Synthesis and activity of functionalizable derivatives of the serotonin (5-HT) 5-HT2A receptor (5-HT2AR) antagonist M100907

The approach of tethering together two known receptor ligands, to be used as molecular probes for the study of G protein-coupled receptor (GPCR) systems, has proven to be a valuable approach. Selective ligands that possess functionality that can be used to link to other ligands, are useful in the development of novel antagonists and agonists. Such molecules can also be attached to reporter molecules, such as fluorophores, for the study of GPCR dimerization and its role in signaling. The highly selective serotonin (5-HT) 5-HT_2A receptor (5-HT_2AR) antagonist M100907 (volinanserin) is of clinical interest in the treatment of neurological and mental health disorders. Here, we synthesized the most active (+)-M100907 enantiomer as well as a series of derivatives that possessed either an alkyne or an azide. The triazole resulting from the dipolar cycloaddition of these groups did not interfere with the ability of the bivalent ligand to act as an antagonist. Thus, we have synthesized a number of compounds which will prove useful in elucidating the role of the 5-HT_2AR in the central nervous system.     

Isolation and characterization of polymorphic microsatellite loci in nurse shark (Ginglymostoma cirratum)

We report on the development of nine polymorphic microsatellite loci in nurse shark (Ginglymostoma cirratum) using a combination of enriched and unenriched subgenomic libraries. Based on the small percentage of positive clones in the unenriched library (0.4%) it appears that microsatellites are very scarce in nurse shark genomes. Numbers of alleles at polymorphic loci ranged from two to 15; observed heterozygosity ranged from 0.17 to 0.90. We expect these loci to be useful for studies of breeding structure and paternity.     

Association of Polymorphisms of the CHI3L1 Gene with Asthma and Atopy: A Populations-Based Study of 6514 Danish Adults

Background

YKL-40 is a chitinase-like glycoprotein encoded by the chitinase 3-like 1 gene, CHI3L1, localized at chromosome 1q32.1. Increased levels of serum YKL-40 have been reported to be a biomarker for asthma and a reduced lung function. Interestingly, the C-allele of the -131 C→G (rs4950928) polymorphism of CHI3L1 has been shown to associate with bronchial hyperresponsiveness and reduced lung function suggesting that variations in CHI3L1 may influence risk of asthma. The objective of the present study was to investigate the association of common variation in the CHI3L1 locus with asthma, atopy and lung function in a large population-based sample of adults.

Methods/Principal Findings

Eleven single nucleotide polymorphisms (SNPs) of CHI3L1 including rs4950928 were genotyped in 6514 individuals. Asthma was defined as self-reported history of physician-diagnosed asthma. Total IgE and specific IgE to inhalant allergens were measured on serum samples. Lung function was measured by spirometry. Homozygosity of the rs4950928 G allele as compared to homozygosity of the C allele was associated with self-reported physician diagnosed asthma (OR 1.5 (95% CI, 1.00–2.26)) and with prevalence of atopic asthma (OR 1.93 (95% CI, 1.21–3.07)) after adjustment for age, sex, smoking status, socio-economic class and BMI. Carriers of rs883125 G allele had a significantly lower prevalence of atopy (OR 0.82 (CI, 0.72; 0.94)) as compared to homozygosity of the C allele. None of the SNPs examined were significantly associated with FEV1. However, two SNPs (rs10399931and rs4950930) appeared to be significantly associated with FEV₁/FVC-ratio. Subgroup analyses of never-smokers did not consistently influence the associations in an either positively og negatively way.

Conclusions

In contrast to previous studies, the rs4950928 G allele, and not the C allele, was found to be associated with asthma. A few other SNPs of the CHI3L1 was found to be significantly associated with atopy and FEV1/FVC ratio, respectively. Thus, more studies seem warranted to establish the role of CHI3L1 gene in asthma and atopy.     

Enhancing Identifications of Lipid-embedded Proteins by Mass Spectrometry for Improved Mapping of Endothelial Plasma Membranes in Vivo

Lipid membranes structurally define the outer surface and internal organelles of cells. The multitude of proteins embedded in lipid bilayers are clearly functionally important, yet they remain poorly defined. Even today, integral membrane proteins represent a special challenge for current large scale shotgun proteomics methods. Here we used endothelial cell plasma membranes isolated directly from lung tissue to test the effectiveness of four different mass spectrometry-based methods, each with multiple replicate measurements, to identify membrane proteins. In doing so, we substantially expanded this membranome to 1,833 proteins, including >500 lipid-embedded proteins. The best method combined SDS-PAGE prefractionation with trypsin digestion of gel slices to generate peptides for seamless and continuous two-dimensional LC/MS/MS analysis. This three-dimensional separation method outperformed current widely used two-dimensional methods by significantly enhancing protein identifications including single and multiple pass transmembrane proteins; >30% are lipid-embedded proteins. It also profoundly improved protein coverage, sensitivity, and dynamic range of detection and substantially reduced the amount of sample and the number of replicate mass spectrometry measurements required to achieve 95% analytical completeness. Such expansion in comprehensiveness requires a trade-off in heavy instrument time but bodes well for future advancements in truly defining the ever important membranome with its potential in network-based systems analysis and the discovery of disease biomarkers and therapeutic targets. This analytical strategy can be applied to other subcellular fractions and should extend the comprehensiveness of many future organellar proteomics pursuits.The plasma membrane provides a fundamental physical interface between the inside and outside of any cell. Beyond creating a protected compartment with a segregated, distinct, and well controlled internal milieu for the cell, it also mediates a wide variety of basic biological functions including signal transduction, molecular transport, membrane trafficking, cell migration, cell-cell interactions, intercellular communication, and even drug resistance. Plasma membrane-associated proteins, especially integral membrane proteins (IMPs)¹ that traverse the lipid bilayer, are key elements mediating these vital biological processes. Consistent with its fundamental importance in both normal cellular functions and pathophysiology, the plasma membrane has also been targeted extensively for biomarker discovery and drug development. In fact, more than two-thirds of known targets for existing drugs are plasma membrane proteins (1).Despite the potential benefits, profiling the proteome of plasma membranes comprehensively using standard large scale methods including MS-based strategies has been limited and technically quite challenging. Intrinsic hydrophobicity, a wide concentration range of proteins, and other factors have hampered IMP resolution and identification using conventional two-dimensional gel electrophoresis. Gel and gel-free protein separations, including combinations of both, have been reported as an alternative to two-dimensional gel electrophoresis (2–9). Yet most such efforts have focused predominantly on identifying rather soluble proteins from body fluids (i.e. plasma, serum, and cerebrospinal fluid), cell lysates, or cytoplasm. These proteins, unlike IMPs, are relatively abundant and readily susceptible to enzymatic digestion in solution. Various attempts have been made to solubilize and enrich for IMPs, including different detergents, solvents, high pH solutions, and affinity purification (10–22). Even when organellar membranes are enriched through isolation by subcellular fractionation, the yield of proteins identified has been below expectation, especially for multipass transmembrane proteins such as G-protein-coupled receptors.Here we systematically characterize four analytical approaches to enhance the identification of proteins, specifically those embedded in plasma membranes isolated directly from vascular endothelium in rat lung. Endothelial cells (ECs) constitute the tissue-blood interface that controls many important physiological functions, including tissue homeostasis, nutrition, vasomotion, and even drug delivery. In vivo mapping of the EC plasma membrane proteome provides unique opportunities for extending basic understanding in vascular biology and for directing the delivery of therapeutic and imaging agents in vivo (23–25). But it also presents distinct challenges beyond those generally associated with extraction, solubilization, and identification of IMPs in cells and tissues. ECs form a thin monolayer lining each blood vessel. They constitute a very small fraction of all the cells existing in tissue, thereby making it difficult to isolate sufficiently pure EC plasma membrane fractions for proteomics analysis using conventional subcellular fractionation techniques. Although relatively simple to isolate from tissue and grow in culture, ECs require cues from the tissue microenvironment to maintain their tissue-specific qualities and thus undergo rapid and considerable phenotypic drift after isolation (26).We have developed a specialized coating procedure using colloidal silica nanoparticles perfused through the blood vessels of the tissue to isolate luminal plasma membranes of the vascular endothelium as they exist natively in tissue (26–28). Our initial survey of these plasma membranes isolated directly from rat lungs used primarily three standard analytical techniques of the time: two-dimensional electrophoresis, Western analysis, and the shotgun method of two-dimensional liquid chromatography-tandem mass spectrometry (24, 26). We identified 450 proteins of which only ∼15% were IMPs. Although at the time this was a notable total number of proteins, more IMPs are expected. In fact, this large scale 2DC study did not identify several well known EC surface marker proteins, including specific enzymes, adhesion molecules, and growth factor receptors.Here we comparatively analyze four different MS-based strategies involving two- and three-dimensional separation by combining protein prefractionation via SDS-PAGE with in-gel digestion to produce peptides separated by one- and two-dimensional nano-HPLC before seamless and continuous MS analysis. Each method used multiple replicate measurements to comprehensively identify proteins, especially IMPs, and in doing so achieved a clear statistical definition of completeness that permits meaningful comparisons. Ultimately this analysis greatly expanded the EC plasma membranome to 1,833 proteins of which nearly 30% are membrane-embedded.