Detection of hantaviruses in Brazilian rodents by SYBR-Green-based real-time RT-PCR.

Current knowledge of the pathogenic hantavirus indicates that wild rodents are its primary natural reservoir. Specific primers to detect the presence of viral genomes were developed using an SYBR-Green-based real-time RT-PCR protocol. One hundred sixty-four rodents native to the Atlantic Forest biome were captured in São Paulo State, Brazil, and their tissues were tested. The presence of hantavirus RNA was detected in sixteen rodents: three specimens of Akodon montensis, three of Akodon cursor, two of Necromys lasiurus, one of Juliomys sp., one of Thaptomys nigrita, five of Oligoryzomys nigripes, and one of Oryzomys sp. This SYBR Green real-time RT-PCR method for detection of hantavirus may be useful for surveying hantaviruses in Brazil.

Inhibitors to the Src SH2 domain: a lesson in structure--thermodynamic correlation in drug design.

Src homology 2 (SH2) domains play a key role in many tyrosine kinase-mediated intracellular signal transduction pathways. Aberrancies in the interaction of these domains can lead to a range of disease states. As a result, the pharmaceutical industry has made a large temporal and financial investment in the development of specific inhibitors to these domains. Focusing on the interactions of the SH2 domain from the protein Src, we report how the correlation of structural and thermodynamic data allows an assessment of the process of drug design. The binding site of the protein includes two pockets; one interacts with phosphotyrosine groups on cognate ligands, and the other accommodates an aliphatic hydrophobic side chain. The interaction with cognate ligands is also mediated by a network of water molecules. Thermodynamic data from isothermal titration calorimetric studies suggest that modification of the interactions in the SH2 binding site has been largely unsuccessful in producing high-affinity inhibitors. Furthermore, it appears that compounds that disrupt the interfacial water pay the price for the loss of the contribution to the free energy from a network of hydrogen bonds.

Comparison of binding energies of SrcSH2-phosphotyrosyl peptides with structure-based prediction using surface area based empirical parameterization.

The prediction of binding energies from the three-dimensional (3D) structure of a protein-ligand complex is an important goal of biophysics and structural biology. Here, we critically assess the use of empirical, solvent-accessible surface area-based calculations for the prediction of the binding of Src-SH2 domain with a series of tyrosyl phosphopeptides based on the high-affinity ligand from the hamster middle T antigen (hmT), where the residue in the pY+ 3 position has been changed. Two other peptides based on the C-terminal regulatory site of the Src protein and the platelet-derived growth factor receptor (PDGFR) are also investigated. Here, we take into account the effects of proton linkage on binding, and test five different surface area-based models that include different treatments for the contributions to conformational change and protein solvation. These differences relate to the treatment of conformational flexibility in the peptide ligand and the inclusion of proximal ordered solvent molecules in the surface area calculations. This allowed the calculation of a range of thermodynamic state functions (deltaCp, deltaS, deltaH, and deltaG) directly from structure. Comparison with the experimentally derived data shows little agreement for the interaction of SrcSH2 domain and the range of tyrosyl phosphopeptides. Furthermore, the adoption of the different models to treat conformational change and solvation has a dramatic effect on the calculated thermodynamic functions, making the predicted binding energies highly model dependent. While empirical, solvent-accessible surface area based calculations are becoming widely adopted to interpret thermodynamic data, this study highlights potential problems with application and interpretation of this type of approach. There is undoubtedly some agreement between predicted and experimentally determined thermodynamic parameters: however, the tolerance of this approach is not sufficient to make it ubiquitously applicable.

Probing the nature of interactions in SH2 binding interfaces--evidence from electrospray ionization mass spectrometry.

We have adopted nanoflow electrospray ionization mass spectrometry (ESI-MS) and isothermal titration calorimetry (ITC) to probe the mechanism of peptide recognition by the SH2 domain from the Src family tyrosine kinase protein, Fyn. This domain is involved in the mediation of intracellular signal transduction pathways by interaction with proteins containing phosphorylated tyrosine (Y*) residues. The binding of tyrosyl phosphopeptides can mimic these interactions. Specificity in these interactions has been attributed to the interaction of the Y* and residues proximal and C-terminal to it. Previous studies have established that for specific binding with Fyn, the recognition sequence consists of pTyr-Glu-Glu-Ile. The specific interactions involve the binding of Y* with the ionic, and the Y* + 3 Ile residue with the hydrophobic binding pockets on the surface of the Fyn SH2 domain. In this work, a variation in the Y* + 3 residue of this high-affinity sequence was observed to result in changes in the relative binding affinities as determined in solution (ITC) and in the gas phase (nanoflow ESI-MS). X-ray analysis shows that a feature of the Src family SH2 domains is the involvement of water molecules in the peptide binding site. Under the nanoflow ESI conditions, water molecules appear to be maintained in the Fyn SH2-ligand complex. Compelling evidence for these molecules being incorporated in the SH2-peptide interface is provided by the prevalence of the peaks assigned to water-bound over the water-free complex at high-energy conditions. Thus, the stability of water protein-ligand complex appears to be intimately linked to the presence of water.

Construction of a mouse yeast artificial chromosome library in a recombination-deficient strain of yeast.

We have constructed a new generation yeast artificial chromosome (YAC) library from female C57BL/10 mice in a recombination-deficient strain of Saccharomyces cerevisiae carrying a mutation in the RAD52 gene. The YAC library contains 41,568 clones with an average insert size of 240 kilobases, representing a greater than threefold coverage of the mouse genome. Currently, the library can be screened by polymerase chain reaction and we have isolated positive clones at a number of loci in the mouse genome. This rad52 library should enable a long-term assessment of the effect of one of the yeast recombination pathway genes on both, genome-wide YAC clone stability and the frequency of chimaeric clones.