Base composition analysis of human mitochondrial DNA using electrospray ionization mass spectrometry: a novel tool for the identification and differentiation of humans

In traditional approaches, mitochondrial DNA (mtDNA) variation is exploited for forensic identity testing by sequencing the two hypervariable regions of the human mtDNA control region. To reduce time and labor, single nucleotide polymorphism (SNP) assays are being sought to possibly replace sequencing. However, most SNP assays capture only a portion of the total variation within the desired regions, require a priori knowledge of the position of the SNP in the genome, and are generally not quantitative. Furthermore, with mtDNA, the clustering of SNPs complicates the design of SNP extension primers or hybridization probes. This article describes an automated electrospray ionization mass spectrometry method that can detect a number of clustered SNPs within an amplicon without a priori knowledge of specific SNP positions and can do so quantitatively. With this technique, the base composition of a PCR amplicon, less than 140 nucleotides in length, can be calculated. The difference in base composition between two samples indicates the presence of an SNP. Therefore, no post-PCR analytical construct needs to be developed to assess variation within a fragment. Of the 2754 different mtDNA sequences in the public forensic mtDNA database, nearly 90% could be resolved by the assay. The mass spectrometer is well suited to characterize and quantitate heteroplasmic samples or those containing mixtures. This makes possible the interpretation of mtDNA mixtures (as well as mixtures when assaying other SNPs). This assay can be expanded to assess genetic variation in the coding region of the mtDNA genome and can be automated to facilitate analysis of a large number of samples such as those encountered after a mass disaster.     

A computational model of the human left-ventricular epicardial myocyte

A computational model of the human left-ventricular epicardial myocyte is presented. Models of each of the major ionic currents present in these cells are formulated and validated using experimental data obtained from studies of recombinant human ion channels and/or whole-cell recording from single myocytes isolated from human left-ventricular subepicardium. Continuous-time Markov chain models for the gating of the fast Na(+) current, transient outward current, rapid component of the delayed rectifier current, and the L-type calcium current are modified to represent human data at physiological temperature. A new model for the gating of the slow component of the delayed rectifier current is formulated and validated against experimental data. Properties of calcium handling and exchanger currents are altered to appropriately represent the dynamics of intracellular ion concentrations. The model is able to both reproduce and predict a wide range of behaviors observed experimentally including action potential morphology, ionic currents, intracellular calcium transients, frequency dependence of action-potential duration, Ca(2+)-frequency relations, and extrasystolic restitution/post-extrasystolic potentiation. The model therefore serves as a useful tool for investigating mechanisms of arrhythmia and consequences of drug-channel interactions in the human left-ventricular myocyte.     

Chemical biology studies on norrisolide

The cellular activity of norrisolide (7), a novel Golgi-vesiculating agent, was dissected as function of its chemical structure. This natural product induces irreversible vesiculation of the Golgi membranes and blocks protein transport at the level of the Golgi. The Golgi localization and fragmentation effects of 7 depend on the presence of the perhydroindane core, while the irreversibility of fragmentation depends on the acetyl group of 7. We show that fluorescent derivatives of norrisolide are able to localize to the Golgi apparatus and represent important tools for the study of the Golgi structure and function.     

Nearest-neighbor classifier as a tool for classification of protein families

Knowledge about protein function is essential in understanding the biological processes. A specific class or family of protein shares common structural and chemical properties amongst its member sequences. The set of properties that display its unique characteristics for clearly classifying a protein sequence into its corresponding protein family needs to be studied. Our study of these important properties conducted on four major classes of proteins namely Globins, Homeoboxes, Heat Shock proteins (HSP) and Kinase have shown that frequency of twenty naturally occurring amino acids, hydrophobic content of protein, molecular weight of protein, isoelectric point of protein, secondary structure composition of amino acid residues as helices, coils and sheets and the composition of helices, coils and sheets in the secondary structure topology plays a significant role in correctly classifying the protein into its corresponding class or family as indicated by the overall efficiency of Nearest Neighbor Classifier as 84.92%.     

Unconventional secretion of Acb1 is mediated by autophagosomes

Starving Dictyostelium discoideum cells secrete AcbA, an acyl coenzyme A–binding protein (ACBP) that lacks a conventional signal sequence for entering the endoplasmic reticulum (ER). Secretion of AcbA in D. discoideum requires the Golgi-associated protein GRASP. In this study, we report that starvation-induced secretion of Acb1, the Saccharomyces cerevisiae ACBP orthologue, also requires GRASP (Grh1). This highlights the conserved function of GRASP in unconventional secretion. Although genes required for ER to Golgi or Golgi to cell surface transport are not required for Acb1 secretion in yeast, this process involves autophagy genes and the plasma membrane t-SNARE, Sso1. Inhibiting transport to vacuoles does not affect Acb1 secretion. In sum, our experiments reveal a unique secretory pathway where autophagosomes containing Acb1 evade fusion with the vacuole to prevent cargo degradation. We propose that these autophagosome intermediates fuse with recycling endosomes instead to form multivesicular body carriers that then fuse with the plasma membrane to release cargo.     

Redundant Function of cmaA2 and mmaA2 in Mycobacterium tuberculosis cis Cyclopropanation of Oxygenated Mycolates

The Mycobacterium tuberculosis cell envelope contains a wide variety of lipids and glycolipids, including mycolic acids, long-chain branched fatty acids that are decorated by cyclopropane rings. Genetic analysis of the mycolate methyltransferase family has been a powerful approach to assign functions to each of these enzymes but has failed to reveal the origin of cis cyclopropanation of the oxygenated mycolates. Here we examine potential redundancy between mycolic acid methyltransferases by generating and analyzing M. tuberculosis strains lacking mmaA2 and cmaA2, mmaA2 and cmaA1, or mmaA1 alone. M. tuberculosis lacking both cmaA2 and mmaA2 cannot cis cyclopropanate methoxymycolates or ketomycolates, phenotypes not shared by the mmaA2 and cmaA2 single mutants. In contrast, a combined loss of cmaA1 and mmaA2 had no effect on mycolic acid modification compared to results with a loss of mmaA2 alone. Deletion of mmaA1 from M. tuberculosis abolishes trans cyclopropanation without accumulation of trans-unsaturated oxygenated mycolates, placing MmaA1 in the biosynthetic pathway for trans-cyclopropanated oxygenated mycolates before CmaA2. These results define new functions for the mycolic acid methyltransferases of M. tuberculosis and indicate a substantial redundancy of function for MmaA2 and CmaA2, the latter of which can function as both a cis and trans cyclopropane synthase for the oxygenated mycolates.Mycobacterium tuberculosis infection is an ongoing global health crisis. Alleviation of this crisis will require a multidisciplinary approach that must include new antibiotics active against M. tuberculosis. A growing body of literature implicates cell envelope lipids in the pathogenesis of M. tuberculosis infection (5-10, 14-15, 20). The enzymatic pathways that synthesize M. tuberculosis cell envelope lipids are the target of presently available antituberculosis antimicrobials and may be candidates for future antibiotic development.The mycolic acids of M. tuberculosis are alpha-alkyl, beta-hydroxy fatty acids which are 75 to 85 carbons in length (3). There are three classes of major mycolic acids: alpha-, methoxy-, and ketomycolates (Fig. ​(Fig.1).1). Whereas all mycobacteria synthesize mycolic acids, only pathogenic mycobacteria (for example, M. tuberculosis, M. leprae, M. avium, and M. bovis) produce significant quantities of mycolic acids with cyclopropane rings, three-member carbon rings which are added to the meromycolate chain (3). Alpha-mycolates have two cis cyclopropane rings, while methoxy- and ketomycolates have either a cis or trans cyclopropane ring at the proximal position, the latter with a distal methyl branch (Fig. ​(Fig.1).1). In contrast to the case with Escherichia coli, which encodes a single cyclopropane fatty acid synthase (CFAS) (16-17), the M. tuberculosis genome encodes a family of S-adenosyl methionine-dependent methyltransferases that modify cell envelope mycolic acids with methyl branches and cyclopropane rings. Despite substantial amino acid identity, systematic characterization of M. tuberculosis null mutants in each of these methyltransferases has revealed highly specific functions which were not revealed when the enzymes were overexpressed in M. smegmatis (12, 26, 28). Deletion of pcaA greatly reduces synthesis of the proximal cyclopropane ring of the alpha-mycolates (15), whereas deletion of mmaA2 greatly reduces the distal cyclopropane of the same lipid (13). Loss of mmaA2 also causes a mild impairment of methoxymycolate, but not ketomycolate, cis cyclopropanation (13). Similar genetic approaches established cmaA2 as the only trans cyclopropane synthase of oxygenated mycolates (14), while loss of mmaA3 abolishes methoxymycolates, a spontaneous mutation found in many M. bovis BCG strains (4, 11). Finally, deletion of mmaA4 abolishes synthesis of both methoxy- and ketomycolates (10). Recent chemical-genetic analysis of this enzyme family indicates that combined inhibition of their function is lethal to M. tuberculosis, strongly supporting an approach targeting this enzyme family for antimicrobial development (2, 8-19, 25).Open in a separate windowFIG. 1.Chemical structures of the major mycolic acids of M. tuberculosis. Cyclopropane rings and methyl branches are shown and annotated with the methyltransferase responsible for their synthesis.In addition to this essential role in combination, recent evidence implicates individual cyclopropane modifications as important determinants of M. tuberculosis host-pathogen interactions. Inactivation of pcaA causes attenuation of M. tuberculosis in the mouse model of infection while stimulating less-severe granulomatous pathology (15, 23). In contrast, deletion of cmaA2 has no effect on bacterial loads during mouse infection but causes hypervirulence while inducing more-severe granulomatous pathology (24). Inactivation of mmaA4, which leads to an absence of methoxy- and ketomycolates, causes a severe growth defect during the first 3 weeks of infection (10). All of these studies implicate the fine structure of mycolic acids in the pathogenesis of M. tuberculosis infection. One mechanism by which cyclopropanation mediates pathogenesis is through altered inflammatory activity of trehalose dimycolate (TDM), an inflammatory glycolipid. The cyclopropane content of TDM is a major determinant of its inflammatory activity, and this altered TDM is responsible for the virulence phenotypes of cyclopropane-deficient M. tuberculosis strains (9, 23-24).Despite major advances in our understanding of the biosynthesis and pathogenetic function of cyclopropanated mycolic acids through genetic approaches, the methyltransferase(s) that synthesizes the cis cyclopropane ring on the methoxy- and ketomycolates is unknown. In addition, the function of the MmaA1 methyltransferase has not been explored through construction of a null mutant. Prior experiments found that overexpression of mmaA1 in M. tuberculosis resulted in accumulation of trans-unsaturated and -cyclopropanated oxygenated mycolates (27). These data suggested that MmaA1 acts in the biosynthesis of trans-cyclopropanated oxygenated mycolates either by adding the methyl branch distal to the cyclopropane ring or as a cis-trans isomerase or both. In addition, although there was a defect in cis cyclopropanation of methoxymycolates in the ΔmmaA2 strain, this defect was mild, suggesting redundancy with another unidentified enzyme. In this article, we define novel functions for three cyclopropane synthases using a new selectable marker to construct M. tuberculosis strains deficient in multiple mycolic acid methyltransferases. Through this approach, we show that CmaA2 and MmaA2 are redundant for cis cyclopropanation of the proximal position of the methoxymycolates and ketomycolates and that MmaA1 is upstream of CmaA2 in trans cyclopropanation.     

The mechanistic aspects in hydroxylation reactions catalyzed by fluorinated porphyrins of manganese and iron: Role of aqueous phosphate

The role of aqueous phosphate in the selective hydroxylation of cyclohexane to cyclohexanol (60-68% yields) and cyclohexene to 2-cyclohexene-1-ol (98% yield) has been discussed. Fluorinated porphyrins of manganese and iron were used as catalysts in acetonitrile with aqueous-K₂HPO₄ and t-BuOOH as co-catalyst and oxidant, respectively. The generation of the oxo-manganese reactive intermediate was identified by ¹H, ¹⁹F NMR, EPR, UV-Vis and mass spectral studies. The formation of phosphate adduct of the oxo-manganese reactive intermediates has been proposed on the basis of high binding constant of dipotassium hydrogen phosphate with the catalyst.