This video says about itself:
The palm squirrel or three-striped palm squirrel, Funambulus palmarum, is a species of rodent in the family Sciuridae found naturally in Bangladesh & India (south of the Vindhyas) and Sri Lanka. In the late 19th century, the palm squirrel was introduced into Western Australia, where it has since become a minor pest, actively targeted for eradication due to its lack of natural predators. The closely related five-striped palm squirrel, F. pennantii, is found in northern India, and its range partly overlaps with this species.
The palm squirrel is about the size of a large chipmunk, with a bushy tail slightly shorter than its body. The back is a grizzled, gray-brown color with three conspicuous white stripes which run from head to tail. The two outer stripes run from the forelegs to the hind legs only. It has a creamy-white belly and a tail covered with interspersed, long, black and white hair. The ears are small and triangular. Juvenile squirrels have significantly lighter coloration, which gets progressively darker as they age. Albinism is rare, but exists in this species.
From Science News:
Gene gives mice and chipmunks their pinstripes
Biologists identify new molecular pathway behind mammalian fur patterns
By Tina Hesman Saey
2:00pm, November 2, 2016
Chipmunks and other rodents’ light stripes are painted with a recycled brush, a new study suggests.
A protein previously known to guide facial development was repurposed at least twice during evolution to create light-colored stripes on rodents, researchers report November 2 in Nature. The protein, called ALX3, could be an important regulator of stripes in other mammals, including cats and raccoons, says Michael Levine, a developmental biologist at Princeton University who was not involved in the new study.
Some research has shown how butterflies and other insects create their often elaborate wing patterns (SN: 7/17/10, p. 28). But scientists still don’t understand the biological machinery used by mammals to generate the dots, spots, splotches and stripes that decorate their coats. Uncovering the molecular equipment may shed light on the evolutionary processes that help animals camouflage themselves and adapt to their environments.
In the new study, evolutionary developmental biologist Ricardo Mallarino of Harvard University and colleagues examined the multicolored stripes of African striped mice (Rhabdomys pumilio). Two light-colored stripes, each flanked by black stripes, run down the mice’s backs. A strip of fur the same brownish color as most of the rest of the body separates the dark-light-dark striping. The patterns are created by three types of hair: Hairs with banded yellow shafts growing from a black base populate the strip in the middle, while completely black hairs from base to tip are found in the black stripes. Hairs with a black base but no pigment in the shaft make up the light stripes.
Those unpigmented hairs were mysterious, says Hopi Hoekstra, the Harvard evolutionary biologist who led the new study. Usually, white hair arises because animals have a mutation that prevents cells from making pigments, she says. But since the African striped mice carry no such mutations, it was clear that the mice must create the stripes in a different way.
In vertebrates, pigment-producing cells called melanocytes migrate around the body as the embryo develops. One way stripes could form is by melanocytes moving to create the pattern. Previous research in zebrafish indicated that stripes on the fish’s sides form that way (SN: 2/22/14, p. 9). Light stripes might result if the melanocytes don’t migrate into a strip of the mice’s skin, the researchers reasoned. Hair would grow there, but wouldn’t have any pigment. That’s the first thing Mallarino checked. He examined white stripes in the skin of striped mouse embryos a couple of days before birth. Melanocytes had no trouble infiltrating the light striped area, he found. But once in the stripe, the cells did not mature properly and so made no pigment.
To find out what might be stopping melanocytes from producing pigment, the researchers examined gene activity in the different types of stripes in the mouse embryos. In the light stripes, the gene that produces ALX3 is much more active than it is in the brown or black stripes, the researchers discovered. That result was a surprise because no one knew that ALX3 is involved in pigmentation, Hoekstra says. It was known for helping to regulate the formation of bones and cartilage in the face.
It wasn’t clear whether the high levels of ALX3 caused the light stripes or not. So Hoekstra’s team did experiments in lab mouse cells to find out how the protein might affect pigmentation. Raising levels of ALX3 in cells interfered with activity of a gene called Mitf, a master regulator of pigment production and melanocyte maturation.
It turns out that even in lab mice more of the protein is made on the belly, which tends to be light colored. Previous pigmentation research failed to turn up ALX3 because researchers were working with white mice, Hoekstra says.
Eastern chipmunks (Tamias striatus), which last shared a common ancestor with African striped mice about 70 million years ago, also made more ALX3 in the light stripes on their flanks, the researchers found. The results suggest that different rodents independently recycled ALX3’s ability to make light-colored belly fur and used it to also paint light stripes on the back. Stripes may help rodents that are active during the day blend into the background and avoid the sharp eyes of predators, Hoekstra says.
Evolution tends to be thrifty, often reusing old genes for new purposes, says Nipam Patel, an evolutionary developmental biologist at the University of California, Berkeley. The new study is “a really nice illustration that evolution isn’t biased,” he says. “It takes what it gets and works with that.”
The researchers still don’t know why ALX3 gets turned up in the light stripes. Another protein may turn on its production, or rodents have found other ways to dial up ALX3 production in certain places. Researchers need to discover what turns on ALX3 to pinpoint the exact evolutionary change responsible for the striped pattern, Patel says.