The study of iron‐ and copper‐binding proteome of Fusarium oxysporum and its effector candidates

Author:

Kushwah Ankita Singh1,Dixit Himisha2,Upadhyay Vipin2,Verma Shailender Kumar23ORCID,Prasad Ramasare1

Affiliation:

1. Department of Biosciences and Bioengineering Indian Institute of Technology Roorkee Roorkee Uttarakhand India

2. Centre for Computational Biology & Bioinformatics Central University of Himachal Pradesh Kangra Himachal Pradesh India

3. Department of Environmental Studies University of Delhi, North Campus Delhi India

Abstract

AbstractFusarium oxysporum f.sp. lycopersici is a phytopathogen which causes vascular wilt disease in tomato plants. The survival tactics of both pathogens and hosts depend on intricate interactions between host plants and pathogenic microbes. Iron‐binding proteins (IBPs) and copper‐binding proteins (CBPs) play a crucial role in these interactions by participating in enzyme reactions, virulence, metabolism, and transport processes. We employed high‐throughput computational tools at the sequence and structural levels to investigate the IBPs and CBPs of F. oxysporum. A total of 124 IBPs and 37 CBPs were identified in the proteome of Fusarium. The ranking of amino acids based on their affinity for binding with iron is Glu > His> Asp > Asn > Cys, and for copper is His > Asp > Cys respectively. The functional annotation, determination of subcellular localization, and Gene Ontology analysis of these putative IBPs and CBPs have unveiled their potential involvement in a diverse array of cellular and biological processes. Three iron‐binding glycosyl hydrolase family proteins, along with four CBPs with carbohydrate‐binding domains, have been identified as potential effector candidates. These proteins are distinct from the host Solanum lycopersicum proteome. Moreover, they are known to be located extracellularly and function as enzymes that degrade the host cell wall during pathogen–host interactions. The insights gained from this report on the role of metal ions in plant–pathogen interactions can help develop a better understanding of their fundamental biology and control vascular wilt disease in tomato plants.

Funder

University Grants Commission

Publisher

Wiley

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