Giardia secretome highlights secreted tenascins as a key component of pathogenesis.

Background: Giardia is a protozoan parasite of public health relevance that causes gastroenteritis in a wide range of hosts. Two genetically distinct lineages (assemblages A and B) are responsible for the human disease. Although it is clear that differences in virulence occur, the pathogenesis and virulence of Giardia remain poorly understood. Results: The genome of Giardia is believed to contain open reading frames that could encode as many as 6000 proteins. By successfully applying quantitative proteomic analyses to the whole parasite and to the supernatants derived from parasite culture of assemblages A and B, we confirm expression of ∼1600 proteins from each assemblage, the vast majority of which are common to both lineages. To look for signature enrichment of secreted proteins, we considered the ratio of proteins in the supernatant compared with the pellet, which defined a small group of enriched proteins, putatively secreted at a steady state by cultured growing trophozoites of both assemblages. This secretome is enriched with proteins annotated to have N-terminal signal peptide. The most abundant secreted proteins include known virulence factors such as cathepsin B cysteine proteases and members of a Giardia superfamily of cysteine-rich proteins that comprise variant surface proteins, high-cysteine membrane proteins, and a new class of virulence factors, the Giardia tenascins. We demonstrate that physiological function of human enteric epithelial cells is disrupted by such soluble factors even in the absence of the trophozoites. Conclusions: We are able to propose a straightforward model of Giardia pathogenesis incorporating key roles for the major Giardia-derived soluble mediators.

The CLCA gene family: putative therapeutic target for respiratory diseases.

The CLCA proteins were first shown to exist in bovine trachea and named as chloride channels calcium activated (CLCA) due to the calcium-dependent chloride conductance that appeared to be activated on expression of these proteins in trachea and other secretory epithelial cells. Since their initial discovery the CLCA gene family has grown extensively and family members have been identified in bovine, human, murine, equine and porcine tissues. The CLCA proteins appear to have a role to play in chloride conductance across epithelial cells and hence epithelial fluid secretion; cell-cell adhesion, apoptosis, cell cycle control and tumorgenesis and metastasis; mucous production and cell signalling in respiratory diseases such as asthma and chronic obstructive pulmonary disease (COPD). There are four human homologues; hCLCA1, hCLCA2, hCLCA3 and hCLCA4. Interest in these proteins has gathered pace with the description of hCLCA1's involvement in several human respiratory diseases. This review will describe the CLCA gene family and then move on to look at the growing body of evidence that suggests that at least hCLCA1 has an important role in the pathogenesis of respiratory disease such as asthma, COPD and cystic fibrosis (CF).

Bestrophin expression and function in the human pancreatic duct cell line, CFPAC-1.

Pancreatic duct epithelial cells (PDECs) have been shown to express calcium activated chloride channels (CaCCs) and there is evidence for their involvement in fluid secretion from these cells. The molecular identity of the CaCC in PDECs remains unknown. Recently, the bestrophin family of proteins have been proposed as a potential molecular candidate for CaCCs. Expression of bestrophins is strongly correlated with the function of CaCCs in a variety of tissues. In the present study, the expression of bestrophins has been investigated in the cystic fibrosis pancreatic duct cell line, CFPAC-1. Iodide efflux analysis was used to characterise native CaCCs in CFPAC-1 cell monolayers. Efflux was induced with the addition of UTP (100 microM, 10.2 +/- 1.5 nmol min(-1)), which was blocked by the chloride channel blockers niflumic acid (81%) and DIDS (90%). The UTP-stimulated iodide efflux was shown to be Ca(2+) dependent and cAMP independent. RT-PCR analysis of RNA isolated from CFPAC-1 cells demonstrated positive identification of all four human bestrophin mRNAs. Western blot of CFPAC-1 cell protein isolates with antibodies specific to human bestrophin 1 (hBest1) showed that hBest1 protein was expressed in this cell line. HBest1 was present on the cell surface, demonstrated using biotinylation and confocal imaging, as well as in the cytoplasm. SiRNA-mediated silencing of hBest1 in CFPAC-1 cells reduced the UTP-stimulated iodide efflux by around 40%. This study provides evidence that the bestrophins are expressed in pancreatic duct cells and, more specifically, that hBest1 plays a role in the CaCCs found in these cells.

Lubiprostone.

Sucampo Pharmaceuticals Inc and Takeda Pharmaceutical Co Ltd are developing, a ClC-2 chloride channel activator and a bicyclic member of a series of fatty acid compounds, for the potential treatment of a number of gastrointestinal conditions, including constipation, irritable bowel syndrome, postoperative bowel dysfunction and opioid bowel dysfunction.

MZF-1 and DbpA interact with DNase I hypersensitive sites that correlate with expression of the human MUC1 mucin gene.

The MUC1 mucin is a large membrane-tethered glycoprotein that shows differential expression in many adenocarcinomas, where it contributes to their invasive and metastatic properties. We previously identified DNase I hypersensitive sites at -750 and -250 bp in the human MUC1 gene promoter and showed concordance between the -250 site and MUC1 mRNA levels in vivo. Transient expression assays using promoter constructs, in which the core DHS was deleted, to drive reporter gene expression revealed in vivo evidence for their activity. DNase I footprinting using nuclear extracts from HPAF human pancreatic carcinoma cells and MCF7 breast carcinoma cells identified three protein-binding elements in these regions (-250FP1, FP2 and -750FP). Electrophoretic mobility shift assays detected several complexes between HPAF nuclear proteins and labeled FP DNA probes. Southwestern blots and UV cross-linking experiments identified myeloid zinc finger-1 (MZF-1) as a candidate transcription factor among proteins binding to the -250FP1 and FP2 sequences. Another candidate that was identified by screening an HPAF cDNA expression library with the -250FP1 probe is DNA binding protein A (DbpA). Exogenous DbpA expression in COS-7 cells was accompanied by upregulation of MUC1 promoter activity via the -250 DHS, suggesting that DbpA binding to the -250 DHS can influence human MUC1 gene expression.

Substrate specificity and functional characterisation of the H+/amino acid transporter rat PAT2 (Slc36a2).

Functional characteristics and substrate specificity of the rat proton-coupled amino acid transporter 2 (rat PAT2 (rPAT2)) were determined following expression in Xenopus laevis oocytes using radiolabelled uptake measurements, competition experiments and measurements of substrate-evoked current using the two-electrode voltage-clamp technique. The aim of the investigation was to determine the structural requirements and structural limitations of potential substrates for rPAT2. Amino (and imino) acid transport via rPAT2 was pH-dependent, Na(+)-independent and electrogenic. At extracellular pH 5.5 (in Na(+)-free conditions) proline uptake was saturable (Km 172+/-41 muM), demonstrating that rPAT2 is, relative to PAT1, a high-affinity transporter.PAT2 preferred substrates are L-alpha-amino acids with small aliphatic side chains (e.g. the methyl group in alanine) and 4- or 5-membered heterocyclic amino and imino acids such as 2-azetidine-carboxylate, proline and cycloserine, where both D- and L-enantiomers are transported. The major restrictions on transport are side chain size (the ethyl group of alpha-aminobutyric acid is too large) and backbone length, where the separation of the carboxyl and amino groups by only two CH(2) groups, as in beta-alanine, is enough to reduce transport. Methylation of the amino group is tolerated (e.g. sarcosine) but increasing methylation, as in betaine, decreases transport. A free carboxyl group is preferred as O-methyl esters show either reduced transport (alanine-O-methyl ester) or are excluded. The structural characteristics that determine the substrate specificity of rPAT2 have been identified. This information should prove valuable in the design of selective substrates/inhibitors for PAT1 and PAT2.