Identification and Characterization of a Novel Intracellular Poly(3-Hydroxybutyrate) Depolymerase from Bacillus megaterium

A gene that codes for a novel intracellular poly(3-hydroxybutyrate) (PHB) depolymerase, designated PhaZ1, has been identified in the genome of Bacillus megaterium. A native PHB (nPHB) granule-binding assay showed that purified soluble PhaZ1 had strong affinity for nPHB granules. Turbidimetric analyses revealed that PhaZ1 could rapidly degrade nPHB granules in vitro without the need for protease pretreatment of the granules to remove surface proteins. Notably, almost all the final hydrolytic products produced from the in vitro degradation of nPHB granules by PhaZ1 were 3-hydroxybutyric acid (3HB) monomers. Unexpectedly, PhaZ1 could also hydrolyze denatured semicrystalline PHB, with the generation of 3HB monomers. The disruption of the phaZ1 gene significantly affected intracellular PHB mobilization during the PHB-degrading stage in B. megaterium, as demonstrated by transmission electron microscopy and the measurement of the PHB content. These results indicate that PhaZ1 is functional in intracellular PHB mobilization in vivo. Some of these features, which are in striking contrast with those of other known nPHB granule-degrading PhaZs, may provide an advantage for B. megaterium PhaZ1 in fermentative production of the biotechnologically valuable chiral compound (R)-3HB.Polyhydroxyalkanoates (PHAs) are a group of polyesters that are produced by numerous bacteria as carbon and energy storage materials in response to nutritional stress (13, 27, 29). Poly(3-hydroxybutyrate) (PHB) is the most common and intensively studied PHA. Intracellular native PHB (nPHB) granules are composed of a hydrophobic PHB core and a surface layer consisting of proteins and phospholipids (13). The PHB of intracellular nPHB granules is in an amorphous state. When intracellular nPHB granules are exposed to extracellular environments due to cell death and lysis, the amorphous PHB is transformed into a denatured semicrystalline state. nPHB granules subjected to physical damage or solvent extraction to remove the surface layer can also crystallize into denatured PHB (dPHB) (13, 15). Artificial PHB (aPHB) granules, in which PHB is in an amorphous state, can be prepared from semicrystalline dPHB and detergents (1, 11, 23, 31).Various extracellular PHB depolymerases (PhaZs) that are secreted by many PHB-degrading bacteria have been demonstrated to specifically degrade dPHB (13, 14, 37). One exception is that PhaZ7, an extracellular PHB depolymerase secreted by Paucimonas lemoignei, displays unusual substrate specificity for amorphous PHB, with 3-hydroxybutyrate (3HB) oligomers as the main products of enzymatic hydrolysis (7). PhaZ7 exhibits no enzymatic activity toward dPHB. So far, a growing number of intracellular PHB depolymerases have been characterized. The intracellular PHB depolymerase PhaZa1 of Ralstonia eutropha (also called Cupriavidus necator) H16 has recently been established to be especially important for the intracellular mobilization of accumulated PHB (42). The main in vitro hydrolytic products of PhaZa1 degradation of amorphous aPHB are 3HB oligomers (31). PhaZd1, another intracellular PHB depolymerase of R. eutropha H16, shows no significant amino acid similarity to PhaZa1. The in vitro hydrolytic products of PhaZd1 degradation of amorphous aPHB are also 3HB oligomers. A 3HB monomer is rarely detected as a hydrolytic product (1). The intracellular PHB depolymerase PhaZ of Paracoccus denitrificans was reported previously to degrade protease-treated nPHB granules in vitro, with the release of 3HB dimers and oligomers as the main hydrolytic products (6). Recently, we have identified a novel intracellular PHB depolymerase from Bacillus thuringiensis serovar “israelensis” (39). The B. thuringiensis PhaZ shows no significant amino acid similarity to any known PHB depolymerase. This PhaZ has strong amorphous PHB-hydrolyzing activity and can release a considerable amount of 3HB monomers by the hydrolysis of trypsin-treated nPHB granules (39). It is of note that purified PhaZd1 from R. eutropha, PhaZ from P. denitrificans, and PhaZ from B. thuringiensis need pretreatment of nPHB granules with protease to remove surface proteins for PHB degradation (1, 6, 39). They show only very little or no activity toward nPHB granules without trypsin pretreatment. It has been demonstrated previously that these intracellular PHB depolymerases cannot hydrolyze dPHB (1, 31, 39).(R)-3HB, a biotechnologically valuable chiral compound, has been widely used for syntheses of antibiotics, vitamins, and pheromones (3, 30, 38). One way to produce (R)-3HB is heterologous coexpression of a PHB synthetic operon and a gene encoding an amorphous PHB-degrading PhaZ in Escherichia coli (3, 18, 25, 33, 38). A common problem encountered by this method is that oligomeric and dimeric forms of 3HB often constitute a major portion of the products of enzymatic hydrolysis, thus requiring further hydrolysis by 3HB oligomer hydrolase or heating under alkaline conditions to generate 3HB monomers (3, 18, 25, 33).Bacillus megaterium genes involved in the biosynthesis of nPHB granules have been cloned from strain ATCC 11561 and characterized previously (19, 21, 22). A gene encoding the extracellular PHB depolymerase PhaZ from B. megaterium was recently cloned from strain N-18-25-9 (34). However, little is known about B. megaterium genes involved in the intracellular mobilization of PHB. In this study, we have identified in B. megaterium ATCC 11561 an intracellular PHB depolymerase that could rapidly degrade nPHB granules in vitro without the need for trypsin pretreatment of the nPHB granules. Moreover, almost all the in vitro hydrolytic products released from the degradation of amorphous PHB by this PhaZ were 3HB monomers. This PhaZ could also hydrolyze dPHB with the generation of 3HB monomers. Thus, it appears to be a novel intracellular PHB depolymerase and may have promising potential for biotechnological application in the production of enantiomerically pure (R)-3HB monomers.     

Production of Chiral (R)-3-Hydroxyoctanoic Acid Monomers,Catalyzed by Pseudomonas fluorescens GK13 Poly(3-Hydroxyoctanoic Acid) Depolymerase

The extracellular medium-chain-length polyhydroxyalkanoate (MCL-PHA) depolymerase of Pseudomonas fluorescens GK13 catalyzes the hydrolysis of poly(3-hydroxyoctanoic acid) [P(3HO)]. Based on the strong tendency of the enzyme to interact with hydrophobic materials, a low-cost method which allows the rapid and easy purification and immobilization of the enzyme has been developed. Thus, the extracellular P(3HO) depolymerase present in the culture broth of cells of P. fluorescens GK13 grown on mineral medium supplemented with P(3HO) as the sole carbon and energy source has been tightly adsorbed onto a commercially available polypropylene support (Accurel MP-1000) with high yield and specificity. The activity of the pure enzyme was enhanced by the presence of detergents and organic solvents, and it was retained after treatment with an SDS-denaturing cocktail under both reducing and nonreducing conditions. The time course of the P(3HO) hydrolysis catalyzed by the soluble and immobilized enzyme has been assessed, and the resulting products have been identified. After 24 h of hydrolysis, the dimeric ester of 3-HO [(R)-3-HO-HO] was obtained as the main product of the soluble enzyme. However, the immobilized enzyme catalyzes almost the complete hydrolysis of P(3HO) polymer to (R)-3-HO monomers under the same conditions.Polyhydroxyalkanoates (PHAs) are environmentally friendly polyesters that are biosynthesized by numerous microorganisms during unbalanced growth (3, 32). PHAs show material properties similar to those of conventional plastics, having important advantages such as biodegradability, apparent biocompatibility, and the ability to be manufactured from renewable resources (6, 38, 39). According to the number of carbon atoms of the side chain of the monomers, PHAs are classified as short-chain-length (SCL) PHAs (3 to 5 carbon atoms) and medium-chain-length (MCL) PHAs (6 to 14 carbon atoms) (16, 17, 32).The ability to degrade extracellular PHA in the environment and to use its degradation products as a source of carbon and energy depends on the release of specific extracellular PHA depolymerases (14, 15, 20). Depending on the depolymerase, as a result of enzymatic PHA degradation, the end products are only monomers, both monomers and dimers, or a mixture of oligomers (16). Enantiomer pure (R)-3-hydroxyalkanoic acid [(R)-3-HA] monomers are very attractive building blocks of interest not only in the biomedical and pharmaceutical fields (9, 10) but also for being used as starting materials to obtain other new polyesters (8). Thus, the development of a cost-effective industrial process for the production of both MCL-PHA depolymerase enzyme and (R)-3-HA monomers is of considerable interest.At present, few extracellular MCL-PHA depolymerases have been purified and characterized (11, 21-24, 33). Traditionally, the purification of microbial depolymerases is achieved by a conventional multistep chromatographic methodology, which includes hydrophobic interaction and size exclusion chromatographies (7, 21, 24, 37). The poly(3-hydroxyoctanoic acid) [P(3HO)] depolymerase from Pseudomonas fluorescens GK13 was the first enzyme purified (37) and characterized at the molecular level (36).Adsorption of lipases on polypropylene supports has been extensively used for large-scale lipase immobilization (18, 25, 28, 29) since it is a simple and economical method. Moreover, the immobilization of enzyme allows its reusability and increases its operational stability and ease of product recovery (1). Accurel MP-1000 is a commercially available hydrophobic, microporous, low-density polypropylene powder that presents a large surface area for adsorption because of its very small particle size (4). This support has been successfully used for adsorption of lipases and esterases with high yield directly from the fermentation broth (2, 13).As lipases, MCL-PHA depolymerases are hydrophobic proteins with a tendency to adsorb to hydrophobic supports. In this study we report a novel method for the purification of the P(3HO) depolymerase from P. fluorescens GK13 by adsorption to a polypropylene support as well as some relevant properties of the enzyme. Moreover, this protocol allows the immobilization of the enzyme directly from the culture broth. The immobilized enzyme degrades completely the P(3HO) polymer and releases 3-hydroxyoctanoic acid [(R)-3-HO]. This is the first report describing the immobilization of an extracellular MCL-PHA depolymerase and its potential use in the production of (R)-3-HO chiral monomers.     

Identification of the Polyhydroxyalkanoate (PHA)-Specific Acetoacetyl Coenzyme A Reductase among Multiple FabG Paralogs in Haloarcula hispanica and Reconstruction of the PHA Biosynthetic Pathway in Haloferax volcanii

Genome-wide analysis has revealed abundant FabG (β-ketoacyl-ACP reductase) paralogs, with uncharacterized biological functions, in several halophilic archaea. In this study, we identified for the first time that the fabG1 gene, but not the other five fabG paralogs, encodes the polyhydroxyalkanoate (PHA)-specific acetoacetyl coenzyme A (acetoacetyl-CoA) reductase in Haloarcula hispanica. Although all of the paralogous fabG genes were actively transcribed, only disruption or knockout of fabG1 abolished PHA synthesis, and complementation of the ΔfabG1 mutant with the fabG1 gene restored both PHA synthesis capability and the NADPH-dependent acetoacetyl-CoA reductase activity. In addition, heterologous coexpression of the PHA synthase genes (phaEC) together with fabG1, but not its five paralogs, reconstructed the PHA biosynthetic pathway in Haloferax volcanii, a PHA-defective haloarchaeon. Taken together, our results indicate that FabG1 in H. hispanica, and possibly its counterpart in Haloarcula marismortui, has evolved the distinct function of supplying precursors for PHA biosynthesis, like PhaB in bacteria. Hence, we suggest the renaming of FabG1 in both genomes as PhaB, the PHA-specific acetoacetyl-CoA reductase of halophilic archaea.Several haloarchaeal species belonging to the genera Haloferax, Haloarcula, Natrialba, and Haloquadratum are capable of synthesizing short-chain-length polyhydroxyalkanoates (SCL-PHAs) (6, 8, 14, 16), a large family of biopolymers with desirable biodegradability, biocompatibility, and thermoplastic features (31). Although the metabolic pathways of PHAs in bacteria have been characterized in detail (10, 15, 20, 25, 26, 37), the genes involved in PHA biosynthesis in haloarchaea were not recognized until recently, when the PHA synthase genes were identified and characterized for Haloarcula marismortui, Haloarcula hispanica, and Haloferax mediterranei (6, 19). These archaeal PHA synthases are all composed of two subunits, PhaE and PhaC. They are homologous to the class III PHA synthases from bacteria but have a longer C-terminal extension in the PhaC subunit. Nevertheless, the pathway of supplying the PHA precursors has not yet been clarified for any haloarchaeal strain.Both H. mediterranei and H. hispanica are able to synthesize poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) from unrelated carbon sources, despite the content of the (R)-3-hydroxyvalerate (3-HV) monomer of PHBV in H. mediterranei (10 to 13 mol%) (4, 19) being much higher than that in H. hispanica (∼3 mol%) (19). Conversely, the bacteria Ralstonia eutropha and Synechocystis sp. strain PCC6803, which possess class I and III PHA synthases, respectively, accumulate just poly(3-hydroxybutyrate) (PHB) when the 3-HV-related carbon sources (i.e., propionate and valerate) are not supplied (30). In these two bacteria, the biosynthesis of the (R)-3-hydroxybutyrate coenzyme A [(R)-3-HB-CoA] precursor is conducted by two steps. First, two acetyl-CoA molecules are condensed into one acetoacetyl-CoA molecule by the enzyme β-ketothiolase (PhaA). The acetoacetyl-CoA is then reduced to (R)-3-HB-CoA by a PHA-specific acetoacetyl-CoA reductase (PhaB). The resulting (R)-3-HB-CoA is subsequently incorporated into PHB, catalyzed by PHA synthases (26, 36).Both PhaB and FabG belong to the short-chain dehydrogenase/reductase (SDR) superfamily, whose members are homologous in sequence and have several conserved motifs (27, 29). Interestingly, although FabGs naturally reduce 3-ketoacyl-ACP to form (R)-3-hydroxyacyl-ACP in fatty acid biosynthesis, a few FabGs also recognize 3-ketoacyl-CoA and hence function in PHA biosynthesis. For example, the FabG proteins of Escherichia coli and Pseudomonas aeruginosa have been demonstrated to supply precursors for PHA biosynthesis in recombinant E. coli cells (21, 22, 32, 35). In addition, several FabG paralogs may have evolved a distinct function, to be responsible only for PHA accumulation. This situation was observed in Synechocystis sp. strain PCC6803, where the originally annotated FabG (12) was renamed PhaB after an understanding of its function in PHA biosynthesis (36).Genome-wide analysis of H. marismortui ATCC 43049 (1) revealed eight FabG paralogs in this haloarchaeon. Similarly, multiple fabG paralog genes (fabG1 to fabG6) were also observed in the newly sequenced genome of H. hispanica (our unpublished data). In this study, we demonstrate that fabG1, but not the other five fabG paralogs, encodes the PHA-specific acetoacetyl-CoA reductase in H. hispanica. It is responsible for providing (R)-3-HB-CoA for PHA biosynthesis in Haloarcula species, and interestingly, this enzyme also functions well in Haloferax volcanii, endowing this PHA-defective strain with the ability to accumulate PHA when cotransformed with PHA synthase genes.     

Regulation of IRSp53-Dependent Filopodial Dynamics by Antagonism between 14-3-3 Binding and SH3-Mediated Localization

Filopodia are dynamic structures found at the leading edges of most migrating cells. IRSp53 plays a role in filopodium dynamics by coupling actin elongation with membrane protrusion. IRSp53 is a Cdc42 effector protein that contains an N-terminal inverse-BAR (Bin-amphipysin-Rvs) domain (IRSp53/MIM homology domain [IMD]) and an internal SH3 domain that associates with actin regulatory proteins, including Eps8. We demonstrate that the SH3 domain functions to localize IRSp53 to lamellipodia and that IRSp53 mutated in its SH3 domain fails to induce filopodia. Through SH3 domain-swapping experiments, we show that the related IRTKS SH3 domain is not functional in lamellipodial localization. IRSp53 binds to 14-3-3 after phosphorylation in a region that lies between the CRIB and SH3 domains. This association inhibits binding of the IRSp53 SH3 domain to proteins such as WAVE2 and Eps8 and also prevents Cdc42-GTP interaction. The antagonism is achieved by phosphorylation of two related 14-3-3 binding sites at T340 and T360. In the absence of phosphorylation at these sites, filopodium lifetimes in cells expressing exogenous IRSp53 are extended. Our work does not conform to current views that the inverse-BAR domain or Cdc42 controls IRSp53 localization but provides an alternative model of how IRSp53 is recruited (and released) to carry out its functions at lamellipodia and filopodia.The ability of a cell to rapidly respond to extracellular cues and direct cytoskeletal rearrangements is dependent on an array of signaling complexes that control actin assembly (58). The protrusive structures at the leading edges of motile cells are broadly defined as lamellipodia or filopodia (14). Lamellae are sheet-like protrusions composed of dendritic actin arrays that drive membrane expansion, with the “lamellipodium” representing a narrow region at the edge of the cell (in culture) characterized by rapid actin polymerization. This F-actin assembly is suggested to require Arp2/3 activity that nucleates new actin filaments from the sides of existing ones (58, 71) and capping proteins that limit the length of these new filaments and stabilize them (7). Arp2/3 activity in turn is regulated by the WASP/WAVE family of proteins, such as N-WASP and WAVE2 (68), whose regulation is a subject of intense interest (12, 29, 36, 41, 56, 76).Filopodia contain parallel bundles of actin filaments containing fascin (22). These are dynamic structures that emanate from the periphery of the cell and are retracted, with occasional attachment (to the dish in culture). Thus, they have been thought to have a sensory or exploratory role during cell migration (28). This is the case for neuronal growth cones, where filopodia sense attractant or repulsive cues and dictate direction in axonal path finding (9, 17, 25, 35). Filopodia have been shown to be important in the context of dendritic-spine development (64, 77), epithelial-sheet closure (26, 60, 79), and cell invasion/metastasis (80, 83).Lamellipodia have been well characterized since the pioneering work of Abercrombie et al. in the early 1970s (2, 3, 4). Filopodia require symmetry breaking at the leading edge (initiation), followed by elongation driven by a filopodial-tip protein complex (14, 28). A few proteins have been identified in this complex; Mena/Vasp serve to prevent capping at the barbed ends of bundled actin filaments (7, 53), and Dia2 promotes F-actin elongation (57, 85). Termination of filopodial elongation is not understood but nonetheless is likely to be tightly regulated. In the absence of F-actin elongation, retraction of the filopodium takes place by a rearward flow of F-actin and filament depolymerization (22).IRSp53 is in a position to play a pivotal role in generating filopodia; this brain-enriched protein was discovered as a substrate of the insulin receptor (87). Subsequently, IRSp53 was identified as an effector for Rac1 (50) and Cdc42 (27, 38), where it participates in filopodium and lamellipodium production (38, 51, 54, 86), neurite extension (27), dendritic-spine morphogenesis (1, 15, 66, 67), cell motility and invasiveness (24). The N terminus of IRSp53 contains a conserved helical domain that is found in five different gene products and is referred to as the IRSp53/MIM homology domain (IMD) (51, 70). This domain has been postulated to bind to Rac1 (50, 70) in a nucleotide-independent manner (52), but no convincing effector-like region has been identified. A Cdc42-specific CRIB-like sequence that does not bind Rac1 (27, 38) allows coupling of this and perhaps related Rho GTPases. The structure of the IMD reveals a zeppelin-shaped dimer that could bind “bent” membranes; thus, its potential as an F-actin-bundling domain (51, 82) could be an in vitro artifact often attributed to proteins with basic patches (46). Although there are reports of F-actin binding at physiological ionic strength (ca. 100 mM KCl) (82, 19), this region when expressed in isolation does not decorate F-actin in vivo.Two reports showed the IMD to be an “inverse-BAR” domain. BAR (Bin-amphipysin-Rvs) domains are found in proteins involved in endocytic trafficking, such as amphipysin and endophilin, and stabilize positively bent membranes, such as those on endocytic vesicles (31, 47). The IMD domains of both IRSp53 (70) and MIM-B (46) associate with lipids and can induce tubulations of PI(3,4,5)P₃ or PI(4,5)P₂-rich membranes, respectively. These tubulations are equivalent to membrane protrusions and are also referred to as negatively bent membranes. Ectopic expression of the IMD from IRSp53 (51, 70, 82, 86) or two other family members, MIM-B (11, 46) and IRTKS (52), can give rise to cells with many peripheral extensions. MIM-B is said to stimulate lamellipodia (11), while IRTKS generates “short actin clusters” at the cell periphery (52).In IRSp53 is a CRIB-like motif that mediates binding to Cdc42 (27, 38), but the function of this interaction in unclear. Cdc42 could relieve IRSp53 autoinhibition as described for N-Wasp (38), but there is little evidence for this. It has been suggested that Cdc42 controls IRSp53 localization and actin remodeling (27, 38), but another study indicated that these events are Cdc42 independent (19). IRSp53 contains a central SH3 domain that may bind proline-rich proteins, such as Dia1 (23), Mena (38), WAVE2 (49, 50, 69), and Eps8 (19, 24). However, it seems unlikely that all of these represent bona fide partners, and side-by-side comparison is provided in this study. Mena is involved in filopodium production (37), Dia1 in stress fiber formation (81), and WAVE2 in lamellipodium extension (72). Thus, Mena is a better candidate as a partner for IRSp53-mediated filopodia than Dia1 or WAVE2.There is good evidence for IRSp53 as a cellular partner for Eps8 (19). Eps8 is an adaptor protein containing an N-terminal PTB domain that can associate with receptor tyrosine kinases (65), and perhaps β integrins (13), and a C-terminal SH3 domain that can associate with Abi1 (30). Binding of the general adaptor Abi1 appears to positively regulate the actin-capping domain at the C terminus of Eps8 (18). It has been suggested that IRSp53 and Eps8 as a complex regulate cell motility, and perhaps Rac1 activation, via SOS (24); more recently, their roles in filopodium formation have been addressed (19). The involvement of IRSp53, but not MIM-B or IRTKS, in filopodium formation might be related to its role as a Cdc42 effector. We show here that, surprisingly, the CRIB motif is not essential for this activity, but rather, the ability of IRSp53 to associate via its SH3 domain is required, and that this domain is controlled by 14-3-3 binding.We have focused on the regulation of Cdc42 effectors that bind 14-3-3, including IRSp53 and PAK4, which are found as 14-3-3 targets in various proteomic projects (32, 44). In this study, we characterize the binding of 14-3-3 to IRSp53 and uncover how this activity regulates IRSp53 function. The phosphorylation-dependent 14-3-3 binding is GSK3β dependent, and 14-3-3 blocks the accessibility of both the CRIB and SH3 domains of IRSp53, thus indicating its primary function in controlling IRSp53 partners. This regulation of the SH3 domain by 14-3-3 is critical in the proper localization and termination of IRSp53 function to promote filopodium dynamics.     

Rickettsia felis Infection in a Common Household Insect Pest,Liposcelis bostrychophila (Psocoptera: Liposcelidae)

Many species of Rickettsia are well-known mammalian pathogens transmitted by blood-feeding arthropods. However, molecular surveys are continually uncovering novel Rickettsia species, often in unexpected hosts, including many arthropods that do not feed on blood. This study reports a systematic molecular characterization of a Rickettsia infecting the psocid Liposcelis bostrychophila (Psocoptera: Liposcelidae), a common and cosmopolitan household pest. Surprisingly, the psocid Rickettsia is shown to be Rickettsia felis, a human pathogen transmitted by fleas that causes serious morbidity and occasional mortality. The plasmid from the psocid R. felis was sequenced and was found to be virtually identical to the one in R. felis from fleas. As Liposcelis insects are often intimately associated with humans and other vertebrates, it is speculated that they acquired R. felis from fleas. Whether the R. felis in psocids causes disease in vertebrates is not known and warrants further study.Many species of Rickettsia are well-known mammalian pathogens that are transmitted by blood-feeding arthropods via bites or feces and can cause mild to fatal diseases in humans (33). Some species are also considered potential bioterrorism agents (4). Most Rickettsia research has focused on pathogens that are found in two closely related species groups, the typhus and spotted fever groups, such as Rickettsia prowazekii, Rickettsia rickettsii, and Rickettsia typhi, the causal agents of epidemic typhus, Rocky Mountain spotted fever, and murine typhus, respectively (3, 4, 33). However, recent surveys suggest that Rickettsia bacteria are much more widespread than previously suspected and that they are being detected in novel hosts, the vast majority of which are arthropods, including many that do not feed on blood (29, 45).The number of new rickettsial species that cause diseases in humans is rapidly increasing (33). One such species that has been generating much interest in recent years is Rickettsia felis, the causative agent of a murine typhus-like disease (1, 2, 13, 16, 17, 28, 44). The disease is often unrecognized, and even though it is considered clinically mild, it can cause severe illness and death in older patients and in cases of delayed diagnosis (2). R. felis was identified only in 1990 (1) and has since been found worldwide in fleas, where it is maintained transovarially and can reach high infection rates (e.g., 86% to 94% in cat fleas) (2, 3, 44), as well as in ticks and mites (34). While experimental infections have confirmed that R. felis is transmitted to vertebrate hosts via blood feeding and that R. felis occurs in an infectious extracellular state (39), it is not known whether transmission can also occur through contamination of broken skin by infected vector feces, as in R. typhi (3, 34).A number of features distinguish R. felis from species in both the typhus and spotted fever groups. Lately, it has been proposed that R. felis be in its own group, allied with Rickettsia akari and Rickettsia australis, the causal agents of rickettsial pox and Queensland tick typhus, respectively, and a number of recently discovered strains infecting insects that do not feed on blood (16, 17, 29, 45). Moreover, R. felis was the first Rickettsia species shown to have a plasmid (28). While plasmids now appear to be quite widespread in the genus, the R. felis plasmid stands out with respect to its relatively large size and distinctive gene content (5, 6, 9, 14, 17).This study reports that a common and cosmopolitan insect, the psocid Liposcelis bostrychophila (Psocoptera: Liposcelidae) harbors R. felis. Liposcelids are the closest free-living relatives of parasitic lice (19) and are well-known for their close proximity to humans, particularly as pests in houses and grain storage facilities (8, 41). Through 16S rRNA gene sequencing, L. bostrychophila was recently shown to harbor a strain of Rickettsia (29, 30, 42). A systematic molecular characterization of this Rickettsia was conducted, demonstrating that it is authentic R. felis. Furthermore, the psocid symbiont plasmid was sequenced and was shown to be virtually identical to the plasmid from R. felis that infects cat fleas.     

Population Structure of the Lyme Borreliosis Spirochete Borrelia burgdorferi in the Western Black-Legged Tick (Ixodes pacificus) in Northern California

Factors potentially contributing to the lower incidence of Lyme borreliosis (LB) in the far-western than in the northeastern United States include tick host-seeking behavior resulting in fewer human tick encounters, lower densities of Borrelia burgdorferi-infected vector ticks in peridomestic environments, and genetic variation among B. burgdorferi spirochetes to which humans are exposed. We determined the population structure of B. burgdorferi in over 200 infected nymphs of the primary bridging vector to humans, Ixodes pacificus, collected in Mendocino County, CA. This was accomplished by sequence typing the spirochete lipoprotein ospC and the 16S-23S rRNA intergenic spacer (IGS). Thirteen ospC alleles belonging to 12 genotypes were found in California, and the two most abundant, ospC genotypes H3 and E3, have not been detected in ticks in the Northeast. The most prevalent ospC and IGS biallelic profile in the population, found in about 22% of ticks, was a new B. burgdorferi strain defined by ospC genotype H3. Eight of the most common ospC genotypes in the northeastern United States, including genotypes I and K that are associated with disseminated human infections, were absent in Mendocino County nymphs. ospC H3 was associated with hardwood-dominated habitats where western gray squirrels, the reservoir host, are commonly infected with LB spirochetes. The differences in B. burgdorferi population structure in California ticks compared to the Northeast emphasize the need for a greater understanding of the genetic diversity of spirochetes infecting California LB patients.In the United States, Lyme borreliosis (LB) is the most commonly reported vector-borne illness and is caused by infection with the spirochete Borrelia burgdorferi (3, 9, 52). The signs and symptoms of LB can include a rash, erythema migrans, fever, fatigue, arthritis, carditis, and neurological manifestations (50, 51). The black-legged tick, Ixodes scapularis, and the western black-legged tick, Ixodes pacificus, are the primary vectors of B. burgdorferi to humans in the United States, with the former in the northeastern and north-central parts of the country and the latter in the Far West (9, 10). These ticks perpetuate enzootic transmission cycles together with a vertebrate reservoir host such as the white-footed mouse, Peromyscus leucopus, in the Northeast and Midwest (24, 35), or the western gray squirrel, Sciurus griseus, in California (31, 46).B. burgdorferi is a spirochete species with a largely clonal population structure (14, 16) comprising several different strains or lineages (8). The polymorphic ospC gene of B. burgdorferi encodes a surface lipoprotein that increases expression within the tick during blood feeding (47) and is required for initial infection of mammalian hosts (25, 55). To date, approximately 20 North American ospC genotypes have been described (40, 45, 49, 56). At least four, and possibly up to nine, of these genotypes are associated with B. burgdorferi invasiveness in humans (1, 15, 17, 49, 57). Restriction fragment length polymorphism (RFLP) and, subsequently, sequence analysis of the 16S-23S rRNA intergenic spacer (IGS) are used as molecular typing tools to investigate genotypic variation in B. burgdorferi (2, 36, 38, 44, 44, 57). The locus maintains a high level of variation between related species, and this variation reflects the heterogeneity found at the genomic level of the organism (37). The IGS and ospC loci appear to be linked (2, 8, 26, 45, 57), but the studies to date have not been representative of the full range of diversity of B. burgdorferi in North America.Previous studies in the northeastern and midwestern United States have utilized IGS and ospC genotyping to elucidate B. burgdorferi evolution, host strain specificity, vector-reservoir associations, and disease risk to humans. In California, only six ospC and five IGS genotypes have been described heretofore in samples from LB patients or I. pacificus ticks (40, 49, 56) compared to approximately 20 ospC and IGS genotypes identified in ticks, vertebrate hosts, or humans from the Northeast and Midwest (8, 40, 45, 49, 56). Here, we employ sequence analysis of both the ospC gene and IGS region to describe the population structure of B. burgdorferi in more than 200 infected I. pacificus nymphs from Mendocino County, CA, where the incidence of LB is among the highest in the state (11). Further, we compare the Mendocino County spirochete population to populations found in the Northeast.     

Cell-to-Cell Spread of the RNA Interference Response Suppresses Semliki Forest Virus (SFV) Infection of Mosquito Cell Cultures and Cannot Be Antagonized by SFV

In their vertebrate hosts, arboviruses such as Semliki Forest virus (SFV) (Togaviridae) generally counteract innate defenses and trigger cell death. In contrast, in mosquito cells, following an early phase of efficient virus production, a persistent infection with low levels of virus production is established. Whether arboviruses counteract RNA interference (RNAi), which provides an important antiviral defense system in mosquitoes, is an important question. Here we show that in Aedes albopictus-derived mosquito cells, SFV cannot prevent the establishment of an antiviral RNAi response or prevent the spread of protective antiviral double-stranded RNA/small interfering RNA (siRNA) from cell to cell, which can inhibit the replication of incoming virus. The expression of tombusvirus siRNA-binding protein p19 by SFV strongly enhanced virus spread between cultured cells rather than virus replication in initially infected cells. Our results indicate that the spread of the RNAi signal contributes to limiting virus dissemination.In animals, RNA interference (RNAi) was first described for Caenorhabditis elegans (27). The production or introduction of double-stranded RNA (dsRNA) in cells leads to the degradation of mRNAs containing homologous sequences by sequence-specific cleavage of mRNAs. Central to RNAi is the production of 21- to 26-nucleotide small interfering RNAs (siRNAs) from dsRNA and the assembly of an RNA-induced silencing complex (RISC), followed by the degradation of the target mRNA (23, 84). RNAi is a known antiviral strategy of plants (3, 53) and insects (21, 39, 51). Study of Drosophila melanogaster in particular has given important insights into RNAi responses against pathogenic viruses and viral RNAi inhibitors (31, 54, 83, 86, 91). RNAi is well characterized for Drosophila, and orthologs of antiviral RNAi genes have been found in Aedes and Culex spp. (13, 63).Arboviruses, or arthropod-borne viruses, are RNA viruses mainly of the families Bunyaviridae, Flaviviridae, and Togaviridae. The genus Alphavirus within the family Togaviridae contains several mosquito-borne pathogens: arboviruses such as Chikungunya virus (16) and equine encephalitis viruses (88). Replication of the prototype Sindbis virus and Semliki Forest virus (SFV) is well understood (44, 71, 74, 79). Their genome consists of a positive-stranded RNA with a 5′ cap and a 3′ poly(A) tail. The 5′ two-thirds encodes the nonstructural polyprotein P1234, which is cleaved into four replicase proteins, nsP1 to nsP4 (47, 58, 60). The structural polyprotein is encoded in the 3′ one-third of the genome and cleaved into capsid and glycoproteins after translation from a subgenomic mRNA (79). Cytoplasmic replication complexes are associated with cellular membranes (71). Viruses mature by budding at the plasma membrane (35).In nature, arboviruses are spread by arthropod vectors (predominantly mosquitoes, ticks, flies, and midges) to vertebrate hosts (87). Little is known about how arthropod cells react to arbovirus infection. In mosquito cell cultures, an acute phase with efficient virus production is generally followed by the establishment of a persistent infection with low levels of virus production (9). This is fundamentally different from the cytolytic events following arbovirus interactions with mammalian cells and pathogenic insect viruses with insect cells. Alphaviruses encode host response antagonists for mammalian cells (2, 7, 34, 38).RNAi has been described for mosquitoes (56) and, when induced before infection, antagonizes arboviruses and their replicons (1, 4, 14, 15, 29, 30, 32, 42, 64, 65). RNAi is also functional in various mosquito cell lines (1, 8, 43, 49, 52). In the absence of RNAi, alphavirus and flavivirus replication and/or dissemination is enhanced in both mosquitoes and Drosophila (14, 17, 31, 45, 72). RNAi inhibitors weakly enhance SFV replicon replication in tick and mosquito cells (5, 33), posing the questions of how, when, and where RNAi interferes with alphavirus infection in mosquito cells.Here we use an A. albopictus-derived mosquito cell line to study RNAi responses to SFV. Using reporter-based assays, we demonstrate that SFV cannot avoid or efficiently inhibit the establishment of an RNAi response. We also demonstrate that the RNAi signal can spread between mosquito cells. SFV cannot inhibit cell-to-cell spread of the RNAi signal, and spread of the virus-induced RNAi signal (dsRNA/siRNA) can inhibit the replication of incoming SFV in neighboring cells. Furthermore, we show that SFV expression of a siRNA-binding protein increases levels of virus replication mainly by enhancing virus spread between cells rather than replication in initially infected cells. Taken together, these findings suggest a novel mechanism, cell-to-cell spread of antiviral dsRNA/siRNA, by which RNAi limits SFV dissemination in mosquito cells.     

Alignment of the c-Type Cytochrome OmcS along Pili of Geobacter sulfurreducens

Immunogold localization revealed that OmcS, a cytochrome that is required for Fe(III) oxide reduction by Geobacter sulfurreducens, was localized along the pili. The apparent spacing between OmcS molecules suggests that OmcS facilitates electron transfer from pili to Fe(III) oxides rather than promoting electron conduction along the length of the pili.There are multiple competing/complementary models for extracellular electron transfer in Fe(III)- and electrode-reducing microorganisms (8, 18, 20, 44). Which mechanisms prevail in different microorganisms or environmental conditions may greatly influence which microorganisms compete most successfully in sedimentary environments or on the surfaces of electrodes and can impact practical decisions on the best strategies to promote Fe(III) reduction for bioremediation applications (18, 19) or to enhance the power output of microbial fuel cells (18, 21).The three most commonly considered mechanisms for electron transfer to extracellular electron acceptors are (i) direct contact between redox-active proteins on the outer surfaces of the cells and the electron acceptor, (ii) electron transfer via soluble electron shuttling molecules, and (iii) the conduction of electrons along pili or other filamentous structures. Evidence for the first mechanism includes the necessity for direct cell-Fe(III) oxide contact in Geobacter species (34) and the finding that intensively studied Fe(III)- and electrode-reducing microorganisms, such as Geobacter sulfurreducens and Shewanella oneidensis MR-1, display redox-active proteins on their outer cell surfaces that could have access to extracellular electron acceptors (1, 2, 12, 15, 27, 28, 31-33). Deletion of the genes for these proteins often inhibits Fe(III) reduction (1, 4, 7, 15, 17, 28, 40) and electron transfer to electrodes (5, 7, 11, 33). In some instances, these proteins have been purified and shown to have the capacity to reduce Fe(III) and other potential electron acceptors in vitro (10, 13, 29, 38, 42, 43, 48, 49).Evidence for the second mechanism includes the ability of some microorganisms to reduce Fe(III) that they cannot directly contact, which can be associated with the accumulation of soluble substances that can promote electron shuttling (17, 22, 26, 35, 36, 47). In microbial fuel cell studies, an abundance of planktonic cells and/or the loss of current-producing capacity when the medium is replaced is consistent with the presence of an electron shuttle (3, 14, 26). Furthermore, a soluble electron shuttle is the most likely explanation for the electrochemical signatures of some microorganisms growing on an electrode surface (26, 46).Evidence for the third mechanism is more circumstantial (19). Filaments that have conductive properties have been identified in Shewanella (7) and Geobacter (41) species. To date, conductance has been measured only across the diameter of the filaments, not along the length. The evidence that the conductive filaments were involved in extracellular electron transfer in Shewanella was the finding that deletion of the genes for the c-type cytochromes OmcA and MtrC, which are necessary for extracellular electron transfer, resulted in nonconductive filaments, suggesting that the cytochromes were associated with the filaments (7). However, subsequent studies specifically designed to localize these cytochromes revealed that, although the cytochromes were extracellular, they were attached to the cells or in the exopolymeric matrix and not aligned along the pili (24, 25, 30, 40, 43). Subsequent reviews of electron transfer to Fe(III) in Shewanella oneidensis (44, 45) appear to have dropped the nanowire concept and focused on the first and second mechanisms.Geobacter sulfurreducens has a number of c-type cytochromes (15, 28) and multicopper proteins (12, 27) that have been demonstrated or proposed to be on the outer cell surface and are essential for extracellular electron transfer. Immunolocalization and proteolysis studies demonstrated that the cytochrome OmcB, which is essential for optimal Fe(III) reduction (15) and highly expressed during growth on electrodes (33), is embedded in the outer membrane (39), whereas the multicopper protein OmpB, which is also required for Fe(III) oxide reduction (27), is exposed on the outer cell surface (39).OmcS is one of the most abundant cytochromes that can readily be sheared from the outer surfaces of G. sulfurreducens cells (28). It is essential for the reduction of Fe(III) oxide (28) and for electron transfer to electrodes under some conditions (11). Therefore, the localization of this important protein was further investigated.     

Stereospecific Biotransformation of Dihydrodaidzein into (3S)-Equol by the Human Intestinal Bacterium Eggerthella Strain Julong 732

Stereochemical course of isoflavanone dihydrodaidzein (DHD) reduction into the isoflavan (3S)-equol via tetrahydrodaidzein (THD) by the human intestinal anaerobic bacterium Eggerthella strain Julong 732 was studied. THD was synthesized by catalytic hydrogenation, and each stereoisomer was separated by chiral high-performance liquid chromatography. Circular dichroism spectroscopy was used to elucidate the absolute configurations of four synthetic THD stereoisomers. Rapid racemization of DHD catalyzed by Julong 732 prevented the substrate stereospecificity in the conversion of DHD into THD from being confirmed. The absolute configuration of THD, prepared by reduction of DHD in the cell-free incubation, was assigned as (3R,4S) via comparison of the retention time to that of the authentic THD by chiral chromatography. Dehydroequol (DE) was unable to produce the (3S)-equol both in the cell-free reaction and in the bacterial transformation, negating the possible intermediacy of DE. Finally, the intermediate (3R,4S)-THD was reduced into (3S)-equol by the whole cell, indicating the inversion of stereochemistry at C-3 during the reduction. A possible mechanism accounting for the racemization of DHD and the inversion of configuration of THD during reduction into (3S)-equol is proposed.Isoflavones are natural dietary phytoestrogens mainly occurring in the leguminous plants, such as soybean. Daidzein and genistein, two major isoflavones in soybean, have received a considerable attention due to their bioactivities beneficial to the human health, including estrogenic (9), anticancer (14), antioxidant (1, 21), and cardioprotective (11) activities. Recently, special interest has been focused on the biological effects of the daidzein metabolites, which are being actively studied for drug development (5, 16).Daidzein is known to be metabolized in the human intestine by the resident microflora, and various metabolites, such as dihydrodaidzein (DHD), 7,4′-dihydroxyisoflavan-4-ol (tetrahydrodaidzein; THD), 7,4′-dihydroxyisoflav-3-ene (dehydroequol; DE), O-desmethylangolensin (O-DMA), and equol, are detected in the human urine (Fig. ​(Fig.1)1) (6, 7, 10). Among the metabolites, (3S)-equol has about 100 times higher estrogenic activity than daidzein itself (15). However, only about 30 to 50% of humans can produce equol from daidzein (12). In addition, a high correlation was found between the beneficial effects on females by soy food intake and the presence of equol in their urine (4). Therefore, the ability to metabolize daidzein into equol conferred by the intestinal microflora in human is regarded as a hallmark of daidzein responsiveness (3, 34).Open in a separate windowFIG. 1.Proposed pathway for isoflavone daidzein reduction by intestinal microflora leading to equol formation. The absolute configuration of THD is depicted as (3R,4S) according to the conclusion of the present study.The daidzein metabolic sequence has been proposed based on the presence of various metabolites of daidzein produced by the human intestinal bacteria; daidzein is reduced into DHD, then into THD and DE, and finally into (3S)-equol in sequential reactions (Fig. ​(Fig.1)1) (7, 10). However, the pathway and the individual reactions in the pathway have not been fully elucidated partly due to the unavailability of pure microbial isolates.To confirm the proposed metabolic pathway of the human intestinal microflora, attempts have been made to isolate the daidzein-metabolizing bacterial phenotype from human feces. The reduction of daidzein into equol through the cooperation of the microfloral community in the human intestine is thought to be likely and was demonstrated by using the whole microflora from human (2) and monkey (23) feces. However, daidzein metabolism by the whole-rat intestinal flora results in the formation of DHD, and further reaction leading to the formation of unknown aliphatic compounds was implied (24).Various bacterial phenotypes have been suggested to have a responsible role in daidzein metabolism in the small intestines of animals. An anaerobic bacterium, Clostridium sp. strain HGH6 (8), and a Clostridium-like strain, TM-40 (27), were found to reduce daidzein into DHD, and the C-ring cleavage was executed by a strain of Eubacterium (25). A human intestinal bacterium that could produce equol was first reported in 2005. Eggerthella strain Julong 732, which could not reduce daidzein into DHD, was found to reduce DHD into equol (28), thus establishing the aforementioned reduction sequence leading to the biologically active (S)-equol from daidzein via DHD in the human intestine (7, 10). Eggerthella species are normal residents of the human gut, and some species are implicated as causative agents of bacteremia (13). The microbial phenotypes that can reduce daidzein all the way into equol were recently isolated from mice (19), rats (20), pigs (33), and humans (18, 32). Nevertheless, the enzymology of the reduction, such as the nature of the enzyme responsible and the reaction mechanism, has yet to be established.In the present study, the enzyme reaction mechanisms of two consecutive reduction reactions converting DHD into (3S)-equol were stereochemically assessed. To this end, four stereoisomers of THD were first synthesized, and their absolute configurations were determined. With the correlation of the absolute configuration of the synthetic THD isomers and the circular dichroism (CD) spectra at hand, the absolute configuration of THD produced through the cell-free bacterial reduction of DHD was determined. Each synthetic THD stereoisomer was then tested as a metabolic feedstock for (3S)-equol production during the growth of Julong 732. We found that only one of the THD steroisomers, (3R,4S)-THD, the very stereoisomer produced by the bacterial DHD reduction, was converted into (3S)-equol and that the final reduction accompanied the inversion of the configuration at C-3 of THD.     

Selection of a Bacillus pumilus Strain Highly Active against Ceratitis capitata (Wiedemann) Larvae

Ceratitis capitata (Wiedemann) (Diptera: Tephritidae), the Mediterranean fruit fly (medfly), is one of the most important fruit pests worldwide. The medfly is a polyphagous species that causes losses in many crops, which leads to huge economic losses. Entomopathogenic bacteria belonging to the genus Bacillus have been proven to be safe, environmentally friendly, and cost-effective tools to control pest populations. As no control method for C. capitata based on these bacteria has been developed, isolation of novel strains is needed. Here, we report the isolation of 115 bacterial strains and the results of toxicity screening with adults and larvae of C. capitata. As a result of this analysis, we obtained a novel Bacillus pumilus strain, strain 15.1, that is highly toxic to C. capitata larvae. The toxicity of this strain for C. capitata was related to the sporulation process and was observed only when cultures were incubated at low temperatures before they were used in a bioassay. The mortality rate for C. capitata larvae ranged from 68 to 94% depending on the conditions under which the culture was kept before the bioassay. Toxicity was proven to be a special characteristic of the newly isolated strain, since other B. pumilus strains did not have a toxic effect on C. capitata larvae. The results of the present study suggest that B. pumilus 15.1 could be considered a strong candidate for developing strategies for biological control of C. capitata.The Mediterranean fruit fly (medfly), Ceratitis capitata, is considered a highly invasive agricultural and economically important pest throughout the world. In less than 200 years the range of this species has expanded from its native habitat in sub-Saharan Africa, and it has become a cosmopolitan species (26) that is present on five continents (14, 46). The wide distribution of the medfly is attributed, among other things, to its remarkably polyphagous behavior (more than 300 host plants have been reported) (43), to its resistance to cold climates (65), and to successful establishment after multiple introductions (30, 49) as a result of the increasing frequency of global trade (46).Medfly infestations cause serious economic losses and sometimes result in complete loss of crops (76). Numerous methods have been tried to control medfly populations, including chemical products, such as malathion and other organophosphate insecticides (4, 8), classic biological control programs based on the release of some of parasitoids and predators (38, 41, 44), toxic baits (2, 13, 31, 32, 35, 56), mass trapping systems (24, 51), the sterile insect technique (7, 34, 61, 63, 72, 73), and development of integrated strategies of management (71). In spite of all of these attempts, control of Mediterranean fruit fly populations has been ineffective, and losses associated with this pest worldwide are constantly increasing (21, 46).Insecticides based on microbial agents (bacteria, fungi, and viruses) are a promising alternative that has received a great deal of attention for control of C. capitata (5, 13, 18, 40, 55), but so far no such insecticide has reached a commercial stage. Among the microbial insecticides, bacteria are very successful agents in biological control programs (17, 29). The entomopathogenic bacteria belonging to the genus Bacillus are natural agents used for biological control of invertebrate pests and are the basis of many commercial insecticides. Three species of the genus Bacillus have been mass produced and commercialized: Bacillus sphaericus, Bacillus thuringiensis, and Paenibacillus popilliae (formerly Bacillus popilliae) (29, 54). These organisms have different spectra and levels of activity that are correlated with the nature of the toxins, which are very frequently produced during sporulation (16, 17). B. thuringiensis was the first Bacillus species used in biological control programs for pests and human vector disease insects (17, 62). During its stationary phase, this Gram-positive, aerobic, ubiquitous, endospore-forming bacterium produces parasporal crystalline inclusions composed mainly of two types of insecticidal proteins (Cry and Cyt toxins) (62) that are toxic to a variety of insects, in some cases at the species level.There have been some reports of B. thuringiensis strains active against other fruit flies (3, 37, 58, 59, 67), but there has been no report of any Bacillus strain with activity against C. capitata.The aim of this study was to search for novel bacteria belonging to the genus Bacillus, specifically B. thuringiensis, with activity against adults and larvae of C. capitata that could be used as biological control agents. Isolation of 115 bacterial strains, evaluation of the insecticidal activities of these strains, and identification of a novel strain of Bacillus pumilus that is highly toxic to C. capitata larvae are reported here. In addition, we found that toxicity was observed only when cultures of B. pumilus strain 15.1 were exposed to low temperatures. The isolation of this novel pathogenic strain could be important for future development of biotechnological strategies aimed at reducing the economic losses caused by C. capitata.     

Effects of Aeration on the Synthesis of Poly(3-Hydroxybutyrate) from Glycerol and Glucose in Recombinant Escherichia coli

Bioreactor cultures of Escherichia coli recombinants carrying phaBAC and phaP of Azotobacter sp. FA8 grown on glycerol under low-agitation conditions accumulated more poly(3-hydroxybutyrate) (PHB) and ethanol than at high agitation, while in glucose cultures, low agitation led to a decrease in PHB formation. Cells produced smaller amounts of acids from glycerol than from glucose. Glycerol batch cultures stirred at 125 rpm accumulated, in 24 h, 30.1% (wt/wt) PHB with a relative molecular mass of 1.9 MDa, close to that of PHB obtained using glucose.Polyhydroxyalkanoates (PHAs), accumulated as intracellular granules by many bacteria under unfavorable conditions (5, 8), are carbon and energy reserves and also act as electron sinks, enhancing the fitness of bacteria and contributing to redox balance (9, 11, 19). PHAs have thermoplastic properties, are totally biodegradable by microorganisms present in most environments, and can be produced from different renewable carbon sources (8).Poly(3-hydroxybutyrate) (PHB) is the best known PHA, and its accumulation in recombinant Escherichia coli from several carbon sources has been studied (1, 13). In the last few years, increasing production of biodiesel has caused a sharp fall in the cost of its main by-product, glycerol (22). Its use for microbial PHA synthesis has been analyzed for natural PHA producers, such as Methylobacterium rhodesianum, Cupriavidus necator (formerly called Ralstonia eutropha) (3), several Pseudomonas strains (22), the recently described bacterium Zobellella denitrificans (7), and a Bacillus sp. (18), among others. Glycerol has also been used for PHB synthesis in recombinant E. coli (12, 15). PHAs obtained from glycerol were reported to have a significantly lower molecular weight than polymer synthesized from other substrates, such as glucose or lactose (10, 23).Apart from the genes that catalyze polymer biosynthesis, natural PHA producers have several genes that are involved in granule formation and/or have regulatory functions, such as phasins, granule-associated proteins that have been shown to enhance polymer synthesis and the number and size of PHA granules (17, 24). The phasin PhaP has been shown to exert a beneficial effect on bacterial growth and PHB accumulation from glycerol in bioreactor cultures of strain K24KP, a recombinant E. coli that carries phaBAC and phaP of Azotobacter sp. FA8 (6).Because the redox state of the cells is known to affect the synthesis of PHB (1, 4, 14), the present study investigates the behavior of this recombinant strain under different aeration conditions, by using two substrates, glucose and glycerol, with different oxidation states.     

Ustilago maydis Rho1 and 14-3-3 Homologues Participate in Pathways Controlling Cell Separation and Cell Polarity

Proteins of the 14-3-3 and Rho-GTPase families are functionally conserved eukaryotic proteins that participate in many important cellular processes such as signal transduction, cell cycle regulation, malignant transformation, stress response, and apoptosis. However, the exact role(s) of these proteins in these processes is not entirely understood. Using the fungal maize pathogen, Ustilago maydis, we were able to demonstrate a functional connection between Pdc1 and Rho1, the U. maydis homologues of 14-3-3ɛ and Rho1, respectively. Our experiments suggest that Pdc1 regulates viability, cytokinesis, chromosome condensation, and vacuole formation. Similarly, U. maydis Rho1 is also involved in these three essential processes and exerts an additional function during mating and filamentation. Intriguingly, yeast two-hybrid and epistasis experiments suggest that both Pdc1 and Rho1 could be constituents of the same regulatory cascade(s) controlling cell growth and filamentation in U. maydis. Overexpression of rho1 ameliorated the defects of cells depleted for Pdc1. Furthermore, we found that another small G protein, Rac1, was a suppressor of lethality for both Pdc1 and Rho1. In addition, deletion of cla4, encoding a Rac1 effector kinase, could also rescue cells with Pdc1 depleted. Inferring from these data, we propose a model for Rho1 and Pdc1 functions in U. maydis.Morphological switching is a unique attribute of all dimorphic fungi, which alternate between budding and filamentous growth. In some cases, as with mating, this is a prerequisite for genetic diversity for this subfamily of fungi. In addition, many dimorphic fungal pathogens rely on this ability in order to effectively invade their host. In general, the transition between these alternate life forms means a complete turnover of cellular and proteomic components, which often involves cell cycle arrest and/or cytoskeletal rearrangement. Although the cellular proteomes associated with these two processes share many components, there are both temporal and spatial regulations that are manifested during the transitional phase (4).Temporal-spatial regulation of the proteome during the dimorphic transition requires cooperation and synchronized communication among different regulatory pathways. Two highly intricate, yet well-established, signaling cascades that regulate fungal morphogenesis are the mitogen-activated protein kinase (MAPK) (34, 46) and protein kinase A pathways (11). These signaling cascades detect and perpetuate extracellular stimuli, e.g., pheromones and nutrients, which lead to phase transitions in dimorphic fungi. Although the mechanisms are not as fully understood, members of two highly conserved families of proteins, Rho/Rac GTPases and 14-3-3 proteins, have also been shown to control filamentation. Constituents of the Rho/Rac protein family have been shown to regulate actin organization (26, 35, 36), cytokinesis (3, 49, 52), cell integrity (42, 56), pathogenicity (29), signal transduction (22, 44, 56), and cell migration (8). Their activity is dependent upon the reversible binding of guanine nucleotides catalyzed by guanine nucleotide exchange factors (GEFs) and GTPase activating proteins (GAPs) (15, 22, 23, 25, 44). Upon activation, Rho-GTPases stimulate downstream effector proteins such as p21-activated kinases (PAKs) (29, 51) or Rho kinase (ROCK) (36). Based on in silico analysis of the genome sequence, the fungal pathogen of maize, Ustilago maydis, contains six different Rho/Rac encoding genes: cdc42, rac1, and four additional genes predicted to encode Rho-like proteins (20). Of these, only the roles of Cdc42 and Rac1 have been examined in depth. Cdc42 was shown to regulate cytokinesis, while Rac1 regulates hyphal development in U. maydis (26). We examine here the place of a Rho1 homologue, Rho1, in U. maydis cell morphology, polarity, and development.Similarly, the highly conserved, ubiquitously expressed 14-3-3 proteins that are found in most eukaryotes have also been shown to contribute to cellular differentiation and cytoskeletal organization. Like Rho-GTPases, 14-3-3 proteins play multiple roles, in cytoskeletal function, cell cycle regulation, apoptosis, and the regulation of a variety of signaling pathways (17, 19, 33, 50). These acidic proteins have been found in each cellular compartment and most organisms examined possess multiple isoforms: seven isoforms are found in mammals, and as many as fifteen isoforms have been identified in plants (31). Interestingly, the yeast Saccharomyces cerevisiae, the fruit fly, Drosophila melanogaster, and the nematode, Caenorhabditis elegans, each possess only two 14-3-3 isoforms (50), while Candida albicans contains a single isoform (37). They function typically by binding their particular ligands at phosphoserine or phosphothreonine residues (50). It is not clear what 14-3-3 proteins do in the processes mentioned above, whether they act as scaffolds or effectors. Inspection of the U. maydis genome sequence revealed that this organism could be ideal for the study of 14-3-3 proteins because, unlike most other organisms, the U. maydis genome contains only a single 14-3-3 homologue. Due to its predicted binding of phosphorylated proteins, we named this homologue Pdc1 (for phosphorylation domain coupling protein [10]). Recently, the protein (also designated Bmh1 [32]) was also shown to be involved in cell cycle regulation.Despite the functional differences between Rho-GTPases and 14-3-3 proteins, we provide evidence that members of these two families participate in the same regulatory cascade(s) that control morphogenesis in the dimorphic fungus U. maydis. We are able to demonstrate that both Pdc1 and Rho1 are essential for cell viability. In addition, overexpression of Rho1 led to the reduction of filamentation. Overexpression of Rac1 triggers filamentation in U. maydis (13, 29). We show here that deleting Rac1 eliminates the lethal effect imposed by either Rho1 or Pdc1 depletion. Our results have led us to predict that both Rho1 and Pdc1 are negative regulators of Rac1 in U. maydis and that they play important roles in polarized growth and cytokinesis.     

An Extreme Thermophile,Thermus thermophilus,Is a Polyploid Bacterium

An extremely thermophilic bacterium, Thermus thermophilus HB8, is one of the model organisms for systems biology. Its genome consists of a chromosome (1.85 Mb), a megaplasmid (0.26 Mb) designated pTT27, and a plasmid (9.3 kb) designated pTT8, and the complete sequence is available. We show here that T. thermophilus is a polyploid organism, harboring multiple genomic copies in a cell. In the case of the HB8 strain, the copy number of the chromosome was estimated to be four or five, and the copy number of the pTT27 megaplasmid seemed to be equal to that of the chromosome. It has never been discussed whether T. thermophilus is haploid or polyploid. However, the finding that it is polyploid is not surprising, as Deinococcus radiodurans, an extremely radioresistant bacterium closely related to Thermus, is well known to be a polyploid organism. As is the case for D. radiodurans in the radiation environment, the polyploidy of T. thermophilus might allow for genomic DNA protection, maintenance, and repair at elevated growth temperatures. Polyploidy often complicates the recognition of an essential gene in T. thermophilus as a model organism for systems biology.The extreme thermophile Thermus thermophilus is a Gram-negative aerobic bacterium that can grow at temperatures ranging from 50°C to 82°C (33, 34). The genome sequences of two strains, HB27 and HB8, are available (13; see also http://www.ncbi.nlm.nih.gov/sites/entrez?db=genome&cmd=Retrieve&dopt=Overview&list_uids=530). The genome of the HB27 strain consists of a chromosome (1.89 Mb) and a megaplasmid (0.23 Mb), while that of the HB8 strain includes a plasmid (9.3 kb) coupled with a chromosome (1.85 Mb) and a megaplasmid (0.26 Mb) (13; see also the NCBI website [above]). This organism has attracted attention as one of the model organisms for genetic manipulation, structural genomics, and systems biology (9, 44). In the case of the HB8 strain, the Structural and Functional Whole-Cell Project for T. thermophilus HB8, which aims to understand the mechanisms of all the biological phenomena occurring in the HB8 cell by investigating the cellular components at the atomic level on the basis of their three-dimensional (3-D) structures, is in progress (44). In addition to the stability and ease of crystallization of thermophilic proteins, natural competency and an established genetic engineering system add value to T. thermophilus HB8 as a model organism (12, 14, 23, 44). Thermostabilized resistances against antibiotics such as kanamycin (Km), hygromycin (Hm), and bleomycin (Bm), which were developed by directed evolution, have also encouraged the system (5, 6, 16, 29; Y. Koyama, unpublished data).However, we had been puzzled about several gene disruptions in T. thermophilus HB8 that resulted from replacement with the drug resistance gene. Even if drug-resistant transformants were obtained, the target gene of the transformants had not often been deleted. The target gene, probably an essential gene, seemed to coexist with the drug resistance gene. A similar phenomenon has been reported in the deletion of the recJ gene in Deinococcus radiodurans (7). Repeated observation of this phenomenon suggested that T. thermophilus HB8 might possess multiple genomic copies. Many bacteria, including the most-studied bacteria Escherichia coli and Bacillus subtilis, essentially carry a single genomic copy per cell and are genetically haploid organisms (3, 10, 42, 43). On the other hand, several bacteria have been proposed to be polyploid, harboring multiple genomic copies per cell. They include Buchnera species (21, 22), Blattabacterium species (24), Epulopiscium species (1, 4), Borrelia hermsii (20), Azotobacter vinelandii (28, 35), Neisseria gonorrhoeae (41), D. radiodurans (11, 27), a few Lactococcus lactis laboratory strains (26), and many cyanobacteria (2, 25, 37). In particular, D. radiodurans, an extremely radioresistant bacterium, has been suggested to be closely related to the genus Thermus by comparative genomic analysis (13, 32). The radioresistant bacterium carries four genome copies per cell in the stationary phase and up to 10 copies per cell during exponential growth (11, 27). In contrast with this well-known polyploidy of D. radiodurans, no report on the genomic copy number of Thermus has been done, in spite of the attention it has received as a model organism. Therefore, in this paper, the potential polyploidy and the genomic copy number were first studied in T. thermophilus HB8.     

Vertical Distribution of Ammonia-Oxidizing Crenarchaeota and Methanogens in the Epipelagic Waters of Lake Kivu (Rwanda-Democratic Republic of the Congo)

Four stratified basins in Lake Kivu (Rwanda-Democratic Republic of the Congo) were sampled in March 2007 to investigate the abundance, distribution, and potential biogeochemical role of planktonic archaea. We used fluorescence in situ hybridization with catalyzed-reported deposition microscopic counts (CARD-FISH), denaturing gradient gel electrophoresis (DGGE) fingerprinting, and quantitative PCR (qPCR) of signature genes for ammonia-oxidizing archaea (16S rRNA for marine Crenarchaeota group 1.1a [MCG1] and ammonia monooxygenase subunit A [amoA]). Abundance of archaea ranged from 1 to 4.5% of total DAPI (4′,6-diamidino-2-phenylindole) counts with maximal concentrations at the oxic-anoxic transition zone (∼50-m depth). Phylogenetic analysis of the archaeal planktonic community revealed a higher level of richness of crenarchaeal 16S rRNA gene sequences (21 of the 28 operational taxonomic units [OTUs] identified [75%]) over euryarchaeotal ones (7 OTUs). Sequences affiliated with the kingdom Euryarchaeota were mainly recovered from the anoxic water compartment and mostly grouped into methanogenic lineages (Methanosarcinales and Methanocellales). In turn, crenarchaeal phylotypes were recovered throughout the sampled epipelagic waters (0- to 100-m depth), with clear phylogenetic segregation along the transition from oxic to anoxic water masses. Thus, whereas in the anoxic hypolimnion crenarchaeotal OTUs were mainly assigned to the miscellaneous crenarchaeotic group, the OTUs from the oxic-anoxic transition and above belonged to Crenarchaeota groups 1.1a and 1.1b, two lineages containing most of the ammonia-oxidizing representatives known so far. The concomitant vertical distribution of both nitrite and nitrate maxima and the copy numbers of both MCG1 16S rRNA and amoA genes suggest the potential implication of Crenarchaeota in nitrification processes occurring in the epilimnetic waters of the lake.Lake Kivu is a meromictic lake located in the volcanic region between Rwanda and the Democratic Republic of the Congo and is the smallest of the African Great Rift Lakes. The monimolimnion of the lake contains a large amount of dissolved CO₂ and methane (300 km³ and 60 km³, respectively) as a result of geological and biological activity (24, 73, 85). This massive accumulation converts Lake Kivu into one of the largest methane reservoirs in the world and into a unique ecosystem for geomicrobiologists interested in the methane cycle and in risk assessment and management (34, 71, 72, 85). Comprehensive studies on the diversity and activity of planktonic populations of both large and small eukaryotes and their trophic interplay operating in the epilimnetic waters of the lake are available (33, 39, 49). Recent surveys have also provided a deeper insight into the seasonal variations of photosynthetic and heterotrophic picoplankton (67, 68), although very few data exist on the composition, diversity, and spatial distribution of bacterial and archaeal communities. In this regard, the studies conducted so far of the bacterial/archaeal ecology in Lake Kivu have been mostly focused on the implications on the methane cycle (34, 73), but none have addressed the presence and distribution of additional archaeal populations in the lake.During the last few years, microbial ecology studies carried out in a wide variety of habitats have provided compelling evidence of the ubiquity and abundance of mesophilic archaea (4, 10, 13, 19). Moreover, the discovery of genes encoding enzymes related to nitrification and denitrification in archaeal metagenomes from soil and marine waters (29, 86, 88) and the isolation of the first autotrophic archaeal nitrifier (40) demonstrated that some archaeal groups actively participate in the carbon and nitrogen cycles (56, 64, 69). In relation to aquatic environments, genetic markers of ammonia-oxidizing archaea (AOA) of the marine Crenarchaeota group 1.1a (MCG1) have consistently been found in water masses of several oceanic regions (6, 14, 17, 26, 28, 30, 37, 42, 51, 52, 89), estuaries (5, 9, 26, 53), coastal aquifers (26, 66), and stratified marine basins (15, 41, 44). Although less information is available for freshwater habitats, recent studies carried out in oligotrophic high-mountain and arctic lakes showed an important contribution of AOA in both the planktonic and the neustonic microbial assemblages (4, 61, 89).The oligotrophic nature of Lake Kivu and the presence of a well-defined redoxcline may provide an optimal niche for the development of autotrophic AOA populations. Unfortunately, no studies of the involvement of microbial planktonic populations in cycling nitrogen in the lake exist, and only data on the distribution of dissolved inorganic nitrogen species in relation to phytoplankton ecology (67, 68) and nutrient loading are available (54, 58). Our goals here were to ascertain whether or not archaeal populations other than methane-related lineages were relevant components of the planktonic microbial community and to determine whether the redox gradient imposed by the oxic-anoxic interphase acts as a threshold for their vertical distribution in epipelagic waters (0- to 100-m depth). To further explore the presence and potential activity of nitrifying archaeal populations in Lake Kivu, samples were analyzed for the abundance and vertical distribution of signature genes for these microorganisms, i.e., the 16S rRNA of MCG1 and the ammonia monooxygenase subunit A (amoA) gene by quantitative PCR.     

Species-Specific Cell Wall Binding Affinity of the S-Layer Proteins of Mosquitocidal Bacterium Bacillus sphaericus C3-41

The binding affinities and specificities of six truncated S-layer homology domain (SLH) polypeptides of mosquitocidal Bacillus sphaericus strain C3-41 with the purified cell wall sacculi have been assayed. The results indicated that the SLH polypeptide comprised of amino acids 31 to 210 was responsible for anchoring the S-layer subunits to the rigid cell wall layer via a distinct type of secondary cell wall polymer and that a motif of the recombinant SLH polypeptide comprising amino acids 152 to 210 (rSLH_152-210) was essential for the stable binding of the S-layer with the bacterial cell walls. The quantitative assays revealed that the K_D (equilibrium dissociation constant) values of rSLH_152-210 and rSLH_31-210 with purified cell wall sacculi were 1.11 × 10⁻⁶ M and 1.40 × 10⁻⁶ M, respectively. The qualitative assays demonstrated that the SLH domain of strain C3-41 could bind only to the cell walls or the cells treated with 5 M guanidinium hydrochloride of both toxic and nontoxic B. sphaericus strains but not to those from other bacteria, indicating the species-specific binding of the SLH polypeptide of B. sphaericus with bacterial cell walls.Crystalline bacterial cell surface layers (S-layers) cover the cell surfaces of many bacteria and archaea during all stages of growth and division. S-layers are composed of identical protein or glycoprotein subunits, which can assemble into two-dimensional crystalline arrays and exhibit oblique, square, or hexagonal symmetry (27, 28, 30). S-layers play key roles in the interaction between bacterial cells and environment as protective coats, molecular sieves, ion traps, cell adhesion mediators, and attachment structures (4, 21, 26, 29). Many S-layer proteins possess an N-terminal region with highly conserved amino acid sequences, which is called an S-layer homology (SLH) domain. An SLH domain contains one, two, or three repeating SLH motifs (6, 16). Each SLH motif is composed of about 55 amino acids containing 10 to 15 conserved residues (6, 17). It is suggested that the SLH domain of S-layer proteins is responsible for the binding of the S-layer subunits to the rigid cell wall layer (6, 15, 17, 19, 25), while the middle and C-terminal parts include the domains which are involved in the self-assembly process (27). In the case of Bacillaceae, secondary cell wall polymers (SCWP) are responsible for binding with SLH domains (13, 18, 19), but the SLH domains of some other bacteria have an affinity for peptidoglycan (33).Bacillus sphaericus is a gram-positive soil bacterium that represents a strictly aerobic group of mesophilic endospore-forming bacteria. Due to its specific toxicity to target mosquito larvae and the limited environment impact, some strains of this bacterium have been successfully used worldwide in integrated mosquito control programs. Previous studies revealed that some nontoxic strains of B. sphaericus contained S-layer proteins, and the S-layer proteins of B. sphaericus NCTC 9602, JG-A12, P1, and CCM 2177 have been studied in detail elsewhere (3, 7-9, 12, 22).B. sphaericus C3-41, a highly active strain isolated from a mosquito-breeding site in China in 1987, has different levels of toxicity against Culex spp., Anopheles spp., and Aedes spp. This strain belongs to the flagella serotype H5a5b, like strains 2362 and 1593 (32), and it has been developed as a commercial larvicide (JianBao) for mosquito larva control in China during the last decade (31). The genomic analysis of strain C3-41 revealed that an S-layer protein gene (slpC) (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"EF535606","term_id":"145975949","term_text":"EF535606"}}EF535606) exists on the chromosomal genome and its sequence is identical to the S-layer protein of B. sphaericus 2362 (1, 10), composed of 3,531 bp encoding a protein of 1,176 amino acids with a molecular size of 125 kDa. Although the binding function of S-layers has been identified in some nontoxic B. sphaericus strains (6, 11), it is not well documented in mosquitocidal B. sphaericus strains, and there are few reports on the binding function of each SLH motif and the binding specificity.In this study, the binding affinities and specificities of each SLH motif of S-layer protein from mosquitocidal B. sphaericus C3-41 alone and in combination with the different cell wall preparations have been investigated, and the species-specific binding of SLH polypeptide with bacterial cell walls has been demonstrated.