john hawks weblog

paleoanthropology, genetics and evolution

invasive

  • Shoe ecology and invasive species

    Wed, 2010-08-18 12:30 -- John Hawks

    On the topic of invasive species, here's one about algae spreading worldwide on the soles of hip waders: "Fly Fishers Serving as Transports for Noxious Little Invaders".

    “We people are clearly the vector for its spread,” said Jonathan McKnight, a wildlife biologist with the Maryland Department of Natural Resources who is trying to protect streams like the Youghiogheny River from didymo, whirling disease and other aquatic invaders.

    “It’s fly fishermen who are doing it,” Mr. McKnight said. “The people who love and appreciate those rivers the most have got to be the ones protecting them.” He said his department planned to ban felt soles this fall.

    Not in the story: the British Columbia streams where didymo originated were mostly under glaciers 10,000 years ago. It was a rapid invader in that habitat long before fishermen got involved.

    Tags: 
    invasive
    conservation
    non-primate

  • Mailbag: Invasive species growth phases

    Sat, 2010-08-14 11:27 -- John Hawks

    Re: "Lag times in biological invasions:

    The initial location of the invasion is not likely to be ideal for the introduced species. Eventually it spreads to an area it is better adapted to and then begins it's growth phase.

    Yes, that's one of the environmental reasons for a lag, often people provide the dispersal vector to bring it to the favorable habitat. Sometimes, people bring the habitat to the invader -- pollution abatement programs sometimes come with a blossom of colonizing species. As you'll see I'm more interested in some much longer-term phenomena, where these issues of environmental factors will also include cultural changes.

    Tags: 
    invasive
    population dynamics

  • Lag times of biological invasions

    Fri, 2010-08-13 18:54 -- John Hawks

    A biological invasion occurs when a species rapidly colonizes a new geographical area. The new area is often very far from the regions considered to be part of the species' native range.

    Well-known examples include the invasion of the southern states of the U.S. by fire ants (originally South American), zebra mussels (originally eastern European) in the Great Lakes, the dispersal of cane toads (originally South American) in Australia, and grey squirrels (originally North American) in England. I've written about invasive species before, focusing on the example of fire ants.

    Many invasions are not instantly successful, and don't really get going until quite a long time after a species is first introduced to a new geographical area. This is called a lag. This phenomenon may seem mysterious. Some alien species seem to cling by their fingernails at low numbers for years, before suddenly exploding into invasiveness.

    Crooks and Soulé (1999) [1] examined this issue of "lag times" for invasive species. There are several reasons why such lags may occur, or be manifested in historical records. The following notes are mostly a paraphrase and summary of this book chapter, with pointers to additional and subsequent research. They delineate several reasons why biologists may detect a lag during a biological invasion.

    1. The species was actually expanding, but wasn't detected in some areas.

    The most obvious reason why a biologist might observe a lag time between introduction and the rapid growth of a population is that he wasn't looking hard enough. Or, to put it more gently, the resolution of observations is not great enough to detect a positive rate of growth at low initial numbers.

    In this consideration of the lag effect during invasions, it should be noted that many estimates of the time between initial invasion and subsequent population explosion may be conservative. This arises from yet another leg effect: Our lag in determining the presence of a new invasive species. It is likely that many invaders are present in low numbers for some time before they are first recorded. Such "early stage subdetectability" was suggested to occur for the medfly (Ceratitis capitata) in California, which may have been present for more than 50 years prior to its discovery in 1975 (Carey, 1996). Such lags in detection of exotics will be especially likely for small or cryptic species in undersampled habitats (108-109).

    This is analogous to the problem of detecting natural selection on a rare allele. It just hasn't grown enough to make it obvious that any shifts in numbers aren't merely random fluctuations.

    Needless to say, if the sampling scheme excludes large areas and provides diagnostic samples at intervals of thousands of years -- like the archaeological record -- the lag in detection of a population may be extreme.

    2. The inherent lag effect.

    This is discussed by Crooks and Soule (1999) from pages 109-114. In some sense, it is a null hypothesis for a lag. For mathematical reasons, a population's numbers follow a curvilinear pattern that may appear as a lag in observational data.

    The exponential growth of a population has a noticable inflection point. When the population is small, its numbers increase slowly. The equation representing growth at a constant intrinsic rate r is:

    N_t = N_0 e^{rt}

    As the population becomes common, its absolute numbers begin to grow very rapidly. Its growth may appear to accelerate or explode in numbers, even though it is actually growing at the same intrinsic rate as before.

    A second inherent lag involves dispersal. The most common model for dispersal of a biological invasion is a diffusion wave model, attributable to R. A. Fisher [2], and developed further by Skellam [3]. This model predicts that a dispersing population will form a "wavefront" that moves at a linear rate over time. This means that the radius of the area occupied by a dispersing population will increase linearly with time. When a population is spreading over a two-dimensional geography, the area it occupies will increase as the square of time.

    This model correponds very well to many historical cases of biological invasion. For example, fire ants:

    Fire ant initial invasion area from 1928-1949

    Fire ant dispersal in southern U.S. from ca. 1939 to 1995. Figure from Brown 1957 p. 260 [4]. Brown took the plot from Wilson (1951).

    When a population already occupies a substantial area, it becomes easy to confirm its rate of increase. But below some threshold area, this small-scale spread can be difficult to observe. Moreover, the diffusion model may break down at small population sizes. The stable wavefront really does not establish itself until a population has saturated its center of origin. Before that point, the dispersal of individuals may cover less area than predicted by the model's linear rate of increase.

    3. Environmental causes for prolonged lags.

    The inherent lag effect occurs even when a population is increasing in numbers and radius at a constant rate. But the rate of increase may vary for many reasons. It is useful to consider both the intrinsic growth rate (r) and the dispersal function (D) separately, as a change in either of these may cause an apparent lag in the pattern of a biological invasion. Crooks and Soule (1999) considered these to be "prolonged" lags, in that they may be greater than expected from the mathematics of growth and dispersal in a population with constant r and D. They first discussed cases where the dispersal or growth rates may be modified by environmental changes.

    In historical cases of biological invasions, human-induced changes in the environment have often enhanced the growth rate or dispersal of invasive populations. I like their example of cut-leaved teasel (pp. 105-106) because I pass a stand of teasel on the highway on my way into Madison:

    The cut-leaved teasel (Dipsacus laciniatus) is a weed that arrived to New York prior to 1900, and in 1913 it was reported only from Albany (Solceki 1993). However, in the last thirty years the plant, which is capable of forming monocultures that exclude most native vegetation, has spread quickly throughout much of the mid-west. This rapid spread has been attributed to dispersal via the interstate highway system, as the teasel is particularly common along highways and roads.

    Obviously, providing an interstate highway of long-distance dispersal to a species with a positive growth rate is going to accelerate an invasion.

    Likewise, human-induced habitat disturbance can make conditions favorable for colonizing species. This phenomenon encompasses situations as varied as the elimination of predators (e.g., coyote eradication allows red foxes to spread), fire abatement (helping red cedars spread into grassland), dams (reducing high water levels and thereby allowing canyon-bottom sandbar communities to spread) or trash dumping (creating mosquito habitat in water traps).

    Climate change may play a role in some invasions. Warming trends have gotten the most attention, in that they may allow some invasive species to extend their ranges further north. But greater local importance may go to shifts in aridity or rainfall.

    The final case they discussed (p. 117) is the Allee effect, a model in which a population at low density cannot find mates or utilize resources as efficiently as a denser population. As they note, this model was discussed by Lewis and Kareiva (1993) [5] as a possible cause of lag times in biological invasions. The same topic was picked up in a 2005 review by Taylor and Hastings [6]. Allee effects might qualify as an intrinsic lag, they are simply a case where the right population growth model is not constant growth, but density-dependent growth. But an environmental change may relax an Allee effect; likewise a genetic change in the invasive population may make it more capable of persisting at low density and thereby overcoming the Allee dynamics.

    4. Genetic causes for prolonged lags.

    To my mind, the most interesting cases entail actual evolution of the invading population to increase its ability to invade. Crooks and Soulé (117) provided a background to this topic, drawing heavily from the literature on colonizing species from the mid-1960's:

    The possibility of a lack of a genetic "fit" of a colonizing population to cause prolonged lags was widely speculated upon at a conference on the genetics of colonizing species (Baker and Stebbins, 1965). Fraser (1965) discussed situations where "migrants move into an environment to which they are not specifically adapted" and "will have an initial phase during which the specific adaptations will have to evolve". Lewontin (in Mayr, 1965) also discussed this issue of “break-out” colonizations, where “under continuous identical selection, there is a long period of stalling of increase in fitness followed by a rapidly rise.” Similarly Mayr (1965) suggested that the sudden spreading of the Serin Finch and Collared Dove may be caused by genetic mutation. Baker (in Mayr, 1965; Baker, 1965) commented that the “sudden explosive spread of animals after a period when nothing very much seems to be happening is paralleled by plants,” that “if a newly introduced plant does not have appropriate `general-purpose' genotypes available, it may be confined to a restricted area until these do become available through recombination or introgression.”

    In 1999, Crooks and Soulé noted that there were essentially no empirical cases where such genetic adaptation had been shown important for an invading population. It made great evolutionary sense, the problem was that genetic changes were extremely hard to demonstrate (118).

    Most mutations that are likely to contribute to fitness are subtle, quantitative changes in the phenotype, rather than qualitative, "Mendelian", phenotypic alterations. But the chances of researchers stumbling on such beneficial new mutations by random search are virtually nil.

    This situation changed markedly during the last decade. By 2002, Carol Lee [7] could compile a short review paper outlining cases of biological evolution accompanying invasion. Many invasive species have undergone Whether such changes were necessary to explain lag times was not clear.

    More obvious was the importance of genetic variation, in Darwin's sense, as a prerequisite for adaptation to occur. A new colonizing species, starting at low numbers, is likely to lack variation (118-119):

    [P]opulation genetics theory provides some insight into the interplay between population size and genetic evolution. First, because of founder effects (Mayr, 1963) [8] very small populations (less than 50 individuals or so) are unlikely to be able to evolve improvements in fitness (Franklin, 1980; Soulé, 1980).

    Calculations based on balancing total mutation rates with genetic drift suggest that until the population size increases to about one thousand, natural selection will not be a very effective force in counteracting the randomizing effects of genetic drift ... and most beneficial mutations, even if they occur, will have a low probability of being incorporated into the population (Soulé, 1980).

    Crooks and Soulé concluded that a positive feedback is likely to exist between population size and invasiveness. One way that this might affect an invading population is that new adaptive variation will appear in proportion to its expanding numbers. Hence, the invasiveness of the population may actually increase over time as its numbers increase. That would make the inflection point of explosive growth relatively steeper, compared to the case where no new adaptive variation were possible.

    A small population becomes more and more likely, as time goes by, to develop the variations that makes it invasive. This would tend to enhance the lag time effect -- a population truly hanging on at low numbers, until the critical adaptive changes happen to enable it to spread widely.

    The importance of genetic diversity to the invasiveness of exotic species has since been demonstrated clearly in several empirical cases. Maybe the most well-known was described by Kolbe and colleagues (2004) [9], who studied a species of Cuban lizards that had been introduced in Florida and throughout the Caribbean. The invasive populations were cases where recurrent introductions had brought genetic variation from Cuba or other sources into small founder populations.

    Why lags are important

    I don't need to say a lot about why invasion lag times are interesting; I'll revisit this issue later. But one aspect that resonates for biologists (120):

    Recognition of both inherent and prolonged lags suggest that the past performance of an invasive species may be a poor predictor of its future potential for numerical increase, range extension, and ecological effects. It is dangerous to assume that ecological containment (mal-adaptation) will last forever, especially if numbers of individuals pass the threshold that increase the likelihood of enhancements of local adaptation by natural selection.

    From one way of thinking, this is no more than to conclude that natural selection is stochastic, and a new adaptive trait can appear at any time. It's more likely to happen in a large population, and it's more likely to happen when the population is far from an adaptive optimum.

    But an alien species is more likely than natives to be far from its adaptive optimum, because it finds itself in a geographical setting far from where it evolved. It may be barely hanging on in this new location. But in the long run that's an ominous sign -- it's the signal that the genetic background of this alien may have a lot of potential for rapid improvement.

    References

    1. Crooks JA, and Soule ME. 1999. Lag times in population explosions of invasive species: Causes and implications. In: Sandlund OT, Schei PJ, Viken \r{A}slaug Invasive Species and Biodiversity Management. Invasive Species and Biodiversity Management. Dordrecht, Netherlands. p 103–125.
    2. Fisher RA. 1937. The Wave of Advance of Advantageous Genes. Annals of Eugenics 7:355–369.
    3. Skellam JG. 1951. Random Dispersal in Theoretical Populations. Biometrika 38:196–218.
    4. Brown WL. 1957. Centrifugal Speciation. Quarterly Review of Biology 32:247–277.
    5. Lewis M. 1993. Allee Dynamics and the Spread of Invading Organisms. Theoretical Population Biology [Internet] 43:141–158. Available from: http://dx.doi.org/10.1006/tpbi.1993.1007
    6. Taylor CM, and Hastings A. 2005. Allee effects in biological invasions. Ecology Letters [Internet] 8:895–908. Available from: http://dx.doi.org/10.1111/j.1461-0248.2005.00787.x
    7. Lee C. 2002. Evolutionary genetics of invasive species. Trends in Ecology & Evolution [Internet] 17:386–391. Available from: http://dx.doi.org/10.1016/S0169-5347(02)02554-5
    8. Mayr E. 1963. Animal Species and Evolution. Cambridge, MA.
    9. Kolbe JJ, Glor RE, Rodriguez Schettino L, Lara AC, Larson A, and Losos JB. 2004. Genetic variation increases during biological invasion by a Cuban lizard. Nature [Internet] 431:177–181. Available from: http://dx.doi.org/10.1038/nature02807
    Tags: 
    invasive
    population genetics
    colonization
    population dynamics

  • Invasive argument

    Wed, 2010-08-11 10:07 -- John Hawks

    I've been reading a lot about invasive species lately, for reasons which will soon become apparent.

    This morning, Ronald Bailey of Reason magazine has an essay about biological invasions: "Invasion of the invasive species!" Bailey notes that invasive species often increase local biodiversity. He then wonders why this is a bad thing?

    The fear among opponents of "invasive species" is the aggressive outsiders will cause a holocaust among the native plants. That might initially seem reasonable because there are a few species, like kudzu, purple loosestrife, and water hyacinth, that grow with alarming speed wherever they show up. But that doesn't mean other species are in danger. “There is no evidence that even a single long term resident species has been driven to extinction, or even extirpated within a single U.S. state, because of competition from an introduced plant species,” Macalester College biologist Mark Davis notes [PDF]. Yet this spurious threat of extinction persists as one of the chief reasons given for trying to prevent the introduction of exotic species.

    Here's why it's a bad thing: Exponential growth. It starts small, but once it gets going it's very expensive or impossible to slow or stop. Gypsy moths. Emerald ash borers. Fire ants.

    Bailey correctly notes that the effects on birds are much more noticeable than those on plants, but doesn't observe that this is because the population sizes of plants are vastly larger than birds. It's harder to make a plant extinct. With less than a couple hundred years separating us from the initial introduction of most invasive species, it's too early to assess the extinction rate of indigenous species. And it's disingenuous to say that we haven't documented an extinction, when we're spending millions of dollars to prevent them! Plus, he's dead wrong when it comes to islands, where reductions in native flora have rapid impacts on native animal populations.

    For Bailey, it comes down to aesthetics -- people like their nature pure and unadulterated by species from the wrong part of the world:

    Fair enough. But this is not a scientific argument. Sax and New Mexico University biologist James Brown correctly observe that whether the impacts of introduced species “are considered to be positive or negative, good or bad is a subjective value judgment rather than an objective scientific finding. Scientists are no more uniquely qualified to make such ethical decisions than lay people.”

    But his essay isn't about introduced species, it's about invasive species. We can't easily predict which introduced animals will become the next fire ants or zebra mussels. Who would have predicted that lionfish would become a huge problem in the Caribbean? It doesn't take an ethicist to figure out that it's hard to keep something manageable when you can't predict its growth rate!

    Sure, some people like the Everglades better with all those pythons. A few yokels was all it took to put them there.

    Tags: 
    introgression
    ecology
    invasive

  • "Don't let invasive biofuel crops invade your country"

    Wed, 2008-05-21 00:34 -- John Hawks

    That's a quote from the International Union for Conservation of Nature, in this Elizabeth Rosenthal article. This spring has seen a backlash against biofuel generation based on its apparent impact on food prices. Among the most promising alternatives to starch or sugar-based ethanol production is cellulosic production from wild grasses or reeds.

    The problem is that the perfect biofuel species -- one that grows easily in a variety of habitats, with little care, and possibly perennial so that it can be harvested year after year without repeated planting -- pretty much is the textbook definition of an invasive plant species.

    The European Union is funding a project to introduce the "giant reed, a high-yielding, non-food plant into Europe Union agriculture," according to its proposal. The reed is environmentally friendly and a cost-effective crop, poised to become the "champion of biomass crops," the proposal says.

    A proposed Florida biofuel plantation and plant, also using giant reed, has been greeted with enthusiasm by investors, its energy sold even before it is built.

    But the project has been opposed by the Florida Native Plants Society and a number of scientists because of its proximity to the Everglades, where giant reed overgrowth could be dangerous, they said. The giant reed, previously used mostly in decorations and in making musical instruments -- is a fast-growing, thirsty species that has drained wetlands and clogged drainage systems in other places where it has been planted. It is also highly flammable and increases the risk of fires.

    Well, burning the stuff certainly defeats the purpose. It seems to me that most of these drawbacks come from insisting on a monoculture, which -- if you have an efficient cellulose processing capacity -- I don't see why you care about. A real natural marsh or tallgrass ecosystem can't stand much mowing, but if you could tune a multispecies ecology for biofuel production, that would pose much less risk of invasive potential, and would be less trouble to look after. The tallgrass ecosystem was based on burning, anyway, so you should be able to maintain the soil while taking out hydrocarbons with minimal fertilizing.

    Tags: 
    invasive
    conservation

  • From the front lines of the squirrel war

    Mon, 2007-10-08 23:29 -- John Hawks

    The Sunday NY Times has a long, entertaining article about the defenders of British red squirrels.

    "Can I, um, suggest something?" [Baron] Redesdale said to the three women. He was seated on a couch with a red-squirrel throw. "I was thinking . . . it would be great to form a sort of mobile kill group." He explained: "We just knock on people's doors and find out if there's a gray and get them to put the traps in." One person a day, he said, would go around and do the actual killings. The women gave Redesdale a "Candid Camera" look. Was this a joke?

    Yes, the leader of the resistance is a real baron, Rupert Redesdale, and the article paints a vivid picture of him along with a looney-sounding squirrel-roasting sidekick. These guys are begging to turn into a Wes Anderson movie.

    Writer D. T. Max treats the American gray squirrels as metaphors for everything from Thatcherite fiscal policy to American imperialism. Which, it turns out, is sort of how they got to England in the first place. Of course, the real problem is squirrelpox -- the flesh-eating disease that gray squirrels carry without effect, but that kills red squirrels dead.

    But the real treasure in this article is the House of Lords debate:

    [B]efore turning his attention to Squirrel Nutkin, Earl Peel proposed conducting "a brief health check" of various other Beatrix Potter characters. "Starting with Tabitha Twitchit and Tom Kitten" -- both cats -- "they are truly on top of their game. . . . Let us now consider the status of Mr. Tod, the fox. On second thoughts, given that he has taken up 700 hours of parliamentary time, it would be somewhat hypocritical of me to prolong the debate." He went on: "That brings me on seamlessly to the other really controversial character that graced the class of 1912 -- and that of course is Tommy Brock," Potter's badger. "Hasn't he done well?"

    Peel continued: "Despite suffering from and carrying tuberculosis, he has successfully managed to establish himself in the hearts and minds of the nation as being more important than dairy cows or, indeed, farmers' livelihoods, and like Mr. Tod, has managed to secure his very own legislation."

    Peel concluded his health check: "Squirrel Nutkin must look back on his alma mater and think to himself, 'How could it have all gone so wretchedly wrong for me?'"

    Can anyone doubt that a hundred years from now, it will be SpongeBob, Patrick and Squidward making an appearance in a debate about coral reef protection?

    Tags: 
    invasive

  • Invasive species

    Sun, 2007-03-04 22:08 -- John Hawks

    The story of colonizing species encompasses a wide range of "colonizing ability". From attempts at deliberate introductions, we know that some species just don't have a great potential to colonizing new territory; others succeed for a while and then explode.

    We don't know the number of failed accidental introductions, but we do know a lot about one extreme -- the accidental introductions of alien species that become invasive problems. Such species have such a high colonizing potential (at least in certain contexts) that their populations explode beyond the numbers in their native ranges.

    Brown (1957), discussing the colonizing ability of populations at the center of population ranges, brings in a number of examples of such invasive species, whose spread is often apparent within the span of decades or even years. One of these is the invasion and spread of the fire ant into North America.

    Fire ants were inadvertently imported to the U.S. from South America sometime around 1918. Wilson (1953) gave an account of the early population history of these ants. It was clear in these early years that there were two forms of the ants, a dark-colored form and a red form. Of these, the red form was the more invasive, but it appeared that the real invasive character of the population might be attibutable to hybridization between the two. Brown (1957:259) quoted Wilson (1953):

    For about ten years [the Mobile population] remained both genetically homogeneous, corresponding to the dark southern race richteri Forel of the South American parental population, and relatively unsuccessful in its new surroundings. In the period following 1930 a smaller reddish form rose to abundance, interbred extensively with the original dark form, and apparently precipitated the species' explosive increase to pest proportions. By 1949 the reddish form had largely replaced the dark form, which had become limited principally to the southern strip of the main population and part of its eastern and western periphery and to two outlying, isolated populations in Mississippi.

    To this, Brown (1957:260) added:

    The dark-phase colonies are now limited to certain separated peripheral areas of the range and a few minor enclaves within the main area of infestation, and even where they occur, they are often in the minority. All degrees of intergration [sic] link dark and red phases. As the red forms press outward, the dark forms apparently suffer both genetic swamping and competition-aggression, and consequently tend to extinction in most habitats. In spite of these forces at work against it, the dark form persists, genetically embedded, so to speak, in the dense and expanding matrix of red populations. This case is very instructive in showing how, regardless of its origin in this particular case, a genetic change actually spreads from a central point of introduction and tends in this way to cause a central-peripheral differential.

    For Brown, the entire case of fire ant invasion is an evidence for central species having a greater colonizing potential than peripheral ones, because the tropical Solenopsis species were displacing congeneric S. geminata and S. xyloni, which had been common throughout the Caribbean and Gulf of Mexico coastal areas. The entire New World, from the point of view of Solenopsis is a zone with a tropical center and subtropical and temperate peripheries. In this case, Brown proposed that the displacement of fire ants from a central area (southern Brazil or Argentina) to the northern periphery had enabled the invasive character of the spread, although with probable adaptive changes in the new colonizing population.

    The other element of this argument is that populations face more competition from similar competitor species and more natural disease and predation in the central parts of their ranges. Where a species can exist at higher densities, it can support more parasites, pathogens, and predators. For fire ants, these predators and parasites include a number of species that have been deliberately introduced as part of efforts to control their spread in the U.S.

    Fire ant initial invasion area from 1928-1949

    Fire ant dispersal in southern U.S. from ca. 1939 to 1995. Figure from Brown 1957 p. 260. Brown took the plot from Wilson (1951).

    I looked at that figure and gasped -- imagine living in one of the outlying counties in 1949 and knowing that pattern of spread.

    Of course, from there the dispersal simply exploded. A good review of the history of fire ant spread was given by Anne-Marie Callcott and Homer Collins (1996). Their maps of infested counties over time say it all:

    Fire ant dispersal map, 1939-1995

    Fire ant dispersal in southern U.S. from ca. 1939 to 1995. Figures from Callcott and Collins 1996, pp. 244-246, recompiled for web format.

    By the 1970's it was understood that the two forms of invasive fire ants had been two species (the dark form, Solenopsis richteri and the red Solenopsis invicta). The differentiation between the two at the colonizing edges of the fire ant wave is a genuine hybrid zone. Shoemaker and colleagues (1996) sampled the genetics of ants in this hybrid zone, finding that genetic markers and morphological characters introgressed at different rates, and that there appeared to be selection against hybrids in contact with one or the other parental type.

    Later, Ross and Shoemaker (2005) studied the genetics of these South American species (S. richteri and S. invicta) in their native ranges. They found that the species were fully reproductively isolated at study sites where both were found. Additionally, the extent of genetic differentiation between different populations of each, and the presence of a third closely related species (S. quinquecuspis) led them to suggest that the group "is actively radiating species". This would be a confirmation of Brown's (1957) argument for the high speciation potential of the central populations in the range of this genus. It remains to be seen whether these central populations have actively generated new colonizing species to displace more peripheral populations by natural movement.

    In the case of fire ants, the rapid colonization of the North American invaders has been aided by some unique social changes, described by Kenneth Ross and colleagues (1996). Probably most people think of ant colonies as having a single queen and many workers and soldier ants. But some kinds of ants form colonies with multiple queens. Imported fire ants have both single-queen and multiple-queen colonies, but the size and proportion of multiple-queen colonies has greatly increased relative to their South American range. This reduces intercolony competition and facilitates their spread compared to native species.

    Later work has shown that S. invicta has a genetic switch that determines whether queens will form their own colonies or whether they will remain in their natal colony or attempt to join a new one. The system is described by Tsutsui and Suarez (2003):

    Queens from the two social forms typically possess different genotypes at the general protein-9 (Gp-9) allozyme locus (Ross 1997; Ross & Keller 1998; Krieger & Ross 2002 ). Monogyne colonies contain queens that are BB at Gp-9 and produce new BB queens that disperse and found colonies independently (Shoemaker & Ross 1996). Conversely, the queens in polygyne colonies are almost exclusively Bb and can produce BB, Bb, and bb queens. New Bb queens either join their natal colony or attempt to join other polygyne colonies (DeHeer et al. 1999). Any BB queens that attempt to join polygyne colonies or reproduce within them are killed by the Bb workers present in polygyne colonies (Ross & Keller 1998). Studies of queen dispersal have shown that newly produced polygyne queens with the BB genotype, who are doomed to execution if they remain in their natal colony or attempt to join other colonies, may attempt to found colonies independently, but with limited success (DeHeer et al. 1999). The bb genotype appears to be lethal in workers, and fertile bb queens are extremely rare (Ross 1997; but see DeHeer et al. 1999; Goodisman et al. 2000. Interestingly, polygyne colonies in the native range can possess reproductive queens that are either BB or Bb (Keller & Ross 1999). This difference between native and introduced populations could indicate the presence of other undiscovered genes or alleles that affect queen number or could be the result of a genetic bottleneck on variation at the loci involved in this process (Keller & Ross 1999; Krieger & Ross 2002).

    This is an interesting case with several elements. A simple genetic strategy is held polymorphic because the homozygotes for the multiple-queen strategy are completely nonviable. In the new founder populations, this allele might be lost completely. Also, possible modifier loci may lose alleles that restrain the formation of supercolonies in their native range.

    Still, when it comes to social changes of invasive ants, nothing compares to the case of the Argentine ant (Linepithema humile). Like fire ants, the Argentine ant invaded the American South, becoming common early in the 1900's. They have also invaded California and the Southwest as well as five of the other six continents (sparing Antarctica...). In Argentine ants, the genetic uniformity of new colonizing populations is so great that the ants form supercolonies stretching across large areas. Here's a passage from a review paper by Neil Tsutsui and Andrew Suarez (2003):

    Throughout their introduced range Argentine ants are highly unicolonial ( Newell & Barber 1913; Markin 1970; Keller & Passera 1989; Way et al. 1997; Suarez et al. 1999; Tsutsui et al. 2000; Giraud et al. 2002) and can attain remarkably high densities. For example, in an early attempt to eradicate Argentine ants from a 19-acre ( 7.7-ha) orange grove in Louisiana, Horton (1918 )reported trapping an astounding 1.3 million queens in artificial nest boxes over the course of 1 year. Including workers and brood, the total volume of Argentine ants collected was over 1000 gallons (Horton 1918). Although a single "supercolony" occupies virtually the entire Californian range ( Tsutsui et al. 2000), close examination has revealed several smaller "secondary" colonies (Holway et al. 1998; Tsutsui & Case 2001). The secondary colonies are spatially restricted, aggressive toward one another and toward the large supercolony, genetically distinct from one another and the large supercolony, and may be the result of separate introductions or genetic drift (Suarez et al. 1999; Tsutsui et al. 2001).

    Yuck! Looking at the 20 inches of snow lining my yard is a whole lot easier when I consider how few invasive ant species have come from Siberia.

    The invading Argentine ants have an even more substantial reduction in genetic diversity than fire ants, with heterozygosity being reduced to a third of its value in the native range of the ants. Not only founder effects, but also unique patterns of social behavior and selection maintain this low diversity. There is selection against genetically different colonies, who are outcompeted by supercolonies of genetically similar lineages. Also, a phenomenon called "queen execution" tends to increase the relatedness of individuals within colonies by eliminating a proportion of reproductives.

    Tsutsui and Suarez (2003) present a good argument for understanding the genetics of this transformation to highly invasive phenotypes:

    Finally, there are dozens of introduced ant species about which virtually nothing is known (McGlynn 1999). Many of these species may have the potential to become invasive, and prevention may be possible only if we are aware of their dispersal capabilities (both natural and human-mediated) and the factors that could facilitate their successful establishment and spread.

    Invasive fire ants have recently reached California and are busily displacing the Argentine ants there. After reading through a number of articles, the final message of many of them has been that invasive species will ultimately be controlled only by the arrival of new invasive competitors.

    Yippee.

    References:

    Brown WL, Jr. 1957. Centrifugal speciation. Q Rev Biol 32:247-277.

    Callcott A-M, Collins HL. 1996. Invasion and range expansion of imported fire ants (Hymenoptera: Formicidae) in North America from 1918-1995. The Florida Entomologist 79:240-251.

    Ross KG, Vargo EL, Keller L. 1996. Social evolution in a new environment: the case of introduced fire ants. Proc Nat Acad Sci USA 93:3021-3025. Abstract

    Shoemaker DD, Ross KG, Arnold ML. 1996. Genetic structure and evolution of a fire ant hybrid zone. Evolution 50:1958-1976.

    Tsutsui ND, Suarez AV. 2003. The colony structure and population biology of invasive ants. Conservation Biol 17:48-58. doi:10.1046/j.1523-1739.2003.02018.x

    Wilson EO. 1953. Origin of the variation in the imported fire ant. Evolution 7:262-263.

    Tags: 
    speciation
    invasive
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