The geographical limits to the distribution of a species are determined by biotic or abiotic factors. Core populations are those occurring within the centre of the range, and marginal populations (also called peripheral populations) are found at the boundary of the range.
The inability of a species to expand its range beyond a certain geographic area is because of some limiting factor or factors to which the species cannot successfully adapt. In some cases, geographical range limits are entirely predictable, such as the physical barrier of an ocean for a terrestrial species. In other cases the specific reasons why species do not pass these boundaries are unknown, however, ecology is the main determinant of the distribution of a species. The fitness of a species falls at the edges of its distributional range, with population growth and fitness falling to zero beyond where a species can survive.
For many species of invertebrate animals, the exact geographic range limits have never been precisely ascertained, because not enough scientific field work has been carried out in many parts of the world to map distribution more precisely, therefore finding a range extension for species, especially marine species, is not an uncommon occurrence.
Marginal distributions can have conservation implications.
Terminology
The science of understanding the distributions of organisms is known as chorology, a branch of biogeography. The core population of a species are those individuals occurring within the centre of the range. Although one cannot ever truly know the ideal niche of a particular species, it can be approximated from the core of the distribution, this is known as the "realized ecological niche". Marginal or peripheral populations are those found at the boundary of the range. When the distribution of a species is changing, the leading edge populations are at the expanding geographic edge of the distribution range whilst rear edge populations are undergoing retreat.
The central‐marginal hypothesis, also sometimes called the "central-peripheral population hypothesis", posits that there is less genetic diversity and greater inter‐population genetic differentiation at the range margins, as compared to the range cores. This is based on the assumption that the habitat is most ideal at the centre of a distribution and ecological conditions decline towards the margin. Because the population size at the margin is likely to be smaller, genetic drift can have a larger effect and reduce the genetic variation of marginal populations. Reduced gene flow between central and peripheral populations also limits the genetic diversity at the margins. High selection pressure, due to a less than ideal habitat at the margin, furthermore reduces genetic diversity. Although exceptions to this hypothesis are common, in general this rule appears to hold empirically true. The spatial distribution often differs, with the population being more dense in the centre as opposed to the margins, this can often have a simple probability distribution pattern. The gene flow between central and peripheral populations may prevent range expansion when it does not allow the gene pool at margin to differentiate. Conditions at the centre of the range differ from those at the periphery, therefore adapted alleles at the centre may not benefit marginal populations experiencing different conditions. The asymmetrical gene flow hypothesis posits that there is more gene flow from central to peripheral populations. Empirical data supporting this theory is less robust.
When circumstances, usually climatic, restrict the distribution to a small area, this is known as a refugium. In Europe, for example, the geographical spokes sticking out of the continent in the south - the Iberian Peninsula, Italy and the Balkans served as refugia for warmth-adapted species during the Ice Ages.
Abiotic factors
Gradients in any abiotic factor, such as climate, create physiological barriers to dispersal. All species have limits of tolerance to abiotic factors. Too much or too little of anything can lower their survival and reproductive success and cause reduced fitness. Changes in temperature resulting from global warming, for example, may cause a species to change its geographical distribution northward. Precipitation can also be a key determinant in limiting the geographic range edges of species. This is often seen in organisms with high water demands, whose survival and reproduction is limited by dry conditions. Moisture in the soil can also put limits on the distribution of an organism. There are many other abiotic factors that can determine a species range, including dissolved oxygen, conductivity, alkalinity and pH.
Biotic factors
Interactions between organisms can cause limitations to the distribution of a species. One interaction that may limit a distribution is predation, where prey species are limited from a particular area by very efficient predators, or where these predators may permit certain prey to have larger ranges. Interspecific competition is another common determinant of the distribution of individual species. Where two similar species share an overlapping range, competition often causes the distributions to shift to exclude one of the two. The geographic range of one species may be linked to another, where the range of one species cannot extend independent of the other. This is seen in parasitism or mutualism, where survival is not possible without the hosts. Parasitism can also play another role in determining the distribution of a species: marginal populations with suboptimal habitats can carry a higher parasite load. This may be because less favourable conditions at the margins of a distribution lead to lower resistance to infection.
Anthropogenic factors
Humans can cause changes to the environment and alter distributions. Deforestation can increase the habitat of certain species and allow them to expand their distribution, or change distributions in response to a decrease in habitat. Recent changes in average temperatures, which may be caused by humans, are causing changes in the distribution of some species, such as northward expansion. Humans have also initiated many range expansions by introducing species to new locations both intentionally and accidentally. These species may survive and reproduce in these new locations and thus expand their distribution. These species may also cause changes in the distributions of native species that cannot tolerate the novel competition.
Combined influences
In most cases combinations of factors are responsible for limiting the geographic range edge of species. Abiotic and biotic factors may work together in determining the range of a species. An example might be some obligate seeder plants where the distribution is limited by the presence of wildfires, which are needed to allow their seed bank to germinate, and also use dispersal of their seeds mediated by ants.
See also
References
- ^ Mott, CL (2010). "Environmental Constraints to the Geographic Expansion of Plant and Animal Species". Natural Education Knowledge. 3 (10): 72.
- Hardie, DC; Hutching JA (2010). "Evolutionary ecology at the extreme of species' ranges". Environmental Reviews. 18 (NA): 1–20. doi:10.1139/a09-014.
- Stanton-Geddes, J; Tiffin P; Shaw RG (2012). "Role of climate and competitors in limiting fitness across range edges of an annual plant". Ecology. 93 (7): 1604–1613. doi:10.1890/11-1701.1. PMID 22919907.
- Morelli, Federico (August 2013). "Relative importance of marginal vegetation (shrubs, hedgerows, isolated trees) surrogate of HNV farmland for bird species distribution in Central Italy". Ecological Engineering. 57: 261–266. doi:10.1016/j.ecoleng.2013.04.043.
- ^ Policy brief on Marginal and peripheral forests (PDF) (Report). COST European Cooperation in Science and Technology. pp. 1–6. FPS COST Acti on FP1202. Retrieved 5 October 2020.
- Guo, Qinfeng (11 June 2014). "Central-marginal population dynamics in species invasions". Frontiers in Ecology and Evolution. 2 (23). doi:10.3389/fevo.2014.00023.
- ^ Yang, Aihong; Dick, Christopher W.; Yao, Xiaohong; Huang, Hongwen (10 May 2016). "Impacts of biogeographic history and marginal population genetics on species range limits: a case study of Liriodendron chinense". Scientific Reports. 6 (25632): 25632. Bibcode:2016NatSR...625632Y. doi:10.1038/srep25632. PMC 4861920. PMID 27162176.
- Kennedy, John Paul; Preziosi, Richard F.; Rowntree, Jennifer K.; Feller, Ilka C. (February 2020). "Is the central‐marginal hypothesis a general rule? Evidence from three distributions of an expanding mangrove species, Avicennia germinans (L.) L." Molecular Ecology. 29 (4): 704–719. doi:10.1111/mec.15365. PMC 7065085. PMID 31990426.
- Dai, Q; Fu JZ (2011). "When central populations exhibit more genetic diversity than peripheral populations: a simulation study". Chinese Science Bulletin. 56 (24): 2531–2540. Bibcode:2011ChSBu..56.2531D. doi:10.1007/s11434-011-4605-x.
- Brown, JH (1984). "On the relationship between abundance and distribution of species". The American Naturalist. 124 (2): 255–279. doi:10.1086/284267. S2CID 84276000.
- Kirkpatrick, M; Barton NH (1997). "Evolution of a species' range". American Naturalist. 150 (1): 1–23. doi:10.1086/286054. PMID 18811273. S2CID 28389132.
- Harter, D. E. V.; Jentsch, A.; Durka, W. (May 2015). "Holocene re‐colonisation, central–marginal distribution and habitat specialisation shape population genetic patterns within an Atlantic European grass species". Plant Biology. 17 (3): 684–693. doi:10.1111/plb.12269. PMID 25266560.
- Battisti, A; Stastny M; Netherer S; Robinet C; Schopf A; Roques A; Larsson S (2005). "Expansion of geographic range in the pine processionary moth caused by increased winter temperatures". Ecological Applications. 15 (6): 2084–2096. doi:10.1890/04-1903. hdl:11577/1421038. S2CID 85727778.
- Bateman, BL; Abell-Davis SE; Johnson CN (2011). "Climate-driven variation in food availability between the core and range edge of the endangered northern betting (Bettongia tropica)". Australian Journal of Zoology. 59 (3): 177–185. doi:10.1071/zo11079. S2CID 18311626.
- Duckworth, G; Altwegg R; Guo D (2010). "Soil moisture limits foraging: a possible mechanism for the range dynamics of the hadeda ibis in southern Africa". Diversity and Distributions. 16 (5): 765–772. doi:10.1111/j.1472-4642.2010.00683.x. S2CID 83593117.
- Neff, MR; Jackson DA (2011). "Effects of broad-scale geological changes on patterns in macroinvertebrate assemblages". Journal of the North American Benthological Society. 30 (2): 459–473. doi:10.1899/10-052.1. S2CID 53642682.
- ^ Holt, RD; Barfield M (2009). "Trophic interactions and range limits: the diverse roles of predation". Proc. R. Soc. B. 276 (1661): 1435–1442. doi:10.1098/rspb.2008.1536. PMC 2677217. PMID 19324814.
- Hersteinsson, P; Macdonald W (1992). "Interspecific competition and the geographical distribution of red and arctic foxes Vulpes vulpes and Alopex lagopus". Oikos. 64 (3): 505–515. doi:10.2307/3545168. JSTOR 3545168.
- Armitage, DW; Jones SE (2020). "Coexistence barriers confine the poleward range of a globally distributed plant" (PDF). Ecology Letters. 23 (12): 1838–1848. doi:10.1111/ele.13612. PMID 33022085. S2CID 222183571.
- Stanton-Geddes, J; Anderson C (2011). "Does a facultative mutualism limit species expansion?". Oecologia. 167 (1): 149–155. doi:10.1007/s00442-011-1958-4. PMID 21380848. S2CID 25646719.
- Briers, R (2003). "Range limits and parasite prevalence in a freshwater snail". Proceedings of the Royal Society of London. 270 (Suppl 2): 178–180. doi:10.1098/rsbl.2003.0046. PMC 1809944. PMID 14667375.
- Kostecke, RM; Ellison K; Summers SG (2004). "Continued range expansion by bronzed cowbirds in the southwestern united states". The Southwestern Naturalist. 49 (4): 487–492. doi:10.1894/0038-4909(2004)049<0487:crebbc>2.0.co;2. S2CID 85732049.
- Larsen, TH (2012). "Upslope range shifts of Andean dung beetles in response to deforestation: compounding and confounding effects of microclimactic change". Biotropica. 44 (1): 82–89. doi:10.1111/j.1744-7429.2011.00768.x. S2CID 83292640.
- Crozier, L (2004). "Warmer winters drive butterfly range expansion by increasing survivorship". Ecology. 85 (1): 231–241. doi:10.1890/02-0607.
- McNeil, JN; Duchesne R (1977). "Transport of hay and its importance in the passive dispersal of the European skipper, Thymelicus lineola (Lepidoptera:Hesperiidae)". Can. Entomol. 109 (9): 1253–1256. doi:10.4039/ent1091253-9. S2CID 86013170.
- Arnan, X; Rodrigo A; Molowny-Horas R; Retana J (2010). "Ant-mediated expansion of an obligate seeder species during the first years after fire". Plant Biology. 12 (6): 842–852. doi:10.1111/j.1438-8677.2009.00294.x. PMID 21040299.