sites. OZCAR is one of two French mirrors of the European Strategy Forum on Research Infrastructure (eLTER-ESFRI) project