A Mouse That Sings

singing mouse

The deer mouse is just one type of mouse that is known to sing. (Photo credit: Thomas Kitchin and Victoria Hurst/Design Pics Inc./Alamy)

You are likely quite familiar with the sound of birds singing. You might have also heard the sounds of frogs singing a chorus around a pond or lake. But did you know that some mice sing too? What is the reason behind this unusual behavior? [Read more…]

Scientists Decode the Language of Prairie Dogs

prairie dogs

Prairie dogs have a more extensive language than previously thought. (Photo credit: Photodisc/Getty Images)

If you’ve ever walked through a prairie dog town, you probably heard the prairie dogs’ high-pitched alarm call. But did you ever think they were talking about you? Recent research indicates that just might be exactly what they were doing.

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Fish Flatulence — How Certain Fish Communicate in School

Most animals do not pass gas for any purpose other than necessity. In the oceans, however, there is an animal that may use flatulence as a means of communication. [Read more…]

The Cockroach Communication Network


New research indicates cockroach communication is dependent on microbes in their feces. (Photo credit: Erik Karits/Shutterstock)

Chances are, you’ve seen a gathering of cockroaches some place at some time. Conditions don’t even need to be especially filthy for these most reviled of insect pests to appear.

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Understanding Squid Camouflage

No other animal can match the speed and range of coloration found in squid camouflage. (Photo credit: Jeff Rotman / Alamy)

Given their soft bodies, squids cant rely on a hard shell to protect them from predators. Instead, these cephalopods use a sophisticated system of camouflage to help keep them safe from detection. [Read more…]

Cavefish Don’t Need to See to Find Food

Though they lack eyes, cavefish have other adaptations that help them to survive in their dark habitats. (Photo credit: Martin Shields / Photo Researchers, Inc.)

The fish species Astyanax mexicanus is interesting in that it includes both cave-dwelling and surface-dwelling populations. In Mexico there are 30 separate populations of cavefish. Many of these populations evolved in isolation, which means each population evolved independently of the others. The populations that live in caves lack eyes and body pigment, while the populations that live aboveground have large eyes and are pigmented. Due to these obvious phenotypic differences within the same species, cavefish are a popular subject for evolutionary biologists.

Though in early stages of development cavefish have eyes that begin to grow, at a certain stage programmed cell death, or apoptosis, occurs in the lens and the eyes stop growing. The surrounding skin tissues around the eyes continue to grow, covering over the space where eyes would typically be found. The remains of the undeveloped eye can be found buried within the eyes orbital socket.

However, even without eyes, cavefish still retain the ability to detect changes in light due to the functions of the pineal gland. If a shadow occurs above the fish, they will swim upward to investigate, as it may be a source of food, and without predators in the cave system, they do not fear being eaten. (In direct contrast, surface-dwelling fish typically seek shelter in the presence of a shadow.)

Compared to surface-dwelling fish, cavefish have a larger mouth and jaws and a greater number of tastebuds. Cavefish also have larger and more neuromasts than surface-dwelling fish. Neuromasts are specialized nerve cells that are a part of a fish’s lateral line. In cavefish, these cells are more densely distributed on the fish’s head, particularly in the area where its eyes would be. Cavefish use these sensory organs to detect movement and vibration in their watery environment. The response to vibrations in the water, called vibration attraction behavior, or VAB, is an adaptive behavior. Vibration detection helps cavefish find sources of food in the water, which, without eyes, they would not be able to see. Recent cavefish research conducted by evolutionary biologists indicated that VAB and neuromast abundance coevolved to make up for the loss of vision in cavefish and help the blind fish find food in darkness.

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