The metabolism of adenosine nucleotides in thoracic muscle mitochondria from the American cockroach

Mills, Richard Randolph

January 1964

Myokinase and three inorganic pyrophosphatases with pH optima of 6.4, 7.2 and 8.4 have been isolated and purified from the thoracic muscle mitochondria of the American cockroach. Myokinase was purified over 100-fold by heat and acid treatment, ammonium sulfate fractionation and column chromatography on G-75 sephadex. Some properties of the enzyme were determined. These include: a pH optimum of 5.8, an optimum Mg concentration of 3 x 10⁻³ M, a substrate specificity for ADP, and an equilibrium constant of 0.44. In addition, Km and Ki values were determined for each adenosine nucleotide, inhibition studies were conducted, and the enzyme was found to have the greatest stability against heat denaturation at a neutral pH. From the results obtained here it appears that the enzyme apyrase is not responsible for the rapid dephosphorylation of ATP. In addition, this study indicates that a specific triphosphatase coupled with myokinase produces the products AMP and P_i which are found when crude homogenates are used as the enzyme. The three inorganic pyrophosphatases were purified by sonication, ultracentrifugation, ammonium sulfate fractionation, and column chromatography on G-75 sephadex, DEAE cellulose, and CM cellulose. The three enzymes were found to have distinct pH optima: one acid, one neutral and one alkaline. The enzyme activated at a neutral pH needed only one-half as much Mg as substrate. The optimum ratio for the other two enzymes was one to one. Substrate specificity studies indicated that the enzymes may be important in the breakdown of polyphosphates and GTP. No other high energy phosphate bonds were acted on. The physiological significance remains obscure although data from this study indicate that an important function of the enzymes may be to remove undesirable pyrophosphate from the mitochondria. / Ph. D.

LD5655.V856 1964.M445

Cockroaches -- Physiology

Enzymes -- Synthesis

Human lysosomal sulphate transport

Lewis, Martin David.

January 2001

Addendum inserted at back Includes bibliographical references (leaves 266-287). 1. Introduction -- 2. Materials and general methods -- 3. Characterisation and partial purification of the lysosomal sulphate transporter -- 4. Identification of proteins involved in lysosomal sulphate transport -- 5. The relationship between a sulphate anion transporter family and the lysosomal sulphate transporter -- 6. Investigation of sulphate transport in human skin fibroblasts -- 7. Concluding remarks

Lysosomes

Enzymes Synthesis

Enzyme activation

Metabolism, Inborn errors of

Glycosaminoglycans Metabolism

Lysosomal storage diseases

Human lysosomal sulphate transport / Martin David Lewis.

Lewis, Martin D.

January 2001

Addendum inserted at back / Includes bibliographical references (leaves 266-287). / xxiv, 289 leaves, [2] leaves of plates : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Paediatrics, 2001

Lysosomes

Enzymes Synthesis.

Enzyme activation.

Metabolism, Inborn errors of.

Glycosaminoglycans Metabolism.

Lysosomal storage diseases.

Use of immunological procedures to measure rate of accumulation and degradation of inducible NADP-specific glutamate dehydrogenase during cell cycle of synchronous Chlorella

Yeung, Anthony Tung

January 1979

A new five-step purification procedure was developed which could be completed in five days with an 80 to 85 percent yield of electrophoretically pure nicotinamide adenine dinucleotide phosphate-specific glutamate dehydrogenase from Chlorella sorokiniana. A monospecific, highly purified antibody against the enzyme was prepared from the antisera of immunized rabbits. The antibody was purified on a stable antigen affinity column which was prepared by covalent-coupling of the holoenzyme to CNBr activated Sepharose 4B followed by cross-linking of the enzyme subunits together with dimethylsuberimidate. With ³H-leucine and ³⁵S-sulfate, as labeling agents of whole cells, the reproducibility and efficiency of both direct- and indirect-immunoprecipitation procedures were tested with pure labeled-enzyme as an internal standard. For these studies, a partially purified sheep anti-rabbit immunoglobulin G fraction was employed as a secondary antibody. A modified indirect immunoprecipitation procedure was tested in a cell cycle experiment to determine whether it would be feasible to use as a tool for further cell cycle experiments on enzyme turnover. Although the method was somewhat lengthy, it appeared to be reliable and was used to reveal that during the first one-third of the cell cycle of fully-induced cells, the NADPGDH has a maximum half-life of 1.6 h. Rocket immunoelectrophoresis was used to show that enzyme catalytic activity and antigen increased in a parallel fashion during the cell cycle of fully-induced cells. These data suggest that the cell cycle catalytic activity pattern reflects de novo synthesis of new molecules of enzyme. Since the enzyme in fully-induced cells undergoes rapid in vivo degradation, changes in the rate of enzyme synthesis probably determine the rate of enzyme accumulation during the Chlorella cell cycle in the continuous presence of ammonium. / Ph. D.

LD5655.V856 1979.Y485

Cell cycle

Eukaryotic cells

Chlorella

Enzymes -- Synthesis

Development of a novel dehydrogenase and a stable cofactor regeneration system

Vázquez-Figueroa, Eduardo

20 August 2008

The first goal of this work focused on the development of an amine dehydrogenase (AmDH) from a leucine dehydrogenase using site-directed mutagenesis. We aimed at reductively aminating a prochiral ketone to a chiral amine by using leucine dehydrogenase (LeuDH) as a starting template. This initial work was divided into two stages. The first focused mutagenesis to a specific residue (K68) that we know is key to developing the target functionality. Subsequently, mutagenesis focused on residues known to be in close proximity to a key region of the substrate (M65 and K68). This approach allowed for reduced library size while at the same time increased chances of generating alternate substrate specificity. An NAD+-dependent high throughput assay was optimized and will be discussed. The best variants showed specific activity in mU/mg range towards deaminating the target substrate. The second goal of this work was the development of a thermostable glucose dehydrogenase (GDH) starting with the wild-type gene from Bacillus subtilis. GDH is able to carry out the regeneration of both NADH and NADPH cofactors using glucose as a substrate. We applied the structure-guided consensus method to identify 24 mutations that were introduced using overlap extension. 11 of the tested variants had increased thermal stability, and when combined a GDH variant with a half-life ~3.5 days at 65℃ was generated--a ~10⁶increase in stability when compared to the wild-type. The final goal of this work was the characterization of GDH in homogeneous organic-aqueous solvent systems and salt solutions. Engineered GDH variants showed increased stability in all salts and organic solvents tested. Thermal stability had a positive correlation with organic solvent and salt stability. This allowed the demonstration that consensus-based methods can be used towards engineering enzyme stability in uncommon media. This is of significant value since protein deactivation in salts and organic solvents is not well understood, making a priori design of protein stability in these environments difficult.

Consensus sequence

Glucose dehydrogenase

Cofactor regeneration

Protein engineering

Salt and solvent stability

Biocatalysis

Enzymes

Mutagenesis

Enzymes Synthesis

Organic solvents

The lysosomal degradation of heparan sulphate : a comparative study of the physical and catalytic properties of the heparan sulphate degradative enzymes / by Craig Freeman

Freeman, Craig

January 1991

Copies of author's previously published articles inserted / Includes bibliographic references / 2 v. (various foliations) : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Summary: Studies the enzymology of some of the nine lysosomal exo-enzyme activities which act together to degrade the more highly sulphated regions of the glycosaminoglycans heparin and heparan sulphate. A deficiency of any one of these enzyme activities can result in one of the lysosomal storage disorders collectively known as the Mucopolysaccharidoses (MPS) / Thesis (Ph.D.)--University of Adelaide, Dept. of Paediatrics, 1991

574.87/4

616.3/9 20

Lysosomes.

Enzymes Synthesis.

Enzyme activation.

Metabolism, Inborn errors of.

Glycosaminoglycans Metabolism.

Lysosomal storage diseases.

Insights Into The Mechanistic Details Of The M.Tuberculosis Pantothenate Kinase : The Key Regulatory Enzyme Of CoA Biosynthesis

Parimal Kumar, *

07 1900

Tuberculosis (TB), caused by Mycobacterium tuberculosis, has long been the scourge of humanity, claiming millions of lives. It is the most devastating infectious disease of the world in terms of mortality as well as morbidity (WHO, 2009). The lack of a uniformly effective vaccine against TB, the development of resistance in the Mycobacterium tuberculosis against the present antitubercular drugs and its synergy with AIDS has made the situation very alarming. This therefore necessitates a search for new antitubercular drugs as well as the identification of new and unexplored drug targets (Broun et aI., 1992). Coenzyme A is an essential cofactor for all organisms and is synthesized in organisms from pantothenate by a universally conserved pathway (Spry et al., 2008; Sassetti and Rubin, 2003). The first enzyme of the pathway, pantothenate kinase catalyzes the most important step of the biosynthetic process, being the first committed step of CoA biosynthesis and the one at which all the regulation takes place (Gerdes et aI., 2002) This thesis describes the successful cloning of PanK from Mycobacterium tuberculosis, its expression in E. coli, single step affinity purification, and complete biochemical and biophysical characterization. In this work, pantothenol, a widely believed inhibitor of pantothenate kinase, has been shown to act as a substrate for the mycobacterial pantothenate kinase. Further it was shown that the product, 4'phosphopantothenol, thus formed, inhibited the next step of the CoA biosynthesis pathway in vitro. The study was extended to find outthe fate of pantothenol inside the cell and it was demonstrated that the CoA biosynthetic enzymes metabolized the latter into the pantothenol derivative of CoA which then gets incorporated into acyl carrier protein. Lastly, it was decisively shown that pantothenate kinase is not only regulated by feedback inhibition by CoA but, also regulated through feed forward stimulation by Fructose 1, 6 biphosphate (FBP), a glycolytic intermediate. The binding site of FBP was determined by docking and mutational studies of MtPanK. Chapter 1 presents a brief survey of the literature related to Coenzyme A biosynthesis pathway and describes the objective of the thesis. It also presents a history of TB and briefly reviews literature describing TB as well as the life cycle, biology, survival strategy, mode of infection and the metabolic pathways operational in the TB parasite, Mycobacterium tuberculosis. The chapter details the enzymes involved in CoA biosynthesis pathway from various organims. Chapter 2 In this chapter, cloning of the ORF (Rv1092c), annotated as pantothenate kinase in the Tuberculist database (http://genolist.pasteur.frfTubercuList), its expression in E. coli and purification using affinity chromatography has been described. Protein identity was confirmed by MALDI-TOF and by its ability to complement the pantothenate kinase temperature sensitive mutant, DV70. This chapter also illustrates the oligomeric status of MtPanK in solution and describes the biochemical characterization of MtPanK by means of two different methods, spectrophotometrically by a coupled assay and calorimetrically by using Isothermal Titration Calorimetry. Feedback inhibition of MtPanK by CoA is also discussed in this chapter. Chapter 3 describes the biophysical characterization of MtPanK. It discusses the enthalpy (~H) and free energy change (~G) accompanying the binding of a non-hydrolysable analogue of ATP; CoA; acetyl CoA and malonyl-CoA to MtPanK. The chapter details the energetics observed upon ATP binding to pantothenate-saturated MtPanK further elucidating the order of the reaction. This chapter also describes the various strategies which were designed and tested to remove CoA from the enzyme as the latter is always purified from the cell in conjunction with CoA. Validation of these strategies for complete CoA removal (by studying the n value from ITC studies) is further described. Chapter 4 discusses the interaction of the well-studied inhibitor of pantothenate kinases from other sources (e.g. the malarial parasite), pantothenol, with the mycobacterial enzyme. In order to investigate the interaction of this compound with MtPanK, its effect on the kinetic reaction carried out by the enzyme was studied by several methods. Surprisingly, a new band corresponding to 4'phosphopantothenol appeared when the reaction mix of MtPanK with pantothenol and ATP was separated on TLC. The identity of the new spot was confirmed by mass spectrometry analyses of the MtPanK reaction mixture.. These findings established the fact that pantothenol is a substrate of pantothenate kinase. To delve deeper into the mechanism of interaction of this compound with the enzymes of the coenzyme A biosynthesis pathway, the ability of pantothenol to serve as a substrate for the next step of the pathway, MtCoaBC was studied. Using various approaches it was established that pantothenol is actually a substrate for the MtPanK and the inhibition observed earlier (Saliba et aI., 2005) is actually due to the inability of CoaBC to utilize 4' -phosphopantothenol as substrate. Chapter 5 takes the story from Chapter 4 further detailing the effects of pantothenol on cultures of E. coli and M. smegmatis. I observed that pantothenol does not inhibit the culture of E. coli or M. smegmatis. So, further studies were carried out to know the fate of pantothenol once it is converted into 4'phosphopantothenoi. Since, the next enzyme of the pathway does not utilize 4'phosphopantothenol, I checked the further downstream enzyme of the pathway, CoaD, and found that it converts 4'-phosphopantothenol to thepantothenol derivative of dephospho-CoA. The next enzyme of the pathway, CoaE, took up this pantothenol derivative of dephospho-CoA as a substrate and converted it to the pantothenol derivative of CoA which was then transferred to apo-ACP by holo-ACP synthase. The holo-ACP thus synthesized enters into the dedicated pathway of fatty acid synthesis. Extensive investigations have been carried out on the regulation of pantothenate kinases, by the product of the pathway, Coenzyme A and its thioesters, xx establishing the latter as the feedback regulators of these enzymes. In order to determine if the cell employs mechanisms to sense available carbon sources and consequently modulate its coenzyme A levels by regulating activity of the enzymes involvedin CoA biosynthesis, glycolytic intermediates were tested against MtPanK for their possible role in the regulation of MtPanK activity. Chapter 6 details my identification of a novel regulator of MtPanK activity, fructose-I, 6-bisphosphate (FBP), a glycolytic intermediate, which enhances the MtPanK catalyzed phosphorylation of pantothenate by three fold. Further, the possible mechanisms through which FBP mediates MtPanK activation are also discussed. This chapter also describes the experiments carried out to identify the binding site of FBP on MtPariK.Interestingly, docking of FBP on MtPanK revealed that FBP binds close to the ATP binding site on the enzyme with one of its phosphates overlapping with the 3'~phosphate of CoA thereby validating its competitive binding relative to CoA on MtPanK. Based on these observations I propose that the binding of FBP to MtPanK lowers the activation energy of pantothenate phosphorylation by PanK. Chapter 7 presents a summary of the findings of this work. Coenzyme A biosynthesis pathway harbors immense potential in the development of drug against many communicable diseases, thanks to its essentiality for the pathogens and the differences between the pathogen and host CoA biosynthetic enzymes. The work done in this thesis extensively characterizes the first committed enzyme of the CoA biosynthetic pathway, pantothenate kinase, from Mycobacterium tuberculosis (MtPanK). The thesis also deals with the fate of a known inhibitor of PanK and proves it as a substrate for MtPanK. Finally this thesis describes a new link between glycolysis and CoA biosynthesis. Biotin, like coenzyme A, is another essential cofactor required by several enzymes in critical metabolic pathways. De novo synthesis of this critical metabolite has been reported only in plants and microorganisms. Therefore targeting the synthesis of biotin in the tubercular pathogen is another effective means of handicapping the tubercle pathogen. During the course of my studies, I also investigated the mycobacterial biotin biosynthesis pathway, studying the first enzyme of the pathway, 7-keto-8-aminopelargonic acid (KAPA) synthase (bioF) in extensive detail. Appendix 1 elucidates the kinetic properties of 7-keto-8aminopelargonic acid synthase (bioF) from Mycobacterium tuberculosis and proves beyond doubt that D-alanine which has previously been reported to act as a competitive inhibitor for the B. sphaericus enzyme (Ploux et al., 1999), is actually a substrate for the mycobacterial bioF.

Tuberculosis

Micobacterial Pantothenate Kinase

Enzymes - Synthesis

Coenzyme A - Biosynthesis

Enzymes - Regulation

M. tuberculosis

Pantothenate Kinase

Mycobacterium tuberculosis

Pantothenol

Microbiology