The Archaeal Proteasome Is Regulated by a Network of AAA ATPases

The proteasome is the central machinery for targeted protein degradation in archaea, Actinobacteria, and eukaryotes. In its basic form, it consists of a regulatory ATPase complex and a proteolytic core particle. The interaction between the two is governed by an HbYX motif (where Hb is a hydrophobic residue, Y is tyrosine, and X is any amino acid) at the C terminus of the ATPase subunits, which stimulates gate opening of the proteasomal α-subunits. In archaea, the proteasome-interacting motif is not only found in canonical proteasome-activating nucleotidases of the PAN/ARC/Rpt group, which are absent in major archaeal lineages, but also in proteins of the CDC48/p97/VAT and AMA groups, suggesting a regulatory network of proteasomal ATPases. Indeed, Thermoplasma acidophilum, which lacks PAN, encodes one CDC48 protein that interacts with the 20S proteasome and activates the degradation of model substrates. In contrast, Methanosarcina mazei contains seven AAA proteins, five of which, both PAN proteins, two out of three CDC48 proteins, and the AMA protein, function as proteasomal gatekeepers. The prevalent presence of multiple, distinct proteasomal ATPases in archaea thus results in a network of regulatory ATPases that may widen the substrate spectrum of proteasomal protein degradation.     

FISSION1A,an Arabidopsis Tail-Anchored Protein,Is Localized to Three Subcellular Compartments

Dear Editor, The multiple targeting proteins that have been described in yeast, mammals, and plants have generated intriguing areas of inquiry, including the evolutionary relevance of common proteins shared by different organelles, the mechanisms that determine targeting to each organelle, and, finally, the extent of this phenomenon. Several dual-targeted proteins have been identified in eukaryotic cells.     

BLD10/CEP135 Is a Microtubule-Associated Protein that Controls the Formation of the Flagellum Central Microtubule Pair

Cilia and flagella are involved in a variety of processes and human diseases, including ciliopathies and sterility. Their motility is often controlled by?a central microtubule (MT) pair localized within the ciliary MT-based skeleton, the axoneme. We characterized the formation of the motility apparatus in detail in Drosophila spermatogenesis. We show that assembly of the central MT pair starts prior to the meiotic divisions, with nucleation of a singlet MT within the basal body of a small cilium, and that the second MT of the pair only assembles much later, upon flagella formation. BLD10/CEP135, a conserved player in centriole and flagella biogenesis, can bind and stabilize MTs and is required for the early steps of central MT pair formation. This work describes a genetically tractable system to study motile cilia formation and provides an explanation for BLD10/CEP135's role in assembling highly stable MT-based structures, such as motile axonemes and centrioles.     

Cell Separation in Vibrio cholerae Is Mediated by a Single Amidase Whose Action Is Modulated by Two Nonredundant Activators

Synthesis and hydrolysis of septal peptidoglycan (PG) are critical processes at the conclusion of cell division that enable separation of daughter cells. Cleavage of septal PG is mediated by PG amidases, hydrolytic enzymes that release peptide side chains from the glycan strand. Most gammaproteobacteria, including Escherichia coli, encode several functionally redundant periplasmic amidases. However, members of the Vibrio genus, including the enteric pathogen Vibrio cholerae, encode only a single PG amidase, AmiB. Here, we show that V. cholerae AmiB is crucial for cell division and growth. Genetic and biochemical analyses indicated that AmiB is regulated by two activators, EnvC and NlpD, at least one of which is required for AmiB''s localization to the cell division site. Localization of the activators (and thus of AmiB) is dependent upon the cell division protein FtsN. These factors mediate septal PG cleavage in E. coli as well; however, their precise roles vary between the two organisms in a number of ways. Notably, even though V. cholerae EnvC and NlpD appear to be functionally redundant under most growth conditions tested, NlpD is specifically required for intestinal colonization in the infant mouse model of cholera and for V. cholerae resistance against bile salts, perhaps due to environmental regulation of AmiB or its activators. Collectively, our findings reveal that although the cellular components that enable cleavage of septal PG appear to be generally conserved between E. coli and V. cholerae, they can be combined into diverse functional regulatory networks.     

Uso1 Protein Is a Dimer with Two Globular Heads and a Long Coiled-Coil Tail

USO1is one of the essential genes inSaccharomyces cerevisiaewhose gene products participate in protein transport from the endoplasmic reticulum to the Golgi apparatus. This product was purified to homogeneity. Electron microscopic study revealed that it has a single or double globular domain with a long tail and that the molecule is a dimer. A peak position of the distribution of rod length was 154.5 nm, in agreement with the secondary structure prediction that it has a long α-helix at the carboxyl terminus. Probability of coiled-coil formation was also predicted from the primary structure of the product, which asserts that it has a long α-helical coiled-coil at the carboxyl-terminal region with some interruptions. Certainly, the electron microscopic image of this molecule had some hinges within the rod region. The distance was measured between the globular domain and the hinges. Two peaks of the distribution of the hinge position exist at 23.1 and 85.5 nm from the globular domain. This is consistent with the predicted positions of interruption. These results give new experimental evidence that Uso1 protein is a dimer and has an α-helical coiled-coil tail with two globular heads.     

Occurrence of Three Felids across a Network of Protected Areas in Thailand: Prey,Intraguild, and Habitat Associations

Clouded Leopard, Leopard, and Tiger are threatened felids in Southeast Asia, but little is known about the factors influencing their distributions. Using logistic regression, we assessed how habitat variables, prey detection patterns, and presence of intraguild predators affect the occurrence of these felids across 13 protected areas within Thailand. Our analysis is based on data from 1108 camera‐trap locations (47,613 trap‐nights). Clouded Leopard and Leopard are associated with habitat where Red Muntjac and Eurasian Wild Pig were most likely to be present. Tiger are associated with habitat with a higher likelihood for the presence of Gaur, Eurasian Wild Pig, and Sambar. Clouded Leopard and Tiger were both weakly associated with areas with mature evergreen forest. Besides availability of prey, associations with potential competitors also appear to influence the distribution of these felids, although the strength of these effects requires further investigation. Occurrence rates for Clouded Leopard were no different in protected areas with Leopard versus without Leopards. Leopard had similar occurrence rates regardless of the presence of Tiger, but Leopards were less likely to be detected at the same camera‐trap points with the larger felid. Our results suggest that the two most commonly photographed prey species in the study areas serve as key prey species, Eurasian Wild Pig for all three carnivores and Red Muntjac for Leopard and Clouded Leopard.     

Pair correlation function for a dusty plasma

Analytic expressions for pair electron-grain and ion-grain radial distribution functions are derived under the assumption of a short-range binary interaction between mobile particles and an immobile charged grain, which is treated as a point particle.     

Mitofilin Is a Transmembrane Protein of the Inner Mitochondrial Membrane Expressed as Two Isoforms

Mitofilin, also known as heart muscle protein, is a recently identified mitochondrial protein. We have isolated two human cDNAs that encode different isoforms of mitofilin. Using reverse PCR, we provide evidence that both isoforms are derived by alternative splicing and encode two proteins of 88 and 90 kDa that are detected in immunoblot analyses with mitofilin-specific antibodies. Immunofluorescence microscopy, fractionating of human osteosarcoma cells, and protease protection experiments with isolated mitochondria and mitoplasts indicate that mitofilin is an integral membrane protein of the inner mitochondrial membrane.³⁵S-labeled mitofilin is transported into isolated yeast mitochondria in a reaction that depends on the membrane potential across the inner mitochondrial membrane (ΔΨ). During mitochondrialin vitroimport, mitofilin is proteolytically processed to the mature protein that is also detected in cellular fractions, indicating that the amino-terminal leader sequence is removed. Sequence analysis and our results suggest that mitofilin is anchored in the inner mitochondrial membrane with an amino-terminal transmembrane domain, while the majority of the protein is extruding into the intermembrane space.     

Shortest-Path Network Analysis Is a Useful Approach toward Identifying Genetic Determinants of Longevity

Background

Identification of genes that modulate longevity is a major focus of aging-related research and an area of intense public interest. In addition to facilitating an improved understanding of the basic mechanisms of aging, such genes represent potential targets for therapeutic intervention in multiple age-associated diseases, including cancer, heart disease, diabetes, and neurodegenerative disorders. To date, however, targeted efforts at identifying longevity-associated genes have been limited by a lack of predictive power, and useful algorithms for candidate gene-identification have also been lacking.

Methodology/Principal Findings

We have utilized a shortest-path network analysis to identify novel genes that modulate longevity in Saccharomyces cerevisiae. Based on a set of previously reported genes associated with increased life span, we applied a shortest-path network algorithm to a pre-existing protein–protein interaction dataset in order to construct a shortest-path longevity network. To validate this network, the replicative aging potential of 88 single-gene deletion strains corresponding to predicted components of the shortest-path longevity network was determined. Here we report that the single-gene deletion strains identified by our shortest-path longevity analysis are significantly enriched for mutations conferring either increased or decreased replicative life span, relative to a randomly selected set of 564 single-gene deletion strains or to the current data set available for the entire haploid deletion collection. Further, we report the identification of previously unknown longevity genes, several of which function in a conserved longevity pathway believed to mediate life span extension in response to dietary restriction.

Conclusions/Significance

This work demonstrates that shortest-path network analysis is a useful approach toward identifying genetic determinants of longevity and represents the first application of network analysis of aging to be extensively validated in a biological system. The novel longevity genes identified in this study are likely to yield further insight into the molecular mechanisms of aging and age-associated disease.     

ErbB Tyrosine Kinases and the Two Neuregulin Families Constitute a Ligand-Receptor Network

The recently isolated second family of neuregulins, NRG2, shares its primary receptors, ErbB-3 and ErbB-4, and induction of mammary cell differentiation with NRG1 isoforms, suggesting functional redundancy of the two growth factor families. To address this possibility, we analyzed receptor specificity of NRGs by using an engineered cellular system. The activity of isoform-specific but partly overlapping patterns of specificities that collectively activate all eight ligand-stimulatable ErbB dimers was revealed. Specifically, NRG2-β, like NRG1-α, emerges as a narrow-specificity ligand, whereas NRG2-α is a pan-ErbB ligand that binds with different affinities to all receptor combinations, including those containing ErbB-1, but excluding homodimers of ErbB-2. The latter protein, however, displayed cooperativity with the direct NRG receptors. Apparently, signaling by all NRGs is funneled through the mitogen-activated protein kinase (MAPK). However, the duration and potency of MAPK activation depend on the identity of the stimulatory ligand-receptor ternary complex. We conclude that the NRG-ErbB network represents a complex and nonredundant machinery developed for fine-tuning of signal transduction.     

Vicariance in a Cryptic Species Pair of European Pseudoscorpions (Arachnida, Pseudoscorpiones, Chthoniidae)

Following the first records of Chthonius (Ephippiochthonius) boldorii Beier, 1934 in central Europe, a species which was previously assumed to occur exclusively in Mediterranean caves, 116 series (595 specimens) of the cryptic taxa C. (E.) boldorii and C. (E.) fuscimanus Simon, 1900 (Syn. C. (E.) austriacus Beier, 1931) were re-examined. Although multivariate analyses suggest specific separation, there is only one unequivocal character for discrimination: the presence or absence of a single isolated tooth on the moveable finger of the chelicerae. The distributions were found to be largely allopatric, therefore it is concluded that the species rank of the two morphospecies is justified. North of the Alps, an almost vicariant pattern emerged: east of 14° E fuscimanus occurs, west of this line boldorii occurs. The results provide a basis for discussing the relevance of minute morphological differences in pseudoscorpion taxonomy.     

Poly(ADP-Ribose) Polymerase Is a Substrate Recognized by Two Metacaspases of Podospora anserina

The two metacaspases MCA1 and MCA2 of the fungal aging model organism Podospora anserina (PaMCA1 and PaMCA2, respectively) have previously been demonstrated to be involved in the control of programmed cell death (PCD) and life span. In order to identify specific pathways and components which are controlled by the activity of these enzymes, we set out to characterize them further. Heterologous overexpression in Escherichia coli of the two metacaspase genes resulted in the production of proteins which aggregate and form inclusion bodies from which the active protein has been recovered via refolding in appropriate buffers. The renaturated proteins are characterized by an arginine-specific activity and are active in caspase-like self-maturation leading to the generation of characteristic small protein fragments. Both activities are dependent on the presence of calcium. Incubation of the two metacaspases with recombinant poly(ADP-ribose) polymerase (PARP), a known substrate of mammalian caspases, led to the identification of PARP as a substrate of the two P. anserina proteases. Using double mutants in which P. anserina Parp (PaParp) is overexpressed and PaMca1 is either overexpressed or deleted, we provide evidence for in vivo degradation of PaPARP by PaMCA1. These results support the idea that the substrate profiles of caspases and metacaspases are at least partially overlapping. Moreover, they link PCD and DNA maintenance in the complex network of molecular pathways involved in aging and life span control.     

The Gene Encoding the Heat-Stable Enterotoxin of Vibrio cholerae Is Flanked by 123-Base Pair Direct Repeats

The heat-stable enterotoxin (O1-ST) gene (sto) was cloned from chromosome of the strain GP156 of Vibrio cholerae O1 (Inaba, El Tor) in Escherichia coli K-12, and its nucleotide seqence was determined. The nucleotide sequence of sto was very similar to that of NAG-ST gene (stn) of V. cholerae non-O1. Both sto and stn were flanked by 123-base pair direct repeats which had at least 93% homology to one another and included some inverted repeats. All the strains of V. cholerae, V. mimicus, V. metschnikovii, V. hollisae and Yersinia enterocolitica examined by colony hybridization had the direct repeat sequence regardless of ST-gene possession.     

Cloning and Targeted Disruption of MLG1, a Gene Encoding Two of Three Extracellular Mixed-Linked Glucanases of Cochliobolus carbonum

Mixed-linked glucanases (MLGases), which are extracellular enzymes able to hydrolyze β1,3-1,4-glucans (also known as mixed-linked glucans or cereal β-glucans), were identified in culture filtrates of the plant-pathogenic fungus Cochliobolus carbonum. Three peaks of MLGase activity, designated Mlg1a, Mlg1b, and Mlg2, were resolved by cation-exchange and hydrophobic-interaction high-performance liquid chromatography (HPLC). Mlg1a and Mlg1b also hydrolyze β1,3-glucan (laminarin), whereas Mlg2 does not degrade β1,3-glucan but does degrade β1,4-glucan to a slight extent. Mlg1a, Mlg1b, and Mlg2 have monomer molecular masses of 33.5, 31, and 29.5 kDa, respectively. The N-terminal amino acid sequences of Mlg1a and Mlg1b are identical (AAYNLI). Mlg1a is glycosylated, whereas Mlg1b is not. The gene encoding Mlg1b, MLG1, was isolated by using PCR primers based on amino acid sequences of Mlg1b. The product of MLG1 has no close similarity to any known protein but does contain a motif (EIDI) that occurs at the active site of MLGases from several prokaryotes. An internal fragment of MLG1 was used to create mlg1 mutants by transformation-mediated gene disruption. The total MLGase and β1,3-glucanase activities in culture filtrates of the mutants were reduced by approximately 50 and 40%, respectively. When analyzed by cation-exchange HPLC, the mutants were missing the two peaks of MLGase activity corresponding to Mlg1a and Mlg1b. Together, the data indicate that Mlg1a and Mlg1b are products of the same gene, MLG1. The growth of mlg1 mutants in culture medium supplemented with macerated maize cell walls or maize bran and the disease symptoms on maize were identical to the growth and disease symptoms of the wild type.