Respiratory microbiomes reflect whale health

Carolyn A Miller; Enrico Pirotta; Sharon Grim; Michael J. Moore; John W Durban; Peter L Tyack; Holly Fearnbach; Samantha G M Leander; Amy R Knowlton; Amy M Warren; Monica A Zani; Regina Asmutis-Silvia; Heather M Pettis; Amy Apprill

doi:10.1093/ismejo/wraf231

Respiratory microbiomes reflect whale health

Carolyn A Miller^*, Enrico Pirotta^*, Sharon Grim, Michael J. Moore, John W Durban, Peter L Tyack, Holly Fearnbach, Samantha G M Leander, Amy R Knowlton, Amy M Warren, Monica A Zani, Regina Asmutis-Silvia, Heather M Pettis, Amy Apprill^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

As important members of the marine ecosystem, baleen whales are frequently managed and protected, but methodology to assess their health remains limited. Recent technological advances, such as the use of drones, support the non-invasive collection of promising health-associated data, including respiratory exhalant microbiota. Here, we considered five health metrics paired with respiratory exhalant samples to examine the utility of characterizing respiratory microorganisms for health diagnostics of North Atlantic right whales (Eubalaena glacialis), one of the most endangered baleen whale species. In 2016–2024, we used drones to collect 103 exhalant samples from 85 individuals to examine the associated microbiome, using amplicon sequencing methods targeting bacteria and archaea. The health status of sampled whales was characterized using an index of body condition derived from full-body vertical drone images, three qualitative assessments obtained from photo-identification imagery, and an existing health and vital rates model. Using an elastic net penalized regression approach, we demonstrate significant relationships between these health metrics and respiratory-associated microorganisms. Bacterial taxa that significantly contributed to the model for the body condition index differed between the thinnest and most robust males in the dataset. The thin whale harbored taxa belonging to the same genus as mammalian pathogens, Clostridium and Peptoniphilus, whereas the robust whale harbored taxa commonly observed in lipid-rich environments, Sediminispirochaeta and Candidatus Gracilibacteria. These differences warrant further investigation into the mechanisms by which bacteria contribute to whale health. Our findings demonstrate the utility of non-invasive multi-metric health models that include respiratory exhalant microbiota for whale health assessment and management.

Original language	English
Article number	wraf231
Pages (from-to)	1-5
Number of pages	5
Journal	ISME Journal
Volume	19
Issue number	1
DOIs	https://doi.org/10.1093/ismejo/wraf231
Publication status	Published - 12 Nov 2025

Keywords

Wildlife health assessment
North Atlantic right whale
Drone
Photogrammetry
Body conditions
Microbiome
Bacteria
Elastic net regression

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Miller-et-al-2025-Respiratory-microbiomes-reflect-ISMEJ-19-wraf231-CCBY
Copyright © The Author(s) 2025. Published by Oxford University Press on behalf of the International Society for Microbial Ecology. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.
Final published version, 970 KBLicence: CC BY

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title = "Respiratory microbiomes reflect whale health",

abstract = "As important members of the marine ecosystem, baleen whales are frequently managed and protected, but methodology to assess their health remains limited. Recent technological advances, such as the use of drones, support the non-invasive collection of promising health-associated data, including respiratory exhalant microbiota. Here, we considered five health metrics paired with respiratory exhalant samples to examine the utility of characterizing respiratory microorganisms for health diagnostics of North Atlantic right whales (Eubalaena glacialis), one of the most endangered baleen whale species. In 2016–2024, we used drones to collect 103 exhalant samples from 85 individuals to examine the associated microbiome, using amplicon sequencing methods targeting bacteria and archaea. The health status of sampled whales was characterized using an index of body condition derived from full-body vertical drone images, three qualitative assessments obtained from photo-identification imagery, and an existing health and vital rates model. Using an elastic net penalized regression approach, we demonstrate significant relationships between these health metrics and respiratory-associated microorganisms. Bacterial taxa that significantly contributed to the model for the body condition index differed between the thinnest and most robust males in the dataset. The thin whale harbored taxa belonging to the same genus as mammalian pathogens, Clostridium and Peptoniphilus, whereas the robust whale harbored taxa commonly observed in lipid-rich environments, Sediminispirochaeta and Candidatus Gracilibacteria. These differences warrant further investigation into the mechanisms by which bacteria contribute to whale health. Our findings demonstrate the utility of non-invasive multi-metric health models that include respiratory exhalant microbiota for whale health assessment and management.",

keywords = "Wildlife health assessment, North Atlantic right whale, Drone, Photogrammetry, Body conditions, Microbiome, Bacteria, Elastic net regression",

author = "Miller, \{Carolyn A\} and Enrico Pirotta and Sharon Grim and Moore, \{Michael J.\} and Durban, \{John W\} and Tyack, \{Peter L\} and Holly Fearnbach and Leander, \{Samantha G M\} and Knowlton, \{Amy R\} and Warren, \{Amy M\} and Zani, \{Monica A\} and Regina Asmutis-Silvia and Pettis, \{Heather M\} and Amy Apprill",

note = "Funding: Funding was provided by Strategic Environmental Research and Development Program [RC20-1097, RC20-7188, RC21-3091], Office of Naval Research [N000142012697, N000142112096], NOAA Cooperative Institute agreement NA19OAR4320074, NA24OARX432C0008, NOAA Fisheries, SR3, and two anonymous donors.",

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doi = "10.1093/ismejo/wraf231",

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AU - Miller, Carolyn A

AU - Pirotta, Enrico

AU - Grim, Sharon

AU - Moore, Michael J.

AU - Durban, John W

AU - Tyack, Peter L

AU - Fearnbach, Holly

AU - Leander, Samantha G M

AU - Knowlton, Amy R

AU - Warren, Amy M

AU - Zani, Monica A

AU - Asmutis-Silvia, Regina

AU - Pettis, Heather M

AU - Apprill, Amy

N1 - Funding: Funding was provided by Strategic Environmental Research and Development Program [RC20-1097, RC20-7188, RC21-3091], Office of Naval Research [N000142012697, N000142112096], NOAA Cooperative Institute agreement NA19OAR4320074, NA24OARX432C0008, NOAA Fisheries, SR3, and two anonymous donors.

PY - 2025/11/12

Y1 - 2025/11/12

N2 - As important members of the marine ecosystem, baleen whales are frequently managed and protected, but methodology to assess their health remains limited. Recent technological advances, such as the use of drones, support the non-invasive collection of promising health-associated data, including respiratory exhalant microbiota. Here, we considered five health metrics paired with respiratory exhalant samples to examine the utility of characterizing respiratory microorganisms for health diagnostics of North Atlantic right whales (Eubalaena glacialis), one of the most endangered baleen whale species. In 2016–2024, we used drones to collect 103 exhalant samples from 85 individuals to examine the associated microbiome, using amplicon sequencing methods targeting bacteria and archaea. The health status of sampled whales was characterized using an index of body condition derived from full-body vertical drone images, three qualitative assessments obtained from photo-identification imagery, and an existing health and vital rates model. Using an elastic net penalized regression approach, we demonstrate significant relationships between these health metrics and respiratory-associated microorganisms. Bacterial taxa that significantly contributed to the model for the body condition index differed between the thinnest and most robust males in the dataset. The thin whale harbored taxa belonging to the same genus as mammalian pathogens, Clostridium and Peptoniphilus, whereas the robust whale harbored taxa commonly observed in lipid-rich environments, Sediminispirochaeta and Candidatus Gracilibacteria. These differences warrant further investigation into the mechanisms by which bacteria contribute to whale health. Our findings demonstrate the utility of non-invasive multi-metric health models that include respiratory exhalant microbiota for whale health assessment and management.

AB - As important members of the marine ecosystem, baleen whales are frequently managed and protected, but methodology to assess their health remains limited. Recent technological advances, such as the use of drones, support the non-invasive collection of promising health-associated data, including respiratory exhalant microbiota. Here, we considered five health metrics paired with respiratory exhalant samples to examine the utility of characterizing respiratory microorganisms for health diagnostics of North Atlantic right whales (Eubalaena glacialis), one of the most endangered baleen whale species. In 2016–2024, we used drones to collect 103 exhalant samples from 85 individuals to examine the associated microbiome, using amplicon sequencing methods targeting bacteria and archaea. The health status of sampled whales was characterized using an index of body condition derived from full-body vertical drone images, three qualitative assessments obtained from photo-identification imagery, and an existing health and vital rates model. Using an elastic net penalized regression approach, we demonstrate significant relationships between these health metrics and respiratory-associated microorganisms. Bacterial taxa that significantly contributed to the model for the body condition index differed between the thinnest and most robust males in the dataset. The thin whale harbored taxa belonging to the same genus as mammalian pathogens, Clostridium and Peptoniphilus, whereas the robust whale harbored taxa commonly observed in lipid-rich environments, Sediminispirochaeta and Candidatus Gracilibacteria. These differences warrant further investigation into the mechanisms by which bacteria contribute to whale health. Our findings demonstrate the utility of non-invasive multi-metric health models that include respiratory exhalant microbiota for whale health assessment and management.

KW - Wildlife health assessment

KW - North Atlantic right whale

KW - Drone

KW - Photogrammetry

KW - Body conditions

KW - Microbiome

KW - Bacteria

KW - Elastic net regression

UR - https://www.scopus.com/pages/publications/105021658977

U2 - 10.1093/ismejo/wraf231

DO - 10.1093/ismejo/wraf231

M3 - Article

SN - 1751-7362

VL - 19

SP - 1

EP - 5

JO - ISME Journal

JF - ISME Journal

IS - 1

M1 - wraf231

ER -

Respiratory microbiomes reflect whale health

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