Anti aging genes discovered

June 13, 2012 by admin

The Fountain of Youth, an anti aging nectar that prolongs time spend on earth; a nectar that can cure every health problem; a nectar, unfortunately, that can be found only in fictional stories. In spite of its fictional existence, the fountain of youth is a kick-start motif for scientist search for longer life span. Youth is the greatest period in everyman’s life and forever young a common wish.

Scientist claim that the root of longer life span lies in human’s genes. It is not something that you can gain reaching certain age and it is not something that you can make by consuming special drugs. Centurion is created from birth. Through out the years scientists have made many researches concerning longer life-span situation. One type of research is published in Science and has two parts.

The first part is called GWAS, or “genome-wide association study.” About 1,000 people over 100 years old were part of the New England Centenarian Study.

The obtained data was compared to a normal aging group of people; their number was also about 1,000. 70 genes were found in centenarians, repeating the study to a smaller group gave the result of 33 genes.

To make sure that everything is fair-and-square, disease-causing genes were examined in both of the groups, centenarians and normal aging people. It was confirmed that centenarians were exposed to disease as much as the normal aging people. The interesting thing is that strong immunity was given to the centenarians by the genes, ergo, longer healthy days.

150 people, centenarians and normal aging people, underwent the model research without the knowledge of who has 70 genes of longer life. The model was 77 % accurate in his prediction to which group the subject belong to. It gave 19 different genetic combinations in the centenarians.

An interesting fact about this is that 15 % had those combinations, meaning that 15 % of us should reach the age of 100 years old, and even more. But reality bites with the result of 1 in 6,000.

There are scientists that greet these results and consider them good data for future research. There are others that counter them stating that the number of people in the research is not enough.

Science confirms the fact that genes have major role in longer life. But it also, firmly states, that if you don’t take care of your body, it won’t be able to take care of you. Healthy nutrition and exercising on a regular schedule is a perfect natural way to contribute years on your calendar. Every body is undergoes aging; so, make it a healthy aging process.

 

Anti Aging

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Gene that leads to severe weight gain with antipsychotic treatment discovered

ScienceDaily (May 7, 2012) — Antipsychotic medications are increasingly prescribed in the US, but they can cause serious side effects including rapid weight gain, especially in children. In the first study of its kind, researchers at Zucker Hillside Hospital and the Feinstein Institute for Medical Research identified a gene that increases weight gain in those treated with commonly-used antipsychotic drugs.

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These findings were published in the May issue of Archives of General Psychiatry.

Second-generation antipsychotics (SGAs) were used as the treatment in this study. SGAs are commonly used to treat many psychotic and nonpsychotic disorders. However, it is important to note that these SGAs are associated with substantial weight gain, including the development of obesity and other cardiovascular risk factors. The weight gain side effect of SGAs is significant because it often results in a reduced life expectancy of up to 30 years in those who suffer from chronic and severe mental illnesses. The weight gain also prompts some to stop taking the medication, adversely impacting their quality of life.

In this genome-wide association study (GWAS), researchers first evaluated a group of pediatric patients in the US being treated for the first time with antipsychotics. They then replicated the result in three independent groups of patients who were in psychiatric hospitals in the United States and Germany or participating in European antipsychotic drug trials. The gene that was identified to increase weight gain, MC4R or melanocortin 4 receptor, has been previously identified as being linked to obesity and type 2 diabetes. In the new study, it was found that patients gained up to 20 pounds when on treatment.

"This study offers the prospect of being able to identify individuals who are at greatest risk for severe weight gain following antipsychotic treatment," said Anil Malhotra, MD, investigator at the Zucker Hillside Hospital Department of Psychiatry Research and Feinstein Institute for Medical Research. "We hope that those who are at risk could receive more intensive or alternative treatment that would reduce the potential for weight gain and we are currently conducting studies to identify such treatment."

Additional Details About the Study

Researchers conducted the first GWAS of SGA-induced weight gain in patients carefully monitored for medication adherence who were undergoing initial treatment with SGAs. To confirm results, they next assessed three independent replication cohorts: 1) a cohort of adult subjects undergoing their first treatment with a single SGA (clozapine), 2) a cohort of adult subjects treated with the same SGAs as in our discovery sample, and 3) a cohort of adult subjects in the first episode of schizophrenia and enrolled in a randomized clinical trial of antipsychotic drugs. The discovery cohort consisted of 139 pediatric patients undergoing first exposure to SGAs. The 3 additional cohorts consisted of 73, 40, and 92 subjects. Patients in the discovery cohort were treated with SGAs for 12 weeks. Additional cohorts were treated for 6 and 12 weeks.

This GWAS yielded 20 single-nucleotide polymorphisms at a single locus exceeding a statistical threshold of P10-5. This locus, near the melanocortin 4 receptor (MC4R) gene, overlaps a region previously identified by large-scale GWAS of obesity in the general population. Effects were recessive, with minor allele homozygotes gaining extreme amounts of weight during the 12-week trial. These results were replicated in 3 additional cohorts, with rs489693 demonstrating consistent recessive effects; meta-analysis revealed a genome-wide significant effect. Moreover, consistent effects on related metabolic indices, including triglyceride, leptin, and insulin levels were observed.

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Protective gene discovered in fat cells

ScienceDaily (Apr. 1, 2012) — In a finding that may challenge popular notions of body fat and health, researchers at Beth Israel Deaconess Medical Center (BIDMC) have shown how fat cells can protect the body against diabetes. The results may lead to a new therapeutic strategy for preventing and treating type 2 diabetes and obesity-related metabolic diseases, the authors say.

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In the last decade, several research groups have shown that fat cells in people play a major role in controlling healthy blood sugar and insulin levels throughout the body. To do this crucial job, fat cells need a small portion of the sugars derived from food. Obesity often reduces the dedicated sugar transport molecules on fat cells, blocking the glucose from entering fat cells. As a result, the whole body becomes insulin resistant, and blood sugar rises, leading to diabetes.

The new study shows why glucose is so important to fat cells. The team discovered a new version of a gene inside fat cells that responds to sugar with a powerful systemic effect.

"If we change that one gene, that makes the animal more prone to or more protected from diabetes," said senior author Barbara Kahn MD, the George R. Minot Professor of Medicine at Harvard Medical School and Vice Chair of the Department of Medicine at BIDMC. "Many foods get converted into sugar, so there is no need to eat more sugar."

The paper is published online April 1 in the journal Nature. In the study, the BIDMC researchers pinpointed the fat gene and its effect in mouse models of human obesity and insulin resistance and reported supporting evidence from fat tissue samples from both lean and obese people.

"Two things were surprising -- first, that a lone gene could shift the metabolism of the fat cell so dramatically and then, that turning on this master switch selectively in adipose tissue is beneficial to the whole body," Kahn said. Twelve years ago, Kahn first demonstrated that fat cells are a master regulator of healthy levels of glucose and insulin in mice and require sugar to do the job.

"The general conception of fat as all bad is not true," said first author Mark Herman MD, an Instructor in Medicine at BIDMC and Harvard Medical School (HMS). "Obesity is commonly associated with metabolic dysfunction that puts people at higher risk for diabetes, stroke and heart disease, but there is a large percentage of obese people who are metabolically healthy. We started with a mouse model that disassociates obesity from its adverse effects."

In the latest study, evidence suggests the newfound gene also may account for the protective effect of glucose uptake in human fat. German collaborators found more gene activity in people with greater insulin sensitivity, based on 123 adipose tissue samples from non-diabetic, glucose tolerant people. The fat gene activity also correlated highly with insulin sensitivity in obese, non-diabetic people, as measured in 38 fat samples by another pair of co-authors based in St. Louis.

"It's a really exciting finding," said Ulf Smith MD PhD, a professor at University of Gothenburg, Sweden, and president of the European Association for the Study of Diabetes. He was not involved in this study. "We've been looking for the mechanism to try to understand why glucose metabolism in adipose tissue is so important for whole-body sensitivity to insulin." Eight years ago, Smith extended Kahn's original findings to people and also showed that fat cells that begin to have trouble taking in sugar can be an early indicator of diabetes. In healthy people, fat cells normally need about 10 percent of the sugars derived from food, he said.

In fat cells, the newfound gene acts as a glucose sensor that converts the sugars into fatty acids, which may play a role in the powerful systemic effect. In response to rising glucose levels, the gene makes a more active version of itself. The active version turns on the cellular machinery that disassembles the sugar molecules and remakes them into fatty acids. The novel version of this gene is called carbohydrate-responsive-element-binding protein-beta, or ChREBP-beta for short.

In the liver, where the original gene was discovered by other scientists, the same fatty acid synthesis process is harmful. There, the transformation of glucose into fatty acids raises triglycerides in the blood and leads to nonalcoholic fatty liver disease.

The mice in the latest study were first developed in Kahn's lab two decades ago to model a surprising feature of human obesity. The number of glucose transporters (GLUT4) drops with obesity -- but only on fat cells -- and it happens early in the development of diabetes. (GLUT4 is also found on muscle and heart cells.) Kahn generated mice with genetic alterations in the amount of GLUT4 in fat cells, seeking clues to the link between obesity and diabetes.

One set of mice features 5 to 10 times the usual number of glucose transporters in its fat cells. These mice are obese but exhibit none of the diseases usually associated with obesity. Another set of mice is missing the glucose transporters on their fat cells, which causes diabetes symptoms despite the fact that these mice have normal body weight.

"There's something very special about GLUT4," Kahn said. "When you wake up and haven't eaten all night, the GLUT4 transporters are inside the cell. Within minutes of eating and glucose reaching the blood and stimulating insulin secretion, the GLUT4 transporters move to the cell surface. It's reliable, fast, dynamic and critical to maintaining normal blood sugar after we eat."

Now, the Kahn team has identified how fat cells with GLUT4 can sense the change in glucose transport into the cell and respond by regulating insulin sensitivity in the entire body. The new study reveals a new, potent version of a gene that transforms glucose into fatty acids. "We definitely do not want to imply that people should eat more sugar," Kahn said.

In future research, the team will investigate whether the gene activity could be working directly through fatty acids or altering fat cells and the molecules they secrete in other ways. The BIDMC team is pursuing the fatty acid angle, in part because it seems to fly in the face of conventional wisdom.

The concept that some fatty acids might be beneficial is not new, but "until recently, it was thought that human adipose tissue was not capable of synthesizing many fatty acids," Herman said. In fact, beneficial fatty acids such as omega-3s from fish, and other fatty acids found in olive oil, are usually recommended as part of a healthy diet.

And the fatty acids humans do generate were not thought to be beneficial. "There is a mythology that elevated fatty acids in the blood are detrimental metabolically and generally signal insulin resistance in people," Kahn said. "Our study demonstrates that doesn't have to be the case. It raises the question of whether there are some special fatty acids being made as a result of upregulation of ChREBP."

The research was funded by the U.S. National Institutes of Health, Boston Area Diabetes Endocrinology Research Center, Boston Nutrition Obesity Research Center, the Picower and JPB Foundations, a Fellowship from the Radcliffe Institute for Advanced Study, and the Deutsche Forschungsgemeinschft DFG.

In addition to Kahn and Herman, study coauthors include BIDMC investigators Odile D. Peroni, and Jorge Villoria; Michel R. Schon of Stadtisches Klinikum Karlsruhe, Karlsruhe, Germany; Nada A. Abumrad and Samuel Klein of Washington University School of Medicine; and Matthias Bluher of the University of Leipzig, Leipzig, Germany.

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