DNA-arrays with electrical detection: a label-free low cost technology for routine use in life sciences and diagnostics.

Fast and highly parallel DNA analysis are essential for improved biomedical research and development. Currently fluorescence-based methods are state of the art in DNA microarray analysis. The necessity to modify the target DNA with labels is costly, laborious and requires skilled personnel. Moreover, false positive calls from unspecific adsorption are possible and it is difficult to discriminate perfect matching target sequences from those with a single mismatch. In this paper a new and simple electrochemical approach for hybridisation detection without the need of labelling the target DNA is described. The EDDA (Electrically Detected Displacement Assay) method uses a solution of short redox-labelled signalling oligonucleotides (oligonucleotides carrying a covalently attached redox active compound like ferrocene) to characterize the hybridisation state of label-free capture probe DNA immobilised on gold electrodes. The number of capture probes associated with signalling oligonucleotides is determined by chronocoulometry. This technique allows to separate the electrochemical response of capture probe associated signal probes from the response of freely diffusing signalling probes. In the absence of the complementary target sequences the redox-labelled signalling probes at the surface give rise to an instantaneous increase of the detection signal, while freely diffusing signalling probes show a significantly delayed response. Hybridisation with targets complementary to the capture probe displace the loosely associated signalling probes thereby decreasing the instantaneous signal. Besides an introduction to the EDDA technology, data validating the method for biological material will be presented and an outlook to the detection of single nucleotide polymorphisms (SNPs) is given.

SopE and SopE2 from Salmonella typhimurium activate different sets of RhoGTPases of the host cell.

The bacterial enteropathogen Salmonella typhimurium employs a specialized type III secretion system to inject toxins into host cells, which trigger signaling cascades leading to cell death in macrophages, secretion of pro-inflammatory cytokines, or rearrangements of the host cell cytoskeleton and thus to bacterial invasion. Two of the injected toxins, SopE and the 69% identical protein SopE2, are highly efficient guanine nucleotide exchange factors for the RhoGTPase Cdc42 of the host cell. However, it has been a puzzle why S. typhimurium might employ two toxins with redundant function. We hypothesized that SopE and SopE2 might have different specificities for certain host cellular RhoGTPases. In vitro guanine nucleotide exchange assays and surface plasmon resonance measurements revealed that SopE is an efficient guanine nucleotide exchange factor for Cdc42 and Rac1, whereas SopE2 was interacting efficiently only with Cdc42, but not with Rac1. Affinity precipitation of Cdc42.GTP and Rac1.GTP from lysates and characteristic cytoskeletal rearrangements of infected tissue culture cells confirmed that SopE is highly efficient at activating Cdc42 and Rac1 in vivo, whereas SopE2 was efficiently activating Cdc42, but not Rac1. We conclude that the translocated effector proteins SopE and SopE2 allow S. typhimurium to specifically activate different sets of RhoGTPase signaling cascades.

Identification of SopE2 from Salmonella typhimurium, a conserved guanine nucleotide exchange factor for Cdc42 of the host cell.

Salmonella typhimurium translocates effector proteins into host cells via the SPI1 type III secretion system to induce responses such as membrane ruffling and internalization by non-phagocytic cells. Activation of the host cellular RhoGTPase Cdc42 is thought to be a key event during internalization. The translocated Salmonella protein SopE is an activator for Cdc42. Because SopE is absent from most S. typhimurium strains it remains unclear whether all S. typhimurium strains rely on activation of Cdc42 to invade host cells. We have identified SopE2, a translocated effector protein common to all S. typhimurium strains. SopE2 is a guanine nucleotide exchange factor for Cdc42 and shows 69% sequence similarity to SopE. Analysis of S. typhimurium mutants demonstrated that SopE2 plays a role in recruitment of the actin-nucleating Arp2/3 complex to the membrane ruffles and in efficient host cell invasion. Transfection experiments showed that SopE2 is sufficient to activate host cellular Cdc42, to recruit the actin-nucleating Arp2/3 complex and to induce actin cytoskeletal rearrangements and internalization. In conclusion, as a result of SopE2 all S. typhimurium strains tested have the capacity to activate Cdc42 signalling inside host cells which is important to ensure efficient entry.

Genetic probing of the interaction between the translation factor SelB and its mRNA binding element in Escherichia coli.

Decoding of the UGA codon in mRNAs for selenoproteins as selenocysteine requires interaction of the translation factor SelB with an mRNA structure, the SECIS element. A genetic analysis of this interaction was performed by selecting for intergenic suppressor mutations in selB which counteracted the detrimental effect of defined mutations in the SECIS element. Both allele-nonspecific and allele-specific mutations, as judged by readthrough of the UGA into the LacZ-encoding segment of fdhF'-'lacZ fusions and by incorporation of selenium, were isolated. selB genes from ten suppressor mutants were sequenced and the corresponding mutations were localized to five positions within the protein. Four of the suppressors had amino acid exchanges within a 23-amino acid stretch in domain 4b of SelB, which probably represent sites of contact between the protein and the mRNA. A fifth mutation was localized in domain 4a of SelB; it promoted allele-nonspecific readthrough. Since a truncated SelB species lacking domain 4b did not show complex formation with the SECIS element, we speculate that the latter mutation affects the interaction between the tRNA-binding and the mRNA-binding domains. None of the SelB variants was able to promote UGA readthrough when major structural changes that altered the length of the helical part or enlarged the apical loop were introduced into the SECIS element. The results obtained also show that novel pairs of SelB/SECIS derivatives can be generated which may be useful for the targeted insertion of selenocysteine into proteins.