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Misumena vatia is a species of crab spider with holarctic distribution. In North America, where it is the largest and best-known flower spider, it is called the goldenrod crab spider or flower (crab) spider, because it is commonly found hunting in goldenrod sprays in the autumn.
Young males in the early summer may be quite small and easily overlooked, but females can grow up to 10 mm (excluding legs); males reach 5 mm at most.
These spiders may be yellow or white, depending on the flower in which they are hunting. Especially younger females, which may hunt on a variety of flowers such as daisies and sunflowers, may change color "at will". Older females require large amounts of relatively large prey to produce the best possible clutch of eggs. They are therefore, in North America, most commonly found in goldenrod (Solidago sp.), a bright yellow flower which attracts large numbers of insects, especially in autumn. It is often very hard even for a searching human to recognize one of these spiders on a yellow flower. These spiders are sometimes called banana spiders because of their striking yellow color.
The much smaller males scamper from flower to flower in search of females and are often seen missing one or more of their legs. This may be due either to near misses by predators such as birds or to fighting with other males.
The young reach a size of about 5 mm by autumn and spend the winter on the ground. They molt for the last time in May of the next year.
For example, in Misumena vatia's method of camouflage, it is able to focus its energy on growing and reproduction because it does not need to spend energy on finding food like other species of spiders. Crab spiders wait for their prey and lures in their prey allowing the female crab spiders to focus on growing and reproduction. Also by matching its environment, it does not need to focus on escaping from predators. In a study done by Robert Fritz and Douglass Morse, 163 adult crab spiders were measured over 3 years looking at reproductive success of the Misumena vatia. They concluded there was a positive correlation between female weight of the adult Misumena vatia and egg clutch size. The conclusion means the greater the female weighed the more eggs were produced. Thus selection for larger female body size increases reproductive success.  According to the studies, Misumena vatia are able to focus its energy on growing and reproduction because of how effective the camouflage conceals the spider from predators. The effectiveness of the camouflage allows the spiders to also not spend energy on finding food. Due to the method of camouflage in Misumena vatia, it has helped increase its survivability and fitness.
These spiders change color by secreting a liquid yellow pigment into the outer cell layer of the body. On a white base, this pigment is transported into lower layers, so that inner glands, filled with white guanine, become visible. The color similarity between the spider and the flower is well matched with a white flower, in particular the Chaerophyllum temulum, compared to a yellow flower based on the spectral reflectance functions.  If the spider dwells longer on a white plant, the yellow pigment is often excreted. It will then take the spider much longer to change to yellow, because it will have to produce the yellow pigment first. The color change is induced by visual feedback; spiders with painted eyes were found to have lost this ability.
- Acorn, John and Sheldon, Ian. Bugs of Ontario, Edmonton: Lone Pine Publishing, 2003
- Fritz, Robert S., and Douglass H. Morse. "Reproductive success and foraging of the crab spider Misumena vatia."Oecologia 65, no. 2 (1985): 194-200.
- Head, Graham. "Selection on Fecundity and Variation in the Degree of Sexual Size Dimorphism Among Spider Species (Class Araneae)." Evolution 49, no. 4 (1995):776.
- Chittka, Lars. "Camouflage of predatory crab spiders on flowers and the colour perception of bees (Aranida: Thomisidae/Hymenoptera: Apidae)." Entomologia Generalis 25, no. 3 (2001): 181-187.
- Oxford, G.S. & Gillespie, R.G. (1998). Evolution and Ecology of Spider Coloration. Annual Review of Entomology 43:619-643. doi:10.1146/annurev.ento.43.1.619 PMID 15012400