Evidence for a two-step mechanism involved in the formation of covalent HC x TSG-6 complexes

IalphaI and TSG-6 interact to form a covalent bond between the C-terminal Asp alpha-carbon of an IalphaI heavy chain (HC) and an unknown component of TSG-6. This event disrupts the protein-glycosaminoglycan-protein (PGP) cross-link and dissociates IalphaI. In simple terms the interaction involves 5 components: (i) the IalphaI HCs, (ii) bikunin, (iii) chondroitin sulfate chain, (iv) TSG-6, and (v) divalent cations. To understand the molecular mechanism of complex formation, the effect of these were separately examined. The data show that although the mature covalent cross-link between the HCs and TSG-6 only involves the C-terminal Asp residue, the native fold of both IalphaI and TSG-6 was essential for the reaction to occur. Similarly, complex formation was prevented if the chondroitin sulfate chain was cleaved, releasing bikunin but maintaining the HC1 and HC2 PGP cross-links. In contrast, releasing the majority of the bikunin protein moiety by limited proteolysis did not prevent complex formation. An analysis of the divalent-cation requirements revealed two distinct interactions between IalphaI and TSG-6: (i) a noncovalent manganese, magnesium, or calcium-independent interaction between TSG-6 and the chondroitin sulfate chain (Kd 180 nM) and (ii) a covalent manganese, magnesium, or calcium-dependent interaction generating HC1 x TSG-6, HC2 x TSG-6, and high molecular weight (HMW) IalphaI. Significantly, both free TSG-6 and HC x TSG-6 complexes were able to bind the chondroitin sulfate chain suggesting that the sites on TSG-6 were distinct. On the basis of these findings, we propose a two-step reaction mechanism involving two putative binding sites. Initially, a cation-independent interaction between TSG-6 and the chondroitin sulfate chain is formed at site 1. Subsequently, a cation-dependent transesterification occurs, generating the covalent HC x TSG-6 cross-link at another site, site 2.     

Yeast and filamentous fungi as model organisms in microbody research

Yeast and filamentous fungi are important model organisms in microbody research. The value of these organisms as models for higher eukaryotes is underscored by the observation that the principles of various aspects of microbody biology are strongly conserved from lower to higher eukaryotes. This has allowed to resolve various peroxisome-related functions, including peroxisome biogenesis disorders in man. This paper summarizes the major advances in microbody research using fungal systems and specifies specific properties and advantages/disadvantages of the major model organisms currently in use.     

Pexophagy: autophagic degradation of peroxisomes

The abundance of peroxisomes within a cell can rapidly decrease by selective autophagic degradation (also designated pexophagy). Studies in yeast species have shown that at least two modes of peroxisome degradation are employed, namely macropexophagy and micropexophagy. During macropexophagy, peroxisomes are individually sequestered by membranes, thus forming a pexophagosome. This structure fuses with the vacuolar membrane, resulting in exposure of the incorporated peroxisome to vacuolar hydrolases. During micropexophagy, a cluster of peroxisomes is enclosed by vacuolar membrane protrusions and/or segmented vacuoles as well as a newly formed membrane structure, the micropexophagy-specific membrane apparatus (MIPA), which mediates the enclosement of the vacuolar membrane. Subsequently, the engulfed peroxisome cluster is degraded. This review discusses the current state of knowledge of pexophagy with emphasis on studies on methylotrophic yeast species.     

Methylglyoxal modification of mSin3A links glycolysis to angiopoietin-2 transcription

Methylglyoxal is a highly reactive dicarbonyl degradation product formed from triose phosphates during glycolysis. Methylglyoxal forms stable adducts primarily with arginine residues of intracellular proteins. The biologic role of this covalent modification in regulating cell function is not known. Here, we report that in retinal Müller cells, increased glycolytic flux causes increased methylglyoxal modification of the corepressor mSin3A. Methylglyoxal modification of mSin3A results in increased recruitment of O-GlcNAc transferase to an mSin3A-Sp3 complex, with consequent increased modification of Sp3 by O-linked N-acetylglucosamine. This modification of Sp3 causes decreased binding of the repressor complex to a glucose-responsive GC box in the angiopoietin-2 promoter, resulting in increased Ang-2 expression. A similar mechanism involving methylglyoxal-modification of other coregulator proteins may play a role in the pathobiology of a variety of conditions associated with changes in methylglyoxal concentration, including cancer and diabetic vascular disease.     

Identification and characterization of porcine mannan-binding lectin A (pMBL-A), and determination of serum concentration heritability

Mannan-binding lectin (MBL) is an innate immune collectin present in the serum of humans and many farm animals. This oligomeric pattern-recognition protein effectively binds to the glycoconjugate arrays present on the surfaces of microorganisms and activates the complement system to enhance pathogen killing and clearance. MBL deficiency is often associated with immunodeficiency in humans. Although two MBLs (MBL-A and MBL-C) have been characterized in various species, the identity of porcine MBL (pMBL) was not clearly defined. In this study, we purified an MBL from porcine serum by mannose affinity, ion exchange, and size exclusion chromatography and determined many of its characteristics. Based on the N-terminal sequence, multiple sequence alignment, and relative affinities to various carbohydrate ligands, we propose that the MBL purified in this study is pMBL-A. We have generated antibodies to this protein and established an immunoassay to quantify pMBL-A in serum. Using this assay, we found breed differences in pMBL-A concentration distributions and heritability estimates. In the Duroc breed (n=588), pMBL-A concentrations show a unimodal distribution with a mean of 9,125 ng/ml. In contrast, the pMBL-A concentration distributions in the Landrace breed (n=533) show three distinct mean values: 301, 2,385, and 11,507 ng/ml. Furthermore, heritability calculations based on an additive genetic variance model with no fixed effects indicate that serum pMBL-A concentration is highly heritable in the Landrace (h ²=0.8) but not in the Duroc breed (h ²=0.15). These genetic differences may be useful in selecting breeding pigs for improved disease resistance.     

Serotonin-Synthesizing Neurons in the Rostral Medullary Raphé/Parapyramidal Region Transneuronally Labelled After Injection of Pseudorabies Virus into the Rat Tail

Serotonin-synthesizing raphé/parapyramidal neurons (5-HT neurons) may function as sympathetic premotor neurons regulating sympathetic outflow to the cutaneous vascular bed. In the present study a genetically engineered pseudorabies virus (PRV) expressing green fluorescent protein (GFP) was injected into the rat tail. After survival for 3–4 days the medulla oblongata was examined using double-label immunohistochemistry, with an antibody against GFP for the virus and an antibody against phenylalanine hydroxylase 8 (PH8) for 5-HT synthesis. Sections were examined using light microscopy, and conventional and confocal fluorescence microscopy. There were two subpopulations of PRV+ve neurons in the raphé/parapyramidal region: a more dorsally and laterally located subgroup of medium-sized and large neurons, mainly non-serotonergic, and a more ventrally located subgroup of small mainly serotonin-synthesizing neurons, including those just dorsal to the pyramids, those in raphé pallidus, and those in close relationship to the ventral surface in the parapyramidal-subependymal zone.Special issue dedicated to Miklós Palkovits.     

Bionanoconjugation via click chemistry: The creation of functional hybrids of lipases and gold nanoparticles

A simple and versatile method for the preparation of functional enzyme-gold nanoparticle conjugates using "click" chemistry has been developed. In a copper-catalyzed 1,2,3-triazole cycloaddition, an acetylene-functionalized Thermomyces lanuginosus lipase has been attached to azide-functionalized water-soluble gold nanoparticles under retention of enzymatic activity. The products have been characterized by gel electrophoresis and a fluorometric lipase activity assay. It is estimated that the equivalent of approximately seven fully active lipase molecules are attached to each nanoparticle.