By virtue of genetic engineering it is possible to transfer genes

By virtue of genetic engineering it is possible to transfer genes involved in Cd tolerance or accumulation in high biomass plants. Nevertheless, the genetic determinants of Cd hyperaccumulation 4SC-202 molecular weight are far from being understood. It is thus indispensable to acquire more knowledge about these processes. Among Cd hyperaccumulators, Arabidopsis halleri (some populations can hyperaccumulate Cd) is considered as a model species for the study of metal homeostasis and detoxification. This review will summarize our knowledge about Cd tolerance and

accumulation acquired in A. halleri and how this knowledge may be used in phytoextraction.”
“We present a schizophrenia association study using an extensive linkage disequilibrium (LD) mapping approach in seven candidate genes with a well established link to dopamine, including receptors (DRD2, DRD3) and genes involved in its metabolism and transport (ACE, COMT, DAT, MAO-A,

MAO-B). The sample included 242 subjects JQ-EZ-05 diagnosed with schizophrenia and related disorders and 373 hospital-based controls. 84 tag SNPs in candidate genes were genotyped. After extensive data cleaning 70 SNPs were analyzed for association of single markers and haplotypes. One block of four SNPs (rs165849, rs2518823, rs887199 and rs2239395) in the 31 downstream region of the COMT gene which included a non-dopaminergic candidate gene, the ARVCF (Armadillo like VeloCardio Facial) gene, was associated

with the risk of schizophrenia. The genetic region including the ARVCF gene in the 22q11.21 chromosome is associated Acyl CoA dehydrogenase with schizophrenia in a Spanish series. Our results will assist in the interpretation of the controversy generated by genetic associations of COMT and schizophrenia, which could be the result of different LD patterns between COMT markers and the 3′ region of the ARVCF gene. (C) 2009 Elsevier Inc. All rights reserved.”
“It is known that even if a ligand peptide is designed to bind to a target receptor on the surface of a pathogen such as viruses, bacteria or cancer cells, it is likely that some receptors are subject to random mutation and thus the ligand has a reduced ability to bind to these receptors. This issue is known as drug-resistant or escape mutants. In this paper, we present an idea to inhibit the evolving receptors by using an ensemble of all possible single- or double-point mutant sequences of the ligand peptide. Several mutant ligands in the ensemble are expected to bind to the mutant receptors, and then the ensemble may create a defensive wall surrounding the target receptors in receptor-sequence space. We examined the effectiveness of this “”evolutionary containment”" of the evolving receptors through eight peptide-protein complex systems, which were retrieved from the Protein Data Bank (PDB).

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