Fact-checked by Grok 2 weeks ago

The Major Transitions in Evolution

The Major Transitions in Evolution is a foundational framework in evolutionary biology, introduced by John Maynard Smith and Eörs Szathmáry in their 1995 book of the same name, which identifies a series of eight pivotal events in life's history where the fundamental units of selection and cooperation shifted to higher levels of organization.^[1] These transitions mark the progression from simple replicating molecules to complex human societies, each involving the subordination of lower-level entities—such as genes or cells—into cooperative wholes that function as new Darwinian individuals, thereby increasing biological complexity.^[2] Central to this concept is the idea that such changes occur through alterations in how heritable information is encoded, transmitted, and translated, often requiring mechanisms to suppress conflict among subunits while enhancing collective fitness.^[3] The eight major transitions, as originally delineated, begin with the encapsulation of independent replicating molecules into protocells, forming the first compartmented units of life capable of division.^[3] This is followed by the aggregation of replicators into chromosomes, enabling more reliable inheritance; the evolution of the genetic code, separating RNA's roles into DNA for storage and proteins for catalysis; and the symbiosis leading to eukaryotic cells from prokaryotic ancestors.^[2] Subsequent transitions include the shift from asexual reproduction to sexual populations, which diversifies genetic combinations; the development of multicellularity from solitary protists into differentiated colonies of plants, animals, and fungi; the formation of eusocial insect societies where individuals sacrifice reproduction for group benefit; and finally, the emergence of human linguistic societies from primate groups, enabling collective knowledge transmission beyond genetic means.^[3] What unites these transitions is a recurring pattern of fraternal (similar subunits cooperating) or egalitarian (dissimilar subunits integrating, like endosymbiosis) dynamics, often stabilized by innovations in inheritance systems that align individual and group interests.^[3] Maynard Smith and Szathmáry's analysis, building on earlier ideas of multilevel selection, argues that these events explain the sporadic bursts of complexity in the fossil record rather than gradual accumulation, challenging purely gradualist views of evolution.^[2] The framework has influenced subsequent research, including revisions that incorporate additional events like the origin of plastids and emphasize the role of rare, irreversible innovations in driving long-term evolutionary trends.^[3] This perspective not only illuminates the hierarchical structure of life—from genes to societies—but also provides tools for understanding contemporary evolutionary questions, such as the potential for further transitions in synthetic biology or microbial consortia.^[3] By focusing on information flow and cooperation, The Major Transitions in Evolution offers a comprehensive lens for interpreting the unity and diversity of living systems.^[1]

Overview of the Concept

Definition and Core Principles

The major transitions in evolution refer to pivotal evolutionary events in which lower-level biological entities, such as molecules or cells, combine to form higher-level units of selection that function and evolve as cohesive wholes, fundamentally altering the mechanisms of heredity and cooperation.^[2] These transitions are characterized by a shift in how genetic information is stored and transmitted, enabling the emergence of more complex organizational levels while reducing the autonomy of the constituent parts.^[2] Coined in the seminal 1995 book by John Maynard Smith and Eörs Szathmáry, the concept builds on earlier ideas, including Lynn Margulis's theory of symbiosis as the origin of eukaryotic cells.^[1]^[2] At their core, major transitions involve the irreversible loss of independent replication by lower-level entities, which become integrated into a collective that replicates as a single unit, thereby increasing overall complexity and suppressing potential conflicts among subunits.^[2] This process fosters hierarchical evolution, where new levels of organization—such as chromosomes from independent replicators or multicellular organisms from unicellular ones—emerge through mechanisms like genetic linkage, compartmentalization, or division of labor that prioritize group-level fitness over individual replication.^[4] Such principles highlight how transitions stabilize cooperation, preventing "cheater" strategies that could undermine the collective, and drive the evolution of life's hierarchical structure.^[2] The framework delineates eight key transitions spanning from replicating molecules to human societies, each exemplifying these principles in the progression toward greater biological complexity.^[2]

Historical Context and Development

The major transitions framework emerged from foundational ideas in evolutionary biology concerning levels of selection and the origins of biological complexity. George C. Williams' 1966 book Adaptation and Natural Selection provided early precursors by critiquing group selection and advocating for a focus on individual-level adaptations, thereby influencing multilevel selection theory and discussions of hierarchical units in evolution.^[5] Similarly, Lynn Margulis' 1981 work Symbiosis in Cell Evolution emphasized symbiosis as a key driver of evolutionary innovation, particularly through endosymbiotic events that integrated prokaryotes into eukaryotic cells, challenging gradualist views of complexity. John Maynard Smith's contributions in the 1980s further shaped the intellectual landscape, particularly his explorations of genetic conflict and levels of selection, as detailed in his 1982 book Evolution and the Theory of Games, where he applied game-theoretic models to conflicts between genetic elements and higher-level entities.^[6] Concurrently, Eörs Szathmáry focused on chemical evolution and the prebiotic origins of life, investigating replicator dynamics and metabolic networks in works such as his 1989 work on the integration of the earliest genetic information, which highlighted transitions from simple chemical systems to informational polymers. These parallel developments culminated in their collaboration, building on the RNA world hypothesis proposed by Walter Gilbert in 1986, which posited self-replicating RNA as a bridge between chemistry and biology.^[7] Prior to the formal book publication, Maynard Smith and Szathmáry outlined key aspects of the framework in their 1995 review article in Nature, which summarized the major transitions and their implications for evolutionary information flow.^[2] This article, along with earlier joint explorations like their 1993 discussion on replicator transitions, formalized the concept by identifying patterns such as the suppression of conflict within emerging higher-level units. The framework thus synthesized disparate threads from multilevel selection, symbiosis, and chemical origins into a cohesive view of evolution's pivotal shifts.

The 1995 Book by Maynard Smith and Szathmáry

Authors and Publication Details

John Maynard Smith (1920–2004) was a British theoretical evolutionary biologist renowned for his pioneering application of game theory to evolutionary problems, particularly through the concept of evolutionarily stable strategies, which analyzed behavioral evolution under natural selection.^[8] His work built on the foundations of population genetics laid by earlier figures such as Ronald Fisher, J.B.S. Haldane, and Sewall Wright, integrating mathematical rigor into studies of adaptation and stability in biological systems.^[9] Maynard Smith held academic positions at University College London and the University of Sussex, where he served as a professor of biology until his retirement.^[10] Eörs Szathmáry (born 1959) is a Hungarian theoretical evolutionary biologist specializing in the origins of life and the mathematical modeling of evolutionary processes.^[11] He earned his PhD from Eötvös Loránd University in Budapest and has held professorships there in biology, focusing on topics like the evolution of genetic codes and multicellularity. Szathmáry served as a permanent fellow at the Collegium Budapest Institute for Advanced Study from 1995 to 2011; since 2011, he has been the director of the Parmenides Center for the Conceptual Foundations of Science.^[12] The seminal work The Major Transitions in Evolution was co-authored by Maynard Smith and Szathmáry and first published in 1995 by W. H. Freeman and Company, with a subsequent edition by Oxford University Press in 1998 (ISBN 978-0-19-850294-4, 360 pages).^[1] The book targets professional biologists, presupposing familiarity with advanced concepts in evolutionary theory and genetics.^[13] Complementing the book, the authors published a foundational review article, "The major evolutionary transitions," in Nature in 1995, which outlined the core framework of informational and organizational shifts in evolution.^[2] In 1999, they released a more accessible companion volume, The Origins of Life: From the Birth of Life to the Origin of Language (Oxford University Press), adapting key ideas from the original work for a broader audience while exploring life's early stages up to linguistic emergence.

Central Thesis and Structure of the Book

The central thesis of The Major Transitions in Evolution posits that the history of life is characterized by a series of rare, punctuated major evolutionary transitions, each marking a fundamental shift in the organization and transmission of genetic information, thereby creating novel levels of biological individuality and units of selection, in contrast to the more common gradual adaptations within existing systems.^[1] These transitions, the authors argue, represent discontinuities in evolutionary progress where lower-level entities (such as molecules or cells) combine to form higher-level entities (such as chromosomes or multicellular organisms) with enhanced cooperative capabilities, fundamentally altering the mechanisms of inheritance and heredity.^[14] This framework challenges traditional views of steady complexity increase, emphasizing instead that such leaps occur infrequently and drive the overall trajectory toward greater organizational complexity.^[1] A core argument throughout the book is that these major transitions resolve the evolutionary challenge of cooperation among selfish lower-level units by establishing mechanisms that suppress "cheaters"—entities that exploit collective benefits without contributing—through innovations like physical compartments, genetic linkage, or enforced sterility in reproductive divisions of labor.^[14] For instance, the authors illustrate how alignment of interests at higher levels, such as in eusocial insect castes, stabilizes cooperation and elevates the group as a new unit of selection, preventing the breakdown that would otherwise favor individualistic defectors.^[1] This theoretical lens unifies diverse biological phenomena under a single explanatory principle, highlighting how transitions not only increase complexity but also enhance the reliability of information transfer across generations.^[14] The book further conceptualizes evolution as a progressive flow of information, tracing its evolution from simple replicating molecules through cellular, organismal, and societal stages, ultimately extending to cultural transmission via human language and "memes" as non-genetic replicators, thereby bridging biological and cultural evolution within a cohesive informational paradigm.^[1] This perspective underscores the transitions' role in creating hierarchical systems where information is increasingly encoded, protected, and disseminated at broader scales.^[14] Structurally, the book is organized into 12 chapters that build from foundational concepts to specific case studies and forward-looking synthesis, grouping content into implicit sections on the chemical origins of life (chapters 1–6), cellular and organismal evolution (chapters 7–9), and higher-level social systems (chapters 10–11), with a concluding chapter on future research directions.^[1] Each transition is examined in dedicated chapters featuring theoretical models, empirical evidence, and discussions of underlying mechanisms, exemplified by the eight key transitions such as the shift from independent replicators to chromosomes or from solitary individuals to eusocial colonies.^[1] This layout allows for a systematic progression, integrating mathematical models of cooperation and information theory where relevant to support the overarching thesis.^[14]

Characteristics of Major Transitions

Common Features Across Transitions

The major evolutionary transitions are characterized by the formation of collectives composed of lower-level entities, such as individual replicators or organisms, which integrate to function as a new, higher-level unit of selection in evolution.^[3] This process elevates the collective to a level where natural selection acts primarily on its properties, rather than solely on the constituent parts.^[15] A defining feature across these transitions is the loss of independent replication by the subunits, rendering them unable to propagate autonomously outside the collective. For instance, subunits that previously replicated on their own become dependent on the higher-level structure for reproduction, thereby reducing competition at the lower level and stabilizing the new unit.^[3] Transitions also involve the emergence of division of labor and functional specialization among the subunits within the collective, allowing the higher-level entity to achieve capabilities beyond those of its components.^[15] This specialization enhances overall efficiency and adaptability, as different subunits take on distinct roles that complement one another. Furthermore, these transitions introduce novel mechanisms for transmitting information and heritable variation, shifting from simpler forms like direct chemical signaling to more complex systems such as encoded genetic instructions. Such innovations in information flow enable the collective to maintain coherence and evolve as a unified entity.^[3] These transitions are often irreversible because the suppression of lower-level variability—through the loss of independent replication and restricted information transfer—prevents reversion to prior states.^[15] Additionally, potential conflicts between subunit and collective interests are resolved via enforcement mechanisms, such as alignment of fitness interests or policing strategies, which promote cooperation at the higher level.^[3] This framework underscores their role in generating new units of selection, as explored in subsequent theoretical developments.^[15]

Role in Units of Selection and Complexity

Major evolutionary transitions redefine the units of selection by establishing higher-level entities, often termed superorganisms, where group-level selection predominates over selection at the level of individual subunits. In this framework, lower-level components—such as molecules, cells, or organisms—lose autonomy as they become integrated parts of a cohesive whole, with the fitness of the superorganism determining evolutionary outcomes rather than the independent replication or survival of subunits. This shift resolves pervasive conflicts that arise when subunits pursue selfish strategies detrimental to the group, enabling the higher unit to act as a single adaptive entity.^[2] These transitions drive an increase in biological complexity by introducing new hierarchical levels of organization, which unlock adaptive possibilities unavailable at prior stages. For instance, the emergence of chromosomes from independent replicators creates a structured genome that coordinates inheritance more effectively, while the formation of multicellularity layers cellular cooperation atop genomic stability, facilitating specialized tissues and organs. Each transition builds upon the previous, forming nested hierarchies from molecular assemblies to societal collectives, thereby expanding the scope for evolutionary innovation and ecological dominance. This hierarchical escalation is not merely additive but transformative, as it allows emergent properties—such as division of labor or collective decision-making—to evolve under selection at the superorganism level.^[2] The theoretical underpinning for these dynamics is multilevel selection theory (MLS), pioneered by David Sloan Wilson in the 1970s, which formalizes how natural selection operates across multiple biological scales simultaneously. In MLS, between-group variation can favor traits that enhance group fitness, even if they reduce individual subunit fitness, provided mechanisms suppress intra-unit conflicts such as cheating or defection. During major transitions, this suppression—through mechanisms like genetic linkage, compartmentalization, or social enforcement—elevates the group to a new unit of selection, stabilizing cooperation and amplifying adaptive potential. Wilson's trait-group model illustrates how even weak group structuring can tip the balance toward higher-level adaptation when within-group competition is curtailed.^[16]

The Eight Original Transitions

From Replicating Molecules to Compartmented Populations

The earliest major transition in evolution marked the shift from independent self-replicating molecules, such as RNA-like polymers dispersed in the primordial soup, to populations of these molecules enclosed within primitive compartments known as protocells. This transition, proposed by Maynard Smith and Szathmáry, transformed loosely organized chemical replicators into spatially confined units capable of collective reproduction, laying the foundation for cellular life. Key mechanisms driving this transition involved the spontaneous self-assembly of amphiphilic lipids into vesicles under prebiotic conditions, forming bilayer membranes that encapsulate replicators without requiring enzymatic intervention. These protocells emerged as replicating molecules became trapped within lipid compartments, allowing for the concentration of genetic material and metabolic precursors in a protected microenvironment.^[17] The primary benefits of compartmentalization included safeguarding replicators from dilution in the vast oceanic environment, which would otherwise limit their exponential growth, and reducing replication errors by maintaining higher local concentrations that facilitate accurate template-directed synthesis. Additionally, these vesicles enabled rudimentary division through processes like fusion and fission, permitting the protocell population to propagate as a unit rather than as scattered individuals. This transition remains unobservable directly due to the ancient timescale and lack of fossil evidence, but it is inferred from experimental models of the lipid world hypothesis, which demonstrates how self-assembling liposomes could sustain Darwinian evolution prior to genetic polymers, and from alkaline hydrothermal vent scenarios where mineral-rich pores naturally form compartment-like structures.^[17] In vent environments, proton gradients across thin iron-sulfide walls provided energy for early metabolism while confining replicators, thus protecting them from environmental fluctuations and promoting stable populations. A central challenge was maintaining cooperative replication within compartments, as "selfish" parasitic molecules could proliferate without contributing to vesicle division, potentially destabilizing the higher-level unit through defection. Maynard Smith and Szathmáry highlighted that such conflicts were mitigated by the stochastic nature of compartment formation, which randomly partitions replicators and favors cooperative ensembles over time via multilevel selection. This resolution ensured the longevity of compartmented populations, setting the stage for further genetic innovations like the RNA world.

From Independent Replicators to Chromosomes

The transition from independent replicators to chromosomes represents a pivotal step in early evolution, where loosely associated genetic elements were integrated into a single, cohesive unit to enhance stability and fidelity. In the hypothesized RNA world, independent RNA replicators functioned autonomously, but this system was vulnerable to parasitic or "selfish" elements that replicated more rapidly than cooperative ones, exploiting the resources of the collective without contributing to overall function.^[3] These cheater replicators could destabilize the population by outcompeting beneficial molecules, leading to a breakdown in cooperative replication dynamics, as modeled in hypercycle theories where parasites disrupt cyclic information flow. Maynard Smith and Szathmáry (1995) argued that this transition addressed such intragenomic conflicts by evolving linked genetic structures, ensuring that all elements replicated synchronously rather than independently. The emergence of chromosomes involved the physical and functional linkage of multiple genes into a single replicative unit, enabling coordinated copying and reducing the risk of fragmentation or loss during replication. This linkage minimized the "assortment load," where mismatched replication rates among independent elements lead to inefficiency, by treating the genome as a unified entity whose fitness depends on the collective performance of its parts.^[3] Key mechanisms included the evolution of more accurate replicative enzymes, such as RNA-dependent RNA polymerases (ribozymes in the RNA world), which lowered error rates and allowed for longer, stable molecular chains without exceeding the error threshold for reliable inheritance.^[18] Additionally, the development of topoisomerase-like activities—enzymes or ribozymes that relieve topological strain during replication—facilitated the unwinding and rejoining of linked strands, preventing tangles that could fragment the emerging chromosome.^[19] These innovations collectively reduced genome fragmentation and promoted the integrity of multi-gene units, as detailed in analyses of early replicative machineries.^[20] This transition is intrinsically tied to the RNA world hypothesis, where self-replicating RNA molecules served dual roles as information carriers and catalysts, setting the stage for more complex genomic organization. Evidence for its occurrence draws from modern prokaryotic systems, where bacterial chromosomes exemplify stable, linked genomes that replicate as integrated wholes, contrasting with plasmids—extrachromosomal elements that behave as selfish replicators, often imposing fitness costs on their hosts while spreading independently.^[21] Plasmids' parasitic nature, including their tendency to encode traits that enhance their own transmission at the expense of chromosomal stability, mirrors the challenges overcome by chromosomal linkage in early evolution.^[22] However, challenges persisted in preventing cheater replicators, whose faster proliferation could still undermine the system unless suppressed by mechanisms like compartmentalization or multilevel selection favoring cooperative units.^[3] This genomic consolidation laid the groundwork for subsequent separations, such as the division between genetic information storage and enzymatic function.

From RNA Genes-Enzymes to DNA-Protein Systems

In the RNA world hypothesis, early life forms relied on RNA molecules to fulfill dual roles as both carriers of genetic information and catalysts for biochemical reactions, exemplified by ribozymes such as self-splicing introns and RNA polymerases that enabled replication. This multifunctional capability of RNA allowed for the emergence of primitive metabolic and replicative systems, but its chemical instability limited the storage and faithful transmission of complex genetic information over time.^[23] The major transition to DNA-protein systems involved a functional division of labor, where DNA assumed the role of a stable genetic repository while proteins evolved as highly efficient, specialized enzymes, enhancing overall cellular efficiency and evolvability. Central to this transition was the evolution of mechanisms for synthesizing DNA from RNA templates and translating genetic information into proteins. Reverse transcriptase-like activities, likely arising from ancient RNA-dependent RNA polymerases, facilitated the initial production of DNA strands, marking an "inverse flow" of information that preceded the unidirectional pathway later formalized in Crick's central dogma. Concurrently, the ribosome—a ribonucleoprotein complex—evolved from RNA-based precursors to catalyze peptide bond formation, enabling the systematic translation of RNA sequences into amino acid chains via the genetic code.^[23] Experimental evidence supports this stepwise development, with ribozymes demonstrated to perform rudimentary polymerization of amino acids, gradually incorporating protein components to refine translation fidelity. The universality of the genetic code across bacteria, archaea, and eukaryotes indicates a single origin for this translation system, likely in the last universal common ancestor (LUCA) approximately 3.5 to 4 billion years ago, shortly after the emergence of life around 4.2 billion years ago. This code, comprising 64 nucleotide triplets assigning 20 standard amino acids and stop signals, provided a robust framework for protein diversity, with its degeneracy minimizing the impact of mutations.^[24] The transition thus inverted the information flow from the RNA-centric era, establishing DNA as the primary heritable material and proteins as the effectors of catalysis, in line with Crick's 1958 central dogma that prohibits routine back-transfer from proteins but accommodates the evolutionary exception via reverse transcription. A key challenge in the RNA world was the high error rate of RNA replication, estimated at 10^{-3} to 10^{-4} mutations per nucleotide per generation due to the molecule's single-stranded nature and vulnerability to hydrolysis, which constrained genome sizes to short lengths.^[25] The adoption of double-stranded DNA addressed this by offering greater chemical stability—resistant to base-catalyzed degradation—and a lower intrinsic mutation rate (around 10^{-5} to 10^{-6}), allowing for longer, more accurate genomes that supported increased complexity in early prokaryotic-like cells.^[19] This shift not only reduced error propagation but also enabled the storage of larger informational repertoires, paving the way for the diversification of metabolic functions.^[25]

From Prokaryotes to Eukaryotes

The transition from prokaryotic cells, such as bacteria and archaea, to eukaryotic cells represents a pivotal major evolutionary transition, marked by the emergence of complex cellular organization including a membrane-bound nucleus, mitochondria, and other organelles. This shift enabled greater metabolic efficiency and cellular complexity, allowing eukaryotes to support larger genomes and more intricate functions compared to the simpler, smaller prokaryotes.^[26] In the framework of major transitions, this event is characterized by the integration of formerly independent entities into a cooperative unit, where the prokaryotic host and endosymbionts formed a new level of selection at the cellular scale.^[27] The primary mechanism driving this transition was endosymbiosis, particularly the incorporation of an alphaproteobacterium as the progenitor of mitochondria, which provided aerobic respiration capabilities to an anaerobic archaeal host.^[28] This endosymbiotic event is estimated to have occurred approximately 2 billion years ago, coinciding with rising atmospheric oxygen levels during the Great Oxidation Event, which favored energy-efficient metabolisms.^[29] The serial endosymbiosis theory, first proposed by Lynn Margulis (then Sagan) in 1967, posited that mitochondria originated from free-living bacteria engulfed by a host cell, with subsequent symbionts contributing to other organelles like chloroplasts in photosynthetic lineages. Strong genetic evidence supports this, as mitochondrial DNA exhibits sequence similarities and phylogenetic affinities to alphaproteobacteria, including shared genes for respiration and protein import.^[30] A major challenge in this transition was the stable integration of endosymbionts, involving extensive gene transfer from the mitochondrial genome to the host nucleus, which reduced the organelle's autonomy while enhancing host control.^[31] This endosymbiotic gene transfer, occurring in large chunks, is estimated to have transferred approximately 400-1,000 genes from the alphaproteobacterial endosymbiont, contributing to about 1-2% of nuclear genes directly attributable to mitochondrial origins, though overall bacterial contributions to eukaryotic genomes are substantially higher (around 50-60%).^[31]^[32] Such transfers were crucial for resolving conflicts between host and symbiont, ensuring mutual dependence and preventing reversion to free-living states, thus solidifying the eukaryotic cell as a heritable unit.^[33]

From Asexual Clones to Sexual Populations

The transition from asexual reproduction via cloning in early eukaryotes to sexual populations with meiosis and genetic recombination constituted a pivotal major evolutionary transition, fundamentally altering the mechanisms of inheritance and adaptation by introducing outcrossing and the shuffling of genetic material. In asexual lineages, reproduction occurred through mitotic division, producing genetically identical clones that efficiently colonized environments but accumulated deleterious mutations over time without mechanisms to purge them effectively. This vulnerability stemmed from the lack of recombination, which in sexual systems allows the separation of beneficial and harmful alleles, thereby enhancing long-term population fitness. The emergence of sex thus represented a shift from solitary genetic lineages to interdependent populations where individual genomes contributed to collective variability, aligning with the broader framework of major transitions by creating a new unit of selection at the population level.^[2] Sexual reproduction likely originated around 1 to 2 billion years ago in the last eukaryotic common ancestor (LECA), coinciding with the diversification of eukaryotic lineages during the Proterozoic Eon, as evidenced by the conserved presence of meiosis-related genes across diverse taxa. Meiosis evolved from modified mitotic processes, incorporating DNA double-strand breaks induced by enzymes like Spo11 to facilitate recombination and ploidy reduction, enabling the fusion of gametes from different individuals (syngamy) followed by halving of chromosome number. This process addressed the limitations of asexuality by promoting genetic diversity through crossing over and independent assortment, allowing faster adaptation to environmental pressures compared to clonal propagation. Early sexual systems may have begun with isogamy, where gametes of similar size fused, but quickly transitioned to anisogamy, characterized by the production of small, mobile sperm and larger, nutrient-provisioning eggs, driven by disruptive selection favoring gamete specialization for motility and provisioning.^[34]^[35]^[36] A primary challenge to the evolution of sex was the two-fold cost, where in dioecious populations, asexual females could allocate all resources to female offspring, potentially outcompeting sexual females who devote half their reproductive effort to non-reproducing males. John Maynard Smith formalized this cost mathematically, demonstrating that an asexual mutant invading a sexual population would double its frequency each generation unless countered by advantages like recombination's role in purging mutations and accelerating adaptive evolution. Outcrossing mitigates Muller's ratchet—the irreversible buildup of deleterious mutations in asexuals—by recombining genomes to eliminate linked harmful variants, particularly beneficial in small or stressed populations. Additionally, the Red Queen hypothesis posits that sex persists because it generates variable progeny, enabling populations to evade rapidly coevolving parasites that disproportionately infect common genotypes, as supported by empirical studies in systems like fish hosts and their trematode parasites. These benefits collectively outweighed the costs, stabilizing sexual reproduction as the dominant mode in eukaryotes despite occasional reversals to asexuality in certain lineages.^[37]

From Unicellular Protists to Multicellular Organisms

The transition from unicellular protists to multicellular organisms represents a pivotal major evolutionary transition, involving the aggregation and integration of individual cells into cooperative units that function as a single entity, thereby enhancing survival and complexity in eukaryotic lineages. This shift occurred approximately 1 billion years ago, following the emergence of eukaryotic cells, and independently in multiple lineages including those leading to animals, plants, and fungi.^[26] Unicellular protists, such as choanoflagellates, served as precursors, with their colonial forms exhibiting early cell-cell interactions that foreshadowed full multicellularity. Key mechanisms facilitating this transition included the evolution of stable cell adhesion and intercellular signaling, which allowed cells to remain associated and coordinate behaviors. In animal lineages, cadherins emerged as crucial adhesion molecules, enabling homotypic cell-cell binding and the formation of tissues from choanoflagellate-like ancestors. Concurrently, signaling pathways like Notch facilitated cell differentiation by mediating lateral inhibition, where neighboring cells adopt distinct fates to promote specialization within the multicellular body. A hallmark of this integration was the progressive loss of totipotency, as cells relinquished their ability to independently replicate the entire organism, instead committing to somatic roles that supported collective reproduction through germline cells. The volvocine green algae, exemplified by Volvox, provide a compelling model for studying this transition, as they display a graded series from unicellular Chlamydomonas to complex multicellular forms with cellular differentiation and division of labor. In Volvox, extracellular matrix components and developmental regulators, including homologs of animal genes like those involved in patterning, evolved to enforce spherical colony formation and asymmetric cell divisions, marking steps toward multicellular complexity.^[38] Similarly, in animal evolution, the co-option of ancient developmental genes, such as Hox cluster genes, supported body plan organization and axis formation in early multicellular aggregates. A central challenge in this transition was preventing "cheating" cells—those that proliferated selfishly at the expense of the group, akin to cancer precursors—requiring the evolution of enforcement mechanisms like programmed cell death (apoptosis) to eliminate non-cooperative individuals.^[39] Such safeguards ensured group-level selection favored integrated multicellularity, laying the foundation for further transitions like eusocial castes in insects.

From Solitary Individuals to Eusocial Colonies

The transition from solitary multicellular individuals to eusocial colonies marks a profound level of biological organization, where independent animals evolve into interdependent societies characterized by cooperative brood care, reproductive division of labor, and overlapping generations. In eusocial systems, a single or few reproductive individuals, often termed queens, monopolize reproduction, while the majority of colony members—non-reproductive workers—perform tasks such as foraging, nest maintenance, and defense, forgoing personal reproduction to support the group's success. This structure is most prominently observed in insects like ants, bees, and termites, where colonies function as superorganisms, with the unit of selection shifting from the individual to the collective.^[40]^[41] Eusociality first emerged approximately 100–150 million years ago during the Cretaceous period, coinciding with the diversification of flowering plants and early angiosperms that provided new ecological opportunities. Fossil evidence from amber inclusions confirms eusocial behavior in ants and termites by around 100 million years ago, with termites likely originating earlier from cockroach-like ancestors. Today, this transition has yielded extraordinary diversity, particularly in ants, with over 15,700 described species forming vast colonies that dominate terrestrial ecosystems in terms of biomass and ecological roles.^[42]^[43]^[44] The evolution of such altruism, where workers sacrifice their reproductive potential, is primarily explained by kin selection, as formalized in Hamilton's rule: a behavior evolves if the inclusive fitness benefit to relatives, weighted by genetic relatedness r, exceeds the cost to the actor (rB > C). In haplodiploid Hymenoptera (ants, bees, and wasps), sex determination produces diploid females and haploid males, resulting in sisters sharing 75% of their genes—higher than the 50% with their own offspring—favoring worker assistance to the queen's brood over personal reproduction. This mechanism promotes the stability of sterile castes by enhancing the indirect fitness of altruists through shared genes.^[45]^[41] However, eusocial colonies face ongoing challenges from potential selfishness, such as workers attempting to lay eggs and reproduce, which could disrupt colony harmony. Inclusive fitness theory predicts that such conflicts are mitigated by policing mechanisms, where dominant workers or the queen destroy or consume eggs laid by subordinate workers, enforcing reproductive altruism and aligning individual actions with colony-level interests. In honeybees and many ant species, this worker policing reduces selfish reproduction to less than 1% of total eggs, stabilizing the division of labor and preventing colony breakdown. These adaptations underscore how eusociality resolves internal conflicts to achieve higher levels of cooperation and efficiency.^[46]^[47]^[48]

From Primate Societies to Human Language-Based Societies

Primate societies represent a foundational level of social organization among mammals, characterized by stable groups where individuals form alliances and maintain bonds primarily through physical grooming and reciprocal interactions. These behaviors foster cooperation, conflict resolution, and information sharing within groups typically limited to around 150 individuals, as predicted by the social brain hypothesis linking neocortex size to group cohesion. In species like chimpanzees and baboons, grooming serves as a currency for social capital, enabling hierarchies and coalitions that enhance survival without the need for advanced symbolic communication. The major transition to human language-based societies marks a shift to open-ended, cumulative cultural evolution, where non-genetic inheritance through memes—units of cultural information such as ideas, symbols, and practices—replaces or supplements genetic and grooming-based bonding. Coined by Richard Dawkins in 1976, the meme concept posits that cultural elements replicate and evolve analogously to genes, allowing rapid adaptation across generations via imitation and teaching. This transition, as outlined in the framework of major evolutionary transitions, enabled human groups to scale beyond primate limits, forming societies with shared knowledge, division of labor, and collective problem-solving independent of kinship ties. A pivotal mechanism was the emergence of symbolic language approximately 50,000 to 100,000 years ago during the Middle Stone Age in Africa, coinciding with behavioral modernity. Archaeological evidence from Blombos Cave in South Africa includes ochre pieces engraved with geometric patterns dating to about 77,000 years ago, indicating abstract symbolic thought and possibly early proto-language use. Complementing this, the evolution of theory of mind—the capacity to infer others' intentions and beliefs—facilitated unprecedented cooperation by promoting trust and coordination in large, diverse groups, distinguishing human collaboration from primate alliances. This sociocultural shift addressed key challenges like the free-rider problem, where individuals might exploit collective efforts without contributing, through the development of social norms and institutions that enforce reciprocity and punish defection. Norms, transmitted linguistically, create conditional cooperation, allowing humans to sustain large-scale societies unlike the kin-based eusocial colonies of insects.^[49] In essence, language-based memes provided a new replicator, transforming human evolution from biological to cultural dominance.

Extensions and Updates to the Framework

Post-1995 Revisions by Szathmáry

In 2015, Eörs Szathmáry proposed significant revisions to the original framework of major evolutionary transitions, refining its theoretical foundations and adjusting the list of transitions to better align with empirical evidence and conceptual clarity.^[3] The updated theory emphasized that true major transitions must establish irreversible new levels of individuality, characterized by the formation of higher-level units that propagate with high fidelity and suppress lower-level conflicts, thereby creating a hierarchical progression in evolutionary complexity.^[3] This refinement introduced a phased structure to transitions—origin, maintenance, and transformation—drawing analogies to phase transitions in physics, where small changes in parameters can lead to abrupt shifts in system properties, such as from liquid to gas.^[3] Szathmáry quantified this by suggesting metrics like the proportion of lineage progression (e.g., 20% or 90% completion) to assess ongoing transitions and predict future ones based on functional synergies among components.^[3] A key adjustment was the demotion of sexual reproduction from a standalone major transition, as it fails to generate a new propagating unit; instead, mating pairs do not integrate into higher hierarchical levels or suppress individual replication effectively.^[3] Szathmáry integrated sex within the broader transition to eukaryotic cells, where meiotic processes enhance genetic mixing but do not constitute an independent level of individuality.^[3] Conversely, the acquisition of plastids through endosymbiosis was elevated to a major transition, exemplifying recursive endosymbiosis that creates novel organelles like chloroplasts in plants or chromatophores in Paulinella chromatophora, approximately 60 million years ago, thereby establishing a new symbiotic unit with irreversible integration.^[3] The revisions also addressed gaps in the original framework by enhancing the role of horizontal gene transfer (HGT) in maintaining transitions, particularly emphasizing viral contributions to gene exchange across lineages.^[3] This better incorporates viruses as vectors for genetic innovation, facilitating the stabilization of higher-level units during transitions like the evolution of the genetic code and prokaryotic maintenance phases, without which lower-level selfishness could undermine collective propagation.^[3] Overall, these updates aim to provide a more predictive and mechanistic theory, applicable to both biological and potential synthetic evolutionary contexts.^[3]

Proposed Additional Transitions

Since the original framework outlined by Maynard Smith and Szathmáry in 1995, subsequent researchers have proposed additional transitions that extend the model to incorporate overlooked mechanisms in early cellular evolution, metabolic upgrades, and potential future sociocultural developments. These suggestions build on the foundational revisions by Szathmáry, emphasizing how new levels of complexity arise from symbiotic or competitive interactions. One prominent proposal involves the role of viruses and mobile genetic elements in driving major transitions through ongoing parasite-host arms races. Eugene Koonin argues that these interactions catalyze increases in organizational complexity, such as the formation of cellular structures and collective behaviors to counter viral threats, thereby facilitating shifts like the origin of prokaryotes, eukaryotes, multicellularity, and eusociality. For instance, virus-host co-evolution is posited to have promoted innovations in immunity and programmed cell death, which in turn enabled the aggregation of cells into multicellular units as a defensive strategy.^[50] This perspective positions viruses not merely as disruptors but as intrinsic drivers of evolutionary novelty across multiple levels of biological organization.^[51] Another suggested addition focuses on secondary endosymbiosis events, particularly the integration of chloroplasts, as a distinct metabolic transition beyond the initial prokaryote-to-eukaryote shift. This process, where a eukaryotic alga engulfs a photosynthetic eukaryote to acquire a plastid, represents a major upgrade in energy capture and biosynthetic capacity, enabling complex multicellular plant life and altering global biogeochemical cycles.^[52] Researchers highlight how this endosymbiosis scaled up photosynthetic efficiency from cyanobacterial ancestors, introducing sublinear metabolic scaling in chloroplasts that supported larger organismal sizes and trophic innovations.^[53] Unlike primary endosymbiosis, secondary events diversified plastid types across eukaryotic lineages, profoundly impacting evolutionary trajectories by enhancing autotrophy in non-photosynthetic hosts.^[54] Metabolic innovations, such as the evolution of oxygenic photosynthesis, have also been proposed as standalone transitions due to their transformative effects on atmospheric chemistry and selective pressures. A 2016 analysis in the context of major transitions emphasizes that oxygenic photosynthesis, originating in ancient cyanobacteria, created sustained changes in evolutionary regimes by enabling aerobic respiration and oxidizing Earth's environment, which paved the way for aerobic multicellularity. This innovation is seen as a critical step that bridges prokaryotic metabolism to eukaryotic complexity, distinct from endosymbiotic acquisitions.^[55] In sociocultural evolution, the integration of human societies with artificial intelligence (AI) has been speculated as a potential ninth major transition, forming a new evolutionary individual through symbiotic interdependence. Proponents suggest that AI-human symbioses could create higher-level units of selection, where collective intelligence emerges from human oversight and machine capabilities, analogous to prior transitions in cooperation and information transfer.^[56] This proposal envisions AI not as a tool but as a co-evolutionary partner, potentially reshaping individuality at the societal scale through enhanced problem-solving and cultural transmission.^[57] While speculative, it extends the framework to anticipate future levels of complexity in technological ecosystems.^[58]

Criticisms and Ongoing Debates

Limitations of the Complexity-Focused Approach

The Major Transitions in Evolution framework has faced criticism for its pronounced focus on increasing hierarchical complexity, which tends to prioritize an "ascent of life" narrative while neglecting evolutionary simplifications that play crucial roles in diversification and adaptation. For instance, the reduction from multicellular forms to unicellular ones, such as in the case of multicellular fungi evolving into yeasts, exemplifies how such simplifications can facilitate rapid evolutionary radiation and ecological success, yet these events are marginalized in the model's emphasis on progressive integration. This bias toward complexification limits the framework's ability to account for the full spectrum of macroevolutionary dynamics, including non-hierarchical or reductive pathways that are equally vital to life's history. Another key limitation concerns the observability of early transitions, particularly those involving hypothetical precursors like protocells or primitive replicator systems. These foundational events lack direct empirical evidence, rendering them largely untestable and dependent on theoretical inference, which undermines the framework's falsifiability and scientific rigor. As a result, the model's reconstructions of origins-of-life transitions risk being speculative, with validation challenges that contrast sharply with the more observable later transitions, such as the prokaryote-to-eukaryote shift. The complexity-focused approach also invites specific critiques regarding its implicit biases and omissions. By positioning human language-based societies as the apparent pinnacle of evolutionary achievement, the framework adopts a progressivist lens that reinforces anthropocentric views of history rather than treating human evolution as one contingent pathway among many. Moreover, it overlooks pervasive mechanisms like lateral gene transfer in prokaryotes, which facilitate non-vertical inheritance and blur the boundaries of individuality assumed in the hierarchical model, thereby underrepresenting the networked nature of early microbial evolution. In response to these shortcomings, the framework has been expanded through related concepts such as "evolutionary transitions in individuality" (ETI), which incorporates diverse forms of cooperation, symbiosis, and metabolic innovations beyond strict complexity increases.^[15] This broader approach aims to address the original model's narrow scope by integrating alternative evolutionary processes that do not fit the unidirectional complexity paradigm.

Alternative Perspectives on Evolutionary Change

One prominent complementary framework to the major transitions model is the evolutionary transition in individuality (ETI), which broadens the scope to encompass any significant shift in the boundaries of individuality, not limited to the specific hierarchical levels outlined by Maynard Smith and Szathmáry. Proposed by Richard E. Michod and others, this approach emphasizes the mechanisms by which lower-level units (such as cells) form cooperative groups that evolve into integrated higher-level individuals, with a focus on the export of fitness from lower to higher levels through conflict mediation and cooperation stabilization. For instance, in volvocine algae, ETIs illustrate how unicellular organisms transition to multicellular forms via the evolution of cell differentiation and interdependence, decoupling group fitness from individual cell fitness. This perspective complements the original transitions by providing a more generalizable lens for understanding individuality across biological scales, including genetic and ecological contexts.^[15] Another complementary model draws analogies from physics, viewing major evolutionary changes as phase transitions characterized by critical points where small perturbations lead to abrupt shifts in system organization.^[3] Eörs Szathmáry, in refining the transitions framework, suggests that these evolutionary phase transitions involve phases of origin (formation of cooperative units), maintenance (suppression of lower-level conflict), and transformation (evolution of novel inheritance at higher levels), akin to how physical systems pass through critical thresholds.^[3] A distinct alternative perspective on the tempo of evolutionary change is punctuated equilibrium, which posits that evolution proceeds through long periods of stasis punctuated by rapid bursts of speciation and morphological innovation, rather than uniform gradualism.^[59] Developed by Niles Eldredge and Stephen Jay Gould, this theory, based on fossil record analyses, argues that most change occurs in small, isolated populations during speciation events, challenging the expectation of hierarchical level-building in major transitions.^[59] Unlike the transitions framework's focus on novelty in units of selection, punctuated equilibrium highlights geographic and ecological drivers of rapid cladogenesis, providing a macroevolutionary pattern that operates independently of complexity thresholds.^[59] Building on these ideas, David C. Queller's criteria for recognizing evolutionary transitions stress the emergence of heritable variation at the group level as a key indicator, requiring mechanisms that align lower-level selection with higher-level outcomes.^[60] Queller distinguishes "fraternal" transitions (where group members are genetic clones or close kin, facilitating cooperation) from "egalitarian" ones (where non-kin integrate through division of labor), emphasizing that true transitions occur when groups reproduce as cohesive units with suppressed internal variance.^[60] This criterion-based approach offers a testable framework for evaluating potential transitions, such as in insect colonies, without presupposing a strict sequence of hierarchical innovations.^[60] Recent developments (as of 2025) have further extended debates, including applications of the transitions framework to human-AI interactions and philosophical critiques questioning the ontological status of transitions, highlighting ongoing refinements to address conceptual breadth and empirical testability.^[56]^[61]

Implications for Evolutionary Biology

Influence on Research in Origins of Life

The framework of major evolutionary transitions, as outlined by Maynard Smith and Szathmáry, has profoundly shaped research on abiogenesis by emphasizing discrete shifts from simple chemical replicators to compartmentalized cellular life, prompting experimental efforts to reconstruct these early stages.^[2] This perspective highlighted the need to bridge prebiotic chemistry with biological evolution, inspiring investigations into how non-living molecular systems could achieve heritable variation and division of labor.^[61] In particular, the transition from independent replicators to populations enclosed in protocells has driven laboratory simulations of primitive membranes, underscoring the role of physical and chemical constraints in the origins of individuality.^[62] A key impact is seen in RNA world experiments, where the framework's focus on informational transitions—from RNA replicators to cooperative networks—has guided long-term evolution studies. Researchers have evolved RNA molecules in vitro to observe shifts from single replicators to interdependent host-parasite systems, mirroring the proposed early transition to collective replication and providing evidence for Darwinian dynamics in prebiotic settings.^[63] Similarly, protocell simulations in the Szostak laboratory have tested the compartment transition by engineering lipid vesicles from prebiotic amphiphiles, demonstrating growth, division, and encapsulation of RNA that enable competition and inheritance—directly informed by the need to model the emergence of bounded units from diffuse chemical soups.^[64] These efforts reveal how weak interactions, such as lipid bilayer permeability, could facilitate the first levels of biological organization.^[65] The framework has also bolstered hypotheses linking hydrothermal vents to the compartment transition, positing that alkaline vents provided natural porous structures for concentrating prebiotic molecules and fostering protocell-like enclosures. Experiments simulating vent conditions have shown how mineral precipitates and organic lipids form hybrid compartments capable of sustaining geochemical gradients, thus integrating the transitions model with environmental geochemistry to explain the shift from abiotic cycles to proto-metabolic networks.^[66] This influence extends to NASA's astrobiology programs, which have adopted the transitions lens to experimentally recreate early evolutionary steps, such as endosymbiosis and multicellularity precursors, using microbial evolution to probe life's universality beyond Earth.^[67] In the 2020s, models increasingly integrate the transitions framework with prebiotic chemistry, combining computational simulations of reaction networks with empirical data to trace pathways from molecular assemblies to viable protocells.^[68] Synthetic biology advances have further enabled recreations of these transitions, with engineered minimal cells evolving under selective pressures to exhibit rudimentary cooperation, offering insights into the informational and compartmental innovations at life's dawn.^[69] By 2025, such approaches have refined our understanding of transitional forms, using lipid mixtures to bridge RNA replication and membrane heredity in lab settings.^[70] Additionally, a 2025 study has applied algorithmic models to the prokaryote-to-eukaryote transition, proposing it as a phase transition driven by genomic complexity and search efficiency, further illuminating mechanisms of early cellular evolution.^[71]

Applications to Sociocultural Evolution

The major transitions framework extends to sociocultural evolution by viewing human language as a key transition that enables the replication and collective transmission of cultural information, akin to memes as units of cultural inheritance. This shift from primate societies to language-based human societies allows for the encoding of abstract knowledge and norms, facilitating cooperation at scales far beyond biological kinship limits and paralleling the collective integration seen in eusocial colonies.^[1] Such mechanisms underpin global human cooperation, where shared linguistic and cultural systems align individual behaviors toward collective goals, much like the division of labor in eusocial insects but achieved through informational rather than genetic fidelity.^[72] Specific applications include dual-inheritance models of cultural evolution, as articulated by Boyd and Richerson, which treat culture as an adaptive system evolving alongside genes and capable of rapid transmission across generations.^[73] These models predict that cultural innovations could drive further transitions, such as through emerging technologies like brain-computer interfaces, which might integrate human cognition with external systems to form higher-level evolutionary individuals. The framework also informs anthropological perspectives, notably Dunbar's social brain hypothesis, which links neocortex expansion to the cognitive demands of tracking social relationships in increasingly complex groups, with language amplifying group sizes to enable societal-scale organization. While the original 1995 formulation underemphasized cultural ratcheting—the cumulative buildup of cultural complexity over time—recent scholarship addresses this gap by emphasizing how iterative cultural modifications sustain evolutionary progress.^[74] In the 2020s, debates have intensified around digital memes and technological replicators, such as "temes" (digital information units stored and varied by machines), as potential new evolutionary entities that could herald transitions beyond biological and cultural domains.^[75] Contemporary works further propose artificial intelligence as a catalyst for such shifts, potentially enabling symbiotic human-AI collectives that redefine individuality and selection at higher levels.^[56]^[76] As of 2025, discussions continue with critiques arguing that sociocultural systems often fail to meet the conditions for true evolutionary transitions in individuality, and theories positing cultural inheritance as the primary driver of a ongoing major shift in human evolution, where cultural adaptations increasingly supplant genetic ones.^[77]^[78]

References

[1]
The Major Transitions in Evolution - John Maynard Smith
These transitions include the origin of life itself, the first eukaryotic cells, reproduction by sexual means, the appearance of multicellular plants and ...
[2]
The major evolutionary transitions | Nature
Mar 16, 1995 · A series of major evolutionary transitions. These involved changes in the way information is stored and transmitted.
[3]
Toward major evolutionary transitions theory 2.0 - PNAS
Brief Survey of the Conceptual Landscape of the Major Transitions. Bonner (4), Buss (5), Maynard Smith (6, 7), Leigh (8), Jablonka (9), and Szathmáry (10–13) ...
[4]
(PDF) The Major Evolutionary Transitions - ResearchGate
Aug 9, 2025 · A series of major evolutionary transitions. These involved changes in the way information is stored and transmitted.
[5]
https://press.princeton.edu/books/paperback/9780691182865/adaptation-and-natural-selection
[6]
Evolution and the Theory of Games
In this 1982 book, the theory of games, first developed to analyse economic behaviour, is modified so that it can be applied to evolving populations. John ...
[7]
Origin of life: The RNA world - Nature
News & Views; Published: 20 February 1986. Origin of life: The RNA world. Walter Gilbert. Nature volume 319, page 618 (1986)Cite this article. 48k Accesses.
[8]
John Maynard Smith | Kyoto Prize - 京都賞
Professor Maynard Smith has made a groundbreaking contribution to the establishment of a unified understanding of fundamental issues in evolutionary biology.
[9]
John Maynard Smith: January 6, 1920–April 19, 2004 - PMC - NIH
John Maynard Smith was one of the most influential evolutionary biologists of the generation that succeeded the “founding fathers” of population genetics.
[10]
John Maynard Smith | Higher education | The Guardian
Apr 21, 2004 · John Maynard Smith, who has died aged 84, was emeritus professor of biology at the University of Sussex and one of the world's greatest evolutionary biologists.Missing: biography | Show results with:biography
[11]
Eörs Szathmáry, Ph.D., D.Sc. - Wissenschaftskolleg zu Berlin
Professor of Biology, Eötvös Loránd University, Budapest. Born in 1959 in Budapest, Hungary. Studied Biology at Eötvös University, Budapest.
[12]
Eörs Szathmary - Parmenides Foundation
Eörs Szathmáry studied biology at the Eötvös Loránd University in Budapest. After finishing his PhD, he served as research fellow at Eötvös University.Missing: biography | Show results with:biography
[13]
The Major Transitions in Evolution. John Maynard Smith and Eors ...
30-day returnsThe Major Transitions in Evolution. John Maynard Smith and Eors Szathmary. New York:W. H. Freeman and Company,1995, 346 pp. US$29.95 paper. ISBN 0-7167-4525 ...
[14]
https://doi.org/10.1038/374227a0
[15]
Major evolutionary transitions in individuality - PNAS
May 11, 2015 · The second step typically involves a number of common features ... J Maynard Smith, E Szathmáry The Major Transitions in Evolution (Oxford Univ ...
[16]
Multilevel Selection and the Major Transitions in Evolution
Jan 1, 2022 · The 'major transitions in evolution' refer to the transitions from solitary replicators to networks of replicators enclosed within compartments.
[17]
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9986030/
[18]
Origin and Evolution of RNA-Dependent RNA Polymerase - Frontiers
Sep 19, 2017 · Our results suggest that RdRp originated from junctions of proto-tRNAs that worked as the first genes at the emergence of the primitive ...
[19]
Origin and Evolution of DNA and DNA Replication Machineries - NCBI
This suggests that reverse transcriptase and DNA polymerases of the A and B families originated from an ancestral RNA polymerase that has also descendants among ...
[20]
Temporal order of evolution of DNA replication systems inferred by ...
Dec 18, 2006 · Support from the evolutionary relationships between DNA and RNA polymerases. The order of emergence of the replication systems proposed here ...
[21]
Selfish genetic elements, genetic conflict, and evolutionary innovation
Jun 20, 2011 · There is growing evidence that SGEs, and the resulting genetic conflict, are an important motor for evolutionary change and innovation.
[22]
The evolutionary landscape of prokaryotic chromosome/plasmid ...
Nov 4, 2024 · Unlike chromosomes, plasmids are often seen as selfish as they encode accessory functions at the energetic expense of host cells. A large number ...
[23]
Evolution of Protein Synthesis from an RNA World - PMC
Ribosomes may have evolved from an ancient RNA replication machinery. rRNA provides their enzymatic activity; proteins may improve efficiency and were ...
[24]
The Genetic Code: Francis Crick's Legacy and Beyond - PMC
Aug 25, 2016 · The genetic code is an algorithm that connects 64 RNA triplets to 20 amino acids, and functions as the Rosetta stone of molecular biology.Missing: 3.5-4 billion
[25]
prebiotic evolutionary advantage of transferring genetic information ...
Both analyses found that RNA replication was intrinsically error-prone compared to DNA, suggesting that total genomic information could increase after the ...
[26]
The Origin and Evolution of Cells - The Cell - NCBI Bookshelf - NIH
The eukaryotes developed at least 2.7 billion years ago, following some 1 to 1.5 billion years of prokaryotic evolution. Studies of their DNA sequences ...Missing: age | Show results with:age
[27]
Introduction | The Major Transitions in Evolution | Oxford Academic
Some of these transitions were unique: for example, the origin of the eukaryotes from the prokaryotes, of meiotic sex, and of the genetic code itself. Other ...
[28]
An integrated phylogenomic approach toward pinpointing the origin ...
Jan 22, 2015 · Overwhelming evidence supports the endosymbiosis theory that mitochondria originated once from the Alphaproteobacteria.
[29]
Origin of Mitochondria | Learn Science at Scitable - Nature
Mitochondria arose through a fateful endosymbiosis more than 1.45 billion years ago. Many mitochondria make ATP without the help of oxygen.
[30]
The Origin and Diversification of Mitochondria - ScienceDirect.com
Nov 6, 2017 · Modern analyses also confirm that the mitochondrial endosymbiont was indeed related to alphaproteobacteria [13], although controversy still ...
[31]
Gene transfer from organelles to the nucleus: Frequent and in big ...
This process, a special kind of lateral gene transfer called endosymbiotic gene transfer (3), appears to be very widespread in nature: ≈18% of the nuclear genes ...
[32]
Endosymbiosis and Eukaryotic Cell Evolution - ScienceDirect.com
Oct 5, 2015 · Genes of both prokaryotic and eukaryotic ancestry are transferred from the endosymbiont nucleus to the secondary host nucleus.
[33]
Origins of Eukaryotic Sexual Reproduction - PMC - PubMed Central
Given its ubiquity and shared core features, sex is thought to have arisen once in the last common ancestor to all eukaryotes.
[34]
https://pmc.ncbi.nlm.nih.gov/articles/PMC3949356/
[35]
The origin and evolution of gamete dimorphism and the male-female ...
As high anisogamy is approached, the disadvantageous dominant homozygote is lost leaving two sexes (sperm producers and ovum producers) in a stable 1 : 1 ratio.
[36]
Red Queen hypothesis supported by parasitism in sexual and clonal ...
Apr 26, 1990 · THE Red Queen hypothesis for the maintenance of biparental sexual reproduction suggests that, for species locked in revolutionary struggles ...<|separator|>
[37]
Triassic origin and early radiation of multicellular volvocine algae
Among the best-studied ETIs is the origin of multicellularity in the green alga Volvox, a model system for the evolution of multicellularity and cellular ...
[38]
Cancer across the tree of life: cooperation and cheating in ... - Journals
Jul 19, 2015 · To control proliferation, multicellular organisms have evolved redundant checks on the cell cycle and mechanisms that automatically trigger ...
[39]
An Introduction to Eusociality | Learn Science at Scitable - Nature
Evolutionary biologists trace the origins of eusociality through a pathway that starts with solitary organisms acquiring benefits to group behavior, eventually ...
[40]
THE EVOLUTION OF EUSOCIALITY - PMC - NIH
Eusociality, in which some individuals reduce their own lifetime reproductive potential to raise the offspring of others, underlies the most advanced forms ...
[41]
The abundance, biomass, and distribution of ants on Earth - PNAS
Ants are highly diverse, comprising more than 15,700 named species and subspecies (26) and possibly as many undescribed ones (27).
[42]
Termite evolution: mutualistic associations, key innovations, and the ...
Jan 3, 2021 · Eusociality emerged ~ 150 million years ago in the ancestor of modern termites, which, since then, have acquired and sometimes lost a series of ...<|separator|>
[43]
The social evolution of termites | ScienceDaily
Feb 8, 2018 · While termites first emerged from the group of cockroaches around 150 million years ago, ants and other eusocial Hymenoptera, including bees ...
[44]
Haploidploidy and the Evolution of the Social Insect - Science
Haploidploidy and the Evolution of the Social Insect: The unusual traits of the social insects are uniquely explained by Hamilton's kinship theory. Robert L ...
[45]
Conflict over Male Parentage in Social Insects | PLOS Biology
Mutual policing is an important mechanism that maintains social harmony in group-living organisms by suppressing the selfish behavior of individuals.
[46]
Cooperative policing behaviour regulates reproductive division of ...
For example, in the Melipona stingless bees, caste is self-determined, and immature females selfishly develop into queens to maximize direct reproduction [46].
[47]
Cooperation among Selfish Individuals in Insect Societies | BioScience
... against selfish behavior, such as worker policing ... Reproductive bribing and policing as evolutionary mechanisms for the suppression of within-group selfishness.
[48]
Two Key Steps in the Evolution of Human Cooperation
Modern theories of the evolution of human cooperation focus mainly on altruism. In contrast, we propose that humans' species-unique forms of cooperation—as ...Abstract · First Step: Obligate... · Conclusion · References Cited
[49]
Virus-host arms race at the joint origin of multicellularity and ... - NIH
We developed a mathematical model of the virus-host co-evolution that involves interaction between immunity, PCD and cellular aggregation.Missing: 2016 | Show results with:2016
[50]
Viruses and mobile elements as drivers of evolutionary transitions
First, the parasite–host arms race leads to increased organizational complexity of biological systems, i.e. serving as a catalyst of evolutionary transitions.
[51]
[PDF] The endosymbiotic origin, diversification and fate of plastids
Overall, this secondary spread of plastids had a major impact on eukaryotic diversity, evolution and global ecology (Falkowski et al. 2004). Many of the ...
[52]
Major evolutionary transitions of life, metabolic scaling and the ...
Endosymbiosis of proto-chloroplasts altered their photosynthetic scaling from apparently superlinearity in cyanobacteria [22] to sublinearity in chloroplasts.
[53]
Endosymbioses Have Shaped the Evolution of Biological Diversity ...
The early serial establishment of mitochondria and chloroplasts through endosymbioses permitted massive upscaling of cellular energetics, multicellularity, and ...Abstract · Introduction · Conclusion · Author Contributions
[54]
Major problems in evolutionary transitions: how a metabolic ...
Aug 6, 2025 · For instance, it does not account for major biological innovations such as the evolution of oxygenic photosynthesis (O'Malley and Powell, 2016) ...
[55]
Major evolutionary transitions in individuality between humans and AI
Jan 23, 2023 · While ETIs to eusociality seem highly improbable, ETIs involving symbioses between humans and artificial intelligence (AI) can be readily envisaged.Missing: ninth | Show results with:ninth
[56]
Could humans and AI become a new evolutionary individual? - PMC
Sep 10, 2025 · Whether AI remains a tool or becomes integrated into a new kind of evolutionary individual depends not on technical capabilities alone, but also ...Missing: ninth | Show results with:ninth
[57]
How Might Artificial Intelligence Influence Human Evolution?
This article considers instead the inevitable but incremental evolutionary consequences of AI's everyday use and human-AI interactions.Missing: ninth | Show results with:ninth
[58]
Philosophical Transactions of the Royal Society B: Biological Sciences
'Biogeneric' developmental processes: drivers of major transitions in animal evolution ... PHILOSOPHICAL TRANSACTIONS B. About this journal · Propose an issue ...Missing: critiques | Show results with:critiques
[59]
(PDF) Punctuated Equilibria: An Alternative to Phyletic Gradualism
In their 1972 paper, Eldredge and Gould devoted considerable space to a discussion of the difficulty that new explanations can have in gaining a foothold in the ...
[60]
Relatedness and the fraternal major transitions - Journals
Corning P and Szathmáry E (2015) “Synergistic selection”: A Darwinian frame ... Smit H (2015) Darwin's Rehabilitation of Teleology Versus Williams ...<|control11|><|separator|>
[61]
The Major Transitions in Evolution—A Philosophy-of-Science ...
Feb 6, 2022 · Maynard Smith, J., and Szathmáry, E. (1995). The Major Transitions in Evolution. (Oxford: Oxford University Press). Google Scholar. McShea, D. ( ...
[62]
From molecular to cellular form: modeling the first major transition ...
Apr 3, 2019 · Szathmáry E, Maynard-Smith J. The major evolutionary transitions. Nature. 1995;374:227–32. Article Google Scholar. Gilbert W. The RNA world ...
[63]
Evolutionary transition from a single RNA replicator to a multiple ...
Mar 18, 2022 · Here we perform long-term evolution experiments of RNA that replicates using a self-encoded RNA replicase. The RNA diversifies into multiple coexisting host ...
[64]
Thermostability of model protocell membranes - PNAS
Sep 9, 2008 · Because prebiotic chemical reactions undoubtedly generated complex mixtures of lipids, rather than a single lipid species, it is plausible that ...Missing: simulations major<|separator|>
[65]
Coupled Growth and Division of Model Protocell Membranes
Mar 26, 2009 · Protocell Dynamics: Modelling Growth and Division of Lipid Vesicles Driven by an Autocatalytic Reaction. ... Jack W Szostak, David C Catling, .
[66]
Hybrid organic–inorganic structures trigger the formation of primitive ...
Aug 10, 2023 · Hydrothermal vents have long been suggested as an ideal location where abiogenesis could have occurred. Simultaneously, a large volume of ...
[67]
[PDF] Experimental Evolution of Major Transitions in the History of Life
A NASA Astrobiology Institute. Reliving the Past: Experimental Evolution of Major Transitions in the History of Life. Thank you! Page 26. APPENDIX. Rationale ...Missing: programs | Show results with:programs
[68]
Computational studies of prebiotic chemistry at the age of machine ...
Sep 23, 2025 · Beyond individual reactions, ML methods can also accelerate the study of chemical reaction networks by predicting transition states, reaction ...
[69]
Evolution of a minimal cell | Nature
Jul 5, 2023 · Here we report on how an engineered minimal cell contends with the forces of evolution compared with the Mycoplasma mycoides non-minimal cell ...
[70]
Synthetic chemistry recreates transitional forms in prebiotic ...
Jun 13, 2024 · In this issue of Chem, Pulletikurti et al. recreate transitional forms based on prebiotic chemical reactions, filling in “missing links” of early membrane ...Missing: major | Show results with:major
[71]
Human socio-cultural evolution in light of evolutionary transitions
Jan 23, 2023 · This issue provides a broad and rich application of the notion of ETI to human past, present and perhaps also future evolution.<|control11|><|separator|>
[72]
Not By Genes Alone: How Culture Transformed Human Evolution ...
This book provides an excellent account of Richerson and Boyd's theory, and is a must-read for anyone interested in gene-culture coevolution.”Missing: transitions | Show results with:transitions
[73]
Ratcheting up the ratchet: on the evolution of cumulative culture - NIH
Human culture, in contrast, has the distinctive characteristic that it accumulates modifications over time (what we call the 'ratchet effect').Missing: transitions | Show results with:transitions
[74]
Temes: An Emerging Third Replicator - National Humanities Center
Aug 23, 2010 · Temes are digital information stored, copied, varied, and selected by machines, short for technological memes, and a third replicator.
[75]
Cultural evolution, social ratcheting and the evolution of human ...
Mar 20, 2025 · The logic of major transitions implies that new entities evolve owing to selective pressures at the level of their ancestral components: kin ...