La Trobe

Differential lysine-mediated allosteric regulation of plant dihydrodipicolinate synthase isoforms

journal contribution
posted on 2024-12-19, 03:06 authored by Cody Hall, Mihwa LeeMihwa Lee, Matthew BoarderMatthew Boarder, Alexandra Mangion, Anthony GendallAnthony Gendall, Santosh Panjikar, Matthew Perugini, Tatiana Soares-da-Costa
Lysine biosynthesis in plants occurs via the diaminopimelate pathway. The first committed and rate-limiting step of this pathway is catalysed by dihydrodipicolinate synthase (DHDPS), which is allosterically regulated by the end product, l-lysine (lysine). Given that lysine is a common nutritionally limiting amino acid in cereal crops, there has been much interest in probing the regulation of DHDPS. Interestingly, knockouts in Arabidopsis thaliana of each isoform (AtDHDPS1 and AtDHDPS2) result in different phenotypes, despite the enzymes sharing > 85% protein sequence identity. Accordingly, in this study, we compared the catalytic activity, lysine-mediated inhibition and structures of both A. thaliana DHDPS isoforms. We found that although the recombinantly produced enzymes have similar kinetic properties, AtDHDPS1 is 10-fold more sensitive to lysine. We subsequently used X-ray crystallography to probe for structural differences between the apo- and lysine-bound isoforms that could account for the differential allosteric inhibition. Despite no significant changes in the overall structures of the active or allosteric sites, we noted differences in the rotamer conformation of a key allosteric site residue (Trp116) and proposed that this could result in differences in lysine dissociation. Microscale thermophoresis studies supported our hypothesis, with AtDHDPS1 having a ~ 6-fold tighter lysine dissociation constant compared to AtDHDPS2, which agrees with the lower half minimal inhibitory concentration for lysine observed. Thus, we highlight that subtle differences in protein structures, which could not have been predicted from the primary sequences, can have profound effects on the allostery of a key enzyme involved in lysine biosynthesis in plants. Databases: Structures described are available in the Protein Data Bank under the accession numbers 6VVH and 6VVI.

Funding

TPSC would like to thank the National Health and Medical Research Council of Australia (APP1091976) and Australian Research Council (DE190100806) for fellowship and funding support, and MAP and SP the Australian Research Council for funding support (DP150103313). Work in ARG's laboratory is supported by the Australian Research Council Research Hub for Medicinal Agriculture (IH180100006). CJH is supported by a La Trobe University Postgraduate Research scholarship and MPB by an Australian Research Training scholarship. ML is supported by the Tracey Banivanua Mar fellowship from La Trobe University. We thank Dr Grant Pearce (University of Canterbury, New Zealand) for supplying pET151/D-Topo harbouring the dapA2 gene. We acknowledge the use of the MX2 beamline at the Australian Synchrotron, part of ANSTO, and made use of the Australian Cancer Research Foundation (ACRF) detector. We also acknowledge the CSIRO Collaborative Crystallisation Centre (www.csiro/C3); Melbourne, Australia) and thank the La Trobe University Comprehensive Proteomics Platform for providing infrastructure support.

History

Publication Date

2021-08-01

Journal

FEBS Journal

Volume

288

Issue

16

Pagination

14p. (p. 4973-4986)

Publisher

Wiley

ISSN

1742-464X

Rights Statement

© 2021 Federation of European Biochemical Societies