Automated nano-electrospray mass spectrometry for protein-ligand screening by noncovalent interaction applied to human H-FABP and A-FABP

A method for ligand screening by automated nano-electrospray ionization mass spectrometry (nano-ESI/MS) is described. The core of the system consisted of a chip-based platform for automated sample delivery from a 96-well plate and subsequent analysis based on noncovalent interactions. Human fatty acid binding protein, H-FABP (heart) and A-FABP (adipose), with small potential ligands was analyzed. The technique has been compared with a previously reported method based on nuclear magnetic resonance (NMR), and excellent correlation with the found hits was obtained. In the current MS screening method, the cycle time per sample was 1.1 min, which is approximately 50 times faster than NMR for single compounds and approximately 5 times faster for compound mixtures. High reproducibility was achieved, and the protein consumption was in the range of 88 to 100 picomoles per sample. Futhermore, a novel protocol for preparation of A-FABP without the natural ligand is presented. The described screening approach is suitable for ligand screening very early in the drug discovery process before conventional high-throughput screens (HTS) are developed and/or used as a secondary screening for ligands identified by HTS.     

The compliance score as a regressor in randomized trials

The compliance score in randomized trials is a measure of the effect of randomization on treatment received. It is in principle a group-level pretreatment variable and so can be used where individual-level measures of treatment received can produce misleading inferences. The interpretation of models with the compliance score as a regressor of interest depends on the link function. Using the identity link can lead to valid inference about the effects of treatment received even in the presence of nonrandom noncompliance; such inference is more problematic for nonlinear links. We illustrate these points with data from two randomized trials.     

A conserved catalytic residue in the ubiquitin-conjugating enzyme family

Ubiquitin (Ub) regulates diverse functions in eukaryotes through its attachment to other proteins. The defining step in this protein modification pathway is the attack of a substrate lysine residue on Ub bound through its C-terminus to the active site cysteine residue of a Ub-conjugating enzyme (E2) or certain Ub ligases (E3s). So far, these E2 and E3 cysteine residues are the only enzyme groups known to participate in the catalysis of conjugation. Here we show that a strictly conserved E2 asparagine residue is critical for catalysis of E2- and E2/RING E3-dependent isopeptide bond formation, but dispensable for upstream and downstream reactions of Ub thiol ester formation. In contrast, the strictly conserved histidine and proline residues immediately upstream of the asparagine are dispensable for catalysis of isopeptide bond formation. We propose that the conserved asparagine side chain stabilizes the oxyanion intermediate formed during lysine attack. The E2 asparagine is the first non-covalent catalytic group to be proposed in any Ub conjugation factor.     

Bias in Template-to-Product Ratios in Multitemplate PCR

Bias introduced by the simultaneous amplification of specific genes from complex mixtures of templates remains poorly understood. To explore potential causes and the extent of bias in PCR amplification of 16S ribosomal DNAs (rDNAs), genomic DNAs of two closely and one distantly related bacterial species were mixed and amplified with universal, degenerate primers. Quantification and comparison of template and product ratios showed that there was considerable and reproducible overamplification of specific templates. Variability between replicates also contributed to the observed bias but in a comparatively minor way. Based on these initial observations, template dosage and differences in binding energies of permutations of the degenerate, universal primers were tested as two likely causes of this template-specific bias by using 16S rDNA templates modified by site-directed mutagenesis. When mixtures of mutagenized templates containing AT- and GC-rich priming sites were used, templates containing the GC-rich permutation amplified with higher efficiency, indicating that different primer binding energies may to a large extent be responsible for overamplification. In contrast, gene copy number was found to be an unlikely cause of the observed bias. Similarly, amplification from DNA extracted from a natural community to which different amounts of genomic DNA of a single bacterial species were added did not affect relative product ratios. Bias was reduced considerably by using high template concentrations, by performing fewer cycles, and by mixing replicate reaction preparations.     

Dominant-Negative Mutations in the G-Protein-Coupled α-Factor Receptor Map to the Extracellular Ends of the Transmembrane Segments

G-protein-coupled receptors (GPCRs) transduce the signals for a wide range of hormonal and sensory stimuli by activating a heterotrimeric guanine nucleotide-binding protein (G protein). The analysis of loss-of-function and constitutively active receptor mutants has helped to reveal the functional properties of GPCRs and their role in human diseases. Here we describe the identification of a new class of mutants, dominant-negative mutants, for the yeast G-protein-coupled α-factor receptor (Ste2p). Sixteen dominant-negative receptor mutants were isolated based on their ability to inhibit the response to mating pheromone in cells that also express wild-type receptors. Detailed analysis of two of the strongest mutant receptors showed that, unlike other GPCR interfering mutants, they were properly localized at the plasma membrane and did not alter the stability or localization of wild-type receptors. Furthermore, their dominant-negative effect was inversely proportional to the relative amount of wild-type receptors and was reversed by overexpressing the G-protein subunits, suggesting that these mutants compete with the wild-type receptors for the G protein. Interestingly, the dominant-negative mutations are all located at the extracellular ends of the transmembrane segments, defining a novel region of the receptor that is important for receptor signaling. Altogether, our results identify residues of the α-factor receptor specifically involved in ligand binding and receptor activation and define a new mechanism by which GPCRs can be inactivated that has important implications for the evaluation of receptor mutations in other G-protein-coupled receptors.G-protein-coupled receptors (GPCRs) comprise a large family of receptors that are found in a wide range of eukaryotic organisms from yeasts to humans (4, 10). These receptors respond to diverse stimuli including hormones, neurotransmitters, and other chemical messengers (48). GPCRs transduce their signal by stimulating the α subunit of a heterotrimeric guanine nucleotide binding protein (G protein) to bind GTP (4, 16). This releases the α subunit from the βγ subunits, and then either the α subunit or the βγ subunits go on to promote signaling depending on the specific pathway (28).GPCRs are structurally similar in that they contain seven transmembrane domains (TMDs) connected by intracellular and extracellular loops. Although many techniques have been applied to study receptor function, much of our knowledge on the mechanisms of GPCR activation comes from the characterization of mutant receptors. Loss-of-function and supersensitive mutants have helped to identify receptor regions needed for ligand binding, G-protein activation, and down-regulation of signaling (4, 49). Furthermore, the study of constitutively active receptor mutations has played a key role in the development of current models for receptor activation (26). Naturally occurring GPCR mutations have also been implicated in a number of human diseases (8, 25, 42). Interestingly, the analysis of different mutant receptors indicates that GPCRs utilize common structural domains for similar functions. In particular, the third intracellular loop has an essential role in G-protein activation in a wide range of GPCRs.The genetic approaches possible in the yeast Saccharomyces cerevisiae have been used to examine the relationship between structure and function of the G-protein-coupled mating pheromone receptors. The α-factor and a-factor pheromones induce conjugation in yeast by binding to receptors with seven TMDs that activate a G-protein signal pathway that is highly conserved with mammalian signaling pathways (24). In fact, some human GPCRs can activate the pheromone signal pathway when they are expressed in yeast (19, 29). The analysis of loss-of-function, supersensitive, and constitutively active α-factor receptor mutants has begun to reveal the mechanisms for activation and regulation of this receptor. For example, the analysis of constitutively active mutants indicates that movement in the transmembrane segments plays a key role in α-factor receptor activation (22). Constitutive mutations and loss-of-function mutations implicate the third intracellular loop in G-protein activation (7, 34, 44). Mutagenesis studies also indicate that the cytoplasmic C terminus is not needed for G-protein activation but is involved in down-regulation of receptors by endocytosis (17) and desensitization of receptors by phosphorylation (6). In addition, studies with chimeric receptors suggest that the specificity for α-factor binding is determined by discontinuous segments of the α-factor receptor that include the transmembrane and extracellular regions (36, 37). Although some of the important domains of the α-factor receptor have been identified in these studies, the molecular mechanism of receptor signaling remains to be determined.Dominant-negative (DN) mutants represent an important class of mutation in which a mutant receptor interferes with the function of the wild-type (WT) version of the receptor. Since the inhibitory phenotype in DN mutants implies loss of some but not all functions of the protein, these mutants have been used to great advantage in other receptor systems. For example, in the case of receptor tyrosine kinases, DN mutants have been used to assign particular functions to specific structural features or to study the effects of blocking receptor signaling (18). In view of the large number of mutations reported for GPCRs, it is intriguing that there are few examples of dominant GPCR mutations (42, 43). Furthermore, in cases where it has been examined, dominant mutations in GPCRs seem to affect primarily the targeting of receptors to the plasma membrane and not directly the function of the WT receptors. Therefore, we sought to determine if the analysis of DN mutants could be applied to GPCRs by taking advantage of the genetic accessibility of the yeast S. cerevisiae. In this report, we describe the identification of DN mutations in the α-factor pheromone receptor. Interestingly, our results indicate that these DN mutants interfere with the activity of the WT receptors by competing for the G protein. In addition, these mutations identify a new domain on the extracellular side of the TMDs that is important for receptor function.     

Gastrointestinal parasites of the chimpanzee population introduced onto Rubondo Island National Park,Tanzania

The release of any species into a novel environment can evoke transmission of parasites that do not normally parasitize the host as well as potentially introducing new parasites into the environment. Species introductions potentially incur such risks, yet little is currently known about the parasite fauna of introduced primate species over the long term. We describe the results of long‐term monitoring of the intestinal parasite fauna of an unprovisioned, reproducing population of chimpanzees introduced 40 years earlier (1966–1969) onto Rubondo Island in Lake Victoria, Tanzania, a non‐native habitat for chimpanzees. Two parasitological surveys (March 1997–October 1998 and October 2002–December 2005) identified Entamoeba spp. including E. coli, Iodamoeba buetschlii, Troglodytella abrassarti, Chilomastix mesnili, Trichuris sp., Anatrichosoma sp., Strongyloides spp., Strongylida fam. gen. sp., Enterobius anthropopitheci, Subulura sp., Ascarididae gen. sp., and Protospirura muricola. The parasite fauna of the Rubondo chimpanzees is similar to wild chimpanzees living in their natural habitats, but Rubondo chimpanzees have a lower prevalence of strongylids (9%, 3.8%) and a higher prevalence of E. anthropopitheci (8.6%, 17.9%) than reported elsewhere. Species prevalence was similar between our two surveys, with the exception of Strongyloides spp. being higher in the first survey. None of these species are considered to pose a serious health risk to chimpanzees, but continued monitoring of the population and surveys of the parasitic fauna of the two coinhabitant primate species and other animals, natural reservoir hosts of some of the same parasites, is important to better understand the dynamics of host–parasite ecology and potential long‐term implications for chimpanzees introduced into a new habitat. Am. J. Primatol. 72:307–316, 2010. © 2009 Wiley‐Liss, Inc.     

Patterns of reproduction in Malayan silvered leaf monkeys at the Bronx Zoo

Within phylogenetic limits reproductive characteristics of a given species may vary between populations in response to ecological and social factors. For instance, in environments where high quality nutrition is readily available, the onset and speed of reproduction are often accelerated. Other influencing factors might be maternal experience or the sex of the infant. Here we present data on reproductive characteristics for the silvered leaf monkey (Trachypithecus cristatus), a medium‐sized Asian colobine housed at the Wildlife Conservation Society's Bronx Zoo as a one‐male group. To place the species into an appropriate phylogenetic context, we limited our comparison to other colobine species. Demographic data span 21.4 years (October 1985 to March 2007) and derive from 30 adult females (128.0 female years). Detailed behavioral data stem from a 2.2 years study (November 2002 to January 2005; 734 days, 4,225 hr). As in other Asian colobines, receptive periods were short (mean=4.3 days, n=68). This is expected for one‐male groups where receptivity likely indicates, rather than conceals, ovulation. Gestation length was estimated based on a change in the pattern of sexual behavior (mean=194.6 days, n=7). It fell within the range reported for the taxon. Births occurred year round, at an early age (mean=2.9 years, n=8), at short intervals (mean=14.9 months, n=59) in combination with a short lactation (mean 12.1 months, n=9) likely due to the nearly unlimited availability of nutrition in this zoo setting. Primiparous females tended to have a longer first interbirth interval but infant survival rates were similar to multipara possibly due to the absence of predators. Maternal investment was independent of the infant's sex and birth sex ratio was even. Our results emphasize that when interpreted with caution, zoo populations yield realistic reproductive characteristics that can help fill the gap in our knowledge about colobine life history. Am. J. Primatol. 71:852–859, 2009. © 2009 Wiley‐Liss, Inc.     

Engineering key components in a synthetic eukaryotic signal transduction pathway

Signal transduction underlies how living organisms detect and respond to stimuli. A goal of synthetic biology is to rewire natural signal transduction systems. Bacteria, yeast, and plants sense environmental aspects through conserved histidine kinase (HK) signal transduction systems. HK protein components are typically comprised of multiple, relatively modular, and conserved domains. Phosphate transfer between these components may exhibit considerable cross talk between the otherwise apparently linear pathways, thereby establishing networks that integrate multiple signals. We show that sequence conservation and cross talk can extend across kingdoms and can be exploited to produce a synthetic plant signal transduction system. In response to HK cross talk, heterologously expressed bacterial response regulators, PhoB and OmpR, translocate to the nucleus on HK activation. Using this discovery, combined with modification of PhoB (PhoB‐VP64), we produced a key component of a eukaryotic synthetic signal transduction pathway. In response to exogenous cytokinin, PhoB‐VP64 translocates to the nucleus, binds a synthetic PlantPho promoter, and activates gene expression. These results show that conserved‐signaling components can be used across kingdoms and adapted to produce synthetic eukaryotic signal transduction pathways.