Ecology test #3 . clap this up
Overgrowth
When one species grows bigger than another and takes its space (mostly in plants) If two plants are trying to live in the same area and one plant starts to grow so big that it blocks the sun and water from the other plant, so it dies.
Definitive host
a host in which the parasite reaches maturity and, if possible, reproduces sexually
Predator/Prey interactions
**()()**
Competitive release (niche expansion)
Niche expansion in response to reduced interspecific competition. occurs when one of two species competing for the same resource disappears, thereby allowing the remaining competitor to utilize the resource more fully than it could in the presence of the first species
Benefits of cooperation
More efficient protection (vigilance) - more time to eat -Can handle prey otherwise impossible
Growth rate of pred pop = 0
When Nh = dp/fc Nh= prey population f = conversion of prey into pred offspring c = capture efficiency dp= predator deaths
Growth rate of pred population increases
When Nh > dp/fc
Growth rate of prey pop declines
When Np > rh/c
Chase down
Must be fast Or have good endurance (at least better than your prey) (Assumes that you can handle prey on your own)
Types of biotic interactions
Mutualism (cooperation) Predation (Parasitism) Competition Commensalism Ammensalism
Specialist
Narrow niche, use a specific range of resources Under stable conditions More specialists in the tropics panda koala aye-aye
Amensalism
Negative for individual A, individual B is unaffected -0 Stepping on a bug
Competition
Neither is doing as well as if they didn't have to compete but they don't have a choice Interspecific- members of different species compete for a shared resource. Intraspecific- members of the same species compete for limited resources. --
Liebig's law of the minimum
"The availability of the most abundant nutrient in the soil is only as good as the availability of the least abundant nutrient in the soil." Or, to put it more plainly, "A chain is only as strong as its weakest link."
Kleptoparasitism
- Form of feeding in which one animal takes prey or other food from another that has caught, collected, or otherwise prepared the food, including stored food.
Mechanical defenses
-Sharp quills of a porcupine, prickly spines of a cactus, tough armor on an armadillo
Predator strategies
...
Parasite classifications
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Chemical (allelopathy)
A biological phenomenon by which an organism produces one or more biochemicals that influence the germination, growth, survival, and reproduction of other organisms. These biochemicals are known as allelochemicals and can have beneficial (positive allelopathy) or detrimental (negative allelopathy) effects on the target organisms
Camouflage
A form of mimicry The hiding of something as a result of its appearance cryptic coloration
Mutualism
A relationship between two species in which both species benefit -Interactions are positive for both participants -Relationship may depend upon environmental conditions -Again may be facultative or obligate, symbiotic or not -Trophic, habitat, service (defensive, dispersive) -Penalties to prevent cheating example: Mycorrhizae and plants Increase access to nutrients Increase access to water
Constitutive response
A response that is always present (thorns)
Similarities
Both : one player benefits other is harmed Both: effect population of exploited species
Aposmatic coloration
Bright colors to show that one is poisonous
Effects of parasitism
Can change outcome of competition Can "regulate" populations of host species Can affect mate choice Feather colors Can lead to co-evolution Eventually perhaps to mutualistic relationship Or vice versa?
Cooperation
Common in carnivores Can overwhelm otherwise unmanageable prey Pack hunters (wolves, lions etc) Social foragers (gulls, primates etc) White pelicans Bubblenetting (whales)
Grazers
Consume only part of each prey item - usually don't kill it Consume several or many in lifetime
Parasites
Consume only part of host item - usually don't kill it outright Attack relatively few hosts in lifetime
Exploitative competition
Deprive others of resources Exploitation competition occurs indirectly through a common limiting resource which acts as an intermediate. For example, use of resources depletes the amount available to others, or they compete for space. Also known as exploitative competition.
The lotka volterra model ...
Describes the cycling of predator and prey populations in relation to each other Other, more complex models actually better describe cycling of predator and prey populations but all generally show that predator-prey interactions have the potential to cause population _cycles__
Competitive outcomes altered by
Disturbance Interactions with other species Evolution (resource partitioning) Character displacement
Competitive exclusion principle
Ecological rule that states that no two species can occupy the same exact niche in the same habitat at the same time Gause's law - is a proposition that states that two species competing for the same resource cannot coexist at constant population values, if other ecological factors remain constant. When one species has even the slightest advantage or edge over another then the one with the advantage will dominate in the long term
Ecto
External parasite- lamprey
Hemi
Facultative parasite - an organism that may resort to parasitic activity, but does not absolutely rely on any host for completion of its life cycle. -Examples of facultative parasitism occur among many species of fungi, such as family members of the genus Armillaria.
Arrangement of isoclines
Generates graphs w/ 4 possible arrangements of _isoclines_ (lines where there is no increase or decrease in population size)
Permanent obligatory interspecific
Has to do it to survive, done to another species, permanent
Down sides of cooperation
Have to share Increased conspiciousness (more visible) Have to obtain more food
Growth rate of predator population decreases when
If Nh < dp/fc
Unstable equilibrium (competition can go either way
In the third scenario, the isoclines of the two species cross one another. Here, the carrying capacity of species 1 (K1) is higher than the carrying capacity of species 2 divided by the competition coefficient (K2/a21), and the carrying capacity of species 2 (K2) is higher than the carrying capacity of species 1 divided by the competition coefficient (K1/a12). - Below both isoclines and above both isoclines the populations increase or decrease as in the first two scenarios, and there is an unstable equilibrium point (closed circle) where the isoclines intersect. -For points above the dashed pink line (species 2 isocline) and below the solid yellow line (species 1 isocline), the outcome is the same as in the first scenario: competitive exclusion of species 2 by species 1. -On the other hand, for points above the solid yellow line (species 1 isocline) and below the dashed pink line (species 2 isocline), the outcome is the same as in the second scenario: competitive exclusion of species 1 by species 2. The two stable equilibrium points are again represented by open circles. In this scenario, the outcome depends on the initial abundances of the two species.
Lotka/Volterra model of competition
Include a coefficient of competition (a) representing the effect of species 2 on species 1 - multiplying N2 by a makes it the equivalent of individuals in species 1 a simple model of the population dynamics of species competing for some common resource. They can be further generalized to include trophic interactions.
Predation
Individual A benefits while individual B does not benefit at all since they are being preyed upon Hawk / mouse, etc Cowbird, lamprey +-
Commensalism
Individual A gets a benefit and individual B is unaffected +0 butterfly sipping sugar off turtles nose
Mechanisms of competition
Interference - directly affect other orgs Chemical - allelopathy Territorial Encounter Overgrowth
Endo
Internal parasite- roundworm, tapeworm
Interspecific parasitism
Interspecific parasitism (host-parasite interactions, e.g. ectoparasites, endoparasites, viruses, pathogens)
Intraspecific parasitism
Intraspecific parasitism (within-species brood parasitism, e.g. egg dumping, sneaking)
Factors which cause cycles?
Lots of things alter cycles Habitat complexity, other species, genetics, hormones, even evolution Bottom line is: we don't really know
Vector
Many parasites have more than one host Transmission from one host to another may require ____
Competition restricts ______
Niches
Holo
Obligate parasite -a parasitic organism that cannot complete its life-cycle without exploiting a suitable host. If an obligate parasite cannot obtain a host it will fail to reproduce.
Temporary obligatory interspecific
Only parasitizes during the nesting season. Example would be brown headed cowbird Only done in times where needed, done to other species, temporarily -Brown-headed cowbird_(Molothrus ater) -Specialized behaviors of young
Consumptive competition
Organisms consume the same resource occurs when food is a limited resource and individuals reduce one another's intake
Distribution is affected by more than just competition
Other relationships - predation, social interactions... Physiology Genetics Environmental tolerances
Contest competition
Refers to a situation where available resources, such as food and mates, are utilized only by one or a few individuals, thus preventing development or reproduction of other individuals.
Mutualism (cooperation)
Positive interaction for both animals each individual benefits from the activity of the other. Stomach bacteria, pollinators, lichens ++
Predation
Predators often focus on prey that is the better competitor why? Their pops are often higher Thus predation often results in increased variation
Predator prey cycle
Prey increasing, predators increasing Prey decreasing, predators increasing Prey decreasing, predators decreasing Prey increasing, predators decreasing Predator and prey populations cycle (sometimes) Predator population _lags__slightly
Difference between predation and parasitism
Prey is killed outright and used for sustenance -Host is not killed outright -Parasites usually need host for more than just sustenance Place to live_ transportation_
Character displacement
Refers to the phenomenon where differences among similar species whose distributions overlap geographically are accentuated in regions where the species co-occur -but are minimized or lost where the species' distributions do not overlap. This pattern results from evolutionary change driven by biological competition among species for a limited resource (e.g. food). The rationale for character displacement stems from the competitive exclusion principle, also called Gause's Law, which contends that to coexist in a stable environment two competing species must differ in their respective ecological niche; without differentiation, one species will eliminate or exclude the other through competition
Niche compression
Restriction of niche in response to niche overlap by competing species May be a result of character displacement, resource partitioning bc competition go from fundamental down to realized niche -increase in population size of multiple species -increase in inter competition - decrease in niche breadth - increase in specialization
Scramble competition
Scramble competition is also defined as "a finite resource that is shared equally amongst the competitors so that the quantity of food per individual declines with increasing population density"
Possible outcomes of competition
Sp 1 wins Sp 2 wins Reach a stable equilibrium Reach an _unstable equilibrium
Interactions with other species
Species interact with other species that require the same resources. Consequently, interspecific competition can alter the sizes of many species' populations at the same time. Experiments demonstrate that when species compete for a limited resource, one species eventually drives the populations of other species extinct. -These experiments suggest that competing species cannot coexist (they cannot live together in the same area) because the best competitor will exclude all other competing species.
Batesian mimicry
Species mimics the appearance of an unpalatable or harmful. model is unpalatable, mimic is palatable
Mutualists
Symbiotic (___living together___) Mutualistic_(depend on each other) ++
Species 1 wins
The first scenario is one in which the isocline for species 1 is above and to the right of the isocline for species two. For any point in the lower left corner of the graph (i.e., any combination of species abundances), both populations are below their respective isoclines and both increase. For any point in the upper right corner of the graph, both species are above their respective isoclines and both decrease. For any point in between the two isoclines, species 1 is still below its isocline and increases, while species 2 is above its isocline and decreases. The joint movement of the two populations (thick black arrows) is down and to the right, so species 2 is driven to extinction and species 1 increases until it reaches carrying capacity (K1). The open circle at this point represents a stable equilibrium. In this scenario, species 1 always outcompetes species 2, and is referred to as the competitive exclusion of species 2 by species 1.
Aggregative response
The preference for consumers to spend most of their feeding time in patches containing the highest density of prey. A generally a short term behavioral adjustment where the predator goes to where its food is going to be most abundant thereby ignore areas of low prey populations.
Effect of a heterogeneous habitat
The principle predicts that in an absolutely homogeneous world with a single resource, only a single species could be stably maintained. "No stable equilibrium can be attained in an ecological community in which some r components are limited by less than r limiting factors. In particular, no stable equilibrium is possible if some r species are limited by less than r factors". Levin concludes that biodiversity is a consequence of the spatial and/or temporal heterogeneity of the world in which species can exploit heterogeneous resources and patterns
Resource partitioning (evolution)
The process whereby similar species exploit the limited resources in an ecological area without one species driving the others into extinction. Through natural selection, each species adopts a pattern of resource usage that isn't competitive. One of the driving forces of evolution
Realized niche
The resources a population actually uses The realized niche may be smaller than the fundamental niche because of interspecific interactions such as: Competition Predation "actual job -much smaller job than fundamental niche cause others are filling it already"
Species 2 wins
The second scenario is the opposite of the first; the isocline of species 2 is above and to the right of the isocline for species 1. This graph can be interpreted in much the same way as the previous one, except that the joint trajectory of the two populations when starting in between the isoclines is up and to the left. In this case species 2 always outcompetes species 1, and species 1 is competitively excluded by species 2.
Ambush (sit and wait)
This is a time when deceit helps Strategy may depend on body condition -(cool lizards vs worm) Ambush techniques vary (spider specializing on harvesting ants (trap door)
Functional response
Type I functional response assumes a linear increase in intake rate with food density, either for all food densities, or only for food densities up to a maximum, beyond which the intake rate is constant The relationship between the density of prey and an individual predator's rate of food consumption.
Tool usage
Use an aspect of the environment to help in foraging Probe for termites, under bark for grubs, etc Sea otter, Egyptian vulture, Ant lion, Archer fish
Predation often results in increased ______ ?
Variation Grazing of large herbivores, starfish
Encounter
When two species physically fight for a needed resource
Generalist
Wide niche, use resources of many types Prey switching? Rat Roach Raccoon
Interactions
Will affect structure of the community and the size, density, dispersion of populations within a species -> realm of "social behavior" / _interaction ecology
Disturbance
a temporary change in environmental conditions that causes a pronounced change in an ecosystem. -fires, flooding, windstorms, insect outbreaks and trampling. Earthquakes, various types of volcanic eruptions, tsunami, firestorms, impact events, climate change A species which is well adapted to a particular disturbance is the Jack Pine in boreal forests exposed to crown fires. They, as well as some other pine species, have specialized serotinous cones that only open and disperse seeds with sufficient heat generated by fire. As a result, this species often dominates in areas where competition has been reduced by fire
Intermediate host
an organism that supports the immature or nonreproductive forms of a parasite.
Micro
bacteria, viruses, protozoans
Behavioral defense
behaving in ways that minimize risk (inflating) Under this defense to predation, organisms migrate to avoid predation, use swarms to confuse or avoid the predator, swim in an inconspicuous manner or utilize escape behavior
Müllerian mimicry
both model and mimic are unpalatable
Coexistance
both species' carrying capacities are lower than the other's carrying capacity divided by the competition coefficient -below both isoclines the populations increase and above both isoclines the populations decrease. In this case, however, when the populations of the two species are between the isoclines their joint trajectories always head toward the intersection of the isoclines. Rather than outcompeting one another, the two species are able to coexist at this stable equilibrium point (open circle). This is the outcome regardless of the initial abundances.
So the population growth equation for species 1 including competition w/ species 2 is
dN1/dt = r1N1 {(K1 -[N1+ a (12)N2]) /K1} N= population size K= carrying capacity a= competition coefficient r= intrinsic rate of increase t= time for a (12) do you just multiply competition coefficient of 1 by 2?
Lotka volterra model of predator/ prey interactions
dNh/dt = (rh)Nh-(c)NhNp Nh= prey population Np = predator population r=reproduction c = capture efficiency (rate of predation)
Cont
dNp/dt = (f)(c)NhNp - (dp)Np f = conversion of prey into pred offspring d= predator deaths Nh= prey population Np= predator population c= capture efficiency
Just because 2 spp do not coexist in the field does not mean competition is the cause
different limits of tolerance, physiology, behavior, genetics etc that may (or may not ) be the result of competition
Temporary facultative interspecific
done to different species, not obligatory , temporary
Macro
fleas, ticks, worms, plants
True predator
kill it and eat it Kill prey more or less immediately Consume several or many prey in lifetime
Social defenses
members of the same species or more than one species defending themselves members of your species come to your defense
Inducible response
mounted only when plants sense a threat (used only when you need it)
Direct transmission
move directly from host to host -Spend basically whole life cycle w/ one host Lamprey Dodder Myxomatosis Black - legged tick -barrelia burgdorferi Bacterial spirochete Lyme disease -2 year lifecycle of tick
Predator responses to prey
numerical response aggregative response response developmental response functional response
Interference
occurs directly between individuals via aggression etc. when the individuals interfere with foraging, survival, reproduction of others, or by directly preventing their physical establishment in a portion of the habitat
Preemptive competition
occurs when individuals occupy space and prevent access to resources by other individuals.
Territorial
occurs when mobile organisms protect a feeding or breeding territory. A behavior in which an animal defends a bounded physical space against encroachment by other individuals, usually of its own species.
Chemical defenses
poisons and stings Bombardier beetle mixes two chemicals from separate glands = boiling hot liquid that it sprays - harm predators.
Cannibalism
practice of eating one's own kind Reduce population density Reduce stress Weed out runts Help your own offspring
And for species 2 population growth rate
r2N2 (K2-[N2+a(21)N1])/K2 N= population size K= carrying capacity a= competition coefficient r= intrinsic rate of increase t= time
Niche overlap
situation in an ecosystem in which different species are in competition for the same energy and space resources; in reality, niche overlap in natural ecosystems is typically zero or minimal
Introduced species
species moved by humans to new geographic areas, either intentionally or accidentally
Numerical response
the change in predator density as a function of change in prey density. associated with the functional response, which is the change in predator's rate of prey consumption with change in prey density Change in size of a population of predators in response to change in density of its prey.
Developmental response
the number of prey each individual predator consumes changes as he predator matures. If a predator eats more prey at higher densities, grows more as a consequence and then kills more prey because of its larger size , this is developmental response
Fundamental niche
the set of resources a population is theoretically capable of using under ideal conditions "the resume"
Indirect transmission
using a vector, to act as an intermediate -Different parts of life cycle are spent w/ different hosts -May change behavior of intermediate host at a particular time in order to "get itself transferred" to the next host
Growth rate of prey pop grows
when Np < rh/c
Growth rate of prey pop = 0
when Np = rh/c Np= predator population rh= reproduction of prey c= capture efficiency
Compensatory response
when being fed on consistently, the plant will put a lot of effort to compensate for the damage
Temporary facultative intraspecific
within same species, doesnt necessarily have to do it, only temporary Brood parasites Common in waterfowl Can lay more eggs -Also effectively "spreading around" your kids - safer
