Dipyridamole is neuroprotective for cultured rat embryonic cortical neurons

The effects of a clinically useful cardiovascular agent, dipyridamole, were examined in a rodent tissue culture model of neuroprotection. Dipyridamole effectively protected rat embryonic day 18 (E18) cortical neurons from either 48 h trophic deprivation or 48 h exposure to the glutathione synthesis inhibitor, L-buthionine (R,S) sulfoximine. The neuron sparing actions of dipyridamole were time- and concentration-dependent and mimicked the actions of exogenously applied glutathione. These results demonstrate that dipyridamole protects primary neuronal cultures against either trophic or chemically mediated insults, and suggest that dipyridamole has a potent antioxidant ability that compensates for glutathione depletion in neuronal cultures.     

New class of orthopoxvirus antiviral drugs that block viral maturation

By using a homology-based bioinformatics approach, a structural model of the vaccinia virus (VV) I7L proteinase was developed. A unique chemical library of approximately 51,000 compounds was computationally queried to identify potential active site inhibitors. The resulting biased subset of compounds was assayed for both toxicity and the ability to inhibit the growth of VV in tissue culture cells. A family of chemotypically related compounds was found which exhibits selective activity against orthopoxviruses, inhibiting VV with 50% inhibitory concentrations of 3 to 12 microM. These compounds exhibited no significant cytotoxicity in the four cell lines tested and did not inhibit the growth of other organisms such as Saccharomyces cerevisiae, Pseudomonas aeruginosa, adenovirus, or encephalomyocarditis virus. Phenotypic analyses of virus-infected cells were conducted in the presence of active compounds to verify that the correct biochemical step (I7L-mediated core protein processing) was being inhibited. Electron microscopy of compound-treated VV-infected cells indicated a block in morphogenesis. Compound-resistant viruses were generated and resistance was mapped to the I7L open reading frame. Transient expression with the mutant I7L gene rescued the ability of wild-type virus to replicate in the presence of compound, indicating that this is the only gene necessary for resistance. This novel class of inhibitors has potential for development as an efficient antiviral drug against pathogenic orthopoxviruses, including smallpox.     

The future of interdisciplinary research and training: how to conquer the silo guardians

We have entered a new era in biomedical research in which large interdisciplinary teams are being established to answer important scientific questions. Scientists of multidisciplinary backgrounds within universities are combining forces and inter-institutional consortia that include alliances between academia and industry are springing up around the country to generate breakthrough advances. A number of driving forces are at work to establish these collaborative research approaches. By contrast, there also are barriers to be surmounted by institutions with silo mentalities for effective partnerships to be established. In order for this new era of research to reach maximal effectiveness, new approaches to education of the young and retraining of established administrators and scientists must take place. These issues were explored thoroughly at the 2006 annual meeting of the Association of Anatomy, Cell Biology and Neurobiology Chairpersons (AACBNC) that was held in Aruba from January 18 to 21. The theme of this historic meeting was the Future of Interdisciplinary Research and Training: Breaking Down the Barriers. In this introductory article, we discuss the formation of a trendsetting Institute of Biomedical Sciences and Technology, the concept of the AACBNC meeting, and the influence of the Institute on the content of the meeting. The proceedings of this meeting, including Nobel Laureate Papers and Nobel Round-Table Discussions on the future of interdisciplinary research and training, are contained in this special issue of Experimental Biology and Medicine, a journal dedicated to the publication of multidisciplinary and interdisciplinary research in the biomedical sciences.     

Migration, site selection, and development of Ornithodiplostomum sp. metacercariae (Digenea: Strigeoidea) in fathead minnows (Pimephales promelas)

The metacercarial stage of trematodes is typically considered an encysted, developmentally quiescent, resting stage. Yet the metacercariae of some species of strigeoid trematode undergo extravagant development within specific tissues of their second intermediate host. Our understanding of patterns of migration, site selection and development of these types of metacercariae is known for only a few species. In this study, we characterize the invasion and development of Ornithodiplostomum sp. metacercariae in their second intermediate host, the fathead minnow, Pimephales promelas. Diplostomules completed their migration into the abdominal cavity between 15 min and 48 h p.i. Most diplostomules migrated along muscular and connective tissue then penetrated the peritoneal lining of the abdominal cavity en route to the liver or pancreas. Alternatively, some diplostomules migrated within the host’s circulatory system, including the heart and arteries of the hepatic portal system. Metacercarial development in the liver and pancreas involved distinct growth, encystment and consolidation phases. Metacercarial volume increased 15-fold between 48 h and 4 weeks p.i., presumably due to absorptive and/or ingestive feeding activities within host tissues. By 2 weeks p.i., metacercariae were enveloped within a cyst wall and they were found loosely attached to the surfaces of internal tissues or unattached within the body cavity. These results emphasize the complex nature of metacercarial migration and growth and demonstrate that their growth and encystment phases occur within different habitats within their intermediate hosts.     

Segmental motions of rat thymidylate synthase leading to half‐the‐sites behavior

Thymidylate synthase (TS) is a homodimeric enzyme with two equivalent active sites composed of residues from both subunits. Despite the structural symmetry of the enzyme, certain experimental results are consistent with half‐the‐sites activity, suggesting negative cooperativity between the active sites. To gain insight into the mechanism behind this phenomenon, we explore segmental motions of rat TS in the absence of ligands, with normal mode analysis as a tool. Using solvent accessible surface area of the active site pocket as a monitor of the degree of opening of the active sites, we classified the first 25 nontrivial normal modes, obtained from the web server of the program ElNémo, according to the behavior of the active sites. We found seven modes that open and close both sites symmetrically and nine that do so in an anticorrelated fashion. We characterized the motions of these modes by visual inspection and through measurement of distances between selected atoms lining the active site pockets. The segments that regulate access to the active site correspond to the loop containing R44, helix K, and a long loop containing residues 103–125, in agreement with a large body of crystallographic studies. These elements can be activated together or in isolation. There are more asymmetric modes than symmetric ones in the set we analyzed, probably accounting for the half‐the‐sites behavior of the enzyme. Three of the asymmetric modes result in changes at the dimer interface and indicate the endpoints of possible communication pathways between the active sites. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 549–559, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

The primary in vivo steroidal alkaloid glucosyltransferase from potato

To provide tools for breeders to control the steroidal glycoalkaloid (SGA) pathway in potato, we have investigated the steroidal alkaloid glycosyltransferase (Sgt) gene family. The committed step in the SGA pathway is the glycosylation of solanidine by either UDP-glucose or UDP-galactose leading to α-chaconine or α-solanine, respectively. The Sgt2 gene was identified by deduced protein sequence homology to the previously identified Sgt1 gene. SGT1 has glucosyltransferase activity in vitro, but in vivo serves as the UDP-galactose:solanidine galactosyltransferase. Two alleles of the Sgt2 gene were isolated and its function was established with antisense transgenic lines and in vitro assays of recombinant protein. In tubers of transgenic potato (Solanum tuberosum) cvs. Lenape and Desirée expressing an antisense Sgt2 gene construct, accumulation of α-solanine was increased and α-chaconine was reduced. Studies with recombinant SGT2 protein purified from yeast show that SGT2 glycosylation activity is highly specific for UDP-glucose as a sugar donor. This data establishes the function of the gene product (SGT2), as the primary UDP-glucose:solanidine glucosyltransferase in vivo.