Moist, sticky skin keep oxygen in. Long, powerful hind legs that are full of muscle help it to jump more than three times its body length. Internal skeloton and vertebrae support it from the continuously pushing gravity force.
Lungs
Aquatic snails cannot live on land for extended periods of time as they require a moist environment to survive. They are not able to adapt to a terrestrial environment due to their need for water to breathe and move.
There is only one terrestrial invertebrate that lives on the Antarctic continent. It is the Antarctic midge -- Belgica Antarctica. From its Wikipedia entry: "To adapt to the cold temperatures, B.antarctica accumulates trehalose, glucose and erythritol."When the occasional bug is imported in logistical movements, the animal dies for lack of food and/or from extreme cold.
Aquatic organisms or terrestrial organisms do not adapt better when there are temperature fluctuations. Changes in temperatures will a direct affect on the organisms which may hinder proper adaptations.
It means that an animal or species adapt physically to the enviorment.
One example of a body structure that helps an organism adapt to its environment is the camouflage patterns on a chameleon's skin. These patterns allow the chameleon to blend in with its surroundings, providing it with protection from predators.
Yes, tiger salamanders undergo metamorphosis. They start their life as aquatic larvae with gills and gradually transform into terrestrial adults with lungs. This process involves significant changes in their body structure, allowing them to adapt to life on land. Metamorphosis can be influenced by environmental factors, such as habitat conditions and food availability.
The mouths tongue is able to extend so stick to its prey, then drag it into the frog's mouth. From there the frog's vomerine teeth trap the prey so it cannot escape, and can then be eaten. By the frog adapting to capture it's prey efficiently, they are able to eat.
The first organisms to adapt to gas exchange on land were likely early terrestrial plants, specifically bryophytes like mosses, which emerged around 470 million years ago. These plants developed structures such as stomata to facilitate gas exchange while minimizing water loss. As terrestrial life evolved, other organisms, including insects and amphibians, also adapted to life on land, further enhancing gas exchange mechanisms.
No, octopuses cannot live on land because they require water to breathe and move. Their bodies are not adapted for terrestrial environments, as they would quickly dehydrate and suffocate.
Blobfish adapt to changes in pressure during decompression by having a gelatinous body structure that allows them to withstand pressure changes without harm. Their bodies are able to maintain their shape and structure even as pressure decreases, preventing them from experiencing the negative effects of decompression.
A major trait that allowed plants to move onto and adapt to dry land was the development of a waxy cuticle on their leaves and stems. This cuticle helps prevent water loss and desiccation, allowing plants to thrive in terrestrial environments.