Neurovirulence of polytropic murine retrovirus is influenced by two separate regions on opposite sides of the envelope protein receptor binding domain

Changes in the envelope proteins of retroviruses can alter the ability of these viruses to infect the central nervous system (CNS) and induce neurological disease. In the present study, nine envelope residues were found to influence neurovirulence of the Friend murine polytropic retrovirus Fr98. When projected on a three-dimensional model, these residues were clustered in two spatially separated groups, one in variable region B of the receptor binding site and the other on the opposite side of the envelope. Further studies indicated a role for these residues in virus replication in the CNS, although the residues did not affect viral entry.     

Separation-based glycoprofiling approaches using fluorescent labels

Glycoprotein analysis is essential within the biopharmaceutical industry, as the structure of the different glycans present can affect the safety and efficacy of products. However analysis of cleaved glycans presents a major analytical challenge, due to their inherent complexity, lack of chromophore and the existence of various isoforms (both position and linkage). In addition, almost all glycoproteins consist of a heterogeneous collection of differently glycosylated variants, so the released glycan pool contains a range of structures. Both normal phase chromatography and capillary gel electrophoresis offer excellent selectivity for the analysis of fluorescently labelled glycans. The normal phase (NP) chromatographic approach is sensitive, reliable and well established, with databases available for searching structures assigned relative to retention times. Capillary gel electrophoresis with laser induced fluorescence (CGE-LIF) offers faster analysis times, though currently no databases are available to search mobilities against structures, therefore data has to be cross-correlated with either normal phase chromatography or mass spectrometry approaches when developing and validating methods. The principles of both methods are described and a review is presented that includes evaluation against a set of criteria established through consultation with the biopharmaceutical industry.     

Heparin binding induces conformational changes in Adeno-associated virus serotype 2

Adeno-associated virus serotype 2 (AAV2) uses heparan sulfate proteoglycan as a cell surface-attachment receptor. In this study the structures of AAV2 alone and complexed with heparin were determined to 18 Å resolution using cryo-electron microscopy and three-dimensional image reconstruction. A difference map showed positive density, modeled as heparin, close to the icosahedral twofold axes and between the protrusions that surround the threefold axes of the capsid. Regions of the model near the threefold place the receptor in close proximity to basic residues previously identified as part of the heparin binding site. The region of the model near the twofold axes identifies a second contact site, not previously characterized but which is also possibly configured by heparin binding. The difference map also revealed two significant conformational changes: (I) at the tops of the threefold protrusions, which have become flattened in the complex, and (II) at the fivefold axes where the top of the channel is widened possibly in response to movement of the HI loops in the capsid proteins. Ordered density in the interior of the capsid in the AAV2–heparin complex was interpreted as nucleic acid, consistent with the presence of non-viral DNA in the expressed capsids.     

Ago2 Immunoprecipitation Identifies Predicted MicroRNAs in Human Embryonic Stem Cells and Neural Precursors

Background

MicroRNAs are required for maintenance of pluripotency as well as differentiation, but since more microRNAs have been computationally predicted in genome than have been found, there are likely to be undiscovered microRNAs expressed early in stem cell differentiation.

Methodology/Principal Findings

SOLiD ultra-deep sequencing identified >10⁷ unique small RNAs from human embryonic stem cells (hESC) and neural-restricted precursors that were fit to a model of microRNA biogenesis to computationally predict 818 new microRNA genes. These predicted genomic loci are associated with chromatin patterns of modified histones that are predictive of regulated gene expression. 146 of the predicted microRNAs were enriched in Ago2-containing complexes along with 609 known microRNAs, demonstrating association with a functional RISC complex. This Ago2 IP-selected subset was consistently expressed in four independent hESC lines and exhibited complex patterns of regulation over development similar to previously-known microRNAs, including pluripotency-specific expression in both hESC and iPS cells. More than 30% of the Ago2 IP-enriched predicted microRNAs are new members of existing families since they share seed sequences with known microRNAs.

Conclusions/Significance

Extending the classic definition of microRNAs, this large number of new microRNA genes, the majority of which are less conserved than their canonical counterparts, likely represent evolutionarily recent regulators of early differentiation. The enrichment in Ago2 containing complexes, the presence of chromatin marks indicative of regulated gene expression, and differential expression over development all support the identification of 146 new microRNAs active during early hESC differentiation.     

Human genetic technologies,European governance and the politics of bioethics

With human genetic technologies now an important area of European research and development, bioethics is becoming increasingly important in its regulation and future. As regulatory decisions are also statements about who should get what, bioethics cannot avoid political controversy. Can bioethics sustain its claimed role as authoritative adviser to decision makers, or will its attempts to reach a consensus on human genetic technologies be perceived as the actions of an ambitious interest group? What, in short, is its political future in Europe and elsewhere?     

Structural insights and functional implications of choline acetyltransferase

The biosynthetic enzyme for the neurotransmitter acetylcholine, choline acetyltransferase (ChAT) (E.C. 2.3.1.6), is essential for the development and neuronal activities of cholinergic systems involved in many fundamental brain functions. ChAT catalyzes the transfer of an acetyl group from acetyl-coenzyme A to choline to form the neurotransmitter acetylcholine. Since its discovery more than 60 years ago much research has been devoted to the kinetic studies of this enzyme. For the first time we report the crystal structure of rat ChAT (rChAT) to 1.55 A resolution. The structure of rChAT is a monomer and consists of two domains with an interfacial active site tunnel. This structure, with the modeled substrate binding, provides critical insights into the molecular basis for the production of acetylcholine and may further our understanding of disease causing mutations.     

Human carbonic anhydrase III: structural and kinetic study of catalysis and proton transfer

The residue phenylalanine 198 (Phe 198) is a prominent cause of the lower activity of human carbonic anhydrase III (HCA III) compared with HCA II and other isozymes which have leucine at this site. We report the crystal structures of HCA III and the site-directed mutant F198L HCA III, both at 2.1 A resolution, and the enhancement of catalytic activity by exogenous proton donors containing imidazole rings. Both enzymes had a hexahistidine extension at the carboxy-terminal end, used to aid in purification, that was ordered in the crystal structures bound in the active site cavity of an adjacent symmetry-related enzyme. This observation allowed us to comment on a number of possible binding sites for imidazole and derivatives as exogenous proton donors/acceptors in catalysis by HCA III. Kinetic and structural evidence indicates that the phenyl side chain of Phe 198 in HCA III, about 5 A from the zinc, is a steric constriction in the active site, may cause altered interactions at the zinc-bound solvent, and is a binding site for the activation of catalysis by histidylhistidine. This suggests that sites of activation of the proton-transfer pathway in carbonic anhydrase are closer to the zinc than considered in previous studies.     

Comparing the accumulation of active- and nonactive-site mutations in the HIV-1 protease

Protease inhibitor resistance still poses one of the greatest challenges in treating HIV. To better design inhibitors able to target resistant proteases, a deeper understanding is needed of the effects of accumulating mutations and the contributions of active- and nonactive-site mutations to the resistance. We have engineered a series of variants containing the nonactive-site mutations M46I and I54V and the active-site mutation I84V. These mutations were added to a protease clone (V6) isolated from a pediatric patient on ritonavir therapy. This variant possessed the ritonavir-resistance-associated mutations in the active-site (V32I and V82A) and nonactive-site mutations (K20R, L33F, M36I, L63P, A71V, and L90M). The I84V mutation had the greatest effect on decreasing catalytic efficiency, 10-fold when compared to the pretherapy clone LAI. The decrease in catalytic efficiency was partially recovered by the addition of mutations M46I and I54V. The M46I and I54V were just as effective at decreasing inhibitor binding as the I84V mutation when compared to V6 and LAI. The V6(54/84) variant showed over 1000-fold decrease in inhibitor-binding strength to ritonavir, indinavir, and nelfinavir when compared to LAI and V6. Crystal-structure analysis of the V6(54/84) variant bound to ritonavir and indinavir shows structural changes in the 80's loops and active site, which lead to an enlarged binding cavity when compared to pretherapy structures in the Protein Data Bank. Structural changes are also seen in the 10's and 30's loops, which suggest possible changes in the dynamics of flap opening and closing.     

Expression of an agrocin-encoding plasmid of Agrobacterium tumefaciens in Rhizobium meliloti

Plasmid RP4 was used to mobilize the agrocin 84-encoding plasmid, pAg396, from Agrobacterium tumefaciens strain 396 to A. tumefaciens C58 and C58CI as well as Rhizobium meliloti. It was transferred to, but not stably maintained in, R. leguminosarum. It could not be transferred to R. lupini, R. japonicum or R. trifolii. Plasmid pAg396 did not segregate in R. meliloti and produced levels of agrocin comparable to the parental strain A. tumefaciens 396. The potential of agrocin producing R. meliloti in biological control of crown gall is being investigated.