Comparative analysis of the ADAM and ADAMTS families

The "A Disintegrin And Metalloproteinase" (ADAM) protein family and the "A Disintegrin-like And Metalloproteinase with ThromboSpondin motifs" (ADAMTS) protein family are two related families of human proteins. The similarities and differences between these two families have been investigated using phylogenetic trees and homology modeling. The phylogenetic analysis indicates that the two families are well differentiated, even when only the common metalloprotease domain is taken into account. Within the ADAM family, several proteins are lacking the binding motif for the catalytic zinc in the active site and thus presumably lack any catalytic activity. These proteins tend to cluster within the ADAM phylogenetic tree and are expressed in specific tissues, suggesting a functional differentiation. The present analysis allows us to propose the following: (i) ADAMTS proteins have a conserved role in the human organism as proteases, with some differentiation in terms of substrate specificity; (ii) ADAM proteins can act as proteases and/or mediators of intermolecular interactions; (iii) proteolytically active ADAMs tend to be more ubiquitously expressed than the inactive ones.     

A critical step in the folding of influenza virus HA determined with a novel folding assay

Most principles of protein folding emerged from refolding studies in vitro on small, soluble proteins, because large ones tend to misfold and aggregate. We developed a folding assay allowing the study of large proteins in detergent such that the extent of cellular assistance required for proper folding can be determined. We identified a critical step in the in vivo folding pathway of influenza virus hemagglutinin (HA). Only the formation of the first few disulfides in the top domain of HA required the intact endoplasmic reticulum. After that, HA proceeded to fold efficiently in a very dilute solution, despite its size and complexity. This study paves the way for detailed structural analyses during the folding of complex proteins.     

2- and 8-alkynyl-9-ethyladenines: Synthesis and biological activity at human and rat adenosine receptors

The synthesis of a series of 9-ethyladenine derivatives bearing alkynyl chains in 2- or 8-position was undertaken, based on the observation that replacement of the sugar moiety in adenosine derivatives with alkyl groups led to adenosine receptor antagonists. All the synthesized compounds were tested for their affinity at human and rat A₁, A_2A, and A₃ adenosine receptors in binding assays; the activity at the human A_2B receptor was determined in adenylyl cyclase experiments. Biological data showed that the 2-alkynyl derivatives possess good affinity and are slightly selective for the human A_2A receptor. The same compounds tested on the rat A₁ and A_2A subtypes showed in general lower affinity for both receptors. On the other hand, the affinity of the 8-alkynyl derivatives at the human A₁, A_2A, and A_2B receptors proved to be lower than that of the corresponding 2-alkynyl derivatives. On the contrary, the affinity of the same compounds for the human A₃ receptor was improved, resulting in A₃ selectivity. As in the case of the 2-alkynyl-substituted compounds, the 8-alkynyl derivatives showed decreased affinity for rat receptors. However, it is worthwhile to note that the 8-phenylethynyl-9-ethyladenine was the most active compound of the two series (K_i in the nanomolar range) at both the human and rat A₃ subtype. Docking experiments of the 2- and 8-phenylethynyl-9-ethyladenines, at a rhodopsin-based homology model, gave a rational explanation of the preference of the human A₃ receptor for the 8-substituted compound.     

Genetic variation and population structure of two species of neo-tropical mud-mussels (Mytella spp)

Mytella guyanensis Lamarck (1819) and Mytella charruana d'Orbigny (1846) are widespread euryhaline bivalves that have become commercially important in Brazil. Despite their importance, however, no genetic information that would be useful to orient governmental policies is available for these species. We analyzed, through allozyme electrophoresis, populations of M. guyanensis and M. charruana along 3,500 km of Brazilian coast. Pairwise comparisons among gene frequencies in M. guyanensis resulted in high levels of pairwise gene identity (I = 0.976 to 0.998). Conversely, significant levels of population structure were found in both M. guyanensis (FST = 0.089) and M. charruana (FST = 0.102). Heterozygosity levels for both species were high (H(e) = 0.090 to 0.134 in M. guyanensis and H(e) = 0.191 to 0.228 in M. charruana). The larger population size of M. charruana could explain, at least partially, the higher levels of genetic variability for this species. These levels of genetic variability yield an effective population size estimate of about 300,000 for M. guyanensis, and 540,000 for M. charruana, based on neutralist expectations. Remarkably, these numbers are much smaller than the estimated actual population sizes. This distortion might be explained by unstable population sizes and it suggests that long-term genetic variability studies are crucial to prevent artifactual viability analysis data for these commercially exploited species.     

The variable C-terminal extension of G-protein-coupled receptor kinase 6 constitutes an accessorial autoregulatory domain

G-protein-coupled receptor kinases (GRK) are known to phosphorylate agonist-occupied G-protein-coupled receptors. We expressed and functionally characterized mouse GRK6 proteins encoded by four distinct mRNAs generated by alternative RNA splicing from a single gene, mGRK6-A to mGRK6-D. Three isoforms, mGRK6-A to mGRK6-C differ in their C-terminal-most portion, which is known to mediate membrane and/or receptor interaction and regulate the activity of GRK4-like kinases. One isoform, mGRK6-D, is identical to the other mGRK6 variants in the N-terminal region, but carries an incomplete catalytical domain. Mouse GRK6-D was catalytically inactive and specifically present in the nucleus of transfected cells. Recombinant mouse GRK6-A to mGRK6-C were found to be membrane-associated in cell-free systems and in transfected COS-7 cells, suggesting that the very C-terminus of GRK6-A, lacking in GRK6-B and mGRK6-C and carrying consensus sites for palmitoylation, is not required for membrane interaction. Interestingly, the shortest catalytically active variant, mGRK6-C, was conspicuously more active in phosphorylating light-activated rhodopsin than mGRK6-A and mGRK6-B, implying that the C-terminus of the latter two variants may fulfil an autoinhibitory function. Mutation and removal of C-terminal-most region of mGRK6-A by site-directed mutagenesis revealed that this region contains three autoregulatory elements: two discontinuous inhibitory elements consisting of a single residue, D560, and the sequence between residues S566 and L576, and an intervening stimulatory element. The results suggest that mGRK6-C may be considered a basic, prototypic representative of the GRK4-like kinases, which is capable of interacting with both plasma membrane and its receptor substrate, but is resistant to further regulatory modification conferred to the prototype via C-terminal extension.     

Genetic and functional characterization of the Escherichia coli BarA-UvrY two-component system: point mutations in the HAMP linker of the BarA sensor give a dominant-negative phenotype

The BarA-UvrY two-component system family is strongly associated with virulence but is poorly understood at the molecular level. During our attempts to complement a barA deletion mutant, we consistently generated various mutated BarA proteins. We reasoned that characterization of the mutants would help us to better understand the signal transduction mechanism in tripartite sensors. This was aided by the demonstrated ability to activate the UvrY regulator with acetyl phosphate independently of the BarA sensor. Many of the mutated BarA proteins had poor complementation activity but could counteract the activity of the wild-type sensor in a dominant-negative fashion. These proteins carried point mutations in or near the recently identified HAMP linker, previously implicated in signal transduction between the periplasm and cytoplasm. This created sensor proteins with an impaired kinase activity and a net dephosphorylating activity. Using further site-directed mutagenesis of a HAMP linker-mutated protein, we could demonstrate that the phosphoaccepting aspartate 718 and histidine 861 are crucial for the dephosphorylating activity. Additional analysis of the HAMP linker-mutated BarA sensors demonstrated that a dephosphorylating activity can operate via phosphotransfer within a tripartite sensor dimer in vivo. This also means that a tripartite sensor can be arranged as a dimer even in the dephosphorylating mode.     

Methylocella species are facultatively methanotrophic

All aerobic methanotrophic bacteria described to date are unable to grow on substrates containing carbon-carbon bonds. Here we demonstrate that members of the recently discovered genus Methylocella are an exception to this. These bacteria are able to use as their sole energy source the one-carbon compounds methane and methanol, as well as the multicarbon compounds acetate, pyruvate, succinate, malate, and ethanol. To conclusively verify facultative growth, acetate and methane were used as model substrates in growth experiments with the type strain Methylocella silvestris BL2. Quantitative real-time PCR targeting the mmoX gene, which encodes a subunit of soluble methane monooxygenase, showed that copies of this gene increased in parallel with cell counts during growth on either acetate or methane as the sole substrate. This verified that cells possessing the genetic basis of methane oxidation grew on acetate as well as methane. Cloning of 16S rRNA genes and fluorescence in situ hybridization with strain-specific and genus-specific oligonucleotide probes detected no contaminants in cultures. The growth rate and carbon conversion efficiency were higher on acetate than on methane, and when both substrates were provided in excess, acetate was preferably used and methane oxidation was shut down. Our data demonstrate that not all methanotrophic bacteria are limited to growing on one-carbon compounds. This could have major implications for understanding the factors controlling methane fluxes in the environment.     

The macrophage alphaMbeta2 integrin alphaM lectin domain mediates the phagocytosis of chilled platelets

alpha(M)beta(2) integrin receptors on myeloid cells mediate the adhesion or uptake of diverse ligands. Ligand binding occurs in the alpha(M) chain, which is composed of an I domain and a lectin domain. The alpha(M) I domain binds iC3b, fibrinogen, intercellular adhesion molecule-1, and other ligands and mediates the adhesion of neutrophils to platelet glycoprotein Ibalpha (GPIbalpha). alpha(M)beta(2) also recognizes beta-GlcNAc residues on GPIbalpha that are clustered on platelets after cooling. The phagocytosis of chilled platelets could be reconstituted when Chinese hamster ovary cells were transfected with alpha(M)beta(2). Replacement of the I domain or the lectin domain of the alpha(M) chain with the corresponding domain from the alpha(X) chain (p150) revealed that the activity of the alpha(M)beta(2) integrin toward chilled platelets resides within the lectin domain and does not require the I domain. Additional evidences for this conclusion are: 1) Sf9 cells expressing solely the alpha(M) lectin domain bound chilled platelets, and 2) soluble recombinant alpha(M) lectin domain inhibited the phagocytosis of chilled platelets by alpha(M)beta(2)-expressing THP-1 cells, whereas I domain substrates showed no inhibitory effect. Therefore chilled platelets are removed from blood by an interaction between beta-GlcNAc residues on clustered GPIbalpha and the lectin domain of alpha(M) chain of the alpha(M)beta(2) integrin, distinguishing this interaction from those mediated by the alpha(M) I domain.     

Identification and characterization of a novel mammalian caspase with proapoptotic activity

Caspases are essential proteases in programmed cell death and inflammation. Studies in murine and human cells have led to the characterization of 14 members of this enzyme family. Here we report the identification of caspase-15, a novel caspase that is expressed in various mammalian species including pig, dog, and cattle. The caspase-15 protein contains a catalytic domain with all amino acid residues critical for caspase activity and a prodomain that is predicted to fold into a pyrin domain structure, which is a unique feature among mammalian caspases. Recombinant porcine caspase-15 underwent autocatalytic processing into its subunits and cleaved both tetrapeptide caspase substrates and the apoptosis regulator protein Bid in vitro. Overexpression of caspase-15 in mammalian cells induced proenzyme maturation, cleavage of Bid, activation of caspase-3, and eventually cell death. Both the proteolytic and the pro-apoptotic activity of caspase-15 were abolished by mutation of the active site cysteine. Since a homolog of caspase-15 is absent in the human and the mouse genome, our results reveal an unexpected variability in the molecular apoptotic machinery of mammals.