Bacillus licheniformis

Bacillus licheniformis
Scientific classification
Kingdom:	Bacteria
Phylum:	Firmicutes
Class:	Bacilli
Order:	Bacillales
Family:	Bacillaceae
Genus:	Bacillus
Species:	B. licheniformis
Binomial name
	Bacillus licheniformis;

Bacillus licheniformis is a bacterium commonly found in the soil. It is found on bird feathers, especially chest and back plumage, and most often in ground-dwelling birds (like sparrows) and aquatic species (like ducks).

It is a gram-positive, thermophilic bacterium. Its optimal growth temperature is around 30°C, though it can survive at much higher temperatures. The optimal temperature for enzyme secretion is 37°C. It can exist in spore form to resist harsh environments, or in a vegetative state when conditions are good.

Scientists are currently exploring its ability to degrade feathers for agricultural purposes. Feathers contain high amounts of non-digestible proteins, but researchers hope that, through fermentation with B. licheniformis, they can use waste feathers to produce cheap and nutritious feather meal to feed livestock.

Ecological research is also being done looking at the interaction between plumage colors and B. licheniformis activity, and the consequences thereof. Feather degrading bacteria may have played an important role in the evolution of molting, and patterns in feather coloration (Gloger's Rule).

Feather protection through psittacofulvin

Bacillus licheniformis degrades feathers of parrots, especially white feathers. Red feathers with high levels of psittacofulvin are more resistant.^[1]

Biological laundry detergent

Bacillus licheniformis is cultured in order to obtain protease for use in biological laundry detergent. The bacterium is well adapted to grow in alkaline conditions, so the protease it produces can withstand high pH levels, making it ideal for this use - the other components of detergents create an alkaline pH. The protease has a pH optimum of between 9 and 10 and is added to laundry detergents in order to digest, and hence remove, dirt made of proteins. This allows for much lower temperatures to be used, resulting in lower energy use and a reduced risk of shrinkage of garments or loss of colored dyes.

Dental applications

In 2012, scientists from Newcastle University studying Bacillus licheniformis as a possible agent to to clean ships' hulls isolated an enzyme that has proven to be an unexpected tooth decay fighter as it has the ability to cut through plaque or a layer or bacteria.^[2]

Nanotech applications
Bacillus licheniformis can be used in synthesise gold nanocubes.^{[citation needed]} Researchers have synthesized gold nanoparticles with sizes between 10 to 100 nanometres. Gold nanoparticles are usually synthesized at high temperatures, in organic solvents and using toxic reagents. The bacteria produce them in much milder conditions.
References

^ Edward H. Burtt, Max R. Schroeder, Lauren A. Smith, Jenna E. Sroka, Kevin J. McGraw (2010): Colourful parrot feathers resist bacterial degradation, Biology Letters, The Royal Society, doi:10.1098/rsbl.2010.0716.

^ <a href="http://www.independent.ie/health/health-news/seaweed-could-fight-tooth-decay-scientists-3158487.html" target="blank">Seaweed could fight tooth decay – scientists</a>. Independent.ie. July 4, 2012. Accessed July 4, 2012

External links
Isolation, Identification, and Characterization of a Feather Degrading Bacteria, Williams et al., 1990

Bacterial Degradation of Black and White Feathers, Goldstein et al., 2003

genome of Bacillus licheniformis ATCC14580 - publication

Microbial nanotechnologists, August 1, 2009

[1] Edward H. Burtt, Max R. Schroeder, Lauren A. Smith, Jenna E. Sroka, Kevin J. McGraw (2010): Colourful parrot feathers resist bacterial degradation, Biology Letters, The Royal Society, doi:10.1098/rsbl.2010.0716.

[2] <a href="http://www.independent.ie/health/health-news/seaweed-could-fight-tooth-decay-scientists-3158487.html" target="blank">Seaweed could fight tooth decay – scientists</a>. Independent.ie. July 4, 2012. Accessed July 4, 2012

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