Global ETD Search

1	The intracellular targeting and regulation of PDE4 cyclic AMP-specific phosphodiesterase enzymes Peden, Alexander Howard January 2000 (has links) No description available. 572 Cyclic adenosine
2	IMPLICATIONS OF CYCLIC AMP-DEPENDENT PROTEIN KINASES AND POLYAMINE BIOSYNTHESIS IN THE REGULATION OF THE HYPOPHYSIAL-THYROID AXIS Combest, Wendell Lee January 1979 (has links) No description available. Thyroid hormones. Cyclic adenosine monophosphate.
3	CYCLIC AMP AND CYCLIC AMP-DEPENDENT PROTEIN KINASE IN CELL GROWTH PROCESSES Costa, Max January 1976 (has links) No description available. Enzymes. Cells. Cyclic adenosine monophosphate.
4	Inositol Trisphosphate and Cyclic Adenosine Diphosphate-Ribose Increase Quantal Transmitter Release at Frog Motor Nerve Terminals: Possible Involvement of Smooth Endoplasmic Reticulum Brailoiu, E., Miyamoto, M. D. 01 December 1999 (has links) The release of chemical transmitter from nerve terminals is critically dependent on a transient increase in intracellular Ca2+.6,25 The increase in Ca2+ may be due to influx of Ca2+ from the extracellular fluid15 or release of Ca2+ from intracellular stores such as mitochondria.1,8,18 Whether Ca2+ utilized in transmitter release is liberated from organelles other than mitochondria is uncertain. Smooth endoplasmic reticulum is known to release Ca2+, e.g., on activation by inositol trisphosphate or cyclic adenosine diphosphate-ribose,2 so the possibility exists that Ca2+ from this source may be involved in the events leading to exocytosis. We examined this hypothesis by testing whether inositol trisphosphate and cyclic adenosine diphosphate-ribose modified transmitter release. We used liposomes to deliver these agents into the cytoplasmic compartment and binomial analysis to determine their effects on the quantal components of transmitter release. Administration of inositol trisphosphate (10-4M) caused a rapid, 25% increase in the number of quanta released. This was due to an increase in the number of functional release sites, as the other quantal parameters were unaffected. The effect was reversed with 40min of wash. Virtually identical results were obtained with cyclic adenosine diphosphate-ribose (10-4M). Inositol trisphosphate caused a 10% increase in quantal size, whereas cyclic adenosine diphosphate-ribose had no effect. The results suggest that quantal transmitter release can be increased by Ca2+ released from smooth endoplasmic reticulum upon stimulation by inositol trisphosphate or cyclic adenosine diphosphate-ribose. This may involve priming of synaptic vesicles at the release sites or mobilization of vesicles to the active zone. Inositol trisphosphate may have an additional action to increase the content of transmitter within the vesicles. These findings raise the possibility of a role of endogenous inositol phosphate and smooth endoplasmic reticulum in the regulation of cytoplasmic Ca2+ and transmitter release. cyclic adenosine diphosphate-ribose frog neuromuscular junction inositol trisphosphate neurosecretion quantal transmitter release smooth endoplasmic reticulum
5	Characterization of Putative Mammalian Adenylyl Cyclase Inhibitors Using the Fission Yeast Schizosaccharomyces pombe Pacella, Daniel January 2022 (has links) Thesis advisor: Charles Hoffman / In both mammals and fission yeast, control of cAMP levels is maintained by adenylyl cyclases (ACs), which synthesize cyclic nucleotide, and by cyclic nucleotide phosphodiesterases (PDEs), which are responsible for its degradation. AC activity is regulated by G proteins, which respond to signals from G protein-coupled receptors (GPCRs) that detect extracellular signaling factors such as hormones. cAMP is a second messenger that has several effectors, with protein kinase A (PKA) being a primary target of activation that phosphorylates several downstream targets and results in modulation of pathways such as cell growth and gluconeogenesis. Aberrant cAMP regulation has been linked to several human disease states, such as McCune-Albright Syndrome, which is the result of elevated cAMP levels. Whereas the targeting of PDEs with drugs and selective inhibitors has been very successful, the AC-inhibiting compounds identified to date are unfavorable for clinical use. Inhibitors may not necessarily bind to and inhibit a given AC directly but instead act on a regulatory pathway such as calmodulin signaling. Theoretically, they also may bind to the G protein, interfere with the AC-G protein stimulatory complex, or regulate a factor of AC transcription. Since more than one AC species is expressed in many human cell types, it is difficult to selectively reduce cAMP levels. Therefore, for an AC inhibitor to be favored as a candidate for drug development, it is likely that the compound should directly bind to and inhibit the AC. This thesis describes my studies on a scaffold of 41 structurally related BCAC compounds, called the BCAC51 scaffold, that was identified in a high-throughput screen (HTS) with Schizosaccharomyces pombe strains transformed with GNAS and either mammalian AC4 or AC7. I carried out a series of experiments to examine whether the compounds bind to and inhibit mammalian ACs directly. The most active compounds were further characterized for potency and specificity against a panel of ACs. Several compounds significantly reduced cAMP production, but it could not be determined if the compounds directly or indirectly altered AC activity. I also cloned and constructed strains expressing the human wild-type AC5 gene and the AC5 R418W mutant, which has shown an increased sensitivity to GNAS. cAMP assays on these strains using various BCAC compounds showed that while most compounds had similar effects on both forms of AC5, BCAC62 was significantly more effective on the wild-type enzyme than on the mutant AC5, although the reason for this is unclear. To test whether the compounds could reduce AC activity in the absence of GNAS (basal activity), a flow cytometry study was carried out using a PKA-repressed GFP reporter. Results suggested that BCAC compounds do reduce basal-AC activity and therefore do not act by binding to and inhibiting GNAS, by interfering with the AC-GNAS stimulatory complex, nor by stimulating PDE. Finally, I developed a molecular genetic screen for mutant alleles of an AC gene that confer compound-resistance. One cycle of the screen is near completion, and the screen provides a foundation for future examination of compound-resistant AC candidates. The results presented in this thesis serve as a basis for further research into members of the BCAC51 compound series being putative direct inhibitors of mammalian ACs. / Thesis (BS) — Boston College, 2022. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Scholar of the College. / Discipline: Biology. Schizosaccharomyces pombe cyclic adenosine monophosphate mammalian adenylyl cyclase inhibitors McCune-Albright Syndrome pharmacology
6	Efficient and robust differentiation of endothelial cells from human induced pluripotent stem cells via lineage control with VEGF and cyclic AMP / VEGF及びcyclic AMP 投与による分化制御を利用したヒトiPS細胞からの高効率かつ高収量な血管内皮細胞分化誘導法の開発 Ikuno, Takeshi 25 September 2017 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20663号 / 医博第4273号 / 新制\|\|医\|\|1024(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授藤渕航, 教授木村剛, 教授岩田想 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM human endothelial cells human induced pluripotent stem cells cell differentiation stem cells cyclic adenosine monophosphate 490
7	Neuronal Growth Cone Dynamics are Regulated by a Nitric Oxide-Initiated Second Messenger Pathway. Welshhans, Kristy 01 October 2007 (has links) During development, neurons must find their way to and make connections with their appropriate targets. Growth cones are dynamic, motile structures that are integral to the establishment of appropriate connectivity during this wiring process. As growth cones migrate through their environment, they encounter guidance cues that direct their migration to their appropriate synaptic targets. The gaseous messenger nitric oxide (NO), which diffuses across the plasma membrane to act on intracellular targets, is a signaling molecule that affects growth cone motility. However, most studies have examined the effects of NO on growth cone morphology when applied in large concentrations and to entire cells. In addition, the intracellular second messenger cascade activated by NO to bring about these changes in growth cone morphology is not well understood. Therefore, this dissertation addresses the effects that a spatially- and temporally-restricted application of physiological amounts of NO can have on individual growth cone morphology, on the second messenger pathway that is activated by this application of NO, and on the calcium cascades that result and ultimately affect growth cone morphology. Helisoma trivolvis, a pond snail, is an excellent model system for this type of research because it has a well-defined nervous system and cultured neurons form large growth cones. In the present study, local application of NO to Helisoma trivolvis B5 neurons results in an increase in filopodial length, a decrease in filopodial number, and an increase in the intracellular calcium concentration ([Ca2+]i). In B5 neurons, the effects of NO on growth cone behavior and [Ca2+]i are mediated via sGC, protein kinase G, cyclic adenosine diphosphate ribose, and ryanodine receptor-mediated intracellular calcium release. This study demonstrates that neuronal growth cone pathfinding in vitro is affected by a single spatially- and temporally-restricted exposure to NO. Furthermore, NO acts via a second messenger cascade, resulting in a calcium increase that leads to cytoskeletal changes. These results suggest that NO may be a signal that promotes appropriate pathfinding and/or target recognition within the developing nervous system. Taken together, these data indicate that NO may be an important messenger during the development of the nervous system in vivo. filopodia protein kinase G soluble guanylyl cyclase growth cone calcium ryanodine receptor cyclic adenosine diphosphate ribose nitric oxide helisoma trivolvis Biology, general
8	Organic dust-induced signaling in human pulmonary epithelial cells : emphasis on effects of cAMP modulation / Burvall, Karin, January 2005 (has links) (PDF) Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 5 uppsatser.
9	Cyclic AMP In Mycobacteria Adenylyl Cyclases And Cyclic AMP Receptor Proteins Sharma, Ritu 09 1900 (has links) (PDF) The discovery of cyclic AMP (cAMP), nearly 50 years ago by Sutherland radically altered the appreciation of metabolic regulation. Since then the presence of cAMP and its tremendous physiological impact has been demonstrated in many prokaryotic systems. In fact, virulence mechanisms of several pathogens known today exploit cAMP dependent pathways. Interestingly the genome of Mycobacterium tuberculosis H37Rv, the causative agent of tuberculosis, encodes as many as 16 adenylyl cyclases (enzymes that convert ATP to 3’, 5’-cAMP) and 10 cyclic-nucleotide binding proteins. Recent reports show that bacterial-derived cAMP manipulates host signaling for bacterial survival, suggesting an important role for cAMP in the pathogenesis of M. tuberculosis. A large number of non-pathogenic species of mycobacteria also share and conserve several of these cAMP metabolism genes, suggesting that cAMP is not only important for pathogenesis but also may play a critical physiological role in the genus. The work carried out in this thesis aims at a better understanding of the role of cAMP by studying the adenylyl cyclases and cyclic AMP receptor proteins (CRPs) from Mycobacterium smegmatis, a non-pathogenic member of the genus. Intracellular cAMP levels in a cell are precisely maintained by modulating the activities of the adenylyl cyclases (cAMP synthesising enzymes), the phosphodiesterases (cAMP hydrolysing enzymes) and the secretion machinery, if any. To assess the role of cAMP in mycobacteria, cAMP levels were measured in M. smegmatis during growth and under various stress conditions. The results show that cAMP levels peak at log phase of growth and decline thereafter. Under acidic conditions or on perturbing the cell-wall, cellular cAMP levels are altered, which indicate a possible role of cAMP in stress adaptation. Earlier work in our laboratory has led to the identification of multiple adenylyl cyclases in the mycobacterial genomes. These cyclases are similar in sequence to the mammalian enzymes and several of them have been shown to be active in vitro displaying a diverse range of biochemical properties. The M. smegmatis genome encodes 10 adenylyl cyclase-like genes. In order to understand the role of cAMP in M. smegmatis, individual cyclases were analysed for their biochemical properties and physiological functions. The work presented in this thesis is concerned with the functional characterization of MSMEG_3578 and MSMEG_3780, two of the several adenylyl cyclases from M. smegmatis. MSMEG_3578 encodes for a protein that comprises two transmembrane domains, an extracellular receptor-like domain, a membrane anchoring HAMP domain and an intracellular cyclase domain. The cyclase domain is closely related to mammalian cyclases but lacks the canonical residues that are critical for the catalysis of class III cyclases. Interestingly, the stop codon of this gene overlaps with the start codon of the downstream gene, MSMEG_3579 (a putative cyclic nucleotide gated mechanosensitive ion channel), suggesting a functional link between the two genes. The conservation of this gene pair across the mycobacterial genus indicates the importance of this putative receptor-effector pair in the physiology of mycobacteria. Additionally, microarray analysis by various groups have shown that this gene pair in Mycobacterium tuberculosis is differentially regulated in conditions that mimic stress the bacteria may experience during infection. In order to ascertain the physiological role of MSMEG_3578, a knock-out M. smegmatis strain was generated and tested for growth and cAMP defects. The knock-out strain showed growth and cAMP profiles similar to the wild-type strain. Over-expression of MSMEG_3578 in M. smegmatis resulted in a significant rise in cAMP levels. Interestingly, over-expression of the MSMEG_3578 adenylyl cyclase in E. coli did not lead to an elevation in cAMP levels indicating that other mycobacterial proteins may be required for the activity of MSMEG_3578 in vivo. In agreement with this, the purified adenylyl cyclase domain of MSMEG_3578 was found to be biochemically inactive in vitro. Additionally, the over-expressing strain has altered colony morphology as compared to the wild type strain. Perturbation of cAMP levels by over-expression of other cyclases also leads to a similar colony morphology phenotype, indicating the phenotype to be controlled by cAMP in general rather than by a specific cyclase in the cell. MSMEG_3780 is a highly conserved, biochemically active adenylyl cyclase, speculated to play a house-keeping function in M. smegmatis. Its orthologs from M. tuberculosis (Rv1647) and M. leprae (ML1399) have been biochemically characterized earlier in our laboratory. To unravel the role of this gene in vivo, the ∆MSMEG_3780 strain was tested for growth and cAMP defects under various conditions. The deletion strain did not show any difference in growth rate or morphology when compared to the wild-type strain. However it showed a reduction in intracellular cAMP levels at the log-phase of growth. Reintroduction of the MSMEG_3780 gene in the deletion strain restored cAMP to wild-type levels, thus indicating a crucial role for this adenylyl cyclase in the maintenance of intracellular cAMP levels during logarithmic growth. In order to investigate the regulation of the MSMEG_3780 gene, its promoter activity was tested under various stress-conditions. Acid-stress specifically resulted in the repression of the MSMEG_3780 promoter activity, a condition which also leads to a decrease in cAMP levels in the cells. Further evidence for the susceptibility of the MSMEG_3780 gene to acid-stress was obtained when the ∆MSMEG_3780 strain failed to reduce intracellular cAMP content upon sustained acid-stress conditions. Since Rv1647 shares similar biochemical properties with MSMEG_3780 and can also heterodimerize with the MSMEG_3780 protein in vitro, it was interesting to test whether the M. tuberculosis ortholog could functionally complement MSMEG_3780. To assess this, a complement strain was generated that contained the Rv1647 gene under the control of MSMEG_3780 promoter, integrated into the genome of ∆MSMEG_3780 strain. Rv1647 protein was able to restore the cAMP phenotype seen on acid stress as well as the cAMP levels in the mutant strain at the log phase of growth. This study indicated the role of cAMP and MSMEG_3780 in acid adaptation and also suggested a non-redundancy of adenylyl cyclases in mycobacteria, where different individual cyclases may have unique functions in the cells. Since Rv1647 could complement the cAMP defective phenotype in ∆MSMEG_3780, this suggests functional parallels between the proteins from the two species. Bacterial adaptation to environmental stress is brought about by a rapid change in its gene expression profile. Cyclic AMP plays an important role by binding to and activating a transcriptional factor, cAMP receptor protein or CRP. We have identified two CRPs from M. smegmatis, viz., MSMEG_0539 and MSMEG_6189 that possess high similarity at the amino acid level (78% overall sequence identity). The CRP ortholog from M. tuberculosis, Rv3676 has been characterized structurally, biochemically and functionally earlier. Western blot and RT-PCR analyses showed that CRPs in M. smegmatis were present during all phases of growth. Both the CRPs were cloned, expressed and shown to bind cAMP. Since the DNA binding domains of Rv3676 and the two M. smegmatis CRPs are nearly identical, the CRPs from M. smegmatis were predicted to bind similar target sequences. Interestingly, a CRP site was identified in the promoter of the MSMEG_3780 gene, suggesting a possible feed-forward or feed-back loop, where the enzymatic product of the adenylyl cyclase now governs its own gene expression. We performed Electrophoretic Mobility Gel Shift Assays (EMSAs) with M. smegmatis lysates to show that CRP binds to the MSMEG_3780 promoter at the CRP site. Subsequent Chromatin Immunoprecipitation (ChIP) assays confirmed that CRP binding to the MSMEG_3780 promoter occurred in vivo. To investigate the role of CRP in the regulation of the MSMEG_3780 gene, luciferase reporter assays with the wild-type and CRP site mutant promoters were carried out. Results suggest that CRP regulates the MSMEG_3780 gene under osmotic stress. However, CRP did not play any role in basal expression of MSMEG_3780 during growth. To assess which CRP of the two is functionally linked to the MSMEG_3780 promoter, we carried out a footprint assay with purified CRPs. It was intriguing to note that both the CRPs were in fact able to bind the promoter albeit under different conditions. Whereas MSMEG_6189 bound the promoter both in the presence and absence of cAMP, MSMEG_0539 bound the promoter only in the presence of cAMP. MSMEG_6189 thus deviates from the accepted CRP paradigm that seeks an absolute requirement of cAMP for specific DNA binding. The present study identifies cAMP as an important stress signal in M. smegmatis. Using MSMEG_3780 as a model gene, the role of cAMP in mycobacteria was studied. The two divergent CRPs that were characterized may function and dictate cAMP-mediated and perhaps independent functions in cells. Taken together, our results provide compelling evidence for the important role of cAMP in the general physiology and stress adaptation in M. smegmatis. Receptor Proteins Mycobacteria Signal Transduction Adenylyl Cyclases Cyclic AMP Receptor Proteins Mycobacterium Smegmatis cAMP 3',5'-cyclic Adenosine Monophosphate M. smegmatis Biochemistry
10	Metallophosphoesterases In Mycobacteria Enigmatic Roles In Regulating Mycobacterial Physiology Mattoo, Rohini 11 1900 (has links) (PDF) Pathogenic bacteria such as M.tuberculosis have evolved several mechanisms to aid their intracellular survival and subvert host defenses. One of the contributing factors is thought to be the production and secretion of large amount of cAMP, Mycobacterial genomes encode a large number of adenylyl cyclases distinct in their structure and regulatory mechanisms. The roles of these enzymes in the physiology and pathogenesis of virulent mycobacteria are only now being elucidated. The roles of phosphodiesterases (PDEs), which serve to lower cAMP levels through degradation are, however, relatively unexplored. The Rv0805 gene was previously shown to code for an active phosphodiesterase from Mycobacterium tuberculosis. Bioinformatics analysis revealed that orthologs of Rv0805 were found even in eukaryotes. Biochemical and structural characterization of Rv0805 revealed that it was a class III cAMP phosphodiesterase. Comparative genomics identified a close ortholog of Rv0805 in M. leprae (ML2210). The genome of M. leprae Encodes only 1,604 predicted proteins and possesses the highest number of pseudogenes, 1,116. The retention of a functional PDE, the ortholog of Rv0805, in the minimal genome of M. leprae is indicative of its importance in cellular physiology. Biochemical characterization of proteins from M. leprae and use of heterologous hosts will help understand this human pathogen better, since there are no tools currently available to genetically manipulate this bacterium. Sequence analysis of ML2210 revealed the presence of conserved motifs and residues known to be critical for catalysis and unique to class III phosphodiesterases. ML2210 shares 83% sequence identity with Rv0805 and 24% sequence identity with the phosphodiesterase from E. coli (cpdA). In vitro biochemical characterization of ML2210 using non-nucleotide colorigenic and cyclic nucleotide substrates revealed that it was an enzymatically active phosphodiesterase. Kinetic parameters of ML2210 with respect ot colorigenic substrates revealed that its catalytic properties were similar to that of Rv0805. However, with respect to hydrolysis of 3’, 5’-cAMP, ML2210 was catalytically more efficient than Rv0805, suggesting that in spite of being orthologs, these enzymes have evolved distinct specificities at their active site. A parallel of monoclonal antibodies raised to Rv0805 was also used understand the differences in the biochemical properties of Rv0805 and ML2210 better. It was observed that only one monoclonal antibody was able to recognize ML2210 by ELISA and not by Western blot analysis. These results revealed that conformational differences between ML2210 and Rv0805 exist. Over-expression of ML2210 in M. smegmatis resulted in a modest decrease in intracellular cAMP levels. Despite the absence of a predicted transmembrane region or a membrane-targeting signal, ML2210 localized to the cell envelop fraction upon over expression in M. smegmatis. Moreover, like Rv0805, over-expression of ML2210 also resulted in perturbation of the cell wall of M. smegmatis, arguing for additional cellular roles of this protein. Orthologs of Rv0805 or ML2210 are found only in slow growing mycobacteria suggesting that other cyclic nucleotide phosphodiesterases could regulate cAMP levels in fast growing mycobacteria like M. smegmatis. Since BLAST results did not retrieve an ortholog of Rv0805 or ML2210, COG1409 (COG database) containing Rv0805 was examined for the presence of other mycobacterial phosphodiesterases. Bioinformatics analysis identified Rv2795c as another PDE from M. tuberculosis. Sequence analysis of Rv2795c revealed the presence of all the motifs conserved in the class III PDEs but Rv2795c shared only 22% sequence identity with Rv0805 and 19% sequence identity with CpdA. Importantly, an ortholog of Rv2795c was identified in M. leprae. Interestingly. Rv2795c and its orthologs branched away from Rv0805, making it phylogenetically distinct and hence warranting further characterization. Recombinant, purified MSMEG_2647 (the Rv2795c ortholog from M. smegmatis) was able to hydrolyze cyclic nucleotides and other phosphodiester substrates in vitro. The Km for colorigenic substrates was higher when compared to the Km of ML2210 or Rv0805 for these substrates. However, the kinetic parameters of MSMEG_2647 for cyclic nucleotides were comparable to those of ML2210 or Rv0805. MSMEG_2647 was a metal dependent enzyme and among the panel of metals tested, Mn2+ supported the highest in vitro catalytic activity of MSMEG_2647. Zn2+ inhibited the catalytic activity of MSMEG_2647. In order to gain insight into the catalysis of MSMEG_2647, the end products of cAMP hydrolysis by MSMEG_2647 were analysed using reverse phase HPLC. The assay revealed that the end products of cyclic nucleotide hydrolysis by MSMEG_2647 were different when compared to the end products of hydrolysis of the same substrates by Rv0805 or ML2210. This suggests differences in the architecture of the active site residues of the mycobacterial MPEs. A mutational anlaysis of the active site residues in MSMEG_2647 was carried out to identify residues involved in substrate recognition and metal coordination. Although Rv0805 and MSMEG_2647 shared only a 22% sequence identity, MSMEG_2647 displayed strict conservation in the core MPE motifs. Mutation of the active residues N97 and H98 in Rv0805 had led to an abrogation of its catalytic activity. However, corresponding mutations of N76A and H77A in MSMEG_2647, did not lead to a loss in its catalytic activity. A third mutation known to be important for the catalytic activity of Rv0805 (D19) was incorporated. The corresponding residue at D19 position was mutated to an alanine. The catalytic activity of MSMEG_2647D19AN76AH77A mutant was abrogated, suggesting that while the core MPE motifs are conserved between mycobacterial PDEs, differences in the ensemble of the active site residues contributing to their catalytic activity exist. Thus, at least two biochemically diverse PDE clades are found in mycobacterial species. In order to decipher the function of MSMEG_2647, its expression was monitored during the growth of M. Smegmatis. The promoter of MSMEG_2647 displayed maximum activity during the logarithmic phase of M. smegmatis growth after which its activity declined as M. smegmatis entered the stationary phase. However in contrast to this, the transcript corresponding to msmeg_2647 mRNA was found at both logarithmic and stationary phases. The MSMEG_2647 protein was also detected at both logarithmic and stationary phases of M. smegmatis. These results suggest that additional factors may contribute to the stability of msmeg_2647 mRNA and protein levels. Localization studies of MSMEG_2647 revealed that MSMEG_2647 was present in the cytosol as well as in the cell envelope fractions. Interestingly, over-expression of MSMEG_2647 did not result in a significant increase in PDE activity in various subcellular fractions, suggesting tight regulation on the in vivo activity in various subcellular fractions, suggesting tight regulation on the in vivo activity of MSMEG_2647. In addition, over-expression of MSMEG_2647 in M. smegmatis led to only a modest decrease in cAMP levels in M. smegmatis. These results suggested additional roles of MSMEG_2647 in the biology of mycobacteria. Overexpression of MSMEG_2647 peturbed the integrity of cell wall as assessed by the use of lipophillic indicators of cell growth, crystal violet and malachite green, and a cell wall targeting antibiotic, isoniazid. Analyzing the gene neighborhood of MSMEG_2647 provided an insight into its putative function. It was observed that the stop codon of msmeg_2647 overlapped with the start codon of msmeg_2648 and stop codon of msmeg-2648 overlapped with the start codon of msmeg_2649. RT PCR was carried out at logarhtimic and stationary phases of M. smegmatis growth, which revealed that a polycistronic mRNA was being transcribed. These results confirmed that msmeg_2647, msmeg_2648 and msmeg_2649 were a part of an operon. Interestingly, these three genes as a gene cluster were confined to only those actinobacteria that produced mycolic acids. An operon often encodes products that form multiprotein complexes and operate in a common pathway. Since there were a part of an operon, a GST pull-down approach was employed to test if MSMEG_2647, MSMEG_2648 and MSMEG_2649 could physically interact. It was observed that MSMEG_2647 interacted with MSMEG_2648 and MSMEG_2649. MSMEG_2648 in turn interacted with MSMEG_2649. A role for MSMEG_2647 as a scaffold recruiting MSMEG_2648 and MSMEG_2649 is therefore proposed. In turn, a complex formation with these proteins may regulate the activity of MSMEG_2647. Attempts to generate a knock out of msmeg_2647 in M. smegmatis by homologous recombination were not successful suggesting either the gene was essential or a polar effect on msmeg_2648(an essential gene for the viability of M. smegmatis) may not allow msmeg_2647 to be deleted from the genome of M. smegmatis. In summary, this study has identified and characterized two new phosphodiesterases from mycobacteria, one from the pathogenic mycobacterium, M. leprae and the other, a PDE from M. smegmatis that is conserved in all species of mycobacteria. Several, key biochemical differences were observed using biochemical and biological approaches. It appears that the cellular roles of mycobacterial phsophodiesterases may extend beyond cAMP hydrolysis, with these proteins not only regulating cell wall properties but also acting as scaffolding proteins in the cell. Metallophosphoesterase Mycobacterial Physiology Mycobacterial Phosphodiesterases Cyclic Nucleotide Signaling Mycobacteria - Pathogenesis Mycobacterium Leprae Mycobacterium Smegmatis Cyclic Adenosine Phosphate Signaling Cyclic Nucleotide Phosphodiesterases M. lepre M. Smegmatis Bacteriology

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