Characterization of Glutaminase-Free Asparaginase (MSMEG_3173)

Overview

Journal ACS Omega

Publisher American Chemical Society

Specialty Chemistry

Date 2024 Sep 30

PMID 39346838

Authors

Paloma Rezende Correa

Marcos Gustavo Araujo Schwarz

Deborah Antunes

Sindy Licette Pinero

Marlon Castro Silva

Mayra Mangabeira Crescencio

Ana Carolina Ramos Guimaraes

Wim Maurits Degrave

Leila Mendonca-Lima

Affiliations

Soon will be listed here.

Abstract

l-asparaginase is an enzyme catalyzing the hydrolysis of l-asparagine into l-aspartate and ammonia, which is of great therapeutic importance in tumor treatment. However, commercially available enzymes are associated with adverse effects, and searching for a new l-asparaginase with better pharmaceutical properties was the aim of this work. The coding sequence for l-asparaginase (MsA) was cloned and expressed. The recombinant protein showed high activity toward l-asparagine, whereas none was detected for l-glutamine. The enzymatic properties ( = 1.403 ± 0.24 mM and = 708.1 ± 25.05 s) indicate that the enzyme would be functional within the expected blood l-asparagine concentration, with good activity, as shown by . The pH and temperature profiles suggest its use as a biopharmaceutical in humans. Molecular dynamics analysis of the MsA model reveals the formation of a hydrogen bond network involving catalytic residues with l-asparagine. However, the same is not observed with l-glutamine, mainly due to steric hindrance. Additionally, the structural feature of residue 119 being a serine rather than a proline has significant implications. These findings help explain the low glutaminase activity observed in MsA, like what is described for the enzyme. This establishes mycobacterial asparaginases as key scaffolds to develop biopharmaceuticals against acute lymphocytic leukemia.

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