Virtual laboratories: Collaborative environments and facilities-on-line

The Department of Energy (DOE) has major research laboratories in a number of locations in the US, typically co-located with large research instruments or research facilities valued at tens of millions to even billions of dollars. Present budget exigencies facing the entire nation are felt very deeply at DOE, just as elsewhere. Advances over the last few years in networking and computing technologies make virtual collaborative environments and conduct of experiments over the internetwork structure a possibility. The authors believe that development of these collaborative environments and facilities-on-line could lead to a ``virtual laboratory`` with tremendous potential for decreasing the costs of research and increasing the productivity of their capital investment in research facilities. The majority of these cost savings would be due to increased productivity of their research efforts, better utilization of resources and facilities, and avoiding duplication of expensive facilities. A vision of how this might all fit together and a discussion of the infrastructure necessary to enable these developments is presented

Characterization of gene polymorphisms related to immune system physiology in Mangalarga horses

The objectives of this study were to standardize a PCR-RFLP genotyping method for the AY_731081:g.1900T>C SNP of the equine CD14 gene, and to characterize this SNP and two other polymorphisms (AY_005808: c.1530A>G of the TLR4 gene and AX_463789: g.133T>C of the Cε gene) in Mangalarga horses, in order to contribute to future studies investigating the association between DNA markers and traits related to immune system physiology in this breed. A total of 151 Mangalarga horses of both sexes and variable ages, representative of the population of São Paulo State, were used. PCR-RFLP was found to be adequate for genotyping of the AY_731081: g.1900T>C SNP of the equine CD14 gene. However, this polymorphism is probably not present in Mangalarga horses, thus impairing association studies using this marker in the breed. The population genetic parameters obtained for the TLR4 AY_005808:c.1530A>G and Cε AX_463789:g.133T>C polymorphisms suggest the use of these markers in association studies with immune system-related traits in Mangalarga horses

Characterization of Brucella abortus lipopolysaccharide macrodomains as mega rafts

The lipopolysaccharides (LPS) of intracellular Proteobacteria such as Brucella, Chlamydia, Legionella and Rickettsia, have properties distinct from enterobacterial LPSs. These properties include deficient LPS induction of host cell activation, low endotoxicity and resistance to macrophage degradation. Together these constitute key virulence mechanisms for intracellular survival and replication. We previously demonstrated that B. abortus LPS captured by macrophages was recycled back to the plasma membrane where it was found associated with macrodomains. Furthermore, this LPS interferes with the MHC class II (MHC-II) presentation of peptides to specific T cell hybridomas. Here, we characterized the Brucella LPS macrodomains by microscopy and biochemistry approaches. We show for the first time that LPS macrodomains act as detergent resistant membranes (DRMs), segregating several lipid-raft components, LPS-binding proteins and MHC-II molecules. Brucella LPS macrodomains remain intact for several months in macrophages and are resistant to the disruptive effects of methyl β-cyclodextrin. Fluorescent anisotropy measurements show that B. abortus LPS is responsible for the formation of rigid surface membrane complexes. In addition, relocalization of MHC-II molecules is observed in these structures. The effects of B. abortus LPS on membrane properties could be responsible for pathogenic effects such as the inhibition of MHC-II-dependent antigen presentation. © 2005 The Authors; Journal compilation © 2005 Blackwell Publishing Ltd.Los lipopolisacáridos (LPS) de Proteobacterias intracelulares como Brucella, Chlamydia, Legionella y Rickettsia, tienen propiedades distintas a los LPS de las enterobacterias. Estas propiedades incluyen una inducción deficiente de los LPS a la activación de las células del huésped, una baja endotoxicidad y una resistencia a la degradación de los macrófagos. En conjunto, constituyen mecanismos de virulencia clave para la supervivencia y replicación intracelular. Anteriormente demostramos que el LPS de B. abortus capturado por los macrófagos se reciclaba de nuevo a la membrana plasmática, donde se encontraba asociado a macrodominios. Además, este LPS interfiere con la presentación de péptidos del MHC clase II (MHC-II) a hibridomas de células T específicos. Aquí, caracterizamos los macrodominios de LPS de Brucella mediante enfoques de microscopía y bioquímica. Demostramos por primera vez que los macrodominios de LPS actúan como membranas resistentes a los detergentes (DRM), segregando varios componentes de los lípidos, proteínas de unión a LPS y moléculas MHC-II. Los macrodominios de LPS de Brucella permanecen intactos durante varios meses en los macrófagos y son resistentes a los efectos disruptivos de la metil β-ciclodextrina. Las mediciones de anisotropía fluorescente muestran que el LPS de B. abortus es responsable de la formación de complejos rígidos de membrana superficial. Además, se observa la relocalización de las moléculas MHC-II en estas estructuras. Los efectos del LPS de B. abortus sobre las propiedades de la membrana podrían ser responsables de efectos patógenos como la inhibición de la presentación del antígeno dependiente del MHC-IIUniversidad Nacional, Costa RicaEscuela de Medicina Veterinari

Consumption and Identity

Consumption and Identit