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Distinct lactate utilization strategies drive niche differentiation between two co-existing Megasphaera species in the rumen microbiome

Distinct lactate utilization strategies drive niche differentiation between two co-existing Megasphaera species in the rumen microbiome
Distinct lactate utilization strategies drive niche differentiation between two co-existing Megasphaera species in the rumen microbiome
Lactate utilization mitigates rumen acidosis and is associated with decreased methane production in the rumen. While several lactate utilization pathways exist across different microbial species in the rumen, how they are metabolically differentiated remains unclear. Here, we show that the key lactate-utilizing species Megasphaera hexanoica and Megasphaera elsdenii display distinct growth strategies based on their fermentative end products. This allows them to co-exist and play distinct metabolic roles, which appear particularly relevant in the early stages of rumen development, as both species are highly enriched in the calf. Specifically, M. hexanoica is more strongly associated with rumen microbiome states that involve increased lactate utilization and preferentially runs reverse beta-oxidation (termed chain elongation) to produce butyrate and medium-chain fatty acids from lactate. As M. elsdenii instead utilizes lactate via the acrylate pathway to produce propionate, we leverage Enzyme Cost Minimization to predict how this pathway relates to a distinct growth strategy. We find that M. elsdenii maximizes growth rate when lactate transiently accumulates, which contrasts M. hexanoica's invariably high-yield strategy. This trade-off, which is supported by the analysis of growth kinetics, metabolic flux, and bioreactors simulating the rumen microbiome, ultimately contributes to co-existence on lactate and may have driven niche differentiation. Lastly, we demonstrate how lactate utilization in the Megasphaera is threatened by toxins widespread in feed, which points to dietary interventions to support calf health.
Megasphaera, lactate utilization, metabolic trade-offs, niche differentiation, rumen
1751-7362
Strachan, Cameron R
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Bowers, Connor M
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Kim, Byung-Chul
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Movsesijan, Tea
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Neubauer, Viktoria
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Mueller, Anna J
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Yu, Xiaoqian A
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Pereira, Fátima C
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Nagl, Veronika
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Faas, Johannes
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Wagner, Martin
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Zebeli, Qendrim
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Weimer, Paul J
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Candry, Pieter
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Polz, Martin F
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Lawson, Christopher E
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Selberherr, Evelyne
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Strachan, Cameron R
957501d8-4de5-4970-8e21-59a16b69bde8
Bowers, Connor M
77e7a491-2bf2-47ba-ae45-01d4b6ad366c
Kim, Byung-Chul
e24f53ff-40e1-4102-b450-c015cc573923
Movsesijan, Tea
0beecdcd-faf0-4eb3-ad68-b6dde8572c85
Neubauer, Viktoria
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Mueller, Anna J
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Yu, Xiaoqian A
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Pereira, Fátima C
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Nagl, Veronika
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Faas, Johannes
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Wagner, Martin
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Zebeli, Qendrim
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Weimer, Paul J
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Candry, Pieter
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Polz, Martin F
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Lawson, Christopher E
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Selberherr, Evelyne
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Strachan, Cameron R, Bowers, Connor M, Kim, Byung-Chul, Movsesijan, Tea, Neubauer, Viktoria, Mueller, Anna J, Yu, Xiaoqian A, Pereira, Fátima C, Nagl, Veronika, Faas, Johannes, Wagner, Martin, Zebeli, Qendrim, Weimer, Paul J, Candry, Pieter, Polz, Martin F, Lawson, Christopher E and Selberherr, Evelyne (2025) Distinct lactate utilization strategies drive niche differentiation between two co-existing Megasphaera species in the rumen microbiome. The ISME Journal, 19 (1), [wraf147]. (doi:10.1093/ismejo/wraf147).

Record type: Article

Abstract

Lactate utilization mitigates rumen acidosis and is associated with decreased methane production in the rumen. While several lactate utilization pathways exist across different microbial species in the rumen, how they are metabolically differentiated remains unclear. Here, we show that the key lactate-utilizing species Megasphaera hexanoica and Megasphaera elsdenii display distinct growth strategies based on their fermentative end products. This allows them to co-exist and play distinct metabolic roles, which appear particularly relevant in the early stages of rumen development, as both species are highly enriched in the calf. Specifically, M. hexanoica is more strongly associated with rumen microbiome states that involve increased lactate utilization and preferentially runs reverse beta-oxidation (termed chain elongation) to produce butyrate and medium-chain fatty acids from lactate. As M. elsdenii instead utilizes lactate via the acrylate pathway to produce propionate, we leverage Enzyme Cost Minimization to predict how this pathway relates to a distinct growth strategy. We find that M. elsdenii maximizes growth rate when lactate transiently accumulates, which contrasts M. hexanoica's invariably high-yield strategy. This trade-off, which is supported by the analysis of growth kinetics, metabolic flux, and bioreactors simulating the rumen microbiome, ultimately contributes to co-existence on lactate and may have driven niche differentiation. Lastly, we demonstrate how lactate utilization in the Megasphaera is threatened by toxins widespread in feed, which points to dietary interventions to support calf health.

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wraf147 - Version of Record
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Accepted/In Press date: 9 July 2025
Published date: 14 July 2025
Keywords: Megasphaera, lactate utilization, metabolic trade-offs, niche differentiation, rumen
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Identifiers

Local EPrints ID: 504205
URI: http://eprints.soton.ac.uk/id/eprint/504205
DOI: doi:10.1093/ismejo/wraf147
ISSN: 1751-7362
PURE UUID: c6c9243b-e87e-4456-91d8-061028807ab6
ORCID for Fátima C Pereira: ORCID iD orcid.org/0000-0002-1288-6481

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Date deposited: 29 Aug 2025 16:36
Last modified: 30 Aug 2025 02:11

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Contributors

Author: Cameron R Strachan
Author: Connor M Bowers
Author: Byung-Chul Kim
Author: Tea Movsesijan
Author: Viktoria Neubauer
Author: Anna J Mueller
Author: Xiaoqian A Yu
Author: Fátima C Pereira ORCID iD
Author: Veronika Nagl
Author: Johannes Faas
Author: Martin Wagner
Author: Qendrim Zebeli
Author: Paul J Weimer
Author: Pieter Candry
Author: Martin F Polz
Author: Christopher E Lawson
Author: Evelyne Selberherr

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