Molecular Insights into the Heme-Binding Potential of Plant NCR247-Derived Peptides

Overview

Journal Chembiochem

Specialty Biochemistry

Date 2024 Dec 31

PMID 39740085

Authors

Sonali M Vaidya

Dhruv C Rathod

Anuradha Ramoji

Ute Neugebauer

Diana Imhof

Affiliations

Soon will be listed here.

Abstract

Heme is involved in many critical processes in pathogenic bacteria as iron acquisition by these microorganisms is achieved by either direct uptake of heme or use of heme-binding proteins called hemophores. Exploring the underlying mechanisms on a molecular level can open new avenues in understanding the host-pathogen interactions. Any imbalance of the heme concentration has a direct impact on the bacterial growth and survival. Thus, heme-regulated proteins that are involved in heme homeostasis poise to be promising targets for research. Similarly, naturally occurring compounds, including cysteine-rich peptides from either plant secondary metabolites or venom toxins from vertebrates and invertebrates, have been studied for their therapeutic potential. NCR247 is such a cysteine-rich peptide, known to be crucial for nitrogenase activity in M. truncatula and its symbiotic relation with S. meliloti. NCR247-derived peptides were suggested to serve as high-affinity heme-binding molecules with remarkable heme-capturing properties. A comprehensive biochemical and computational analysis of NCR247-derived peptides, however, redefines their heme-binding capacity and consequently their potential therapeutic role.

Citing Articles

Molecular Insights into the Heme-Binding Potential of Plant NCR247-Derived Peptides.

Vaidya S, Rathod D, Ramoji A, Neugebauer U, Imhof D Chembiochem. 2024; 26(5):e202400920.

PMID: 39740085 PMC: 11875561. DOI: 10.1002/cbic.202400920.

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