Structural insights on binding mechanism of CAD complexes (CPSase, ATCase and DHOase).

Pyrimidine biosynthetic pathway enzymes constitute an important target for the development of antitumor drugs. To understand the role of binding mechanisms underlying the inborn errors of pyrimidine biosynthetic pathway, structure and function of enzymes have been analyzed. Pyrimidine biosynthetic pathway is initiated by CAD enzymes that harbor the first three enzymatic activities facilitated by Carbamoyl Phosphate Synthetase (CPSase), Aspartate Transcarbamoylase (ATCase) and Dihydroorotase (DHOase). While being an attractive therapeutic target, the lack of data driven us to study the CPSase (CarA and CarB) and its mode of binding to ATCase and DHOase which are the major limitation for its structural optimization. Understanding the binding mode of CPSase, ATCase and DHOase could help to identify the potential interface hotspot residues that favor the mechanism behind it. The mechanistic insight into the CAD complexes were achieved through Molecular modeling, Protein-Protein docking, Alanine scanning and Molecular dynamics (MD) Studies. The hotspot residues present in the CarB region of carboxy phosphate and carbamoyl phosphate synthetic domains are responsible for the assembly of CAD (CPSase-ATCase-DHOase) complexes. Overall analysis suggests that the identified hotspot residues were confirmed by alanine scanning and important for the regulation of pyrimidine biosynthesis. MD simulations analysis provided the prolonged stability of the interacting complexes. The present study reveals the novel hotspot residues such as Glu134, Glu147, Glu154, Asp266, Lys269, Glu274, Asp333, Trp459, Asp526, Asp528, Glu533, Glu544, Glu546, Glu800, Val855, Asp877, Tyr884 and Gln919 which could be targeted for structure-based inhibitor design to potentiate the CAD mediated regulation of aggressive tumors.Communicated by Ramaswamy H. Sarma.

Identification of potential inhibitors for AIRS from de novo purine biosynthesis pathway through molecular modeling studies - a computational approach.

In cancer, de novo pathway plays an important role in cell proliferation by supplying huge demand of purine nucleotides. Aminoimidazole ribonucleotide synthetase (AIRS) catalyzes the fifth step of de novo purine biosynthesis facilitating in the conversion of formylglycinamidine ribonucleotide to aminoimidazole ribonucleotide. Hence, inhibiting AIRS is crucial due to its involvement in the regulation of uncontrollable cancer cell proliferation. In this study, the three-dimensional structure of AIRS from P. horikoshii OT3 was constructed based on the crystal structure from E. coli and the modeled protein is verified for stability using molecular dynamics for a time frame of 100 ns. Virtual screening and induced fit docking were performed to identify the best antagonists based on their binding mode and affinity. Through mutational studies, the residues necessary for catalytic activity of AIRS were identified and among which the following residues Lys35, Asp103, Glu137, and Thr138 are important in determination of AIRS function. The mutational studies help to understand the structural and energetic characteristics of the specified residues. In addition to Molecular Dynamics, ADME properties, binding free-energy, and density functional theory calculations of the compounds were carried out to find the best lead molecule. Based on these analyses, the compound from the NCI database, NCI_121957 was adjudged as the best molecule and could be suggested as the suitable inhibitor of AIRS. In future studies, experimental validation of these ligands as AIRS inhibitors will be carried out.

Exploring the structural features of Aspartate Trans Carbamoylase (TtATCase) from Thermus thermophilus HB8 through in silico approaches: a potential drug target for inborn error of pyrimidine metabolism.

Enzymes involved in the pyrimidine biosynthesis pathway have become an important target for the pharmacological intervention. One among those enzymes, Aspartate Trans Carbamoylase (ATCase), catalyses the condensation of aspartate and carbamoyl phosphate to form N-carbamoyl-l-aspartate and inorganic phosphate. The present study provides the molecular insights into the enzyme ATCase. The three-dimensional structure of ATCase from Thermus thermophilus HB8 was modeled based on the crystal structure of ATCase in Pyrococcus abyssi (PDB ID:1ML4). Molecular dynamics simulation was performed to identify the conformational stability of TtATCase with and without its ligand complexes. Based on the pharmacokinetic properties and the glide-docking scores of ligands from four databases (Maybridge, Binding, Asinex and Technology for Organic Synthesis (TOS laboratory) for the screening of ligands, we identified four potential ligand molecules for TtATCase. From the molecular docking results, we proposed that the residues Thr53, Arg104, and Gln219 are consistently involved in strong hydrogen-bonding interactions and play a vital role in the TtATCase activity. From the results of molecular dynamics simulation, the ligand molecules are found to bind appropriately to the target enzyme. However, the structure of TtATCase needs to be determined experimentally to confirm this.