Symbiosis

Symbiosis is an ecological relationship realized through a direct body-to-body interaction between individuals of separate species, including mutualism and parasitism. Accordingly, intraspecies exploitative interactions do not qualify as parasitism. The dwarf males of the deep-sea anglerfish (Ceratioidei) obtain nutrients from the much larger females, to which they are permanently attached. These males are not parasites, even if they are often called ‘parasitic males’ (Pietsch, Reference Pietsch2005). Likewise, the exploitation of some people by others does not constitute parasitism, although colloquialism sometimes uses the term in this context (see e.g. Lunsing, Reference Lunsing2003), which may seem offensive and unethical to many (Zimmer, Reference Zimmer2000). Further, this criterion excludes associations where the target of exploitation is not a host individual but a group of hosts (like family, colony, etc.). Thus, brood-parasitic birds which exploit host families (Soler, Reference Soler2018), and social parasites which exploit colonies of eusocial insects (Hölldobler and Kwapich, Reference Hölldobler and Kwapich2022) are all excluded, limiting the concept to individual-level exploitative interactions between species (but see also Rothschild and Clay, Reference Rothschild and Clay1952; Barnard, Reference Barnard, Barnard and Behnke1990; Payne, Reference Payne, Clayton and Moore1997).

Intimate relationship

Parasite individuals live in long-standing body-to-body contact with host individuals; inhabiting a single host individual at least for a whole phase of the parasite developmental cycle but often through several life cycles (Price, Reference Price1980; Nunn and Altizer, Reference Nunn and Altizer2006; Poulin, Reference Poulin2007a, Reference Poulin2007b; Locker and Hofkin, Reference Locker and Hofkin2015; Clayton et al., Reference Clayton, Bush and Johnson2016; Lucius and Poulin, Reference Lucius, Poulin, Lucius, Loos-Frank, Lane, Poulin, Roberts and Grencis2017). This long-lasting nature of the bodily contact – colloquially called an ‘intimate relationship’ (Combes, Reference Combes2001) – excludes ‘kleptoparasites’ from animal parasitism and grazers (locusts, ruminants, etc.) from the concept of phytoparasitism. Similarly, it excludes many blood-sucking insects (tabanids, mosquitoes, etc.), ‘micropredators’ in the sense of Poulin (Reference Poulin2011), which have only fleeting contact with their hosts (Lehane, Reference Lehane2005).

Hosts as habitat patches

From the above, it is obvious that the host body acts as a well-defined ‘habitat patch’ for the parasites (and symbionts) (Rothschild and Clay, Reference Rothschild and Clay1952; Anderson and May, Reference Anderson and May1978; Price, Reference Price1980; Rohde, Reference Rohde1993; Clayton and Moore, Reference Clayton, Moore, Clayton and Moore1997; Poulin, Reference Poulin2007b; Locker and Hofkin, Reference Locker and Hofkin2015). This implies that they are relatively small, more numerous, have shorter life cycle and higher reproductive potential, while hosts are large, less numerous, have longer life cycle and lower reproductive potential.

Nutritive relationship

Parasites, just like mutualists, obtain nutrients from the host body and excrete their metabolic by-products (potentially toxic or carcinogenic wastes) there. A similar but non-nutritive interaction is phoresy, which is an exploitation of host mobility and, consequently, host energy resources (Bartlow and Agosta, Reference Bartlow and Agosta2021).

Antagonistic relationship

Parasitism is an antagonistic relationship that damages the host body structure, metabolism or both while benefiting the parasites. In addition, infections often cause further disadvantages, such as exclusion from social (Kurzban and Leary, Reference Kurzban and Leary2001) and sexual relationships (Hamilton and Zuk, Reference Hamilton and Zuk1982), increased chance of predation (Hudson et al., Reference Hudson, Dobson and Newborn1992) and additional co-infections (Sepkowitz, Reference Sepkowitz2002). Contrarily, some parasites may also induce certain beneficial side-effects, e.g. through reduced predation pressure (Hasik et al., Reference Hasik, de Angeli Dutra, Doherty, Duffy, Poulin and Siepielski2023), through negative interactions with other, more virulent infections (Jenner, Reference Jenner1798; Locker and Hofkin, Reference Locker and Hofkin2015), but their net effect on the host is negative by definition. This implies that parasites are dependent on their hosts, while hosts are non-dependent on parasites (Crofton, Reference Crofton1971a; Rohde, Reference Rohde1993). Consequently, parasitism is obligatory for the parasites, but occurrent to the hosts (Ebert, Reference Ebert2005).

Host adaptations to avoid parasite transmission, survival and reproduction

Infections can drastically affect host populations (Hasik and Siepielski, Reference Hasik and Siepielski2022), even though a publication bias may cause mild and symptomless infections to appear much rarer than in reality. The infections' net effects on the hosts can even be so subtle that it is impossible to directly measure, prove or document them. However, these effects may still exert selective pressure on the host populations to evolve adaptive responses to avoid parasite transmission. Due to these host adaptations to avoid infections, transmission from one host to another is a hazardous episode of the parasite life cycle, most often leading to high parasite mortality (Dobson et al., Reference Dobson, Hudson, Lyles and Crawley1992; Combes, Reference Combes2001; Leung and Poulin, Reference Leung and Poulin2008; Locker and Hofkin, Reference Locker and Hofkin2015).

Similarly, host populations frequently also evolve adaptive responses to defend against established infections, to hinder parasite survival, growth and multiplication, providing an indirect verification of the antagonistic nature of the relationship (Poulin, Reference Poulin2007b; Leung and Poulin, Reference Leung and Poulin2008). Despite their counter-adaptations, parasites' vulnerability to host defences typically constitutes a significant cause of their mortality (other than the losses during transmission, see above). Naturally, host nutrient and energy resources allocated to avoidance and defence constitute further parasite-induced metabolic losses.

Since phytophagous arthropods' most effective natural enemies are often species other than the host plants, like parasitoids and predators (Cornell and Hawkins, Reference Cornell and Hawkins1995; Hawkins et al., Reference Hawkins, Cornell and Hochberg1997), this argument does not necessarily apply to them. Therefore, it is advisable to exclude them (most of all species on Earth) from the concept of parasitism (but see also Price, Reference Price1980; Clayton et al., Reference Clayton, Bush and Johnson2016).

Note that host adaptations to avoid or to fight an infection indicate that this symbiont has been parasitic in the past, but not necessarily in the present.

Parasites' distribution across host individuals

Since parasite avoidance and antiparasitic defence are variable traits across hosts, the distribution of parasite individuals across host individuals is aggregated (overdispersed) (Crofton, Reference Crofton1971b; Anderson and May, Reference Anderson and May1978; Clayton and Moore, Reference Clayton, Moore, Clayton and Moore1997). This means that most parasite individuals inhabit a few heavily infected hosts (those with poor avoidance and defence capabilities), while most of the host individuals (those with average or better capabilities) harbour few if any parasites. Contrarily, mutualists often express other types of frequency distributions across host individuals, such as even and polymodal distributions (see e.g. Britayev et al., Reference Britayev, Martin, Krylova, Von Cosel and Aksiuk2007; Elliott et al., Reference Elliott, Chou, Chen, Bloemberg, Bontemps, Martínez-Romero, Velázquez, Young, Sprent and James2009).

The parasitism–mutualism continuum

Contrary to parasites, symbionts which exert positive net effects to the hosts are called mutualists. According to the net costs or benefits caused to the hosts, there is a continuum from parasitism through neutral commensalism to mutualism. Host–symbiont species pairs may shift quite flexibly along this continuum, the nature of their relationship may vary through space and time (Bronstein, Reference Bronstein1994; Leung and Poulin, Reference Leung and Poulin2008; Rózsa and Apari, Reference Rózsa and Apari2012; Lucius and Poulin, Reference Lucius, Poulin, Lucius, Loos-Frank, Lane, Poulin, Roberts and Grencis2017).

Parasites do not usually kill their hosts

Parasites do not usually kill their hosts and therefore, they are not adapted to transmit from dead hosts to new ones. This differentiates them from parasitoids, which kill their host as a prerequisite for successful development and transmission to further host individuals (Rothschild and Clay, Reference Rothschild and Clay1952; Anderson and May, Reference Anderson and May1978; Poulin and Morand, Reference Poulin and Morand2000; Ebert, Reference Ebert2005; Poulin, Reference Poulin2007a, Reference Poulin2007b; Goater et al., Reference Goater, Goater and Esch2014; Locker and Hofkin, Reference Locker and Hofkin2015; Lucius and Poulin, Reference Lucius, Poulin, Lucius, Loos-Frank, Lane, Poulin, Roberts and Grencis2017). According to the different degrees of lethality caused by infections, there is a continuum from non-lethal (more or less mild) parasitism to lethal parasitism (properly called parasitoidism). Host–symbiont species pairs may shift quite flexibly along this continuum, the nature of their relationship may vary through space and time. Taking trophically transmitted parasites as an example, they often manipulate intermediate host behaviour to increase predation by the definitive host. This means that they kill their hosts indirectly through a predator, the frequency and effectiveness of which can vary between species.

Taxonomic scope of parasitism

Finally, several authors specify a taxonomic scope of parasitism for historical and practical reasons (Poulin, Reference Poulin2007a, Reference Poulin2007b; Locker and Hofkin, Reference Locker and Hofkin2015). Some authors delimit the concept to include only animals and ‘animal-like’ (eukaryotic and heterotrophic) protists that parasitize animals (e.g. Goater et al., Reference Goater, Goater and Esch2014). Others include all types of microbes, plants and fungi, both as hosts and as parasites. Finally, some authors include even suborganismal entities – like viruses and macromolecules, such as nucleic acid or protein strands (RNA, DNA, prions) – into the concept of parasitism, setting the maximum of a taxonomical domain (Combes, Reference Combes2001; Lucius and Poulin, Reference Lucius, Poulin, Lucius, Loos-Frank, Lane, Poulin, Roberts and Grencis2017).

Level 1: host cells

A multicellular organism's survival and reproductive success depend on its ability to regulate its cells' growth, survival and reproduction. Cellular infections can modify all these 3 components. First, programmed cell growth can be obstructed by various protist and fungal infections, most notably by Microsporidia, occurring predominantly in fish hosts. Infected cells grow into vast masses of parasites packed within a single host cell called xenoma (Lom and Dyková, Reference Lom and Dyková2005). Second, programmed cell death (apoptosis) and controlled cell division are also essential. Whenever cell division runs amok in an unregulated manner, a malignant tumour develops, threatening the very existence of the multicellular individuals. Taking the population of the USA as an example, approximately 3–4% of all cancer cases are attributable to the most common carcinogenic infections like Helicobacter pylori, hepatitis B virus, hepatitis C virus, human herpes virus type 8, human immunodeficiency virus or human papillomavirus (Islami et al., Reference Islami, Goding Sauer, Miller, Siegel, Fedewa, Jacobs, McCullough, Patel, Ma, Soerjomataram, Flanders, Brawley, Gapstur and Jemal2018). Evidently, infection-induced increase in cellular growth, survival and reproduction reduces the survival and reproduction of the multicellular host organism.

Level 2: host individuals

For obvious reasons, medical and veterinary scientists focus their interest on diseases. Symptoms define diseases, and – understandably – infected hosts' reduced lifespan and fertility are among the most obvious symptoms. Contrarily, health is characterized by a long and fertile life. Therefore, infections that increase host longevity, fertility or both are classified as mutualists. Similarly, in the evolutionary-ecological literature, a parasite-induced reduction of host lifetime reproductive success (LRS) is also interpreted as indisputable evidence for parasitism by thousands of research articles (see e.g. Herre, Reference Herre1993; Lipsitsch et al., Reference Lipsitsch, Siller and Nowak1996; van Dijk and De Baets, Reference van Dijk, De Baets, De Baets and Huntley2021).

Level 3: host lineages

Lineages are comprised of host individuals linked by genetic inheritance along the parent–offspring relationships. Lineages are usually not regarded as a distinct level of biological organization; however, ever since Darwin (Reference Darwin1859) they represent units of selection (see e.g. Garay et al., Reference Garay, Varga, Gámez and Cabello2016; Nunney, Reference Nunney and Keller2019, Krishnan et al., Reference Krishnan, Rózsa, Szilágyi and Garay2023). In modern days, the concept of multilevel selection posits that selection occurs in parallel at various levels in the hierarchy of biological organization (Wade et al., Reference Wade, Wilson, Goodnight, Taylor, Bar-Yam, de Aguiar, Stacey, Werfel, Hoelzer, Brodie, Fields, Breden, Linksvayer, Fletcher, Richerson, Bever, Van Dyken and Zee2010). Following these views, lineages are treated here as one of the parallel levels of selection.

For sake of simplicity, we consider only parthenogenetic (asexual) host lineages. At first glance, this appears to be nonsense because a symbiont which transmits exclusively along mother-to-daughter routes in a parthenogenetic host population necessarily tends to a mutualist way of life. Otherwise, if it reduces host fitness, then it will be lost from the host population (Fine, Reference Fine1975; Frank, Reference Frank1996). In this case, however, the growth rates of infected and non-infected host lineages must be compared. For this purpose, it is not necessary to presume that parasites or mutualists are transmitted along these lineages; instead, the genetic predispositions of hosts (such as genes regulating the immune system) are transmitted along the parent–offspring relationships. Thus, whatever transmission route (horizontal or vertical) is used by parasites, it is the host's infection state (infected or uninfected) that is inherited along the lineages.

By definition, parasites are expected to reduce the growth rate of infected lineages compared to uninfected ones, while mutualists are expected to exert the opposite effect. Readers may intuitively assume that infections which decrease the host individuals' survival and reproduction necessarily decrease the fitness of infected host lineages too – which is not necessarily true. Fitness is a term with several subtly different meanings (Orr, Reference Orr2009). Generally speaking, it is the expected contribution of alleles, genotypes or organisms to future generations relative to the other alternative alleles, genotypes or organisms in the population (Stearns, Reference Stearns1992; Pásztor et al., Reference Pásztor, Botta-Dukát, Magyar, Czárán and Meszéna2016). Let us consider a hypothetical example. Part of the population harbours an infection that halves both longevity and fertility of infected hosts. Say, uninfected hosts complete their life cycle in 2 years and produce 4 offspring at the end of their life, while infected hosts live only for 1 year and produce only 2 offspring at the end of their life. Thus, the annual growth of the uninfected host lineage is 1, 1, 4, 4, 16 through 5 years, while that of the infected hosts is 1, 2, 4, 8, 16 through the same period. In this imaginary case, infection halves both the longevity and LRS of host individuals, while it does not change the fitness (growth rate) of infected lineages. Logically, this symbiont should be classified as a neutral commensal. Under the same simplistic circumstances, a symbiont that doubles the lifespan and fertility of infected hosts would also not qualify as a mutualist.

Real-life host populations, however, most often have overlapping generations; thus, the combined effects of changes in longevity and fecundity are more challenging to assess. Nevertheless, it is easy to construct hypothetical models in which reducing host lifespan, reproduction or both comes together with increasing host lineage growth. Examples are provided for infections that (i) reduce host longevity, do not affect LRS, but increase host lineage growth (Box 1), (ii) do not affect mortality, reduce LRS, but increase host lineage growth (Box 2), (iii) reduce both host lifespan and LRS, but increase host lineage growth (Box 3). In the last hypothetical example, not only host lifespan and LRS, but also the mean annual fecundity is unchanged, while the host lineage growth increases (Box 4). Note that all these counter-intuitive effects are based on the fact that selection favours not only the greater fecundity but also, the faster speed of producing offspring (Brommer et al., Reference Brommer, Merilä and Kokko2002), as visualized in Fig. 1.

Box 1. Increasing host mortality may increase host lineage growth

In population ecology, Leslie matrices are discrete-time, age-structured demographic models of populations with overlapping generations. They describe the multiplication of female individuals only. Let us consider a simple life history model where:

• • the lifespan of the uninfected hosts is 3 years, and the 1st year juveniles do not multiply,

• • the survival rate in the t-th year age is denoted by ω _t,

• • the average fecundity in the t-th year is denoted by α _t,

thus the lifetime reproductive success (LRS) is ω ₁α ₂ + ω ₁ω ₂α ₃ (a host can reach the 2nd year with probability ω ₁ when it multiplies by α ₂, and the 3rd year with probability ω ₁ω ₂when it multiplies α ₃).

Using this notation, the Leslie matrix reads as

$$\left({\matrix{ 0 & {\alpha_2} & {\alpha_3} \cr {\omega_1} & 0 & 0 \cr 0 & {\omega_2} & 0 \cr } } \right).$$

In this model, there are 3 ways how a symbiont might affect the infected host population:

• • decrease or increase the life span,

• • decrease or increase at least one survival rate,

• • decrease or increase at least one fecundity rate.

The long-term growth rate (R ₀) of host lineages can be determined as the asymptotic growth rate (the dominant, positive eigenvalue of the Leslie matrix) corresponding to the stable age distribution (Caswell, Reference Caswell2001).

Using these notations, consider an infection that increases host mortality, does not affect LRS, but increases host lineage growth. Let us compare the Leslie matrices of infected vs uninfected host lineages of a hypothetical population. We assume that not the parasites themselves, but the hosts' state of being infected vs uninfected is transmitted through generations.

Uninfected hosts, LRS: 1 × 1 + 1 × 1 × 3 = 4

$$\left({\matrix{ 0 & 1 & 3 \cr 1 & 0 & 0 \cr 0 & 1 & 0 \cr } } \right)$$

Infected hosts, LRS: 1 × 4 = 4

$$\left({\matrix{ 0 & 4 \cr 1 & 0 \cr } } \right)$$

The long-term growth rate of the uninfected lineage is R ₀ ≈ 1.67, and that of the infected lineage is R ₀ = 2.

Box 2. Reducing host LRS may increase host lineage growth

Using the same notations and assumptions as above, consider the following example:

Uninfected host, LRS: 1 × 1 + 1 × 1 × 5 = 6

$$\left({\matrix{ 0 & 1 & 5 \cr 1 & 0 & 0 \cr 0 & 1 & 0 \cr } } \right)$$

Infected host, LRS: 1 × 3 + 1 × 1 × 2 = 5

$$\left({\matrix{ 0 & 3 & 2 \cr 1 & 0 & 0 \cr 0 & 1 & 0 \cr } } \right)$$

The long-term growth rate of the uninfected hosts is R ₀ ≈ 1.90, and that of the infected hosts is R ₀ = 2.00.

Box 3. Reducing host lifespan and LRS may increase host lineage growth

Using the same notations and assumptions as above:

Uninfected host, LRS: 1 × 1 + 1 × 0.55 × 2 = 2.1

$$\left({\matrix{ 0 & 1 & 2 \cr 1 & 0 & 0 \cr 0 & {0.55} & 0 \cr } } \right)$$

Infected host, LRS: LRS = 1 × 2 = 2

$$\left({\matrix{ 0 & 2 \cr 1 & 0 \cr } } \right)$$

The long-term growth rate of the uninfected lineage is R ₀ ≈ 1.35, and that of the infected lineage is R ₀ ≈ 1.41.

Box 4. Host lifespan, LRS and mean annual fecundity are unchanged, but host lineage growth increases

Using the same notations and assumptions as above:

Uninfected host, LRS: 1 × 1 + 1 × 1 × 2 = 3

$$\left({\matrix{ 0 & 1 & 2 \cr 1 & 0 & 0 \cr 0 & 1 & 0 \cr } } \right)$$

Infected host, LRS: 1 × 2 + 1 × 1 × 1 = 3

$$\left({\matrix{ 0 & 2 & 1 \cr 1 & 0 & 0 \cr 0 & 1 & 0 \cr } } \right)$$

The long-term growth rate of the uninfected hosts is R ₀ ≈ 1.52, and that of the infected hosts is R ₀ ≈ 1.62 (see also Fig. 1).

Figure 1. An infection that does not change host lifespan, lifetime reproductive success (LRS) or mean annual fecundity may still increase or decrease the growth rate of host lineages. Representation of 2 hypothetical parthenogenetic host lineages, where individuals' longevity is 3 years, there is no reproduction in the 1st year, and a total of 3 offspring are produced during the 2nd and 3rd years. Above, individuals breed less intensively in the 2nd year and more intensively in the 3rd year, which is reversed below. Shifting the reproduction peak to an earlier period in the life cycle increases growth rate, even though population dynamic indices (longevity, LRS, annual mortality and fecundity rates) are equal. Solid lines represent the survival of individuals to the following year, and dotted lines represent reproduction. Darker circles represent later generations than lighter ones (see also Box 4).

To the best of our knowledge, no one has raised these points before, so previous studies have never interpreted the differences between parasite-infected and non-infected host lineages along these lines. However, the contradictory results of some studies seem to suggest that similar phenomena may occasionally occur. For example, fungal endophytes increase fecundity in the grass Agrostis hyemalis at the expense – or benefit? – of reducing its longevity (Yule et al., Reference Yule, Miller and Rudgers2013). Toxoplasma gondii, a widespread infection in rodents and humans, increase predation pressure (Berdoy et al., Reference Berdoy, Webster and Macdonald1995) and traffic accidents (Gohardehi et al., Reference Gohardehi, Sharif, Sarvi, Moosazadeh, Alizadeh-Navaei, Hosseini, Amouei, Pagheh, Sadeghi and Daryani2018) of infected hosts while, on the other hand, makes them sexually more attractive potentially increasing their reproductive success (Dass et al., Reference Dass, Vasudevan, Dutta, Soh, Sapolsky and Vyas2011; Borráz-León et al., Reference Borráz-León, Rantala, Krams, Cerda-Molina and Contreras-Garduño2022). We cannot quantify the combined fitness effects of reduced lifespan and (presumably) increased reproductive success of infected hosts; however, host adaptations to combat Toxoplasma infections indicate that it is unfavourable at the lineage level.

Level 4: host populations

We usually expect parasite infections to decrease and mutualist infections to increase the host population growth rate (Anderson and May, Reference Anderson and May1978). In real life, however, host populations are embedded in ecological communities formed by a network of several interspecific relationships. Relationships other than the host–parasite relationship in focus may influence the actual parasite-induced harm or benefit to the host population. Thus, certain symbionts that decrease host fitness at the former levels may still increase host population growth rate.

Looking at a multispecies community, successfully invading populations may benefit from hosting pathogens and transmitting them to endemic competitor populations (McNeill, Reference McNeill1976). ‘McNeill's Rule’, i.e. a pathogen-mediated negative interaction between host species (or populations) is also called ‘parasite-mediated competition’ or ‘apparent competition’ or ‘novel weapon hypothesis’ in the parasitological literature (Hudson and Greenman, Reference Hudson and Greenman1998; Ricklefs, Reference Ricklefs2010; Vilcinskas, Reference Vilcinskas2015). For instance, in human history, the spillover of smallpox and measles from the colonizing European populations decreased the competitive abilities of native populations (McNeill, Reference McNeill1976; Diamond, Reference Diamond1998). Similarly, apparent competition mediated via shared parasites contributes to the invasion success of introduced exotic gamebirds (Tompkins et al., Reference Tompkins, Draycott and Hudson2002a), crayfish (Small and Pagenkopp, Reference Small and Pagenkopp2011) and squirrels (Tompkins et al., Reference Tompkins, Sainsbury, Nettleton, Buxton and Gurnell2002b). This phenomenon is caused by the differential virulence (low in the coevolved invasive species and high in the naive indigenous hosts) that yields a parasite-mediated competitive advantage of the invasive population. Thus, an infection-induced reduction of individual fitness within the invasive host population comes together with the increased competitive success of this population.

Examples of the opposite scenario may also occur, i.e. symbionts that are mutualistic at the individual or lineage level but harmful at the population level. We suspect that Wolbachia infections of some insect populations may exemplify this case. Some strains of Wolbachia induce parthenogenesis in the infected insects, often making whole populations or species parthenogenetic (Knight, Reference Knight2001). Switching to parthenogenesis likely increases individual and lineage multiplication rates since all the metabolic and genetic costs of sex are spared. However, parthenogenetic reproduction is a self-destructive strategy; asexual populations and species are more likely to go extinct in the long run (Moreira et al., Reference Moreira, Fonseca and Rojas2021).