Cooperation between ER stress and calcineurin signaling contributes to the maintenance of cell wall integrity in Candida glabrata

Candida glabrata is the second most common source of Candida infections in humans. In this pathogen, the maintenance of cell wall integrity (CWI) frequently precludes effective pharmacological treatment by antifungal agents. In numerous fungi, cell wall modulation is reported to be controlled by endoplasmic reticulum (ER) stress, but how the latter affects CWI maintenance in C. glabrata is not clearly understood. Here, we characterized a C. glabrata strain harboring a mutation in the CNE1 gene, which encodes a molecular chaperone associated with nascent glycoprotein maturation in the ER. Disruption of cne1 induced ER stress and caused changes in the normal cell wall structure, specifically a reduction in the β-1,6-glucan content and accumulation of chitin. Conversely, a treatment with the typical ER stress inducer tunicamycin up-regulated the production of cell wall chitin but did not affect β-1,6-glucan content. Our results also indicated that C. glabrata features a uniquely evolved ER stress-mediated CWI pathway, which differs from that in the closely related species Saccharomyces cerevisiae. Furthermore, we demonstrated that ER stress-mediated CWI pathway in C. glabrata is also induced by the disruption of other genes encoding proteins that function in a correlated manner in the quality control of N-linked glycoproteins in the ER. These results suggest that calcineurin and ER quality control system act as a platform for maintaining CWI in C. glabrata.     

Neurotrophic Activity of Organosulfur Compounds Having a Thioallyl Group on Cultured Rat Hippocampal Neurons

Several organosulfur compounds found in garlic extract promoted the survival of rat hippocampal neurons in vitro. From the analysis of structure-activity relationship, thioallyl group in these compounds is essential for the manifestation of neurotrophic activity. S-Allyl-L-cysteine (SAC), one of the organosulfur compounds having thioallyl group in garlic extract, also promoted the axonal branching of cultured neurons. These results suggest that thioallyl compounds make a unique group of neurotrophic factors.     

A 3-Mb Sequence-Ready Contig Map Encompassing the Multiple Disease Gene Cluster on Chromosome 11q13.1-q13.3

Despite the presence of several human disease genes on chromosome11q13, few of them have been molecularly cloned. Here, we reportthe construction of a contig map encompassing 11q13.1–q13.3using bacteriophage P1 (P1), bacterial artificial chromosome(BAC), and P1-derived artificial chromosome (PAC). The contigmap comprises 32 P1 clones, 27 BAC clones, 6 PAC clones, and1 YAC clone and spans a 3-Mb region from D11S480 to D11S913.The map encompasses all the candidate loci of Bardet-Biedlesyndrome type I (BBS1) and spinocerebellar ataxia type 5 (SCA5),one-third of the distal region for hereditary paraganglioma2 (PGL2), and one-third of the central region for insulin-dependentdiabetes mellitus 4 (IDDM4). In the process of map construction,61 new sequence-tagged site (STS) markers were developed fromthe Not I linking clones and the termini of clone inserts. Wehave also mapped 30 ESTs on this map. This contig map will facilitatethe isolation of polymorphic markers for a more re.ned analysisof the disease gene region and identi.cation of candidate genesby direct cDNA selection, as well as prediction of gene functionfrom sequence information of these bacterial clones.     

An NMR analysis of ubiquitin recognition by yeast ubiquitin hydrolase: evidence for novel substrate recognition by a cysteine protease.

Yeast ubiquitin hydrolase 1 (YUH1), a cysteine protease that catalyzes the removal of ubiquitin C-terminal adducts, is important for the generation of monomeric ubiquitin. Heteronuclear NMR spectroscopy has been utilized to map the YUH1 binding surface on ubiquitin. When YUH1 was titrated into a sample of ubiquitin, approximately 50% of the (1)H-(15)N correlation peaks of ubiquitin were affected to some degree, as a result of binding to YUH1. It is noteworthy that the amide resonances of the basic residues (Arg42, Lys48, Arg72, and Lys74) were highly perturbed. These positively charged basic residues may be involved in direct interactions with the negatively charged acidic residues on YUH1. In addition to the electrostatic surface, the hydrophobic surfaces on ubiquitin (Leu8, Ile44, Phe45, Val70, Leu71, and Leu73) and YUH1 are also likely to contribute to the binding interaction. Furthermore, the amide resonances of Ile13, Leu43, Leu50, and Leu69, the side chains of which are not on the surface, were also highly perturbed, indicating substrate-induced changes in the environments of these residues as well. These large changes, observed from residues located throughout the five-stranded beta-sheet surface and the C-terminus, suggest that substrate recognition by YUH1 involves a wider area on ubiquitin.     

Cumulative Effect of Amino Acid Replacements Results in Enhanced Thermostability of Potato Type L α-Glucan Phosphorylase

The thermostability of potato type L α-glucan phosphorylase (EC 2.4.1.1) was enhanced by random and site-directed mutagenesis. We obtained three single-residue mutations—Phe39→Leu (F39L), Asn135→Ser (N135S), and Thr706→Ile (T706I)—by random mutagenesis. Although the wild-type enzyme was completely inactivated, these mutant enzymes retained their activity even after heat treatment at 60°C for 2 h. Combinations of these mutations were introduced by site-directed mutagenesis. The simultaneous mutation of two (F39L/N135S, F39L/T706I, and N135S/T706I) or three (F39L/N135S/T706I) residues further increased the thermostability of the enzyme, indicating that the effect of the replacement of the residues was cumulative. The triple-mutant enzyme, F39L/N135S/T706I, retained 50% of its original activity after heat treatment at 65°C for 20 min. Further analysis indicated that enzymes with a F39L or T706I mutation were resistant to possible proteolytic degradation.     

The cytoplasmic region of alpha-1,6-mannosyltransferase Mnn9p is crucial for retrograde transport from the Golgi apparatus to the endoplasmic reticulum in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Och1p and Mnn9p mannosyltransferases are localized in the cis-Golgi. Attempts to live image Och1p and Mnn9p tagged with green fluorescent protein or red fluorescent protein, respectively, using a high-performance confocal laser scanning microscope system resulted in simultaneous visualization of the native proteins in a living cell. Our observations revealed that Och1p and Mnn9p are not always colocalized to the same cisternae. The difference in the dynamics of these mannosyltransferases may reflect differences in the mechanisms for their retention in the cis-Golgi, since it has been reported that Mnn9p cycles between the endoplasmic reticulum and the cis-Golgi whereas Och1p does not (Z. Todorow, A. Spang, E. Carmack, J. Yates, and R. Schekman, Proc. Natl. Acad. Sci. USA 97:13643-13648, 2000). We investigated the localization of chimeric proteins of Mnn9p and Och1p in sec12 and erd1 mutant cells. A chimeric protein, M16/O16, which consists of the N-terminal cytoplasmic region of Mnn9p and the transmembrane and luminal region of Och1p, behaved like Mnn9p, suggesting that the N-terminal cytoplasmic region is important for the intracellular dynamics of Mnn9p. This observation is supported by results from subcellular-fractionation experiments. Mutational analysis revealed that two arginine residues in the N-terminal region of Mnn9p are important for the chimeric protein to cycle between the endoplasmic reticulum and the Golgi apparatus.     

Distribution and roles of X-family DNA polymerases in eukaryotes

Four types of DNA polymerase (Pol beta, Pol lambda, Pol mu and TdT) have been identified in eukaryotes as members of the polymerase X-family. Only vertebrates have all four types of enzyme. Plants and fungi have one or two X-family polymerases, while protostomes, such as fruit flies and nematodes, do not appear to have any. It is possible that the well-known metabolic pathways in which these enzymes are involved are restricted to the vertebrate world. The distribution of the DNA polymerases involved in DNA repair across the various biological kingdoms differs from that of the DNA polymerases involved in chromosomal DNA replication. In this review, we focus on the interesting pattern of distribution of the X-family enzymes across biological kingdoms and speculate on their roles.     

CYP704B1 Is a Long-Chain Fatty Acid ω-Hydroxylase Essential for Sporopollenin Synthesis in Pollen of Arabidopsis

Sporopollenin is the major component of the outer pollen wall (exine). Fatty acid derivatives and phenolics are thought to be its monomeric building blocks, but the precise structure, biosynthetic route, and genetics of sporopollenin are poorly understood. Based on a phenotypic mutant screen in Arabidopsis (Arabidopsis thaliana), we identified a cytochrome P450, designated CYP704B1, as being essential for exine development. CYP704B1 is expressed in the developing anthers. Mutations in CYP704B1 result in impaired pollen walls that lack a normal exine layer and exhibit a characteristic striped surface, termed zebra phenotype. Heterologous expression of CYP704B1 in yeast cells demonstrated that it catalyzes ω-hydroxylation of long-chain fatty acids, implicating these molecules in sporopollenin synthesis. Recently, an anther-specific cytochrome P450, denoted CYP703A2, that catalyzes in-chain hydroxylation of lauric acid was also shown to be involved in sporopollenin synthesis. This shows that different classes of hydroxylated fatty acids serve as essential compounds for sporopollenin formation. The genetic relationships between CYP704B1, CYP703A2, and another exine gene, MALE STERILITY2, which encodes a fatty acyl reductase, were explored. Mutations in all three genes resulted in pollen with remarkably similar zebra phenotypes, distinct from those of other known exine mutants. The double and triple mutant combinations did not result in the appearance of novel phenotypes or enhancement of single mutant phenotypes. This implies that each of the three genes is required to provide an indispensable subset of fatty acid-derived components within the sporopollenin biosynthesis framework.The biopolymer sporopollenin is the major component of the outer walls in pollen and spores (exines). It is highly resistant to nonoxidative physical, chemical, and biological treatments and is insoluble in both aqueous and organic solvents. While the stability and resistance of sporopollenin account for the preservation of ancient pollen grains for millions of years with nearly full retention of morphology (Doyle and Hickey, 1976; Friis et al., 2001), these same qualities make it extremely difficult to study the chemical structure of sporopollenin. Thus, although the first studies on the composition of sporopollenin were reported in 1928 (Zetzsche and Huggler, 1928), the exact structure of sporopollenin remains unresolved. At present, it is thought that sporopollenin is a complex polymer primarily made of a mixture of fatty acids and phenolic compounds (Guilford et al., 1988; Wiermann et al., 2001).Fatty acids were first implicated as sporopollenin components when ozonolysis of Lycopodium clavatum and Pinus sylvestris exine yielded significant amounts of straight- and branched-chain monocarboxylic acids, characteristic fatty acid breakdown products (Shaw and Yeadon, 1966). More recently, improved purification and degradation techniques coupled with analytical methods, such as solid-state ¹³C-NMR spectroscopy, Fourier transform infrared spectroscopy, and ¹H-NMR, have shown that sporopollenin is made up of polyhydroxylated unbranched aliphatic units and also contains small amounts of oxygenated aromatic rings and phenylpropanoids (Guilford et al., 1988; Ahlers et al., 1999; Domínguez et al., 1999; Bubert et al., 2002). Biochemical studies using thiocarbamate herbicide inhibition of the chain-elongating steps in the synthesis of long-chain fatty acids and radioactive tracer experiments provided further evidence that lipid metabolism is involved in the biosynthesis of sporopollenin (Wilwesmeier and Wiermann, 1995; Meuter-Gerhards et al., 1999).Relatively little is known about the genetic network that determines sporopollenin synthesis. However, several Arabidopsis (Arabidopsis thaliana) genes implicated in exine biosynthesis encode proteins with sequence homology to enzymes that are involved in fatty acid metabolism. Mutations in MALE STERILITY2 (MS2) eliminate exine and affect a protein with sequence similarity to fatty acyl reductases; the predicted inability of ms2 plants to reduce pollen wall fatty acids to the corresponding alcohols suggests that this reaction is a key step in sporopollenin synthesis (Aarts et al., 1997). The FACELESS POLLEN1 (FLP1) gene, whose loss causes the flp1 exine defect, encodes a protein similar to those involved in wax synthesis (Ariizumi et al., 2003). The no exine formation1 (nef1) mutant accumulates reduced levels of lipids, and the NEF1 protein was suggested to be involved in either lipid transport or the maintenance of plastid membrane integrity, including those plastids in the secretory tapetum of anthers, where many of the sporopollenin components are synthesized (Ariizumi et al., 2004). The dex2 mutant has mutations in the evolutionarily conserved anther-specific cytochrome P450, CYP703A2 (Morant et al., 2007), which catalyzes in-chain hydroxylation of saturated medium-chain fatty acids, with lauric acid (C12:0) as a preferred substrate (Morant et al., 2007). A recently described gene, ACOS5, encodes a fatty acyl-CoA synthetase that has in vitro preference for medium-chain fatty acids (de Azevedo Souza et al., 2009). Mutations in all of these genes compromise exine formation.Here, we describe an evolutionarily conserved cytochrome P450, CYP704B1, and demonstrate that this gene is essential for exine biosynthesis and plays a role different from that of CYP703A2. Heterologously expressed CYP704B1 catalyzed ω-hydroxylation of several saturated and unsaturated C14-C18 fatty acids. These results suggest the possibility that ω-hydroxylated fatty acids produced by CYP704B1, together with in-chain hydroxylated lauric acids provided by the action of CYP703A2, may serve as key monomeric aliphatic building blocks in sporopollenin formation. Analyses of the genetic relationships between CYP704B1, MS2, and CYP703A2 suggest that all three genes are involved in the same pathway within the sporopollenin biosynthesis framework.