User:Ltdewitt/Littoraria irrorata

L. irrorata is an essential part of the salt marsh ecosystem. This is displayed in its strong relationship with Sporobolus alterniflorus, also known as Spartina alterniflora, a common vegetation found in abundance in Salt Marshes.

Description
L. irrorata is extremely temperature tolerant. The snail retracts its foot into it's shell when experiencing thermal stress which allows them to avoid water loss by evaporation and survive in high temperatures.

Distribution
Spatial distributions of L. irrorata in salt marshes likely depend on predation pressures and vary with geography. It is possible that S. alterniflorus stem density plays a role in the local distribution of L. irrorata.

Habitat
L. irrorata can usually be found on the stock of S. alterniflorus and in some Salt Marshes on dead, fallen leaves of S. alterniflorus. L. irrorata has also been observed to inhabit Spartina cynosuroides. There were no significant differences in snail population density between S. alterniflorus and S. cynosuroides. However, S. cynosuroides was observed to be a safer habitat due to it's superior height. The shell size of the snail has been found to increase with decreasing elevation in Virginia salt marshes but the exact opposite has been found in South Carolina and Florida salt marshes.

Feeding Habits
The diet of L. irrorata also consists of algal mats on the salt marsh floor, dead S. alterniflorus, live S. alterniflorus, marsh sediment. L. irrorata is capable of having a strong top-down control of S. alterniflorus production by the grazing of live S. alterniflorus.

Predation
Predators of L. irrorata include Blue crabs, diamondback terrapins, clapper rail, and northern raccoons. Predator cues for L. irrorata can be water related as well as airborne. It is likely that chemicals in the incoming tide cue the snails to climb S. alterniflorus. It is also possible that blue crabs give off some compound which is aerosolized and detected by L. irrorata. L. irrorata responds quickest to chemicals released when the shells of other snails are broken.

In order to avoid predation,  L. irrorata has the ability increase the thickness of their shell ridge which in turn decreases the size of their aperture opening. This makes it difficult for predators to remove them from their shell. This is an essential function to have as Blue Crabs are commonly seen chipping away at the shell ridge in order to feed on the snail.

Another method L. irrorata uses to avoid predation is vertical climbing of the grass Sporobolus alterniflorus. The snails climb up the grass during high tide to avoid predation and descend during low tide to feed. This is a very effective defense against predators.

Impacts of the Deepwater Horizon Oil Spill
The Deepwater Horizon Oil Spill had major impacts on the productivity, population density, and growth of L. irrorata in salt marshes along the Gulf of Mexico and southeastern United States. Snail densities were reduced by 80-90% on the oil covered salt marsh edges and 50% in the marsh interior. The major loss of adult snails resulted in a reduced mean snail size in salt marshes. It was originally projected that it would take about 3-5 years for the L. irrorata population density to recover from the oil spill. However, snail populations still have not made a full recovery nine years after the oil spill. It is now projected that it could take one to two decades for L. irrorata populations to fully recover at heavily oiled sites.