Fungal Peptidomelanin: A Novel Biopolymer for the Chelation of Heavy Metals

Overview

Journal ACS Omega

Publisher American Chemical Society

Specialty Chemistry

Date 2024 Sep 2

PMID 39220543

Authors

Rakshita Sukruth Kolipakala

Suranjana Basu

Senjuti Sarkar

Beneta Merin Biju

Daniela Salazar

Likhit Reddy

Pushya Pradeep

Muniraj Krishnaveni Yuvapriya

Shrijita Nath

Riley Gall

Anish Hemanth Samprathi

Harshitha Balaji

Eeshaan A B Koundinya

Aparna Shetye

Deepesh Nagarajan

Affiliations

Soon will be listed here.

Abstract

Melanin is an amorphous, highly heterogeneous polymer found across all kingdoms of life. Although the properties of melanin can greatly vary, most forms are insoluble and strongly absorb light, appearing dark brown to black. Here, we describe a water-soluble form of melanin (peptidomelanin) secreted by the spores of (strain: melanoliber) during germination. Peptidomelanin is composed of an insoluble L-DOPA core polymer that is solubilized via short, copolymerized heterogeneous peptide chains forming a "corona" with a mean amino acid length of 2.6 ± 2.3. Based on experiments, we propose a biochemical copolymerization mechanism involving the hydroxylation of tyrosynylated peptides. Peptidomelanin is capable of chelating heavy metals such as lead, mercury, and uranium (as uranyl) in large quantities. Preliminary data indicates that peptidomelanin may have applications for the remediation of heavy metals , including in agricultural settings.

Citing Articles

The genome of strain melanoliber.

Pradeep P, Kolipakala R, Nagarajan D Microbiol Resour Announc. 2025; 14(3):e0080924.

PMID: 39964164 PMC: 11895477. DOI: 10.1128/mra.00809-24.

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