- Biogeography: where life lives
- What is a biodiversity hotspot?
- How biodiversity is distributed globally
- Why biodiversity is distributed unevenly
- New localities lead to new biodiversity
- Tropical rainforest diversity
- Simpson's index of diversity
- Community structure
Species richness and species diversity. Why more diverse ecosystems may be more stable. Roles of foundation and keystone species.
- A community's structure can be described by its species richness, which is the number of species present, and species diversity, which is a measure of both species richness and species evenness (relative numbers).
- Community structure is influenced by many factors, including abiotic factors, species interactions, level of disturbance, and chance events.
- Some species, such as foundation species and keystone species, play particularly important roles in determining their communities' structure.
Different ecological communities can be pretty different in terms of the types and numbers of species they contain. For instance, some Arctic communities include just a few species, while some tropical rainforest communities have huge numbers of species packed into each cubic meter.
One way to describe this difference is to say that the communities have different structures. Community structure is essentially the composition of a community, including the number of species in that community and their relative numbers. It can also be interpreted more broadly, to include all of the patterns of interaction between these different species.
In this article, we'll look at some of the ways that community structure can be quantified (measured numerically). Then, we'll examine factors that shape community structure, focusing especially on foundation and keystone species.
How do we measure community structure?
Two important measures ecologists use to describe the composition of a community are species richness and species diversity.
Species richness is the number of different species in a particular community. If we found species in one community, and species in another, the second community would have much higher species richness than the first.
Communities with the highest species richness tend to be found in areas near the equator, which have lots of solar energy (supporting high primary productivity), warm temperatures, large amounts of rainfall, and little seasonal change. Communities with the lowest species richness lie near the poles, which get less solar energy and are colder, drier, and less amenable to life. This pattern is illustrated below for mammalian species richness (species richness calculated only for mammal species, not for all species). Many other factors in addition to latitude can also affect a community's species-richness.
Species diversity is a measure of community complexity. It is a function of both the number of different species in the community (species richness) and their relative abundances (species evenness). Larger numbers of species and more even abundances of species lead to higher species diversity. For example:
- A forest community with different kinds of trees would have greater species diversity than a forest community with only kinds of trees (assuming that the tree species were even in abundance in both cases).
- A forest community with different kinds of trees in even abundances would have greater species diversity than a forest community with the same number of species in very uneven abundances (for instance, with of the trees belonging to a single species).
In general, ecologists think that more diverse ecological communities are more stable (that is, more able to recover after a disturbance) than less diverse communities. You can explore why this is the case in the video on ecological networks. However, the diversity-stability relationship isn't a universal rule, and there are some cases where other factors (besides species diversity) are more important in determining community and ecosystem stability.
What factors shape community structure?
The structure of a community is the result of many interacting factors, both abiotic (non-living) and biotic (living organism-related). Here are some important factors that influence community structure:
- The climate patterns of the community's location.
- The geography of the community's location.
- The heterogeneity (patchiness) of the environment.
- The frequency of disturbances, or disruptive events.
- Interactions between organisms.
A community's structure can also be shaped by the chance events that happened during its history. For instance, suppose that a single seed blows into the dirt of a particular area. If it happens to take root, the species may establish itself and, after some period of time, become dominant (excluding similar species). If the seed fails to sprout, another similar species may instead be the lucky one to establish itself and become dominant.
Foundation and keystone species
Some species have unusually strong impacts on community structure, preserving the balance of the community or even making its existence possible. These "special" species include foundation and keystone species.
A foundation species plays a unique, essential role in creating and defining a community. Often, foundation species act by modifying the environment so that it can support the other organisms that form the community.
Kelp (brown algae) is a foundation species that forms the basis of the kelp forests off the coast of California. Kelps create environments that allow the survival of other organisms that make up the kelp forest community. The corals of a coral reef are another foundation species. The exoskeletons of living and dead coral make up most of the reef structure, which protects other species from waves and ocean currents. Beavers, which modify their environment by building dams, can also be seen as a foundation species.
A keystone species is a species that has a disproportionately large effect on community structure relative to its biomass or abundance. Keystone species differ from foundation species in two main ways: they are more likely to belong to higher trophic levels (to be top predators), and they act in more diverse ways than foundation species, which tend to modify their environment.
The intertidal sea star Pisaster ochraceus, which is found in the northwestern United States, is perhaps the most famous example of a keystone species. In a classic experiment of community ecology, the sea stars were experimentally removed from the intertidal zone where they lived. As a result, populations of their prey (mussels) increased, altering the species composition of the community and sharply reducing species diversity. When the sea stars were present, about species of barnacles and algae were found in the lower part of the intertidal zone, but when they were missing, the mussel population expanded downward and almost entirely replaced these other species.
This type of sharp reduction in diversity or collapse of community structure commonly occurs when a keystone species is removed. In this case, the loss of diversity happened because the mussels crowded out other species, which could normally persist because the sea stars kept the mussels in check.
Explore outside of Khan Academy
Do you want to learn more about the classic keystone species experiment described above? Check out this scrollable interactive from LabXchange.
LabXchange is a free online science education platform created at Harvard’s Faculty of Arts and Sciences and supported by the Amgen Foundation.
Want to join the conversation?
- Is it possible for there to be more than one keystone species in an area, as well as foundation species?(7 votes)
- Yes, there can be more than one keystones species and foundation species in an area. The densities will be similar for the species but one species can have reduced biomass than the other.(9 votes)
- How does climate shape a biological community?(1 vote)
- Climate is one of the abiotic factors that can introduce variation. According to the videos on niches and competition, no two species can coexist indefinitely if they use the same survival strategy. For example, both wolves and foxes may hunt rabbits, but wolves can run faster so they will eventually outcompete the foxes, driving them to extinction and reducing overall biodiversity. With temperature variation, the foxes' strategy might actually prove better in some years. For example, foxes might have better vision and find it easier to spot rabbits against snow, so they would do better in years with more snow, while wolves will do better in years with less snow. The constant change of climate allows both species to find a niche in otherwise identical conditions and therefore coexist.
Another example would be tree populations - taller trees grow better because they get more sunlight, so if a single tree was to grow much taller than all the others and grow in an umbrella shape, blocking out sunlight and killing all the trees around it, giving other tress 0 chance of survival. If a tree would be much taller that all other trees, it would be more susceptible to breaking due to wind as it would have to take all the wind resistance by itself. A forest full of trees roughly the same height help each other break wind thus climate (wind intensity or lightning bolts) prevent one tree from pushing out all the others.(8 votes)
- Is it possible for there to be more than one keystone species in an area, as well as foundation species?(3 votes)
- Explain why we would expect low species diversity when disturbance/predation occur with a high frequency.(2 votes)
- If a lot of the spices are being eaten by predators and disturbances are stopping the species from surviving and reproducing then the species will die off and it will lead to low diversity(3 votes)
- Can you explain how, for example, an area with only 7 types of species and a total 27 individuals has greater biodiversity than an area with 10 different species and a total 48 individuals?(2 votes)
- Because in the first case there is a smaller number of individuals.
7/27 = 0.25
10/48 = 0.20
Biodiversity is greater in the first case.(3 votes)
- What about the other types of species like other than keystone and foundation species. Someone should add that.(3 votes)
- what are the factors that affect species diversity in an ecosystem(1 vote)
- Several notable factors are listed in the article. I have copied/paraphrased them here.
- Climate of the community's location.
- Geography of the community's location.
- Heterogeneity (patchiness) of the environment
- Frequency of disturbances, or disruptive events.
- Interactions between organisms
Hope this helps!(3 votes)
- what are Dominant species?(1 vote)
- Generally, the predatory species, or species that have a greater amount of members end up being dominant. Hope that helps!(2 votes)
- why can ecological communities be pretty different in terms of the types and numbers of species they contain.(1 vote)
- It all depends on the habitat. For example, a spot with optimal living conditions, such as a jungle, will have more species diversity than an Arctic tundra.
Additionally, consider the variety of habitats on Earth. There are different communities adapted to different ecosystems. A polar bear would not do very well in the Sahara...
In short, harsher climates often mean less diversity, while richer ones generally have more species.
Hope this helps.(1 vote)