Gene Mutation in Fruit Flies Used To Study Kidney Stone Formation

Science Daily published an article entitled “Flies Reveal Kidney Stones In-The-Making” from a research study by Dr. Thomas Chi. Drosophila melanogaster, the common fruit fly, has been utilized in recent studies of  kidney stone formation in humans. Fruit flies have a gene mutation which is responsible for the development of kidney stones that are similar to kidney stones in humans. Due to the fruit flies short life cycle, researchers are able to study kidney stone formation quickly. The study revealed the significance of zinc and genes that are responsible for zinc transportation in the development of kidney stones in flies and humans.

I was very interested to read yet another research study done with Drosophila melanogaster. The fruit fly is a model organism used in research labs all across the county to study and understand the biology of other organisms such as humans.

Article Link: http://www.sciencedaily.com/releases/2013/04/130407090734.htm

http://www.news-medical.net/news/20120323/Fruit-flies-too-get-kidney-stones.aspx

The Mystery of Kidney Stones

Medical News Today has published an article revealing the reason why certain people are more susceptible to kidney stones than others. An average of one million Americans are affected by kidney stones each year, and say that it is one of the worst pains we could ever experience. Researches from Washington University School of Medicine has discovered why people get kidney stones and others don't; and of course the answer is genes. The experiment was conducted in mice, because their kidneys function in the same way as humans. The gene claudin-14 is a common genetic variant and is the causing agent of kidney stones. An estimated 65% of people with this variation had a possibility of increased chances of kidney stones. Kidney stones originate from concentrated urine, where minerals are able to crystallize. Although genes play a major role, diet is also important. If you do not drink enough water, or ingest too much sodium you aslo increase your chances. When referring to claudin-14, in a typical human it is not active which allows the kidneys to filter the way they are designed. However, when sodium intake is increased or not enough water is consumed, RNA molecules are released from claudin-14 and begin the process of kidney stones. With this discovery, it would be great if a medicine or an alternate form could be created to stop the creation of these stones. No one would want to experience this pain, knowing from others how it is one of the worst feelings in the world. Keeping up with your diet would be the simplest way to avoid kidney stones, but since genes sometimes do not allow us to decide our own fate, treatment would be useful.

Who Knew? Fruit Flies Get Kidney Stones Too

A team from Mayo Clinic and the University of Glasgow recently presented their findings on kidney stones in fruit flies at the Genetics Society of America annual meeting. According to physiologist Michael F. Romero, Ph.D., of Mayo Clinic in Rochester, Minn the kidney tubules of a fruit fly are transparent and accessible making them easy to study and not only that the researchers were able to see the new stones as they started to form. Dr. Romero says that the presence of kidney stones didn't seem to affect the fruit flies.



Dr. Romero's team was able to find a gene that encodes a protein that transports oxalate into the fly kidney which leads to kidney stones. Oxlata is also the cause of kidney stone formation in human. When the gene for that protein was modiefied, the fruit flies got fewer kidney stones.  This shows that study of kidney stones in fruit flies can one day lead to treatments in humans.

Dr. Romero and his colleagues are now using this gene as a target for possible drug development. Following is a link to a video on kidney stone formation in Drosophila Fruit flies 

http://www.youtube.com/watch?feature=player_embedded&v=FKAEii-rHsM

Advances in Genetic Diseases Using the Drosophilia

Drosophila Melanogaster has been used as great genetics research models because they allow us to have a better understanding of genetic diseases that little knowledge may be known about.  Through Drosophila research, we have found out how certain genetic diseases affect humans and ways to stop the disease all together or delay their current progression.  There are many human gentic diseases/disorders. In a Medical News Today article published on March 13, 2012, using the Drosophila Melanogaster as a model, researchers have made advancements in the genetic diseases A-T, Rett syndrome, and kidney stones.

A-T is a rare neurodevelopmental disorder that causes cell death in the brain, poor coordination, spidery blood vessels, susceptibility to leukemia and lymphomas, and results in a short life expectancy mostly. Andrew Petersen is a graduate student at University of Wisconsin-Madison who discussed his experiment at a genetics Conference.  Since A-T is lethal in the Drosophila, Peterson created a mutant A-T strand in the flies that allowed the flies to develop symptoms when the environmental temperature was above a certain level.  When the symptoms of A-T began to show,  the flies lost their ability to climb up the vials and eventually ended up dying.  Based on this experiment, Peterson said “We are one step closer to knowing how these diseases occur and possibly we can treat them.”

Another research experiment by Sarah Certel, Ph.D., at the University of Montana-Missoula is also in the works. Dr. Certel is studying the human gene MeCP2 that controls gene activity or expression that has been altered for the experiment in order to put the gene in the flies. Rett syndrome occurs when too little or too much of the protein is produced.  It is a sex-linked disease whose symptoms include seizures, cognitive impairment, and loss of mobility. The altered levels of the MeCP2 protein caused disturbances in the flies' sleep and aggression. For flies, sleep is determined by the lack of activity during day and night. With this information, researchers are trying to establish a connection between cellular changes and behaviors.

Last but not least, Julian Dow, Ph.D., at the University of Glasgow, United Kingdom is studying kidney stones in the flies. Rosy, a mutant fly, discovered a century ago, is linked to the human condition kidney stones. In Dr. Dow’s experiment, he showed the formation of kidney stones in a time –lapsed video inside the Malpighian tubule of a fly. Before this, kidney stones have never been seen forming inside the kidneys.  Along with his research team and Dr. Michael Romero, Dr. Dow is currently researching chemical compounds that will stop the kidney stones from forming. So far, they have found a way to block the gene that transports a compound called oxalate, causing kidney stone formation to be slower.

It is great to see how far research in genetic diseases has come over the many years. Using the Drosophila Melanogaster as a research model has proven to be extremely beneficial in identifying the mechanics of genetic diseases, and they provide results that scientists and researchers will be able to see relatively quickly. Since the research for all three of the experiments are ongoing there isn't a lot of details; however, it is nice to see that there have been more advancements with these diseases. This makes us one step closer to finding a cure or slowing down the progression of them.