Disruption of msl3 abolishes the synthesis of mycolipanoic and mycolipenic acids required for polyacyltrehalose synthesis in Mycobacterium tuberculosis H37Rv and causes cell aggregation

Cell wall lipids of Mycobacterium tuberculosis containing multiple methylbranched fatty acids play critical roles in pathogenesis and thus offer targets for new antimycobacterial drugs. Mycocerosicacid synthase gene (mas) encodes the enzyme that produces one class of such acids. Seven mas-like genes (msls) were identified in the genome. One of them, msl3, originally annotated as two separate genes, pks 3 and pks 4, is now shown to constitute a single open reading frame, which encodes a 220.3 kDa protein. Msl3 was disrupted using a phage mediated delivery system and the gene replacement in the mutant was confirmed by polymerase chain reaction analysis of the flanking regions of the introduced disrupted gene and by Southern analysis. Biochemical analysis showed that the msl3 mutant does not produce mycolipanoic acids and mycolipenic(phthienoic) acids, the major constituents of polyacyl trehaloses and thus lacks this cell wall lipid, but synthesizes all of the other classes of lipids. The absence of the major acyl chains that anchor the surface-exposed acyltrehaloses causes a novel growth morphology; the cells stick to each other, most probably via the intercellular interaction between the exposed hydrophobic cell surfaces, manifesting a bead-like growth morphology without affecting the overall growth rate.     

Improved performance of preordered fungal protease-stearic acid biocomposites: enhanced catalytic activity,reusability, and temporal stability

In an earlier report on fungal protease (F-prot)-fatty acid biocomposite film formation [Gole et al. Anal. Chem. 2000, 72, 4301], it was observed that the biocatalytic activity of the immobilized enzyme was comparable to that of the free enzyme in solution. However, a somewhat negative aspect of the protocol was the steady loss in activity during reuse and storage of the biocomposite film. In this paper, we address the latter issues and demonstrate successful attempts toward the realization of efficient biocomposite films with enhanced biological activity, temporal stability, and excellent reusability. The improved performance of the F-prot-stearic acid biocomposite is accomplished by preordering the fatty acid film by incorporation of Pb(2+) ions into the lipid matrix prior to enzyme immobilization. The lead cation induces lamellar ordering in the lipid film and thus facilitates diffusion of the F-prot molecules into the lipid matrix and accessibility of the substrate molecules (hemoglobin, Hb) to the entrapped F-prot enzyme molecules. The preordering consequently leads to effective control of the "mass transport" problem and might be responsible for the enhanced biological activity ( approximately 36%) of the enzyme molecules in the biocomposite in comparison with the free enzyme in solution, as well the excellent reusability of the composite film. In addition to biocatalytic activity measurements, the formation and characterization of the F-prot-lead stearate biocomposite films was done by quartz crystal microgravimetry and X-ray diffraction.     

Gastric H-K-ATPase and acid-resistant surface proteins

Despite the fact that mucus and bicarbonate are important macroscopic components of the gastric mucosal barrier, severe acidic and peptic conditions surely exist at the apical membrane of gastric glandular cells, and these membranes must have highly specialized adaptations to oppose external insults. Parietal cells abundantly express the heterodimeric, acid-pumping H-K-ATPase in their apical membranes. Its beta-subunit (HKbeta), a glycoprotein with >70% of its mass and all its oligosaccharides on the extracellular side, may play a protective role. Here, we show that the extracellular domain of HKbeta is highly resistant to trypsin in the native state (much more than that of the structurally related Na-K-ATPase beta-subunit) and requires denaturation to expose tryptic sites. Native HKbeta also resists other proteases, such as chymotrypsin and V8 protease, which hydrolyze at hydrophobic and anionic amino acids, respectively. Removal of terminal alpha-anomeric-linked galactose does not appreciably alter tryptic sensitivity of HKbeta. However, full deglycosylation makes HKbeta much more susceptible to all proteases tested, including pepsin at pH <2.0. We propose that 1) intrinsic folding of HKbeta, 2) bonding forces between subunits, and 3) oligosaccharides on HKbeta provide a luminal protein domain that resists gastric lytic conditions. Protein folding that protects susceptible charged amino acids and is maintained by disulfide bonding and hydrophilic oligosaccharides would provide a stable structure in the face of large pH changes. The H-K-ATPase is an obvious model, but other gastric luminally exposed proteins are likely to possess analogous protective specializations.     

Studies on physiology,zoospore morphology and entomopathogenic potential of the aquatic oomycete: Lagenidium giganteum

The oomycete Lagenidium giganteum, a facultative parasite of mosquito larvae requires exogenous sterols for the genesis of zoospores when grown saprobically. Growth media prepared from oil rich materials such as soy or sunflower seed were very effective inducers of virulent zoospores. The external morphology of zoospores of L. giganteum was studied with the aid of philips scanning electron microscope 515. Zoospores were ovoid, bluntly pointed with the groove parallel to the long axis and 0.7 × 1.4 μm. Insect cell walls are known to contain lipid and chitin. L. giganteum was tested for chitinase activity and found to possess 0.76 ± SD0.14 chitinase activity. Use of oil seed for growth of the organism confirms phospholipase activity. Phospholipase production was studied further by egg-yolk plate method. Presence of these two key enzymes that can initiate host cell damage suggests the entomopathogenic potential of L. giganteum. L. giganteum failed to grow at 37 °C limiting its effectiveness in warmer climates. Introduction of this organism to variety of habitats with various mosquito species will demonstrate the efficacy of the organism as a bioinsecticide. This revised version was published online in June 2006 with corrections to the Cover Date.     

Slipped-strand DNAs formed by long (CAG)*(CTG) repeats: slipped-out repeats and slip-out junctions

The disease-associated expansion of (CTG)·(CAG) repeats is likely to involve slipped-strand DNAs. There are two types of slipped DNAs (S-DNAs): slipped homoduplex S-DNAs are formed between two strands having the same number of repeats; and heteroduplex slipped intermediates (SI-DNAs) are formed between two strands having different numbers of repeats. We present the first characterization of S-DNAs formed by disease-relevant lengths of (CTG)·(CAG) repeats which contained all predicted components including slipped-out repeats and slip-out junctions, where two arms of the three-way junction were composed of complementary paired repeats. In S-DNAs multiple short slip-outs of CTG or CAG repeats occurred throughout the repeat tract. Strikingly, in SI-DNAs most of the excess repeats slipped-out at preferred locations along the fully base-paired Watson–Crick duplex, forming defined three-way slip-out junctions. Unexpectedly, slipped-out CAG and slipped-out CTG repeats were predominantly in the random-coil and hairpin conformations, respectively. Both the junctions and the slip-outs could be recognized by DNA metabolizing proteins: only the strand with the excess repeats was hypersensitive to cleavage by the junction-specific T7 endonuclease I, while slipped-out CAG was preferentially bound by single-strand binding protein. An excellent correlation was observed for the size of the slip-outs in S-DNAs and SI-DNAs with the size of the tract length changes observed in quiescent and proliferating tissues of affected patients—suggesting that S-DNAs and SI-DNAs are mutagenic intermediates in those tissues, occurring during error-prone DNA metabolism and replication fork errors.     

Electrochemical and functional characterization of the proline dehydrogenase domain of the PutA flavoprotein from Escherichia coli

The multifunctional PutA flavoprotein from Escherichia coli is a peripherally membrane-bound enzyme that has both proline dehydrogenase (PDH) and Delta(1)-pyrroline-5-carboxylate dehydrogenase (P5CDH) activities. In addition to its enzymatic functions, PutA displays DNA-binding activity and represses proline catabolism by binding to the control region DNA of the put regulon (put intergenic DNA). Presently, information on structure-function relationships for PutA is derived from primary structure analysis. To gain further insight into the functional organization of PutA, our objective is to dissect PutA into different domains and to characterize them separately. Here, we report the characterization of a bifunctional proline dehydrogenase (PutA(669)) that contains residues 1-669 of the PutA protein. PutA(669) purifies as a dimer and has a PDH specific activity that is 4-fold higher than that of PutA. As anticipated, PutA(669) lacks P5CDH activity. At pH 7.5, an E(m) (E-FAD/E-FADH(-)) of -0.091 V for the two-electron reduction of PutA(669)-bound FAD was determined by potentiometric titrations, which is 15 mV more negative than the E(m) for PutA-bound FAD. The pH behavior of the E(m) for PutA(669)-bound FAD was measured in the pH range 6.5-9.0 at 25 degrees C and exhibited a 0.03 V/pH unit slope. Analysis of the DNA and membrane-binding properties of PutA(669) shows that it binds specifically to the put intergenic control DNA with a binding affinity similar to that of PutA. In contrast, we did not observe functional association of PutA(669) with membrane vesicles. We conclude that PutA(669) has FAD-binding and DNA-binding properties comparable to those of PutA but lacks a membrane-binding domain necessary for stable association with the membrane.     

Oligosaccharide and sucrose complexes of amylosucrase. Structural implications for the polymerase activity

The glucosyltransferase amylosucrase is structurally quite similar to the hydrolase alpha-amylase. How this switch in functionality is achieved is an important and fundamental question. The inactive E328Q amylosucrase variant has been co-crystallized with maltoheptaose, and the structure was determined by x-ray crystallography to 2.2 A resolution, revealing a maltoheptaose binding site in the B'-domain somewhat distant from the active site. Additional soaking of these crystals with maltoheptaose resulted in replacement of Tris in the active site with maltoheptaose, allowing the mapping of the -1 to +5 binding subsites. Crystals of amylosucrase were soaked with sucrose at different concentrations. The structures at approximately 2.1 A resolution revealed three new binding sites of different affinity. The highest affinity binding site is close to the active site but is not in the previously identified substrate access channel. Allosteric regulation seems necessary to facilitate access from this binding site. The structures show the pivotal role of the B'-domain in the transferase reaction. Based on these observations, an extension of the hydrolase reaction mechanism valid for this enzyme can be proposed. In this mechanism, the glycogen-like polymer is bound in the widest access channel to the active site. The polymer binding introduces structural changes that allow sucrose to migrate from its binding site into the active site and displace the polymer.     

Systematics of the Lutzomyia species of the verrucarum Theodor group, 1965 (Diptera: Psychodiadae)

The verrucarum group of phlebotomine sand flies includes vectors of Leishmania spp. and Bartonella bacilliformis, and from the perspective of public health is considered as one of the most important groups of neotropical phlebotomine sand flies. Due to marked morphological similarity among species constituting this group, the identification based on conventional taxonomic characters can be difficult. Consequently, the verrucarum group has been the focus of numerous taxonomic comparisons which have included the following methods: chaetotaxy, morphometry, larval spiracular system, chorionic structure, morphology of the genital atrium, cytogenetics, morphological phylogenetics, isoenzymes, random amplified polymorphic DNA, cuticular hydrocarbons, DNA probes, and nuclear and mitochondrial nucleotide sequences. Based on morphological characters of the male terminalia, the verrucarum group has been divided in four series, i.e., verrucarum, serrana, townsendi and pia. Since the revision of the group made by Young and Duncan in 1994, ten new species, principally of Andean origin, have been assigned to 3 of the series verrucarum (L. maranonensis, L. cajamarcensis, L. antioquiensis, L. falcaorum), serrana (L. robusta, L. guilvardae) and pia (L. suapiensis, L. tihuiliensis, L. tocaniensis, L. limafalcaoae). The total number of verrucarum group members is now 40. Explanations for this diversity of species include the isolation of ancestral populations in refugia of humid forest during the quaternary period, the Andean cordilleras as geographical barrier, and the appearance of the Isthmus of Panama. Biology systematics and evolution of the verrucarum group is reviewed with emphasis on the 19 species extant in Colombia.     

Purification,characterization and chemical modification studies on a translation inhibitor protein from Luffa cylindrica

A ribosome-inactivating protein (RIP), luffin has been isolated from the seeds of Luffa cylindrica of Cucurbitaceae family by ammonium sulfate fractionation followed by cation exchange and gel-filtration chromatography. Extensive physico-chemical, immunological and biological characterizations were carried out on luffin and compared with that of gelonin. The molecular mass of luffin was -28 kDa as determined by gel-filtration chromatography and SDS-PAGE. The epsilon-NH2 group(s) of luffin were sequentially modified by N-succinimidyl 6-[3-(2-pyridyldithio) propionamido] hexanoate (LC-SPDP), N-succinimidyl-3-(2-pyridylthio)propionate (SPDP) and 2-iminothiolane (2IT) and their effect on immunoreactivity and ribosome inactivating property was evaluated. Modification of single amino group resulted in about 80% inhibition of immunoreactivity and more than 90% loss of protein synthesis inhibition activity. Modification of 2-3 amino groups further hampered both immunoreactivity and protein-synthesis inhibition property LC-SPDP modification played more pronounced effects on immunoreactivity and RIP activity than that of SPDP. However, 2IT modification retained both the immunoreactivity and RIP activity of luffin-LC-SPDP substantially. SPDP showed more pronounced effect on immunoreactivity and RIP activity as compared to 2IT. Therefore, it seems that the positive charge on lysine residues plays an important role in immunological as well as protein synthesis inhibitory effect of luffin.     

Humor modulates the mesolimbic reward centers

Humor plays an essential role in many facets of human life including psychological, social, and somatic functioning. Recently, neuroimaging has been applied to this critical human attribute, shedding light on the affective, cognitive, and motor networks involved in humor processing. To date, however, researchers have failed to demonstrate the subcortical correlates of the most fundamental feature of humor-reward. In an effort to elucidate the neurobiological substrate that subserves the reward components of humor, we undertook a high-field (3 Tesla) event-related functional MRI study. Here we demonstrate that humor modulates activity in several cortical regions, and we present new evidence that humor engages a network of subcortical regions including the nucleus accumbens, a key component of the mesolimbic dopaminergic reward system. Further, the degree of humor intensity was positively correlated with BOLD signal intensity in these regions. Together, these findings offer new insight into the neural basis of salutary aspects of humor.