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The consequences of budding versus binary fission on adaptation and aging in primitive multicellularity
Umeå universitet, Teknisk-naturvetenskapliga fakulteten, Institutionen för matematik och matematisk statistik. Integrated Science Lab, Umeå University, Umeå, Sweden.
Georgia Institute of Technology, School of Biological Sciences, GA, Atlanta, United States.
BEACON Center for the Study of Evolution in Action, Department of Biology, University of Washington, WA, Seattle, United States.
Georgia Institute of Technology, School of Biological Sciences, GA, Atlanta, United States.
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2021 (Engelska)Ingår i: Genes, E-ISSN 2073-4425, Vol. 12, nr 5, artikel-id 661Artikel i tidskrift (Refereegranskat) Published
Abstract [en]

Early multicellular organisms must gain adaptations to outcompete their unicellular ancestors, as well as other multicellular lineages. The tempo and mode of multicellular adaptation is influenced by many factors including the traits of individual cells. We consider how a fundamental aspect of cells, whether they reproduce via binary fission or budding, can affect the rate of adaptation in primitive multicellularity. We use mathematical models to study the spread of beneficial, growth rate mutations in unicellular populations and populations of multicellular filaments reproducing via binary fission or budding. Comparing populations once they reach carrying capacity, we find that the spread of mutations in multicellular budding populations is qualitatively distinct from the other populations and in general slower. Since budding and binary fission distribute age-accumulated damage differently, we consider the effects of cellular senescence. When growth rate decreases with cell age, we find that beneficial mutations can spread significantly faster in a multicellular budding population than its corresponding unicellular population or a population reproducing via binary fission. Our results demonstrate that basic aspects of the cell cycle can give rise to different rates of adaptation in multicellular organisms.

Ort, förlag, år, upplaga, sidor
MDPI, 2021. Vol. 12, nr 5, artikel-id 661
Nyckelord [en]
Adaptation, Aging, Binary fission, Budding, Filaments, Multicellularity
Nationell ämneskategori
Evolutionsbiologi
Identifikatorer
URN: urn:nbn:se:umu:diva-183525DOI: 10.3390/genes12050661ISI: 000653921500001Scopus ID: 2-s2.0-85105195781OAI: oai:DiVA.org:umu-183525DiVA, id: diva2:1557272
Tillgänglig från: 2021-05-25 Skapad: 2021-05-25 Senast uppdaterad: 2024-07-04Bibliografiskt granskad
Ingår i avhandling
1. Adaptation during the early evolution of multicellularity: mathematical models reveal the impact of unicellular history, environmental stress, and life cycles
Öppna denna publikation i ny flik eller fönster >>Adaptation during the early evolution of multicellularity: mathematical models reveal the impact of unicellular history, environmental stress, and life cycles
2024 (Engelska)Doktorsavhandling, sammanläggning (Övrigt vetenskapligt)
Alternativ titel[sv]
Anpassning av flercellighet under tidig evolution : matematisk modellering av encellig historia, miljöstress, och livscykler
Abstract [en]

Multicellular organisms, such as plants and animals, have independently evolved several times over the last hundreds of millions of years. The evolution of multicellularity has significantly shaped modern ecosystems, yet its origins remain largely unknown. Due to the ancient history and the small size scale of early multicellular organisms, few intact fossils have been preserved. To uncover the origins of large and complex life, researchers have turned to alternative methods such as phylogenetic modeling, experimental evolution, and theoretical frameworks. While these approaches have provided novel insights in the early steps of multicellular evolution, few studies have considered the role of adaptation in these novel life cycles. This thesis addresses the gap in our knowledge by employing mathematical modeling and computer simulations to study adaptation in novel multicellular life cycles.

The first paper investigates the effects of unicellular reproduction modes, such as budding or binary fission, on the spread of growth rate mutations. It demonstrates that unicellular history significantly influences the adaptation rate, with budding cells exhibiting greater sensitivity to the spatial distribution of mutations.

In Paper II, the role of multicellular reproduction mode for the adaptation of altruistic and selfish mutations is explored. Specifically, the study examines how adaptation is affected when the filaments are exposed to a size-based selective pressure. It reveals that while the adaptation of altruistic mutations is favored by large offspring, the spread of selfish mutations depends on both offspring size and selection strength.

While Papers I and II assume deterministic life cycle structures at the multicellular level, paper III investigates the evolution of life cycle regulation when cells use internal information. The model demonstrates that when cells only have access to a limited amount of information, there is significant variation in the types of life cycles that emerge. This suggests that to evolve regulated life cycles, additional mechanisms beyond internal information may be necessary, such as cell communication.

Papers I-III explore multicellular life cycles where all cells are of the same type, yet most multicellular organisms have evolved cell differentiation, with specialized cells performing various tasks. In Paper IV, the evolutionary paths leading to differentiated multicellularity are investigated when a unicellular population is exposed to an abiotic (non-evolving) selective pressure. The model reveals that while a wide range of phenotypic backgrounds and environmental conditions may induce differentiation and multicellularity, continued adaptation to the stress eventually leads to reversion to unicellularity. This reversion occurs because as cells adapt to the stress, the costs associated with differentiation and group formation may no longer be justified. One potential strategy to prevent reversion could involve considering biotic selective pressures that can co-evolve with the population.

Lastly, paper V delves into organisms composed by combinations of uni- and multicellular species. Utilizing this framework to examine present multi-species multicellularity reveals that the species composition influences both the ease of partnership establishment and its stability. Additionally, these chimeric groups can reproduce through various strategies, including fragmentation and complete dissociation. Leaving the constellation endows organisms with a memory of prior partnerships, enhancing their adaptability in forming new ones. This extension opens up novel evolutionary pathways for further exploration.

In summary, this thesis offers new insights into how the life cycle structures of simple multicellular organisms impact mutation accumulation and the acquisition of new traits. The adaptability of organisms plays a pivotal role in fostering higher complexity and paving the way for further evolution. Enhancing our understanding in this domain will continue to illuminate the origins of complex life and elucidate the evolutionary factors underlying the rich diversity of multicellular organisms we encounter today.

Ort, förlag, år, upplaga, sidor
Umeå: Umeå University, 2024. s. 66
Serie
Research report in mathematics, ISSN 1653-0810 ; 77/24
Nyckelord
Multicellularity, evolution, adaptation, life cycles, mutations, unicellular history, information, selective pressures, fragmentation, computational simulations, mathematical modeling
Nationell ämneskategori
Evolutionsbiologi Beräkningsmatematik
Identifikatorer
urn:nbn:se:umu:diva-224561 (URN)978-91-8070-382-6 (ISBN)978-91-8070-381-9 (ISBN)
Disputation
2024-06-14, Hörsal MIT.A.121, Umeå, 09:00 (Engelska)
Opponent
Handledare
Tillgänglig från: 2024-05-24 Skapad: 2024-05-20 Senast uppdaterad: 2024-05-20Bibliografiskt granskad

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