Designing cell-permeant phosphopeptides to modulate intracellular signaling pathways

A central theme in intracellular signaling is the regulatable interaction of proteins via the binding of specialized domains on one protein to short linear sequences on other molecules. The capability of these short sequences to mediate the required specificity and affinity for signal transduction allows for the rational design of peptide-based modulators of specific protein-protein interactions. Such inhibitors are valuable tools for elucidating the role of these interactions in cellular physiology and in targeting such interactions for potential therapeutic intervention. This approach is exemplified by the study of the role of phosphorylation of specific sites on signaling proteins. However, the difficulty of introducing large hydrophilic molecules such as phosphopeptides into cells has been a major drawback in this area. This review describes the application of recently developed cell-permeant peptide vectors in the introduction of biologically active peptides into cells, with particular emphasis on the antennapedia/penetratin, TAT, and signal-peptide based sequences. In addition, the modification of such peptides to increase uptake efficiency and affinity for their targets is discussed. Finally, the use of cell-permeant phosphopeptides to both inhibit and stimulate intracellular signaling mechanisms is described, by reference to the PLCgamma, Grb2, and PI-3 kinase pathways.     

Satellog: A database for the identification and prioritization of satellite repeats in disease association studies

Background  

To date, 35 human diseases, some of which also exhibit anticipation, have been associated with unstable repeats. Anticipation has been reported in a number of diseases in which repeat expansion may have a role in etiology. Despite the growing importance of unstable repeats in disease, currently no resource exists for the prioritization of repeats. Here we present Satellog, a database that catalogs all pure 1–16 repeat unit satellite repeats in the human genome along with supplementary data. Satellog analyzes each pure repeat in UniGene clusters for evidence of repeat polymorphism.     

Comparative analysis of affinity-based 5-hydroxymethylation enrichment techniques

The epigenetic modification of 5-hydroxymethylcytosine (5hmC) is receiving great attention due to its potential role in DNA methylation reprogramming and as a cell state identifier. Given this interest, it is important to identify reliable and cost-effective methods for the enrichment of 5hmC marked DNA for downstream analysis. We tested three commonly used affinity-based enrichment techniques; (i) antibody, (ii) chemical capture and (iii) protein affinity enrichment and assessed their ability to accurately and reproducibly report 5hmC profiles in mouse tissues containing high (brain) and lower (liver) levels of 5hmC. The protein-affinity technique is a poor reporter of 5hmC profiles, delivering 5hmC patterns that are incompatible with other methods. Both antibody and chemical capture-based techniques generate highly similar genome-wide patterns for 5hmC, which are independently validated by standard quantitative PCR (qPCR) and glucosyl-sensitive restriction enzyme digestion (gRES-qPCR). Both antibody and chemical capture generated profiles reproducibly link to unique chromatin modification profiles associated with 5hmC. However, there appears to be a slight bias of the antibody to bind to regions of DNA rich in simple repeats. Ultimately, the increased specificity observed with chemical capture-based approaches makes this an attractive method for the analysis of locus-specific or genome-wide patterns of 5hmC.     

Electrotransfection of Escherichia coli with λgt10 DNA

We have used electroporation to introduce lambda gt10 DNA into E. coli C600 (Electrotransfection). We obtained approximately 10(7) pfu (plaque forming units) per micrograms of lambda gt10 DNA. This frequency is 100-fold higher than the maximum reported for classical calcium chloride-induced transfection. We have also compared electrotransfection with in vitro packaging in cloning experiments using relatively small amounts (less than or equal to 10 ng) of DNA. Our results slow that electrotransfection can generate approximately 1000-fold more plaques than in vitro packaging at these concentrations.     

Identification of a Fungal 1,8-Cineole Synthase from Hypoxylon sp. with Specificity Determinants in Common with the Plant Synthases

Terpenes are an important and diverse class of secondary metabolites widely produced by fungi. Volatile compound screening of a fungal endophyte collection revealed a number of isolates in the family Xylariaceae, producing a series of terpene molecules, including 1,8-cineole. This compound is a commercially important component of eucalyptus oil used in pharmaceutical applications and has been explored as a potential biofuel additive. The genes that produce terpene molecules, such as 1,8-cineole, have been little explored in fungi, providing an opportunity to explore the biosynthetic origin of these compounds. Through genome sequencing of cineole-producing isolate E7406B, we were able to identify 11 new terpene synthase genes. Expressing a subset of these genes in Escherichia coli allowed identification of the hyp3 gene, responsible for 1,8-cineole biosynthesis, the first monoterpene synthase discovered in fungi. In a striking example of convergent evolution, mutational analysis of this terpene synthase revealed an active site asparagine critical for water capture and specificity during cineole synthesis, the same mechanism used in an unrelated plant homologue. These studies have provided insight into the evolutionary relationship of fungal terpene synthases to those in plants and bacteria and further established fungi as a relatively untapped source of this important and diverse class of compounds.     

Atlas – a data warehouse for integrative bioinformatics

Background  

We present a biological data warehouse called Atlas that locally stores and integrates biological sequences, molecular interactions, homology information, functional annotations of genes, and biological ontologies. The goal of the system is to provide data, as well as a software infrastructure for bioinformatics research and development.     

Interaction of activator of G-protein signaling 3 (AGS3) with LKB1, a serine/threonine kinase involved in cell polarity and cell cycle progression: phosphorylation of the G-protein regulatory (GPR) motif as a regulatory mechanism for the interaction of GPR motifs with Gi alpha

Activator of G-protein signaling 3 (AGS3) has a modular domain structure consisting of seven tetratricopeptide repeats (TPRs) and four G-protein regulatory (GPR) motifs. Each GPR motif binds to the alpha subunit of Gi/Go (Gialpha > Goalpha) stabilizing the GDP-bound conformation of Galpha and apparently competing with Gbetagamma for GalphaGDP binding. As an initial approach to identify regulatory mechanisms for AGS3-G-protein interactions, a yeast two-hybrid screen was initiated using the TPR and linker region of AGS3 as bait. This screen identified the serine/threonine kinase LKB1, which is involved in the regulation of cell cycle progression and polarity. Protein interaction assays in mammalian systems using transfected cells or brain lysate indicated the regulated formation of a protein complex consisting of LKB1, AGS3, and G-proteins. The interaction between AGS3 and LKB1 was also observed with orthologous proteins in Drosophila where both proteins are involved in cell polarity. LKB1 immunoprecipitates from COS7 cells transfected with LKB1 phosphorylated the GPR domains of AGS3 and the related protein LGN but not the AGS3-TPR domain. GPR domain phosphorylation was completely blocked by a consensus GPR motif peptide, and placement of a phosphate moiety within a consensus GPR motif reduced the ability of the peptide to interact with G-proteins. These data suggest that phosphorylation of GPR domains may be a general mechanism regulating the interaction of GPR-containing proteins with G-proteins. Such a mechanism may be of particular note in regard to localized signal processing in the plasma membrane involving G-protein subunits and/or intracellular functions regulated by heterotrimeric G-proteins that occur independently of a typical G-protein-coupled receptor.