Acid-sensing ion channel 3 mediates peripheral anti-hyperalgesia effects of acupuncture in mice inflammatory pain

Background  

Peripheral tissue inflammation initiates hyperalgesia accompanied by tissue acidosis, nociceptor activation, and inflammation mediators. Recent studies have suggested a significantly increased expression of acid-sensing ion channel 3 (ASIC3) in both carrageenan- and complete Freund's adjuvant (CFA)-induced inflammation. This study tested the hypothesis that acupuncture is curative for mechanical hyperalgesia induced by peripheral inflammation.     

Human Rhinovirus 14 Enters Rhabdomyosarcoma Cells Expressing ICAM-1 by a Clathrin-, Caveolin-, and Flotillin-Independent Pathway

Intercellular adhesion molecule 1 (ICAM-1) mediates binding and entry of major group human rhinoviruses (HRVs). Whereas the entry pathway of minor group HRVs has been studied in detail and is comparatively well understood, the pathway taken by major group HRVs is largely unknown. Use of immunofluorescence microscopy, colocalization with specific endocytic markers, dominant negative mutants, and pharmacological inhibitors allowed us to demonstrate that the major group virus HRV14 enters rhabdomyosarcoma cells transfected to express human ICAM-1 in a clathrin-, caveolin-, and flotillin-independent manner. Electron microscopy revealed that many virions accumulated in long tubular structures, easily distinguishable from clathrin-coated pits and caveolae. Virus entry was strongly sensitive to the Na⁺/H⁺ ion exchange inhibitor amiloride and moderately sensitive to cytochalasin D. Thus, cellular uptake of HRV14 occurs via a pathway exhibiting some, but not all, characteristics of macropinocytosis and is similar to that recently described for adenovirus 3 entry via α_v integrin/CD46 in HeLa cells.Human rhinoviruses (HRVs), members of the family Picornaviridae that represent a major cause of the common cold, essentially utilize two different receptor types for host cell attachment. The 12 minor group HRVs, exemplified by HRV2, bind low-density lipoprotein receptor (LDLR), LDLR-related protein (LRP) (20), and very-LDLR (VLDLR) (29) and are internalized via the well-characterized clathrin-dependent endocytic pathway (44); however, these ligands, like others, can switch to different entry portals when the clathrin-dependent pathway is blocked (4). Once the virus arrives in endosomal carrier vesicles or late endosomes, uncoating (i.e., the release of the viral RNA genome) is triggered by the acidic pH (35, 39).The 87 major group HRVs, exemplified by HRV14, bind intercellular adhesion molecule-1 (ICAM-1). Following entry, uncoating is triggered by ICAM-1 itself (3), but the low endosomal pH facilitates this process (37). Based on inhibition of infection by the dominant negative (DN) dynamin-2 mutant dyn^K44A, it was proposed that HRV14 also follows a clathrin-dependent pathway in HeLa-H1 cells (9). However, ICAM-1 lacks a clathrin localization signal and even functions as a viral receptor when its cytoplasmic tail is replaced with a glycosylphosphatidylinositol (GPI) anchor (45). Furthermore, dynamin has also been shown to be involved in pathways other than clathrin-mediated endocytosis (CME), such as caveolae- and lipid raft-dependent entry, as a function of ligand and cell type (reviewed in references 30 and 34). Additionally, dynamin might play a role in formation and closure of circular pinocytic ruffles (31). More recently, a specific entry pathway for ICAM-1 ligands into human umbilical vein endothelial cells was identified and termed “cam-mediated endocytosis”; uptake was found to be triggered upon binding of multivalent ligands, such as immunoconjugates and immunobeads, and to occur independently from clathrin and caveolin. Inhibition by amiloride, actin depolymerization, and protein kinase C inhibitors pointed to macropinocytosis (33). So far, it is not known whether these findings are relevant to the entry pathway of HRVs via ICAM-1 as the uptake kinetics was significantly dependent on particle size. For all these reasons, involvement of clathrin in HRV14 uptake is questionable. Accordingly, we explored entry of HRV14 via ICAM-1 and compared the results with the well-characterized clathrin-dependent entry pathway of HRV2 (44). Employing pharmacological compounds, specific DN inhibitors, immunofluorescence, and electron microscopy, we demonstrate that HRV14 enters rhabdomyosarcoma ICAM-1-expressing (RD-ICAM) cells via a pathway independent of clathrin, caveolin, and flotillin.     

Protein structure similarity from principle component correlation analysis

Background  

Owing to rapid expansion of protein structure databases in recent years, methods of structure comparison are becoming increasingly effective and important in revealing novel information on functional properties of proteins and their roles in the grand scheme of evolutionary biology. Currently, the structural similarity between two proteins is measured by the root-mean-square-deviation (RMSD) in their best-superimposed atomic coordinates. RMSD is the golden rule of measuring structural similarity when the structures are nearly identical; it, however, fails to detect the higher order topological similarities in proteins evolved into different shapes. We propose new algorithms for extracting geometrical invariants of proteins that can be effectively used to identify homologous protein structures or topologies in order to quantify both close and remote structural similarities.     

The blueprint of the type-3 injectisome

Type-3 secretion systems are sophisticated syringe-like nanomachines present in many animal and plant Gram-negative pathogens. They are capable of translocating an arsenal of specific bacterial toxins (effector proteins) from the prokaryotic cytoplasm across the three biological membranes directly into the eukaryotic cytosol, some of which modulate host cell mechanisms for the benefit of the pathogen. They populate a particular biological niche, which is maintained by specific, pathogen-dependent effectors. In contrast, the needle complex, which is the central component of this specialized protein delivery machine, is structurally well-conserved. It is a large supramolecular cylindrical structure composed of multiple copies of a relatively small subset of proteins, is embedded in the bacterial membranes and protrudes from the pathogen's surface with a needle filament. A central channel traverses the entire needle complex, and serves as a hollow conduit for proteins destined to travel this secretion pathway. In the past few years, there has been a tremendous increase in an understanding on both the structural and the mechanistic level. This review will thus focus on new insights of this remarkable molecular machine.     

Conditional random pattern model for copy number aberration detection

Background  

DNA copy number aberration (CNA) is very important in the pathogenesis of tumors and other diseases. For example, CNAs may result in suppression of anti-oncogenes and activation of oncogenes, which would cause certain types of cancers. High density single nucleotide polymorphism (SNP) array data is widely used for the CNA detection. However, it is nontrivial to detect the CNA automatically because the signals obtained from high density SNP arrays often have low signal-to-noise ratio (SNR), which might be caused by whole genome amplification, mixtures of normal and tumor cells, experimental noise or other technical limitations. With the reduction in SNR, many false CNA regions are often detected and the true CNA regions are missed. Thus, more sophisticated statistical models are needed to make the CNAs detection, using the low SNR signals, more robust and reliable.     

Protein-Mediated Transformation of Lipid Vesicles into Tubular Networks

Key cellular processes are frequently accompanied by protein-facilitated shape changes in the plasma membrane. N-BAR-domain protein modules generate curvature by means of complex interactions with the membrane surface. The way they assemble and the mechanism by which they operate are largely dependent on their binding density. Although the mechanism at lower densities has recently begun to emerge, how membrane scaffolds form at high densities remains unclear. By combining electron microscopy and multiscale simulations, we show that N-BAR proteins at high densities can transform a lipid vesicle into a 3D tubular network. We show that this process is a consequence of excess adhesive energy combined with the local stiffening of the membrane, which occurs in a narrow range of mechanical properties of both the membrane and the protein. We show that lipid diffusion is significantly reduced by protein binding at this density regime and even more in areas of high Gaussian curvature, indicating a potential effect on molecular transport in cells. Finally, we reveal that the breaking of the bilayer topology is accompanied by the nematic arrangement of the protein on the surface, a structural motif that likely drives the formation of reticular structures in living cells.     

Induced heterodimerization and purification of two target proteins by a synthetic coiled-coil tag

A synthetic de novo designed heterodimeric coiled-coil was used to copurify two target fluorescent proteins, Venus and enhanced cyan fluorescent protein (ECFP). The coiled-coil consists of two 21-amino acid repetitive sequences, (EIAALEK)(3) and (KIAALKE)(3), named E3 and K3, respectively. These sequences were fused to the C-termini of ECFP or Venus followed by either a strep- or a his-tag, respectively, for affinity purification. Mixed lysates of Venus-K3 and ECFP-E3 were subjected to consecutive affinity purification and showed highly specific association between the coiled-coil pair by SDS-PAGE, gel filtration, isothermal titration calorimetry (ITC), and fluorescence resonance energy transfer (FRET). The tagged proteins eluted as heterodimers at the concentrations tested. FRET analysis further showed that the coiled-coil pair was stable in buffers commonly used for protein purification, including those containing high salt concentration and detergent. This study shows that the E3/K3 pair is very well suited for the copurification of two target proteins expressed in vivo because of its high specificity: it forms exclusively heterodimers in solution, it does not interact with any cellular proteins and it is stable under different buffer conditions.