2. Overview of the MCSC

Mitonuclear ecology is a field of evolutionary ecology that emphasizes coadaptation and, therefore, cofunction between the mitochondrial (mt) and nuclear (N) genomes of eukaryotes. All eukaryotic organisms must have efficiently coadapted mt and N genomes to survive and reproduce successfully (Lane Reference Lane2005; Hill Reference Hill2017). This intimate cofunction of mt and N genes directly influences oxidative phosphorylation (OXPHOS), namely, cellular respiration, and thus, the ability of eukaryotes to consume oxygen and produce adenosine triphosphate (ATP, or energetic currency) efficiently. This is because mt and N proteins function side-by-side within complexes of the electron transport system (ETS) and as ribonucleic acids (RNAs) during the translation of proteins. If these gene products do not function well together—that is, if they are not coadapted—then ATP will not be produced efficiently, impeding the essential processes that lead to survival and reproductive success. Although mitonuclear compatibility isn’t the only mechanism underlying isolation between populations, it is, arguably, the most important aspect of eukaryotic function and, hence, speciation. Biological research has largely focused on the N genome and assumed that mt genes are static within and between populations. Yet, recent work on hybridization and mt genetics has revealed varying levels of heterogeneity in mt genotypes. Thus, mitonuclear ecology has underlined the importance of the mt genome in efficient mitochondrial and organism performance.

The mt genome of eukaryotes contains only thirty-seven genes, whereas the N genome contains approximately 20,000 genes. The thirty-seven genes in the mt genome code for thirteen mt proteins, twenty-two transfer RNAs, and two ribosomal RNAs (Rand et al. Reference Rand, Haney and Fry2004; Kühlbrandt Reference Kühlbrandt2015). The thirteen mt proteins function in close association with N-encoded proteins within complexes I, III, IV, and V of the ETS. The remaining twenty-four gene products are involved in the replication of mt genes that influence OXPHOS in alternative ways. Additionally, there are seventy-three N-encoded proteins that form the ETS complexes alongside the thirteen mt-encoded proteins. In total, approximately 1,500 N-encoded proteins function in the mitochondrion (N-mt genes), of which, roughly 180 cofunction closely with mt genes (N_O-mt genes) (see Figure 1).

Figure 1. Illustration of mitonuclear interactions between gene products of the mt and N genomes. tRNA – transfer RNA; rRNA – ribosomal RNA; Q – ubiquinone; Cyt c – cytochrome c. Modified from Hill (Reference Hill2017, 395), figure 1. Color online.

The MCSC says that “a species is a population that is genetically isolated from other populations by incompatibilities in uniquely coadapted mt and N_O-mt genes” (Hill Reference Hill2017, 397).Footnote ³ As stated, the MCSC merely tells us what species (instead of, say, genera) are. It gives us an answer to what Devitt (Reference Devitt2008, 357), following Mayr (Reference Mayr1982, 253–54), calls the category problem/question: In virtue of what is a species S a species (and not a subspecies, a genus, etc.)? However, reflecting on how biologists determine species membership for organisms in mitonuclear ecology, we propose the following constitutive condition for species membership and individuation as an extension of the MCSC: Necessarily, organism O is a member of species S if and only if (iff) its (particular) mt and N_O-mt genes are uniquely coadapted to function well together to promote efficient OXPHOS.Footnote ⁴ As such, this gives an answer to the taxon problem/question: In virtue of what is an organism O a member of species S (and not some other species) (Devitt Reference Devitt2008, 357; Mayr Reference Mayr1982, 253–54)?Footnote ⁵ Thus, as we are characterizing the MCSC, it affords answers to both the category and taxon questions. It is worthwhile to emphasize that our proposed characterization is assumed implicitly when mitonuclear ecologists like Hill determine species membership for organisms, and it fits well with the spirit of mitonuclear ecology that places “the coadaptation of mt and N_O-mt genes at the center of the speciation process” with the goal of “understanding the fundamental nature of species” (Hill Reference Hill2019a, 143).Footnote ⁶

To clarify, although mitochondrial function as it relates to mitonuclear compatibilities is a trait that is shared across all eukaryotes, this doesn’t mean that all eukaryotes are members of the same species. The reason is that specific and unique combinations of mt and N_O-mt genotypes lead to efficient mitochondrial function. These combinations are exclusive to, and different for, distinct species. This contrasts with other traits or N genotypes that, alone, are inevitably shared by organisms across species boundaries. So, the mitonuclear coevolution and amino acid substitutions that have come about in, say, humans will not exist in other primates, such as orangutans. For example, humans and other primates have weakly deleterious mutations that accumulate in the mt-encoded subunits of the cytochrome c oxidase (COX)Footnote ⁷ complex in the ETS. Occasionally, compensatory coevolution occurs, where adaptive substitutions in N-encoded mitochondrial proteins counteract these deleterious effects and prevent fitness decline (Osada and Akashi Reference Osada and Akashi2012).

An outcome of the MCSC is that parents between populations incur a cost of mating through possible decreases in OXPHOS efficiency in hybrids when said parents have incompatible mt and N_O-mt genes. As such, the concept doesn’t focus on whether hybridization can occur, as is the case with the Biological Species Concept (BSC), but it focuses on the function of hybrid offspring, wherein said function exists along a continuum. Consequently, belonging to a species is a matter of degree under the MCSC. Combinations of poorly coadapted gene sets result in hybrid offspring that are either inviable or contain mitochondria with inefficient OXPHOS. We can determine species membership by assessing mitochondrial performance (i.e., ETS function)Footnote ⁸ in hybrids compared to parental lines (e.g., Ellison and Burton Reference Ellison and Burton2006). Hence, we can know whether O is a member of S because mitonuclear incompatibilities will result in decreased mitochondrial efficiency in hybrids of diverged populations, whereas mitochondrial function in hybrids from parental populations with coadapted mt and N_O-mt genes will not differ significantly from parental lines.

Allopatric, mitonuclear speciation is thought to begin when a population splits, and the two allopatric daughter populations first develop unique mt genotypes. The two populations then develop uniquely coadapted N_O-mt genes that maintain mitonuclear compatibilities. If the two populations come into secondary contact at a later time, the uniquely coadapted sets of mt and N_O-mt genes between the two populations may be incompatible when the daughter populations interbreed to form hybrids (see Figure 2).Footnote ⁹ Taxonomically, O is a member of some species S1 and not S2 because it satisfies the necessary and sufficient condition of species membership noted above. With respect to S2, interbreeding with O would lead to hybrids that are either inviable or contain poorly coadapted sets of mt and N_O-mt genes that lead to decreased efficiency of OXPHOS.

Figure 2. Illustration of speciation using the Mitonuclear Compatibility Species Concept. Modified from Hill (Reference Hill2019a, 152), figure 7.3. Color online.

Before continuing, it is worthwhile to consider two potential concerns to further clarify the MCSC. First, because there are many different clusters of organisms in the world (e.g., reproductive communities, demes, populations and metapopulations, phenotypically similar organisms, ancestor-descendant lineages), it may be tempting to conclude that we have given no argument for why the MCSC should be thought of as a species concept, rather than a concept that merely identifies other biologically important groups. In reply, mitonuclear coevolution is crucial to mitochondrial function and, therefore, to all of the energetically demanding processes related to survival and reproductive success. Because organisms must survive and reproduce successfully to evolve, mitonuclear ecology lies at the center of speciation and any legitimate species concept. In contrast, the clusters listed in the preceding text don’t lie at the center of speciation and, hence, shouldn’t underly species concepts because such groups don’t have a direct influence on survival and reproduction across eukaryotes as a whole. Further, the MCSC is a species concept—and not a general guide to grouping organisms—because it makes specific predictions about the function and hybridization of organisms. Additionally, the proof is in the pudding. Below, we identify advantages that the MCSC—if taken as a species concept instead of an identification of merely biologically important groups—has over other species concepts. Last, in our view, the philosophy should follow the science. So, if biologists seriously consider the MCSC as a species concept, it seems fair for philosophers to do so as well and, therefore, enquire into the advantages/disadvantages of adopting the MCSC as a species concept (sections 3 and 4) and the philosophical consequences that may follow (sections 5 and 6).

Second, one may worry that the MCSC gives a circular definition for species membership since it identifies those properties that determine species membership in relation to a particular species (vis-à-vis the notion of uniqueness). The worry, we believe, is misplaced because ultimately those properties that determine species membership will be a particular set of genes. Consider the following: take any two eukaryotes on the planet, call them O1 and O2, and allow them to mate to produce offspring. Based on compatibility of their mt and N_O-mt genes, the resulting offspring will either be viable or not. Of those that are viable, their mitochondrial function will exist on a continuum based on how well their mt and N_O-mt genes cofunction to promote efficient OXPHOS. Members of the same species, then, will be formed based on what offspring are able to survive and reproduce. This is a direct product of efficient mitochondrial function that results from mitonuclear compatibilities. Alternatively, we can carry out cybridFootnote ¹⁰ studies to assess mitochondrial function based on varying levels of mitonuclear compatibility. Said function declines when the genomes of more distantly related organisms are combined. Different levels of coadaptation between the mt and N genomes of two cell lines lead to variance in mitochondrial performance and, therefore, varying levels of relatedness (i.e., different species; see section 4 for more on cybrid studies). Therefore, we need not have a prior determination of what species O1 and O2 belong to determine species membership. Importantly, if we want to provide necessary and sufficient conditions for species membership, what we are looking for is a set of properties {p₁} that, should some organism O possess said properties, it is a member of species S1, {p₂} for S2, and so on. On the MCSC, the properties {p₁} that determine that O1 belongs to S1 (and not S2 or any other species) is the previously mentioned set of mt and N_O-mt genes.

3. Varieties of Species Concepts and Their Relation to the MCSC

Biologists have developed many diverse species concepts, of which the BSC and the Phylogenetic Species Concept (PSC) are most widely adopted in practice today. The BSC states that a species is a population that is reproductively isolated from other populations (Mayr Reference Mayr1940). Under this concept, gene flow is the primary determinant of speciation, with a focus on N genes and the ability of organisms to form hybrids. The PSC states a species is a monophyletic group of common ancestry (De Queiroz and Donoghue Reference De Queiroz and Donoghue1988). Here, the focus is on evolutionary history, where a species stems from a shared line of descent among organisms, in reference to one or more traits.Footnote ¹¹

The MCSC is related to and expounds upon both the BSC and PSC, while settling disagreements and elaborating on details surrounding hybridization and the role of genetics in speciation. The BSC focuses on the exchange of N genes, whereas the MCSC focuses on the exchange of mt and N_O-mt genes that are unique to populations and directly influence OXPHOS through coadaptation. Here, the MCSC provides a narrower focus on which genetic compatibilities are important and unambiguously makes predictions surrounding incompatibilities that result from hybridization. The BSC focuses on speciation that results from cessation of N geneflow and the inability to form hybrids. The MCSC, in contrast, allows for the exchange of N genes and hybridization between species but requires that such species retain distinct, coadapted sets of mt and N_O-mt genes. Although the MCSC is a novel, independent species concept, it does share a limited number of characteristics with preceding concepts, such as breeding and the formation of hybrids, as outlined in the BSC.

Under the PSC, populations have a unique evolutionary history but retain coadapted sets of mt and N_O-mt genes. Hence, a group of organisms may be a separate species under the PSC but not under the MCSC, depending on whether the phylogenetic assessment is of a genetic origin. Again, the MCSC provides a more detailed explanation of what is a “unique” evolutionary history, with emphasis on coadaptation and cofunction between specific genotypes. It is important to note, however, that in most cases, species identified under the PSC are maintained under the MCSC (Hill Reference Hill2017).

The Ecological Species Concept (ESC) defines a species as a “lineage which occupies an adaptive zone minimally different from that of any other lineage in its range and which evolves separately from all lineages outside its range” (Van Valen Reference Van Valen1976, 233). The Genotypic Cluster Species Concept (GCSC) states a species is a “morphologically or genetically distinguishable group of individuals that has few or no intermediates when in contact with other such clusters” (Mallet Reference Mallet1995; Coyne and Orr Reference Coyne and Orr2009, 273). Both the ESC and GCSC are perhaps more distantly related to the MCSC than the BSC and PSC. The ESC focuses on adaptive zones within an environment, which are defined regardless of the organisms present (Van Valen Reference Van Valen1976). Problems with the ESC arise, though, when organisms change their environment to influence their survival and reproductive success, and when different organisms inhabit the same environment without gene flow (e.g., temporal variations as seen in periodical cicadas; Coyne and Orr Reference Coyne and Orr2009). Unlike the MCSC, sympatric taxa that exchange genes to form viable hybrids with efficient mitochondrial function but inhabit different niches would be considered different taxa under the ESC. This issue doesn’t arise with the MCSC. Irrespective of whether organisms inhabit similar or different environments in space or time, the exchange of incompatible mt and N_O-mt genes can influence mitochondrial function and, therefore, organism performance.

Issues with the GCSC arise because there is no specification of how many, or what, genes or traits must be different to define a species. Additionally, it isn’t clear what level of organization determines a cluster (e.g., species, genus, family). One advantage of the GCSC, however, is its application to asexual taxa, given that it doesn’t rely on hybridization. The MCSC doesn’t rely on hybridization either but on how hybrids function (i.e., the diffusion of mt genes). In the following section, we note further details on the advantages and limitations of the MCSC.

4. Advantages and Limitations of the MCSC

We believe the MCSC is an improvement upon other species concepts, but this does not preclude the MCSC from having limitations. Specifically, the MCSC is advantageous and builds on previous concepts in at least four ways: (1) it is a unifying species concept because it is widely applicable, (2) it is objective, in that we can make clear predictions and precise, unambiguous empirical measurements, (3) it is explanatorily superior (in certain respects), and (4) it exists on a continuum. Nonetheless, limitations exist regarding its inability to provide insights into speciation for bacteria and archaea, and it doesn’t specify what is considered “dysfunction” among hybrids.

Virtually all eukaryotes contain mitochondriaFootnote ¹² , including asexualFootnote ¹³ organisms such as plants, fungi, and protists. As such, a species concept such as the MCSC, which is applicable to many organisms (including facultative asexual organisms), is advantageous in comparison to concepts that have a narrower scope with respect to the range of organisms to which they apply. In other words, because the need for mitonuclear coadaptation is universal among eukaryotes, the emphasis on mitonuclear interaction affords a unifying species concept—the MCSC—that is applicable across distantly related eukaryotes, where compatibilities between mt and N genes (and mitochondrial performance) can be compared directly and widely. For instance, if we want to use behavior to build a phylogeny of mammalian taxa, it would be difficult in most respects to compare, say, the behavior of dolphins to the behavior of humans in a meaningful way. However, such an approach is not only possible but practical using the coevolution and cofunction of mt and N genes. Even if we can find similarities in behavior between organisms such as dolphins and humans, such commonalities become nonexistent at the extreme ends of eukaryotic speciation. Still, the cofunction of mt and N genes, and their importance in animal performance, is present across Eukarya.

One limitation is that the MCSC doesn’t work for organisms without mitochondria, such as bacteria or archaea. Yet, it is worth considering whether prokaryotes warrant being organized using species concepts comparable to eukaryotic species concepts, due to lateral gene transfer as seen in bacteria. Here, the consideration is not whether prokaryotes exchange genes but how they do so. According to Hill (Reference Hill2019a), prokaryotes may not warrant such a consideration because they exchange genes in a way that doesn’t rely on vertical gene transfer via recombination (sex), but on horizontal gene transfer (lateral transfer), which isn’t dependent on the transfer of genes from parents to offspring. If this is the case, then the MCSC covers virtually all relevant organisms (i.e., eukaryotes) for which it needs to explain species-level organization. At least those with comparable mechanisms of gene transfer.

Furthermore, as an approach to species and speciation, the MCSC is objective because it affords clear predictions, utilizing precise, unambiguous measurements to delineating species’ identities provided mitochondrial function can be measured in comparison to that of parental lines. This differs from species concepts that are more subjective, such as the GCSC, which doesn’t specify what or how many genes, or traits, are needed to diagnose species boundaries. Simply stating that a species is “morphologically or genetically distinguishable” from other groups without explaining the specific traits or genotypes that are relevant is perhaps problematically subjective, provided researchers can determine this based on their research program and preferences. Likewise, the ESC doesn’t specify the precise qualifications by which an adaptive zone is “minimally different” or what constitutes a lineage to “evolve separately.” Additionally, the PSC doesn’t specify the criteria in deciding which organisms constitute the “smallest monophyletic group.” It doesn’t say whether taxonomic decisions regarding relatedness are based on genetics, morphology, breeding, fossils, and so forth. Instead, the MCSC is based on the evolution and coadaptation of specific mt and N_O-mt genes that must cofunction well to achieve efficient OXPHOS; therefore, researchers can make detailed predictions as to the requirements of speciation by predicting exactly which genes function together and how they influence OXPHOS. One could argue, however, that no objective boundary exists for what is considered hybrid “dysfunction,” provided mitochondrial function exists along a continuum. Although, researchers can correlate mitochondrial function to whole-animal performance including survival, reproductive success, and whole-organism respiration.

Moreover, the MCSC is explanatorily superior to said approaches because it largely explains variation in survival and reproductive success (both of which are energetically demanding), where other approaches don’t. For example, recent work suggests a direct functional connection between the unique combinations of mt and N_O-mt genes of house finches and, thus, their mitochondrial performance, and the process of carotenoid oxidation and feather pigmentation that, in turn, relates to various phenotypic traits such as the plumage color of house finches. Such a connection further “provides a novel mechanistic explanation for why carotenoid coloration relates to a range of aspects of individual performance and why females use plumage redness as a key criterion in choosing mates” (Hill et al. Reference Hill, Hood, Ge, Grinter, Greening, Johnson, Park, Taylor, Andreasen, Powers, Justyn, Parry, Kavazis and Zhang2019c, 8; our emphasis). In general, although it is beyond our scope here to get into details, by “elevating the interaction of mt and N genes to a central process in discussions of speciation” the MCSC “leads to novel explanations for some of the most interesting and perplexing characteristics of species including Haldane’s rule, asymmetrical outcomes of hybrid crosses, and the tendency for N genes to diffuse across species boundaries while mt and Z-linked genes typically show discrete transitions” (Hill Reference Hill2019a, 178). That said, an additional limitation of the MCSC is that it doesn’t afford historical explanations a la Devitt (Reference Devitt2023, ch. 3) (see section 5).

Additionally, the MCSC operates on a continuum of mitochondrial function and, hence, speciation is to some extent a matter of degree. That is, the MCSC states that speciation doesn’t revolve around whether hybrids can form (as with the BSC). Instead, what matters is hybrid function with respect to mitochondrial performance. Parents from different populations risk having offspring with mitochondrial dysfunction if the mt and N_O-mt genes from the populations are incompatible. For instance, if we take cybrid studies such as Kenyon and Moraes (Reference Kenyon and Moraes1997), we observe that when the mtDNA of primates closely related to humans is combined with the N background of humans, respiratory function decreases by 20 percent, 34 percent, and 27 percent, for common chimpanzee, pigmy chimpanzee, and gorilla, respectively, but is functional in comparison to human cell lines. Nevertheless, when the mtDNA of more distantly related primates, for example, orangutan, old-world monkey, new-world monkey, lemur, is set against the N background of humans, mitochondrial performance isn’t restored to a functional state. As such, the key to understanding and defining species boundaries may not rely on whether two populations can interbreed but the extent to which hybrids can function to survive and reproduce successfully, which is directly and largely dependent upon mitochondrial performance (Heine and Hood Reference Heine and Hood2020; Heine Reference Heine2021).

Thus, a consequence of the MCSC is that it gives rise to what we call a “gray zone” for determining the extension of a species, provided hybrid function exists along a continuum. For example, two populations with highly diverged mt genotypes may both be able to function against similar N backgrounds (functioning hybrids), or alternatively, two populations with diverged mt genotypes may function poorly against N backgrounds that are also highly diverged (dysfunctional hybrids). These scenarios create various circumstances that lead to a continuum of greater or lesser mitochondrial function and, therefore, organism performance. This is because the mt genome of two populations can diverge without requiring an equal level of divergence in the N genome. Put differently, the MCSC is consistent with a scenario in which, hypothetically, an organism O belongs to two different species S1 and S2, but the criterion of mitochondrial performance allows for the determination of the species, S1 or S2, that O resides in to a greater degree. Accordingly, under the MCSC, species are not categorically distinct. In our view, this is a feature of the account, not a bug. That said, in cases of hybridization between species in the gray zone, one could also hold that it is indeterminate whether the hybrid belongs to one or another species. In any case, for practicing biologists, pragmatic decisions are made as to which species organism O belongs (such as S1 over S2, for our example). Moreover, DNA barcoding suggests that gray zones are rare. Mt genotype identifies species in agreement with preexisting concepts ∼95 percent of the time. This indicates that abrupt shifts in speciationFootnote ¹⁴ might occur more often than expected under mitonuclear theory (Hill Reference Hill2020). Nonetheless, evolution occurs continuously and, thus, doesn’t fit well into a discontinuous, binary mold. Therefore, species accounts that imply a discontinuous boundary are in some sense artificial because evolution implies there ought to be vague cases of speciation.

As an anonymous reviewer notes, the MCSC has the counterintuitive implication that were a “tiger” to evolve completely independently on a different planet, assuming it is intrinsically and genetically identical to tigers on Earth, it would still be a tiger according to the MCSC. Generally, if two groups of organisms independently evolve the same mt/N_O-mt system, then they are the same species under the MCSC—even if found in outer space. Moreover, if the offspring of two conspecific parents, through mutation, exhibit a very different mt/N_O-mt coadapted system, then they are a different species under the MCSC (unless they fall into the gray zone noted in the preceding text). Conversely, species concepts like the PSC that emphasize evolutionary history don’t have these counterintuitive implications. In response, we make three points. First, perhaps these scenarios are counterintuitive, but they are also extreme and unrealistic, so it seems permissible for there to be counterintuitive implications. Afterall, these implications also hold for the BSC. Second, other such thought experiments count in favor of the MCSC and against the PSC. Consider three such scenarios (from Devitt Reference Devitt2023, 102; original emphasis):

While according to the MCSC Twin-Earth tigers, engineered-tigers, and “tigers” in groups (b) and (c) are all tigers, the PSC (and other species concepts that emphasize actual evolutionary history) holds that such organisms are not tigers. This seems to us highly counterintuitive, also given that the tree of life on Twin Earth would be identical to that on Earth. In our view, the take-home message here is that not much can be concluded about the viability of a serious species concept considered by biologists from reflecting on unrealistic thought experiments. Different folks will have different intuitions, and counterintuitive scenarios will have counterintuitive implications.

5. Intrinsic Essentialism, Relational Essentialism, and Natural Kinds

Our goal in this section is to argue that the MCSC implies that species have fully intrinsic essences and, thus, suggests that species are natural kinds (of sorts). Section 5.1 reviews the received view of “relational essentialism” and Devitt’s new (partly) intrinsic essentialism, while section 5.2 argues for our brand of thoroughgoing intrinsic essentialism and distinguishes it from other types. We will assume metaphysical monism about species; namely, that there is a “single correct species concept” (Ereshefsky Reference Ereshefsky2022). Before starting in earnest, it is worthwhile to get clear on what we mean by a species “essence” and how the idea that O is an S in virtue of an essence may be fleshed out.

Traditionally, species essences are explanatory, so that it is because an organism is a member of some species that it has certain phenotypic characteristics typical of that species.Footnote ¹⁵ Devitt (Reference Devitt2023, 58–59) calls this “the Sober demand:” an essence “must be explanatory.… A species essence will be a causal mechanism that acts on each member of the species, making it the kind of thing that it is” (Sober Reference Sober1980, 25) (quoted in Devitt Reference Devitt2023, 58–59). However, while in what follows we will inquire into whether and to what extent a proposed species essence is causal-explanatory, this is not the notion of essence that we are working with. Instead, we adopt a classificatory notion of essence as discussed in, say, Okasha (Reference Okasha2002, 202): “[The] essence of a kind is … that set of properties which are jointly sufficient and individually necessary for being a member of the kind.” As we elaborate, this allows that said set of properties are intrinsic (intrinsic essentialism), partly intrinsic and partly relational (partly intrinsic essentialism), or relational properties (relational essentialism).Footnote ¹⁶