Mechanistic Characterization of Cyclic Pyranopterin Monophosphate Formation in Molybdenum Cofactor Biosynthesis

Hover, Bradley Morgan

January 2014

<p>The molybdenum cofactor (Moco) is an essential enzyme cofactor found in all kingdoms of life. Moco plays central roles in many vital biological processes, and must be biosynthesized de novo. During its biosynthesis, the characteristic pyranopterin ring of Moco is constructed by a complex rearrangement of guanosine 5'-­triphosphate (GTP) into cyclic pyranopterin (cPMP) through the action of two enzymes, MoaA and MoaC. However, the mechanisms and the functions of the two enzymes are under significant debate. To elucidate their physiological roles, I took a multidisciplinary approach to functionally characterize MoaA and MoaC in vivo and in vitro. In this dissertation, I report the first isolation and characterization of the physiological MoaC substrate, 3',8-­ cyclo-­7,8-­dihydro-­guanosine 5'-triphosphate (3',8-cH2GTP). I also report the first X-­ray crystal structures of MoaC in complex with this highly air sensitive substrate, and its product cPMP. These studies, combined with in vitro experiments using substrate analogs, catalytically impaired mutants, and synthetic peptides, have enabled me to delineate the functions of the Moco biosynthetic enzymes, MoaA and MoaC, and proposed mechanistic models for their roles in the formation of cPMP.</p> / Dissertation

Biochemistry

Chemistry

Molecular chemistry

Cofactor Biosynthesis

Enzymology

MoaA

MoaC

Molybdenum Cofactor

Radical SAM

Structural Studies On Bovine Pancreatic Phospholipase A2 And Proteins Involved In Molybdenum Cofactor Biosynthesis

Kanaujia, Shankar Prasad

10 1900

We have carried out structural studies on bovine pancreatic phospholipase A2 (BPLA2) and two proteins involved in molybdenum cofactor (Moco) biosynthesis pathway. In addition, molecular-dynamics simulations and other analyses have been performed to corroborate the findings obtained from the crystal structures. Crystal structures of the three active-site mutants (H48N, D49N and D49K) of BPLA2 were determined to understand the mechanism by which the mutant H48N is able to catalyze the reaction of phospholipid hydrolysis and to see the effect of the loss of Ca 2+ ion in the active site of D49N and D49K mutants. We found that Asp49 could possibly play the role of a general base instead of His48 in the case of the H48N mutant. In the case of D49N and D49K mutants, the active site of the enzyme is perturbed, whereas the overall tertiary structure of these mutants is intact. In addition, a total of 24 invariant water molecules were identified in all of the crystal structures of BPLA2 available in its archive, PDB. Out of these, four water molecules are essential for the catalytic activity, whereas, the remaining water molecules play a role in the stability of the enzyme. In addition, structural studies on two proteins MoaC and MogA involved in Moco biosynthesis pathway have been carried out. For the first time, crystal structure of MoaC bound with GTP molecule has been reported. The gene id TTHA0341, which is mentioned as MoaB in the CMR database, was annotated as MogA based the comparative analysis of sequences and structures (with the present work and the structures available in the literature). The role of N-and C-termini of MoaB and MogA proteins were proposed that these residues might stabilize the substrate and/or product molecule in the active site. In addition, the residues involved in the oligomerization are compared with MD simulations. The molecular docking studies show that MoaB proteins show more preference to GTP than ATP. The comparison of the two active (MPT and AMP-binding) sites revealed that MPT-binding site is preferred over AMP-binding site for nucleotide binding.

Proteins

Phosphoproteins

Pancreatic Phospholipase

Molybdenum Biosynthesis

Protein Crystallography

Molecular Dynamics Simulations

Molybdenum Cofactor Biosynthesis

Thermus thermophilus HB8

MoaC

MogA

Molybdopterin Synthase

Biochemistry

Hledání fosfoproteinů účastnících se aktivace pylu tabáku in vitro / Revealing phosphoproteins playing role in tobacco pollen activated in vitro

Fíla, Jan

January 2012

5 Abstract Tobacco mature pollen rehydrates in vivo on a stigma tissue, and develops into the rapidly-growing pollen tube. This rehydration process is accompanied by the de-repression of stored mRNA transcripts, resulting in the synthesis of novel proteins. Furthermore, such metabolic switch is also likely to be regulated on the level of post-translational modifications of the already-present proteins, namely via phosphorylation, since it was shown to play a significant regulatory role in numerous cellular processes. Since only a minor part of proteins is phosphorylated in a cell at a time, the employment of various enrichment techniques is usually of key importance. In this diploma project, metal oxide/hydroxide affinity chromatography (MOAC) with aluminium hydroxide matrix was applied in order to enrich phosphoproteins from the mature pollen and the 30-minute in vitro activated pollen crude protein extracts. The enriched fraction was separated by both 2D-GE and gel-free liquid chromatography (LC) approaches with subsequent mass spectrometric analyses. Collectively, 139 phosphoprotein candidates were identified. Additionally, to broaden the number of phosphorylation sites identified, titanium dioxide phosphopeptide enrichment of trypsin-digested mature pollen crude extract was performed. Thanks to the...