DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf

Complex interactions exist between microbiomes and their hosts. Increasingly, defensive metabolites that have been attributed to host biosynthetic capability are now being recognized as products of host-associated microbes. These unique metabolites often have bioactivity targets in human disease and...

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Main Authors: Nicole E. Avalon, Alison E. Murray, Hajnalka E. Daligault, Chien-Chi Lo, Karen W. Davenport, Armand E. K. Dichosa, Patrick S. G. Chain, Bill J. Baker
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
marine natural products
macrolide
biosynthetic gene clusters
Antarctic microbiology
trans-AT type I polyketide synthase
secondary metabolites
Antarctic
The Antarctic
Antarc*
Online Access:https://doi.org/10.3389/fchem.2021.802574.s001
https://figshare.com/articles/dataset/DataSheet1_Bioinformatic_and_Mechanistic_Analysis_of_the_Palmerolide_PKS-NRPS_Biosynthetic_Pathway_From_the_Microbiome_of_an_Antarctic_Ascidian_pdf/17469596
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record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/17469596 2023-05-15T13:58:46+02:00 DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf Nicole E. Avalon Alison E. Murray Hajnalka E. Daligault Chien-Chi Lo Karen W. Davenport Armand E. K. Dichosa Patrick S. G. Chain Bill J. Baker 2021-12-24T04:22:36Z https://doi.org/10.3389/fchem.2021.802574.s001 https://figshare.com/articles/dataset/DataSheet1_Bioinformatic_and_Mechanistic_Analysis_of_the_Palmerolide_PKS-NRPS_Biosynthetic_Pathway_From_the_Microbiome_of_an_Antarctic_Ascidian_pdf/17469596 unknown doi:10.3389/fchem.2021.802574.s001 https://figshare.com/articles/dataset/DataSheet1_Bioinformatic_and_Mechanistic_Analysis_of_the_Palmerolide_PKS-NRPS_Biosynthetic_Pathway_From_the_Microbiome_of_an_Antarctic_Ascidian_pdf/17469596 CC BY 4.0 CC-BY Biochemistry Environmental Chemistry Geochemistry Organic Chemistry Inorganic Chemistry Nuclear Chemistry Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics) Medical Biochemistry and Metabolomics not elsewhere classified Food Chemistry and Molecular Gastronomy (excl. Wine) Analytical Biochemistry Cell Neurochemistry Enzymes Electroanalytical Chemistry Analytical Chemistry not elsewhere classified Organic Green Chemistry Physical Organic Chemistry Catalysis and Mechanisms of Reactions Environmental Chemistry (incl. Atmospheric Chemistry) marine natural products macrolide biosynthetic gene clusters Antarctic microbiology trans-AT type I polyketide synthase secondary metabolites Dataset 2021 ftfrontimediafig https://doi.org/10.3389/fchem.2021.802574.s001 2021-12-30T00:01:30Z Complex interactions exist between microbiomes and their hosts. Increasingly, defensive metabolites that have been attributed to host biosynthetic capability are now being recognized as products of host-associated microbes. These unique metabolites often have bioactivity targets in human disease and can be purposed as pharmaceuticals. Polyketides are a complex family of natural products that often serve as defensive metabolites for competitive or pro-survival purposes for the producing organism, while demonstrating bioactivity in human diseases as cholesterol lowering agents, anti-infectives, and anti-tumor agents. Marine invertebrates and microbes are a rich source of polyketides. Palmerolide A, a polyketide isolated from the Antarctic ascidian Synoicum adareanum, is a vacuolar-ATPase inhibitor with potent bioactivity against melanoma cell lines. The biosynthetic gene clusters (BGCs) responsible for production of secondary metabolites are encoded in the genomes of the producers as discrete genomic elements. A candidate palmerolide BGC was identified from a S. adareanum microbiome-metagenome based on a high degree of congruence with a chemical structure-based retrobiosynthetic prediction. Protein family homology analysis, conserved domain searches, active site and motif identification were used to identify and propose the function of the ∼75 kbp trans-acyltransferase (AT) polyketide synthase-non-ribosomal synthase (PKS-NRPS) domains responsible for the stepwise synthesis of palmerolide A. Though PKS systems often act in a predictable co-linear sequence, this BGC includes multiple trans-acting enzymatic domains, a non-canonical condensation termination domain, a bacterial luciferase-like monooxygenase (LLM), and is found in multiple copies within the metagenome-assembled genome (MAG). Detailed inspection of the five highly similar pal BGC copies suggests the potential for biosynthesis of other members of the palmerolide chemical family. This is the first delineation of a biosynthetic gene cluster from an ... Dataset Antarc* Antarctic Frontiers: Figshare Antarctic The Antarctic
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
marine natural products
macrolide
biosynthetic gene clusters
Antarctic microbiology
trans-AT type I polyketide synthase
secondary metabolites
spellingShingle Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
marine natural products
macrolide
biosynthetic gene clusters
Antarctic microbiology
trans-AT type I polyketide synthase
secondary metabolites
Nicole E. Avalon
Alison E. Murray
Hajnalka E. Daligault
Chien-Chi Lo
Karen W. Davenport
Armand E. K. Dichosa
Patrick S. G. Chain
Bill J. Baker
DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
topic_facet Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
marine natural products
macrolide
biosynthetic gene clusters
Antarctic microbiology
trans-AT type I polyketide synthase
secondary metabolites
description Complex interactions exist between microbiomes and their hosts. Increasingly, defensive metabolites that have been attributed to host biosynthetic capability are now being recognized as products of host-associated microbes. These unique metabolites often have bioactivity targets in human disease and can be purposed as pharmaceuticals. Polyketides are a complex family of natural products that often serve as defensive metabolites for competitive or pro-survival purposes for the producing organism, while demonstrating bioactivity in human diseases as cholesterol lowering agents, anti-infectives, and anti-tumor agents. Marine invertebrates and microbes are a rich source of polyketides. Palmerolide A, a polyketide isolated from the Antarctic ascidian Synoicum adareanum, is a vacuolar-ATPase inhibitor with potent bioactivity against melanoma cell lines. The biosynthetic gene clusters (BGCs) responsible for production of secondary metabolites are encoded in the genomes of the producers as discrete genomic elements. A candidate palmerolide BGC was identified from a S. adareanum microbiome-metagenome based on a high degree of congruence with a chemical structure-based retrobiosynthetic prediction. Protein family homology analysis, conserved domain searches, active site and motif identification were used to identify and propose the function of the ∼75 kbp trans-acyltransferase (AT) polyketide synthase-non-ribosomal synthase (PKS-NRPS) domains responsible for the stepwise synthesis of palmerolide A. Though PKS systems often act in a predictable co-linear sequence, this BGC includes multiple trans-acting enzymatic domains, a non-canonical condensation termination domain, a bacterial luciferase-like monooxygenase (LLM), and is found in multiple copies within the metagenome-assembled genome (MAG). Detailed inspection of the five highly similar pal BGC copies suggests the potential for biosynthesis of other members of the palmerolide chemical family. This is the first delineation of a biosynthetic gene cluster from an ...
format Dataset
author Nicole E. Avalon
Alison E. Murray
Hajnalka E. Daligault
Chien-Chi Lo
Karen W. Davenport
Armand E. K. Dichosa
Patrick S. G. Chain
Bill J. Baker
author_facet Nicole E. Avalon
Alison E. Murray
Hajnalka E. Daligault
Chien-Chi Lo
Karen W. Davenport
Armand E. K. Dichosa
Patrick S. G. Chain
Bill J. Baker
author_sort Nicole E. Avalon
title DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
title_short DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
title_full DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
title_fullStr DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
title_full_unstemmed DataSheet1_Bioinformatic and Mechanistic Analysis of the Palmerolide PKS-NRPS Biosynthetic Pathway From the Microbiome of an Antarctic Ascidian.pdf
title_sort datasheet1_bioinformatic and mechanistic analysis of the palmerolide pks-nrps biosynthetic pathway from the microbiome of an antarctic ascidian.pdf
publishDate 2021
url https://doi.org/10.3389/fchem.2021.802574.s001
https://figshare.com/articles/dataset/DataSheet1_Bioinformatic_and_Mechanistic_Analysis_of_the_Palmerolide_PKS-NRPS_Biosynthetic_Pathway_From_the_Microbiome_of_an_Antarctic_Ascidian_pdf/17469596
geographic Antarctic
The Antarctic
geographic_facet Antarctic
The Antarctic
genre Antarc*
Antarctic
genre_facet Antarc*
Antarctic
op_relation doi:10.3389/fchem.2021.802574.s001
https://figshare.com/articles/dataset/DataSheet1_Bioinformatic_and_Mechanistic_Analysis_of_the_Palmerolide_PKS-NRPS_Biosynthetic_Pathway_From_the_Microbiome_of_an_Antarctic_Ascidian_pdf/17469596
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fchem.2021.802574.s001
_version_ 1766267114990075904

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