![]() ![]() When vole populations peak and competition for food is strongest, they turn to bark as a marginal food, and this shift in foraging behavior coincides with a population decline (Figure 1a). They grow more slowly, reproduce less, and populations decline. ![]() ![]() When preferred foods are scarce, individuals must turn to less desirable foods to prevent starvation. In years when their preferred food items are abundant, populations will grow. The availability of food acts as a bottom-up control that affects population size. Grouse, hares, and voles feed on vegetation, and the availability of their preferred foods will influence the population size of each. Studies of these species have demonstrated linked population cycles in each of the prey species, with population peaks every 3-4 years (Figure 1). For example, red foxes ( Vulpes vulpes) in northern Sweden prey on voles, grouse, and hares. Quite often, these cycles co-occur with population cycles of other species in the same location. Some of the most notable examples of population changes occur in species that experience large, cyclic swings in population size. Additional factors, such as parasites and disease can further influence population dynamics. In reality, the interaction between these two forms of population control work together to drive changes in populations over time. More recently, scientists have discovered that predation can also influence the size of the prey population by acting as a top-down control. Such bottom-up control helped to regulate the population around carrying capacity. Researchers found that when resources (food, nesting sites, or refuges) were limited, populations would decline as individuals competed for access to the limiting resources. ![]() Ecologists have documented examples of such fluctuations in a wide variety of organisms, including algae, invertebrates, fish, frogs, birds, and mammals such as rodents, large herbivores, and carnivores.Įcologists have long wondered about the factors that regulate such fluctuations, and early research suggested that resource availability plays an important role. One heart circulates blood around the body, while the other two pump it past the gills, to pick up oxygen.Populations of organisms do not remain constant the number of individuals within a population changes, sometimes dramatically, from one time period to the next. If the blood (called haemolymph in invertebrates) becomes deoxygenated - when the animal dies, for example - it loses its blue colour and turns clear instead.Īn octopus's three hearts have slightly different roles. The copper-based protein is more efficient at transporting oxygen molecules in cold and low-oxygen conditions, so is ideal for life in the ocean. Well, the blue blood is because the protein, haemocyanin, which carries oxygen around the octopus's body, contains copper rather than iron like we have in our own haemoglobin. Finally, why do octopuses have blue blood?Īre you still wondering why octopus blood is blue and what the three hearts do? The researchers say they're not sure what the benefits of living in a densely populated settlement are for these octopuses, but it may just be a case of necessity, with limited den spaces available in the otherwise flat and featureless area. Frequent aggression, chases and even den evictions were observed among the octopuses living at Octlantis. City living has its advantages and drawbacks, as we all know. ![]()
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