30 April 2009

Genetic Clues Hold Key to Schzophrenia Treatment


Researchers in University of Edinburgh had carried out a study which found that some genes are responsible for mental illnesses such as schizophrenia and bipolar disorder. This enabled them to understand more about the genetics of various mental illnesses.

Schizophrenia is a mental disorder whereby a person would have abnormalities in perception or expression of reality. Having found a gene that plays an important role in the development of these mental illnesses is really good news.

The study had found that gene DISC1 plays a part in development of the mental illnesses and may take control on how some patients respond to the medicines. If some patients with mental illnesses were found to have the gene DISC1 as a primary cause of their illnesses, this would really contribute to the creation of new drugs that would specifically target these patients.

Also, the study had found that gene DISC1 also affects other genes that currently used medicines are made to target. Since it is known that mental illnesses such as schizophrenia have a genetic element and genes like DISC1 plays an important part, this study enables the better understanding of how it affects brain development and also gives hints when things go wrong.

Hopefully this study would give hope to those with these mental illnesses and go a step further to give insight to many genetically-inherited disorders.

Reference

http://www.sciencedaily.com/releases/2009/03/090319224552.htm

Gene Discovery Could Lead to a Male Oral Contraceptive


“A newly discovered genetic abnormality that appears to prevent some men from conceiving children could be the key for developing a male contraceptive, according to University of Iowa researchers reporting their findings in the April 2 online edition of the American Journal of Human Genetics

The female oral contraceptive has been readily available to women for over 40 years and has been proven to be highly effective (when used correctly) in the planning of pregnancies. The only contraceptives available for men are condoms or a vasectomy and currently no male oral contraceptive (M.O.C) exists, however recent research has proven that one may be on the way.

Researchers have identified a gene that is involved in non-syndromic male infertility in humans, which could lead to the development of a M.O.C. The gene itself was hypothesised while the team’s research on Iranian families focused on identifying genetic causes of deafness, and from the collected information of the population it identified two families where male infertility appeared to be inherited.

Using lab mice and focusing on a group of genes that have been implicated in male mice infertility, the researchers discovered that mutations had occurred in the two Iranian families in the gene CATSPER1. DNA analysis however revealed two different mutations, one in each family, with one mutation producing a non-functional protein and the other not producing any at all. Neither mutation was found in the DNA of 576 Iranian men who were screened as controls.

Studies on mice that lack the CATSPER1 gene undertaken at Harvard University have revealed how sperm is affected when the protein is missing or abnormal. The studies have shown that the sperm affected by the mutation of CATSPER1 appear to have motility difficulties, namely the hyperactive motion the sperm uses during fertilization. The research goes on to suggest that this result will also be seen in humans. Further studies have shown that CATSPER1 gene is specific to sperm and therefore potentially minimising the side effects of any drug designed to affect the function of the protein being produced.

Several approaches to M.O.C are being undertaken at other institutions, with one approach displaying particular prevalence. Immunocontraception is where antibodies are developed that bind to the targeted protein produced by CATSPER1 and block its function. This method is in the early stages of development and in order to be useful must be proven to be safe, effective and reversible. If a M.O.C is developed and has been proven to possess these features, would men want to take it? According to surveys conducted by the Medical Research Council Reproductive Biology Unit in the U.K, men would be willing to use a pharmacological oral contraceptive if there was one readily available.

Student 41216747

Dr. Clare Rudkin (P11)

Reference:

University of Iowa (2009, April 10), Gene Discovery Could Lead To Male Contraceptive, ScienceDaily, Retrieved April 30, 2009, from

http://www.sciencedaily.com/releases/2009/04/090402124255.htm

Glowing dogs

Last week the first transgenic dog was produced. The beagle, Ruppy, was cloned with a successful modification of its genome. A gene which was present in sea anemones which made them glow under ultraviolet light was incorporated into a dog fibroblast cell's nucleus, and then the nucleus was inserted into the egg cell of the same species with its nucleus removed. The dog then matured, with all its cells containing this gene.

The incorporated gene coded a protein which was flurecent under ultraviolet light. First, this gene was incorporated into a virus which then was exposed to the cell. Once the gene was injected into nucleus by the virus, this nucleus was taken and inserted into an egg cell.

The point of this was to prove that such cloning and transgenesis can be done in larger mammals and thus can be done in humans to cure diseases and other illnesses.

42055167
for more information go to :

http://www.newscientist.com/article/dn17003-fluorescent-puppy-is-worlds-first-transgenic-dog.html
Major breakthrough in reverting adult cells to stem cells

Researchers at the Scripps Research Institute and other institutes have found a way to safely revert adult fibroblast cells into stem cells.

Stem cells have the ability to differentiate into any of the body’s cell types. Having a readily available source of such cells has major medical implications, potentially allowing the repair of damaged tissues anywhere in the body.

Reverting adult cells of a patient into stem cells has been a goal of researchers for quite some time. If such a feat could be achieved it would avoid the ethical complications of using embryonic stem cells and also could potentially make the immune rejection problems seen in organ transplants a thing of the past.

A method for converting adult cells to stem cells was developed some years ago but involved the insertion of foreign genes into the cell which posed significant safety concerns as the genes would permanently reside within the cells. This also had the potential to lead to the development of cancer.

But this milestone in genetics research has now been achieved through the use of specifically engineered proteins. The resulting reverted stem cells have shown no unusual function and are behaviourally indistinguishable from embryonic stem cells.

Posted By: Hugh Winwood-Smith

References:
http://www.sciencedaily.com/releases/2009/04/090423132559.htm

Scratching: The Key To Itch Relief


The University of Minnesota are undertaking a study which is showing that scratching has the ability to relieve an itch.

The current understanding of an "itch" is believed to be induced by histamines released by the "itchy" skin, which is passed to neurons in the brain via activity in the spinal cord, and then into the cerebral cortex, where the sensation is interpreted and gives the itching sensation. Scratching relieves this by turning off the activity in the spinal cord nerves, thus preventing the message from reaching the brain.

It is hoped that that same "itching" inhibition can be achieved through this research, without the negative drawbacks of actually scratching for patients suffering from chronic itching associated with ecxema, AIDS, Hodhkin's disease, and some patients suffering from renal failure or liver disease, and psychiatric disorders. These include lack of sleep, depression, post-herpetic pruritis, or even causing patients to cause large amounts of damage to them selves through excessive scratching. This group of neuroscientists are trying to understand something every dog and cat knows.

For more information, see:
http://www.sciencedaily.com/releases/2009/04/090428112615.htm

The Unique Genetic Coding for the Colour of Tortoiseshell / Tri-colour Cats


Tortoiseshell, calico or tri-colour describes the coat colouring found exclusively in female cats, with patches of orange, black, chocolate, and white. Tortoiseshell cats are also fondly called 'torties'. These cats are renowned for their independent and resilient nature, although some people prefer to call them temperamental. Their individual nature perhaps mimics their individual coat colours as no two torties will be identical in markings. Cats of this colouration are also believed to bring good luck in the folklore of many cultures, such as Scotland and Ireland.

Cats have 19 pairs of chromosomes, half inherited from the mother and the other half inherited from the father. Like humans, one of the 19 pairs of chromosomes (Y) is called the "sex" chromosome, as it determines the gender of the cat. Females are XX and males XY. That is basic genetics, which is similar to humans.

In cats, they also have gene codes for fur colour, and that is what sets the torties apart from the other cats. This genetic coding is somewhat similar to how hair colour is different in humans, except that in human genetics, the coding for hair colour is less complicated. In cat fur colour genetics, the "orange" gene is known as "O" and is carried only on the X chromosome, thus, it is called a "sex linked" colour. There are two alleles, “O” for orange, which is dominant, and “o” for non orange, which is recessive. The recessive allele allows full expression of a non-orange colour, which is usually black. Therefore, this can produce two phenotypes (either black or orange) in male cats, and three phenotypes (black, orange and tortoiseshell) in females.

Torties have two X chromosomes, one carrying the gene for orange coat colour and the other the black coat colour. Therefore, torties can only be females due to the absence of the Y chromosome. For a cat to be a tortie, she must express both the “O” and “o” simultaneously (Oo). The tortie patchwork effect in female cats for the “O” gene (Oo) is due to a process called the "X chromosome inactivation". As the embryo develops, one or the other X chromosome in every cell in the embryo tissue is randomly inactivated, while the other X chromosome is expressed. This only shows up in pigment producing cells.


(Source of Picture)
Picture above depicts the patchy colouring
result of random activation and inactivation of the X chromosomes.

Then again, it is not entirely true to say that torties can only exist as females. This is where the interesting part on genetic mutation comes in. It was reported that for a male to be a tortoiseshell, he must first have a genetic mutation that causes the male to have two X and one Y chromosome (XXY). The extra X chromosome usually renders the male tortie infertile. It is estimated that only one in about every 1000 torties is male, and that only one in 10000 is fertile. In cases where male torties are fertile, the cats may be a chimera (a single individual formed from 2 fused embryos; at least one of which was male). Therefore, it is possible for a male to be a tortie, but only due to a genetic mutation.

Another odd tidbit in the tortie genetic coding is that you can almost never clone a tortie. It was reported that when a tortoiseshell cat is cloned, a tortie is never the result. A cat of one or the other of the constituent colours is usually obtained. This means that if you had cloned a black / orange tortoiseshell, the clone will be either orange or black. This is once again due to the “X-linked Inactivation” process in the embryo cells.


-By: Kua Chang Yan Ivan, S41580662, P10-

References:
1. Sarah Hartwell (2008). Tortoiseshell and Tri-colour Cats. Accessed 29th April 2009
2. Ozpets (2007). Articles: Tortoiseshell, Calico and Ginger Cats. Accessed 29th April 2009
3. CatWorld (2009). Why are Tortoiseshell Cats Female & Red Cats Male? Accessed 29th April 2009

For Reading:
Click:
HERE, HERE and HERE.

Genetic variation in Arabidopsis thaliana

Weblog – Summary of

"Functional variation in a disease resistance gene in populations of Arabidopsis thaliana"

The paper was authored by T. H. Jorgensen and B. C. Emerson of the Centre for Ecology, Evolution and Conservation, School of Biological Sciences, University of East Anglia, Norwich, England, and was published in the journal Molecular Ecology (2008) 17, 4912-4923.

The authors investigated whether the molecular diversity in RPW8 (Recognition of Powdery Mildew), a gene conferring broad-spectrum resistance to powdery mildews in Arabidopsis thaliana, arose through selection or a random process such as genetic drift. To do this, initially, they investigated whether local populations of A. thaliana were genetically variable by analysing variation at microsatellite loci within their test populations. Secondly, they determined if molecular variation present at RPW8 can explain natural variation in powdery mildew resistance. Thirdly, they related within- and between-population variation at RPW8 with that of neutral satellite markers to provide a test for the presence of selection.

The authors took seeds from eight populations of A. thaliana from locations in England, situated from 2-115 km apart. The populations were from areas of low anthropogenic disturbance. The seeds were germinated and the plants grown under identical conditions within the laboratory. The plants were then inoculated with powdery mildew and inspected for signs of infection at 7 and 14 days. Plants were grouped as susceptible, intermediate, or resistant, depending on their level of infection.

For each plant, the RPW8 gene and 12 microsatellite loci were sequenced using commercially available PCR and sequencing technologies. For the neutrality test, microsatellite loci that are in linkage disequilibrium with RPW8 were included. Statistical analysis of the results were then carried out.

It was found that

· Populations were highly diverse and significantly differentiated at neutral microsatellite loci and therefore fulfilled the criteria for inclusion in the study.

· variation in resistance to powdery mildew was found within most of the study populations.

· Different frequencies of disease phenotype between populations was linked to high genetic variation in RPW8.

· RPW8 is not the only genetic factor involved in resistance to powdery mildew.

· There was no evidence that selection was the agent of maintenance of genetic variation at RPW8.

Rover really is man’s best friend



Ever wondered why some dogs fetch stick and other don’t, well thanks to molecular biologists mapping the complete genome of a dog for the first time we now know it down to genetics. However the question needs to be asked, what can the complete genome of a boxer tell us? Other than Rover’s desire for fetching sticks.

With the complete genome of a boxer, scientists believe that there could be serious health benefits to humans. Dogs and humans alike are known to suffer from many common diseases like heart disease, epilepsy, diabetes, cancer and a whole library of other health related issues. But hope come in the genetic sequence of dogs because of the similarities in disease. It is much easier to identify certain genes in dogs that cause problems because, genes that cause disease in dogs are easier to find than in humans. Mutations in a dozen different genes can cause human disease. In dogs, only one gene mutation can cause a disease, and that same mutated gene causes an identical disease in humans. It is believed that one day genetic engineers will be able to re engineer the specific sequences of genes that cause a disease in order to remove it from the gene pool and thus eliminating the disease. Also it is expected that cancer and other disease treatments for humans will benefited from the dogs genomic sequence

The mapping of genes in other species could not only prove beneficial to them but also humans could improve health care and possibly could possibly hold the key into the treatment and hopefully a cure to serious health problems. In conclusion it looks like we have another reason to call dogs man’s best friend.

References
http://www.sciencedaily.com/videos/2006/0704-doggy_genes.htm

Fearless Mice

Fearless Mice

Eric Dover, 30/04/2009

Researchers at the University of Tokyo have discovered that there are different smell pathways to the brain for innate and learned fear and that they are both controlled by the olfactory neurons in the epithelium of the nose and the bulb of the brain. Discovered in mice, the researchers changed several of the genes in the olfactory bulb so that several of its functions were disabled. This means that the mice not only were not afraid of bad things such as cats and rotten food, but they also showed little interest in other mice and good food.

There are two regions of the olfactory epithelium, the dorsal and ventral and until now no one knew what the difference was between them in how the brain experienced smell. It is now known that the dorsal region controls innate fear responses and the ventral controls learned aversion.

This is helping scientists to explain how odours are translated into actions; this was shown with the mice again. Usually when mouse smells a fox the brain is stimulated to release adrenocorticotropic hormone, which is a sign of stress, however the fearless mice released no such hormone.


Reference: http://www.nature.com/news/2007/071107/full/news.2007.224.html

Additional: http://www.pinktentacle.com/2007/11/scientists-create-fearless-mouse/

Gene-laden Bubbles Grow New Blood Vessels

The Oregon Health and Science University have developed a gene therapy technique that allows microscopic bubbles that have been chemically modified to stick to the cells that line blood vessels.

Cardiologist Jonathan Lindner has developed ultrasound-mediated gene delivery (UMGD) by exploiting contrasting agents that are normally injected into the body to improve ultrasound images. In UMGD, the tiny particles are microbubbles composed of pockets of gas encapsulated by thin membranes that are coated with DNA before injection. A targeted pulse of ultrasound energy "rings" the bubbles like a bell, popping them in a specific location and releasing the DNA into the surrounding tissue. This DNA then binds with the corresponding site of action and this relatively increases the amount of gene transfection that occurs. Lindner also created arm-like mechanism to improve the specificity of the DNA deposit where bubbles attach to the tissue before being popped.

This has been successful in delivering therapeutic DNA to the walls of blood vessels where Dr. Lindner has stimulated the growth of new blood vessels using UMGD with microbubbles carrying a gene for vascular endothelial growth factor. At the present this technology is still in its testing stages but promising results have so far shown that this may be offered as a form of treatment in short future.

In the meantime, Dr. Lindner and his team are investigating as to whether the microbubbles can be used to transport small doses of drugs for a more safer and efficient approach to drug delivery.

American Institute of Physics (2009, April 29). Gene-laden Bubbles Grow New Blood Vessels. ScienceDaily. Retrieved April 29, 2009, from http://www.sciencedaily.com­ /releases/2009/04/090426094213.htm

Giant virus could help scientists learn more about the origins of life


Acanthameoba polyphaga Mimivirus
Image: Rossmann et al., PLoS Biology 2009

Capsid covered in tiny holes
Image: Rossmann et al., PLoS Biology 2009

Mimivirus (Acanthamoeba polyphaga Mimivirus), the world's largest virus, was discovered by accident seventeen years ago living in an amoeba in an English water tower. At .5 microns in diameter, almost the size of a bacterium, this cross between a living and non-living entity has recently revealed to scientists some very unusual features that may help understand the process of evolution.
Using cryo-electron microscopy, researchers were able to examine the virus's surface closely and found several unexpected features including a starfish-shaped structure located on the capsid, its outer layer. This is suspected of being the site through which viral DNA is ejected into a host organism. Additionally, the capsid was covered in tiny holes whose function hasn't yet been determined.

Recently discovered within the genome of Mimivirus were many genes not previously found in viruses including some tRNA components known only in cellular organisms. Although the virus infects amoebas, antibodies have been found in pneumonia patients which gives rise to concerns that the virus may be pathogenic.
Mimivirus is the viral equivalent of a platypus – a partly eukaryotic, partly bacterial oddity which some scientists think might lead to a new classification.

Sharon Edgley s4201745
P9 Th 1300

References:

http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6T32-4J8M3D3-2&_user=10&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=e6820a7d9e3b2d04a65620978d77

Mimivirus and the emerging concept of “giant” virus

Jean-Michel Claverie et alVirus ResearchVolume 117, Issue 1, April 2006 p133-144

Purdue University (2009, April 29). New Details About Mysterious Giant Virus Uncovered.

Blue-eyed people have a single,common ancestor


All Blue Eyed People Related to Brad Pitt?



According to a new paper by a Danish researcher, blue eyes come as the result of a single mutation that occurred 10,000 years ago. Which means that all people with blue peepers have a common ancestor.The paper, published by Danish geneticist Hans Eiberg in the journal Human Genetics, links all baby blues to a single mutation that occurred 10,000 years ago.

Eiberg says the mutation shuts off the production of the pigment responsible for brown eye color, resulting in a pure blue iris. Because the mutation is so specific, it can only be explained one way: "There must be a common ancestor for people with blue eye colour," according to Eiberg. Eiberg started his search for the elusive mutation close to home. Using the Copenhagen Family Bank, a massive genetic database with detailed information on over 6,000 Danes, Eiberg found a family with three generations of blue-eyes. Looking at DNA from their blood, Eiberg homed in on a single, tiny blip in the genetic code. "All of the family had the same mutation," he said.Originally, Eiberg says, everyone in the world had brown eyes. But the mutation acts as a switch that shuts off the OCA2 gene, which controls the eye's production of melanin. Melanin is the pigment that gives colour to eyes and hair.


The mutation limits the OCA2 gene, restricting production of melanin in the eye. The result: The eye's brown colour is diluted, giving people with the mutation pure blue eyes. The mutation is extremely specific: All people with blue eyes have the exact same genetic variation, and anyone with brown or green eyes do not. As a result, Eiberg said, it must have been passed down from a single person.


To make sure the Danish family wasn't a fluke, Eiberg tested hundreds more samples, including people from Turkey with dark hair, light skin and blue eyes and Jordanians with dark hair, dark skin and blue eyes. They all had the same mutation as the Danes. "I have analyzed 800 samples," Eiberg says. "Out of the 800, 799 eyes are the same."


Eiberg has long been fascinated by the genetics of eye color. In 1996, he discovered the OCA2 gene, which helps control eye colour. The blue-eye mutation works directly to turn off the OCA2 gene's production of melanin in the eye.Eye colour is a good example of how research is complicating our understanding of heredity. "Eye colour is a textbook example of how genes work in a simple way, and now it turns out it's a bit more complicated than that," said Zoltan Bochdanovits, a statistical geneticist at the Vrije University in Amsterdam. "They do present quite convincing evidence it's a single mutation causing this."


Where and when the mutation occurred is more speculative, but based on the number of people with pure blue eyes in the world today, Eiberg argues that the original Ol' Blue Eyes lived between 6,000 and 10,000 years ago. Existing research on prehistoric population movements suggest that the original blue-eyed babe may have lived around the Black Sea, near modern-day Ukraine or Turkey, and that their descendants migrated to Northern Europe during the Stone Age.



Reference:
1. http://www.sciencedaily.com/releases/2008/01/080130170343.htm [ Accessed on 20 April 2009]

Stem cell therapy offers hope for blindness cure

A STEM cell therapy to cure the most common cause of blindness has been developed.

Macular degeneration is a medical condition usually found in older adults which results in a loss of vision whereby the light sensing cells in the macula malfunction and over time cease to work resulting in a black spot in the center of the visual field (the macula) because of damage to the retina.
The process uses the science of stem cell research, which involves the destruction of human embryos. In laboratory trials, it has been proven that stem cells can prevent blindness in rats with a similar disease to age related macular degeneration, as well as in pigs.
The treatment involves replacing a layer of degenerated cells with new ones created from embryonic stem cells. The stem-cells are transformed into replicas of the missing cells and are then placed on an artificial membrane, which is inserted in the back of the retina.
It is predicted that this procedure will soon become routine and be generally available within seven years.

Below Left: Before macular degeneration.
Below Right: After macular degeneration.

29 April 2009

Primate Colour vision

Researchers have found a link to our past by looking into the secrets behind our sight.  Humans use three different receptors in our eyes which detect different wavelengths of light.  The use of three such cells in our eyes is called trichromacy.  Some animals have four visual pigments but most animals including most mammals have two, or occasionally even only one.  What makes this especially interesting is that trichromacy is extremely rare in the animal world.  By investigating which primates have three visual pigments we get anouther window into the evolution of both our species and of the other primates.

What is especially interesting is that there is a defining split in the genetics of vision between old and new world primates.  New world primates include squirril monkeys, spider monkeys, howler monkeys and tamarins while new world primates include the great apes, gibbons and mandrills.  New world primates have the ability to be trichromatic but can be dichromatic.  This is because of an unusual method of random selection where the X chromosome only contains one of several possible genes, leaving males dichromatic and females with a chance of having both genes the same resulting in the same.

Cameron Etches 41418466

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Researchers Demonstrate First Common Genetic Risk Factors For Autism

This article was about how there is strong evidence that a genetic component increases the likelihood of autism. In a study of more than 10000 children of which 4500 were diagnosed with autism spectrum disorder, a common genetic variation was found that increased the risk of a child developing autism, along with rare genetic changes that contribute to some cases of autism.

The actual genetic pathway has not been found yet, but studies have come up with some possible genetic pathways that may be responsible for increased risk of autism. A study found that a particular genetic variation, found on a cluster between CDH10 and CDH9, is commonly found in children with autism. Another study also found that deleted or duplicated genes along two major central nervous system gene networks in children with autism spectrum disorders. These changes were located on the ubiquitin pathway, which regulates synaptic operations and nervous system development. Research is still underway to test the effects of the missing or extra genetic copies to see if it in any way relates to an increased risk of autism. Also, geneticists from the University of Pennsylvania School of Medicine and The Children's Hospital of Philadelphia (CHOP), believe they have detected a genetic pathway that is responsible for neurological development, learning and memory, which plays a significant role in the genetic risk of autism.

The research into possible genes causing a higher risk in genetic autism is very important since it may reveal what goes wrong during development in children with autism and will enable scientists to focus on what the cause of autism is at the molecular level.

Link to article: http://www.medicalnewstoday.com/articles/147997.php
By Tiffany Hoang (4203673)

Research breakthrough paves way for 'supercow'


Posted by student: 42007492
Tutor: Margaret Jewell
Prac Session: 7 (Wed 5-8pm)

Scientists in the US have invested $US52 million dollars into attempting to successfully sequence the cow genome in order to create a “supercow”. This investigation into L1 Dominette’s genetic sequence will have positive effects for several parties. It will increase the quality of the beef and milk market in the future, whilst also providing producers will also be able to test the quality of the stock they currently have. While the cattle population has increase with human population, the genetic diversity of the animals have decreased. This has implications for the future of cattle populations, and the study into the genome will allow the possibility of breeding a “supercow” that could possible deal with climate change and the associated environmental consequences. Of the minimum 22,000 genes that the cattle genome contains, 14,000 are common to all sequenced mammals, including humans. Their altered genes are involved in immunity, reproduction, lactation, digestion and metabolism, as compared to other mammals. These differences can play a role in medical advances for human diseases, for example, malaria. As cows do not get malaria, the genes that are found in humans but now cows will narrow down targets for research.

http://abc.com.au/news/stories/2009/04/24/2551319.htm

A Powerful New Tool for Decoding Gene Functions in Mammals and Man


A collaborative project between American and Chinese researchers developed a way to study the function of genes in mice and man by using a moveable genetic element found in cabbage looper moths, called the piggyBac transposon.

Transposons are genetic elements that migrate around DNA, allowing material to be either inserted or relocated. One of the ways this is evident is the manner in which bacteria swap antibiotic resistance genes. Although scientists have been able to adapt this natural procedure to learn the function of individual genes in fruit flies and other simple organisms, they have been unable to do so with vertebrates and mammals.
These genetics were limited as they travelled at low frequencies to limited locations, and had little capacity to carry DNA fragments. The piggyBac transposon however was able to overcome this problem due to its stability and versatility in the mouse and human lines.

The genes piggyBac associates with were made easier to see by adding a red fluorescent protein and an enzyme that changes the coat colour of a white mouse to grey or black. The genes carried by the transposons have been stably inherited and expressed through five generations. "The transposon acts as a genetic beacon, so researchers can easily track its location without having to sequence the entire genome," said senior author Tian Xu, Professor and Vice Chair of Genetics at Yale University School of Medicine. PiggyBac incorporated into many chromosomes in human and mouse cells can be removed from a mouse lineage by breeding with another mouse that has the enzyme to excise the transposon. This technique is a powerful new tool for generating transgenic animals for vertebrates and mammals, and a potential new vehicle for human gene therapy. Although piggyBac inserts itself randomly into the DNA, it most often locates in genes, making it useful for mutating genes and thus, revealing gene functions.

In three months, the two graduate students who worked on the project generated mice mutating 75 different genes. Xu expects the technique to be particularly useful for identifying genes and drug targets for diseases such as cancers and diabetes.

By: Gillian Lawrence, student number 41938955
Tutor:Brenda MacDonald, Prac session: 9 (Thursday 1pm)

References:
http://www.sciencedaily.com : ScienceDaily (Aug. 15, 2005) — New Haven, Conn
Picture-http://www.sciencedaily.com/images/2005/08/050814163056.jpg
Fluorescent puppy is world's first transgenic dog
12:00 23 April 2009 by Ewen Callaway
For similar stories, visit the GM Organisms and Genetics Topic Guides
A cloned beagle named Ruppy – short for Ruby Puppy – is the world's first transgenic dog. She and four other beagles all produce a fluorescent protein that glows red under ultraviolet light.

A team led by Byeong-Chun Lee of Seoul National University in South Korea created the dogs by cloning fibroblast cells that express a red fluorescent gene produced by sea anemones.

Lee and stem cell researcher Woo Suk Hwang were part of a team that created the first cloned dog, Snuppy, in 2005. Much of Hwang's work on human cells turned out to be fraudulent, but Snuppy was not, an investigation later concluded.

This new proof-of-principle experiment should open the door for transgenic dog models of human disease, says team member CheMyong Ko of the University of Kentucky in Lexington. "The next step for us is to generate a true disease model," he says.

However, other researchers who study domestic dogs as stand-ins for human disease are less certain that transgenic dogs will become widespread in research.

Dogs already serve as models for diseases such as narcolepsy, certain cancers and blindness. And a dog genome sequence has made the animals an even more useful model by quickening the search for disease-causing genes. Most dog genetics researchers limit their work to gene scans of DNA collected from hundreds of pet owners.

Making a glowing dog
Lee's team created Ruppy by first infecting dog fibroblast cells with a virus that inserted the fluorescent gene into a cell's nucleus. They then transferred the fibroblast's nucleus to another dog's egg cell, with its nucleus removed. After a few hours dividing in a Petri dish, researchers implanted the cloned embryo into a surrogate mother.

Starting with 344 embryos implanted into 20 dogs, Lee's team ended up with seven pregnancies. One fetus died about half way through term, while an 11-week-old puppy died of pneumonia after its mother accidentally bit its chest. Five dogs are alive, healthy and starting to spawn their own fluorescent puppies, Ko says.

Besides the low efficiency of cloning – just 1.7 per cent of embryos came to term – another challenge to creating transgenic dogs is controlling where in the nuclear DNA a foreign gene lands. Lee's team used a retrovirus to transfer the fluorescent gene to dog fibroblast cells, but they could not control where the virus inserted the gene.

This would seem to prevent researchers from making dog "knockouts" lacking a specific gene or engineering dogs that produce mutant forms of a gene. These knockout procedures are now commonly done in mice and rats, and three researchers earned a Nobel prize in 2007 for developing this method, called "gene targeting".

No bright future?
Ko is working to adapt a procedure used so far in pigs, cows and other animals to target genes in cloned dogs. His lab hopes to knock out a specific oestrogen receptor in dogs to understand the hormone's effects on fertility.

The long lifespan of dogs and their reproductive cycle could make them more relevant to human fertility than mice, he says. "I think these dogs will be a very useful model for our research."

Greg Barsh, a geneticist at Stanford University who studies dogs as models of human disease, says creating a transgenic dog is "an important accomplishment", showing that cloning and transgenesis can be applied to a wide range of mammals.

"I do not know of specific situations where the ability to produce transgenic dogs represents an immediate experimental opportunity," Barsh adds. But transgenic dogs will give researchers another potential tool to understand disease.

However, Nathan Sutter, a geneticist specialising in dogs at Cornell University in Ithaca, New York, says "transgenesis is labourious, expensive and slow".

Add the expense of caring for laboratory-reared dogs and negative public perceptions and it could mean few researchers turn to transgenic dogs like Ruppy, he says: "it's not on my horizon as a dog geneticist at all."

Journal reference: genesis (DOI: 10.1002/dvg.20504)

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