Genomic insights into the evolution of secondary metabolism of Escovopsis and its allies, specialized fungal symbionts of fungus-farming ants

Aileen Berasategui Lopez; Hassan Salem; Abraham G. Moller; Yuliana Christopher; Quimi Vidaurre Montoya; Caitlin Conn; Timothy D. Read; Andre Rodrigues; Nadine Ziemert; Nicole M. Gerardo

doi:10.1128/msystems.00576-24

Genomic insights into the evolution of secondary metabolism of Escovopsis and its allies, specialized fungal symbionts of fungus-farming ants

Aileen Berasategui Lopez^*, Hassan Salem, Abraham G. Moller, Yuliana Christopher, Quimi Vidaurre Montoya, Caitlin Conn, Timothy D. Read, Andre Rodrigues, Nadine Ziemert, Nicole M. Gerardo^*

^*Corresponding author for this work

Ecology & Evolution

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

The metabolic intimacy of symbiosis often demands the work of specialists. Natural products and defensive secondary metabolites can drive specificity by ensuring infection and propagation across host generations. But in contrast to bacteria, little is known about the diversity and distribution of natural product biosynthetic pathways among fungi and how they evolve to facilitate symbiosis and adaptation to their host environment. In this study, we define the secondary metabolism of Escovopsis and closely related genera, symbionts in the gardens of fungus-farming ants. We ask how the gain and loss of various biosynthetic pathways correspond to divergent lifestyles. Long-read sequencing allowed us to define the chromosomal features of representative Escovopsis strains, revealing highly reduced genomes composed of seven to eight chromosomes. The genomes are highly syntenic with macrosynteny decreasing with increasing phylogenetic distance, while maintaining a high degree of mesosynteny. An ancestral state reconstruction analysis of biosynthetic pathways revealed that, while many secondary metabolites are shared with non-ant-associated Sordariomycetes, 56 pathways are unique to the symbiotic genera. Reflecting adaptation to diverging ant agricultural systems, we observe that the stepwise acquisition of these pathways mirrors the ecological radiations of attine ants and the dynamic recruitment and replacement of their fungal cultivars. As different clades encode characteristic combinations of biosynthetic gene clusters, these delineating profiles provide important insights into the possible mechanisms underlying specificity between these symbionts and their fungal hosts. Collectively, our findings shed light on the evolutionary dynamic nature of secondary metabolism in Escovopsis and its allies, reflecting adaptation of the symbionts to an ancient agricultural system.

Original language	English
Article number	e00576-24
Journal	mSystems
Volume	9
Issue number	7
Early online date	21 Jun 2024
DOIs	https://doi.org/10.1128/msystems.00576-24
Publication status	Published - 23 Jul 2024

Funding

We acknowledge funding from the German Research Foundation (Deutsche Forschungsgemeinschaft) under the individual grant program (BE6922/1-1) and Germany\u2019s Excellence Strategy (EXC 2124\u2013390838134) to A.B. and the Alexander Humboldt Foundation to H.S. This work was also funded by the National Science Foundation: C.C., award DBI-711545; H.S., N.G., and T.D.R., award DEB-1754595; N.G., award DEB-1927411. A.R. and Q.V.M. would like to thank the S\u00E3o Paulo Research Foundation [Funda\u00E7\u00E3o de Amparo \u00E0 Pesquisa do Estado de S\u00E3o Paulo (FAPESP)], grant number 2019/03746-0 and 2021/04706-1. We acknowledge funding from the German Research Foundation (Deutsche Forschungsgemeinschaft) under the individual grant program (BE6922/1-1) and Germany\u2019s Excellence Strategy (EXC 2124\u2013390838134) to A.B. and the Alexander Humboldt Foundation to H.S. This work was also funded by the National Science Foundation: C.C., award DBI-711545; H.S., N.G., and T.D.R., award DEB-1754595; N.G., award DEB-1927411. A.R. and Q.V.M. would like to thank the S\u00E3o Paulo Research Foundation [Funda\u00E7\u00E3o de Amparo \u00E0 Pesquisa do Estado de S\u00E3o Paulo (FAPESP)], grant number 2019/03746-0 and 2021/04706-1. We are thankful to Drs. Herm\u00F3genes Fernandez, Cameron Currie, and Ulrich Mueller for providing samples, Dr. In\u00E8s Pons for statistical advice, Dr. Martina Adamek for advice on BGC clustering, and Dr. J. Lovell and Dr. Navarro for help in troubleshooting analyses. A.B., H.S., N.G., and N.Z. conceived the study. N.G. and Y.C. collected samples. A.B., H.S., and C.C. performed DNA extractions. A.B., H.S., and A.G.M. assembled genomes. A.B., Q.V.M., and A.R. performed analyses. A.B. wrote the manuscript. All authors provided valuable comments on the manuscript. Deutsche Forschungsgemeinschaft (DFG) BE6922/1-1 Deutsche Forschungsgemeinschaft (DFG) EXC 2124 - 390838134 National Science Foundation (NSF) 1711545 National Science Foundation (NSF) 1754595 National Science Foundation (NSF) 1927411 Funda\u00E7\u00E3o de Amparo \u00E0 Pesquisa do Estado de S\u00E3o Paulo (FAPESP) 2021/04706-1 Funda\u00E7\u00E3o de Amparo \u00E0 Pesquisa do Estado de S\u00E3o Paulo (FAPESP) 2019/03746-0

Funders	Funder number
FAPESP
Alexander Humboldt Foundation
German Research Foundation
Fundação de Amparo à Pesquisa do Estado de São Paulo	1754595, 1711545, 2019/03746-0, EXC 2124 - 390838134, 2021/04706-1
Fundação de Amparo à Pesquisa do Estado de São Paulo
Deutsche Forschungsgemeinschaft	BE6922/1-1, EXC 2124–390838134
Deutsche Forschungsgemeinschaft
National Science Foundation	DEB-1754595, DBI-711545, DEB-1927411
National Science Foundation

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Berasategui Lopez, A., Salem, H., Moller, A. G., Christopher, Y., Vidaurre Montoya, Q., Conn, C., Read, T. D., Rodrigues, A., Ziemert, N., & Gerardo, N. M. (2024). Genomic insights into the evolution of secondary metabolism of Escovopsis and its allies, specialized fungal symbionts of fungus-farming ants. mSystems, 9(7), Article e00576-24. https://doi.org/10.1128/msystems.00576-24

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abstract = "The metabolic intimacy of symbiosis often demands the work of specialists. Natural products and defensive secondary metabolites can drive specificity by ensuring infection and propagation across host generations. But in contrast to bacteria, little is known about the diversity and distribution of natural product biosynthetic pathways among fungi and how they evolve to facilitate symbiosis and adaptation to their host environment. In this study, we define the secondary metabolism of Escovopsis and closely related genera, symbionts in the gardens of fungus-farming ants. We ask how the gain and loss of various biosynthetic pathways correspond to divergent lifestyles. Long-read sequencing allowed us to define the chromosomal features of representative Escovopsis strains, revealing highly reduced genomes composed of seven to eight chromosomes. The genomes are highly syntenic with macrosynteny decreasing with increasing phylogenetic distance, while maintaining a high degree of mesosynteny. An ancestral state reconstruction analysis of biosynthetic pathways revealed that, while many secondary metabolites are shared with non-ant-associated Sordariomycetes, 56 pathways are unique to the symbiotic genera. Reflecting adaptation to diverging ant agricultural systems, we observe that the stepwise acquisition of these pathways mirrors the ecological radiations of attine ants and the dynamic recruitment and replacement of their fungal cultivars. As different clades encode characteristic combinations of biosynthetic gene clusters, these delineating profiles provide important insights into the possible mechanisms underlying specificity between these symbionts and their fungal hosts. Collectively, our findings shed light on the evolutionary dynamic nature of secondary metabolism in Escovopsis and its allies, reflecting adaptation of the symbionts to an ancient agricultural system.",

author = "{Berasategui Lopez}, Aileen and Hassan Salem and Moller, {Abraham G.} and Yuliana Christopher and {Vidaurre Montoya}, Quimi and Caitlin Conn and Read, {Timothy D.} and Andre Rodrigues and Nadine Ziemert and Gerardo, {Nicole M.}",

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AU - Berasategui Lopez, Aileen

AU - Salem, Hassan

AU - Moller, Abraham G.

AU - Christopher, Yuliana

AU - Vidaurre Montoya, Quimi

AU - Conn, Caitlin

AU - Read, Timothy D.

AU - Rodrigues, Andre

AU - Ziemert, Nadine

AU - Gerardo, Nicole M.

PY - 2024/7/23

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N2 - The metabolic intimacy of symbiosis often demands the work of specialists. Natural products and defensive secondary metabolites can drive specificity by ensuring infection and propagation across host generations. But in contrast to bacteria, little is known about the diversity and distribution of natural product biosynthetic pathways among fungi and how they evolve to facilitate symbiosis and adaptation to their host environment. In this study, we define the secondary metabolism of Escovopsis and closely related genera, symbionts in the gardens of fungus-farming ants. We ask how the gain and loss of various biosynthetic pathways correspond to divergent lifestyles. Long-read sequencing allowed us to define the chromosomal features of representative Escovopsis strains, revealing highly reduced genomes composed of seven to eight chromosomes. The genomes are highly syntenic with macrosynteny decreasing with increasing phylogenetic distance, while maintaining a high degree of mesosynteny. An ancestral state reconstruction analysis of biosynthetic pathways revealed that, while many secondary metabolites are shared with non-ant-associated Sordariomycetes, 56 pathways are unique to the symbiotic genera. Reflecting adaptation to diverging ant agricultural systems, we observe that the stepwise acquisition of these pathways mirrors the ecological radiations of attine ants and the dynamic recruitment and replacement of their fungal cultivars. As different clades encode characteristic combinations of biosynthetic gene clusters, these delineating profiles provide important insights into the possible mechanisms underlying specificity between these symbionts and their fungal hosts. Collectively, our findings shed light on the evolutionary dynamic nature of secondary metabolism in Escovopsis and its allies, reflecting adaptation of the symbionts to an ancient agricultural system.

AB - The metabolic intimacy of symbiosis often demands the work of specialists. Natural products and defensive secondary metabolites can drive specificity by ensuring infection and propagation across host generations. But in contrast to bacteria, little is known about the diversity and distribution of natural product biosynthetic pathways among fungi and how they evolve to facilitate symbiosis and adaptation to their host environment. In this study, we define the secondary metabolism of Escovopsis and closely related genera, symbionts in the gardens of fungus-farming ants. We ask how the gain and loss of various biosynthetic pathways correspond to divergent lifestyles. Long-read sequencing allowed us to define the chromosomal features of representative Escovopsis strains, revealing highly reduced genomes composed of seven to eight chromosomes. The genomes are highly syntenic with macrosynteny decreasing with increasing phylogenetic distance, while maintaining a high degree of mesosynteny. An ancestral state reconstruction analysis of biosynthetic pathways revealed that, while many secondary metabolites are shared with non-ant-associated Sordariomycetes, 56 pathways are unique to the symbiotic genera. Reflecting adaptation to diverging ant agricultural systems, we observe that the stepwise acquisition of these pathways mirrors the ecological radiations of attine ants and the dynamic recruitment and replacement of their fungal cultivars. As different clades encode characteristic combinations of biosynthetic gene clusters, these delineating profiles provide important insights into the possible mechanisms underlying specificity between these symbionts and their fungal hosts. Collectively, our findings shed light on the evolutionary dynamic nature of secondary metabolism in Escovopsis and its allies, reflecting adaptation of the symbionts to an ancient agricultural system.

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DO - 10.1128/msystems.00576-24

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ER -

Genomic insights into the evolution of secondary metabolism of Escovopsis and its allies, specialized fungal symbionts of fungus-farming ants

Abstract

Funding

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