Category Archives: Genome

PUBLIC RELEASE DATE:

6-Mar-2014

Contact: Jia Liu liujia@genomics.cn BGI Shenzhen

Shenzhen, February 27, 2014 - Researchers from Oil Crops Research Institute of the Chinese Academy of Agricultural Sciences, BGI, University of Copenhagen and other institutes have successfully cracked the genome of high oil content crop sesame, providing new lights on the important stages of seed development and oil accumulation, and potential key genes for sesamin production. The joint efforts made sesame become the second Lamiales to be sequenced along with the former published minute genome of Utricularia gibba. The latest study was published online in Genome Biology.

Sesame, Sesamum indicum L., is considered as the queen of oilseeds for its high oil content and quality. It is grown widely in tropical and subtropical areas as an important source of oil and protein. Compared to other eatable oil crops such as soybean, rapeseed, peanut and olive, sesame has innate superiority for its high oil content (~55% of dry seed), and thus is an attractive model for studying lipid biosynthesis. However, currently only limited genomic data of sesame is available.

In this study, researchers presented a high-quality draft genome of the sesame genotype 'Zhongzhi No. 13', an elite cultivar in China been planted over the past ten years. After data process, the assembled sesame genome size is about 337 Mb, with a total of 27,148 genes. The result highlighted the absence of the Toll/interleukin-1 receptor domain in resistance genes, and suggested that this may be a new paradigm in elucidating the interaction of resistance genes along with diseases.

To explore the molecular mechanism of lipid biosynthesis, researchers conducted comparative genomic and transcriptomic analyses and found an expansion on type 1 lipid transfer genes by tandem duplication, a contraction on lipid degradation genes, and the differential expression of essential genes in the triacylglycerol biosynthesis pathway, particularly in the early stage of seed development. Researchers further resequenced 29 sesame accessions from 12 countries to investigate the genetic diversity of lipid-related genes.

Sesamin is an oil-soluble furofuran lignan typically present in sesame seed. Numerous studies on rats and mice have suggested various health benefits of sesamin. This compound is known to promote normalize blood pressure, lower cholesterol, protect the liver, and contribute to weight loss. Sesamin biosynthesis involves two key genes encoding dirigent protein (DIR) and piperitol/sesamin synthase (PSS), respectively. In this study, researchers found that DIR homologues were present in sesame and tomato, but the PSSs are only detected in sesame, indicating the genetic foundation for the sesame-specific product.

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The genome of sesame sheds new lights on oil biosynthesis

Researchers from Oil Crops Research Institute of the Chinese Academy of Agricultural Sciences, BGI, University of Copenhagen and other institutes have successfully cracked the genome of high oil content crop sesame, providing new lights on the important stages of seed development and oil accumulation, and potential key genes for sesamin production. The joint efforts made sesame become the second Lamiales to be sequenced along with the former published minute genome of Utricularia gibba. The latest study was published online in Genome Biology.

Sesame, Sesamum indicum L., is considered as the queen of oilseeds for its high oil content and quality. It is grown widely in tropical and subtropical areas as an important source of oil and protein. Compared to other eatable oil crops such as soybean, rapeseed, peanut and olive, sesame has innate superiority for its high oil content (~55% of dry seed), and thus is an attractive model for studying lipid biosynthesis. However, currently only limited genomic data of sesame is available.

In this study, researchers presented a high-quality draft genome of the sesame genotype 'Zhongzhi No. 13', an elite cultivar in China been planted over the past ten years. After data process, the assembled sesame genome size is about 337 Mb, with a total of 27,148 genes. The result highlighted the absence of the Toll/interleukin-1 receptor domain in resistance genes, and suggested that this may be a new paradigm in elucidating the interaction of resistance genes along with diseases.

To explore the molecular mechanism of lipid biosynthesis, researchers conducted comparative genomic and transcriptomic analyses and found an expansion on type 1 lipid transfer genes by tandem duplication, a contraction on lipid degradation genes, and the differential expression of essential genes in the triacylglycerol biosynthesis pathway, particularly in the early stage of seed development. Researchers further resequenced 29 sesame accessions from 12 countries to investigate the genetic diversity of lipid-related genes.

Sesamin is an oil-soluble furofuran lignan typically present in sesame seed. Numerous studies on rats and mice have suggested various health benefits of sesamin. This compound is known to promote normalize blood pressure, lower cholesterol, protect the liver, and contribute to weight loss. Sesamin biosynthesis involves two key genes encoding dirigent protein (DIR) and piperitol/sesamin synthase (PSS), respectively. In this study, researchers found that DIR homologues were present in sesame and tomato, but the PSSs are only detected in sesame, indicating the genetic foundation for the sesame-specific product.

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The above story is based on materials provided by BGI Shenzhen. Note: Materials may be edited for content and length.

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Genome of sesame sheds new light on oil biosynthesis

Whole Genome Sequencing Project
Dedicated to O #39;Malley de Alley Cat.

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Two university-based clinics have debuted large programs that rely on sequencing to diagnose genetic disorders, including developmental disorders such as autism

Cancer.gov

Reprinted with permission fromSFARI.org, an editorially independent division of The Simons Foundation. (Find original story here.)

Over the past few years, teams of scientists have been finding genetic glitches related to a wide variety of disorders by sequencing exomes, the protein-coding portions of the genome. But these genetic tests are typically out of reach for people unless they enroll in research studies, and even then, theyre almost never privy to their individual results.

But that looks set to change: A few clinics are debuting large programs that rely on sequencing of exomes or even of whole genomes, and making the results directly available to individuals. For less than $10,000 each, the tests offer people with unexplained genetic disorders the chance to find the cause of their condition.

The first academic lab to offer clinical exome sequencing was the Whole Genome Laboratory at Baylor College of Medicine in Houston. Since November 2011, the lab has sequenced the exomes of some 1,700 individuals with undiagnosed conditions, including many children with developmental disorders. It now averages about 200 exomes a month.

"It's gone gangbusters," says Richard Gibbs, director of Baylor's Human Genome Sequencing Center, which helped establish the new lab. The researchers have pinpointed the genetic cause of about one-quarter of the 1,700 cases as mutations in known disease genes, he says.

Last week, the Harvard-affiliated Partners Healthcare Center in Boston launched a similar lab focused on sequencing whole genomes. And two private companies Ambry Genetics in Aliso Viejo, California, and GeneDx in Gaithersburg, Maryland have offered clinical exome sequencing since 2011.

Deciding which parts of the sequencing data should be divulged to individuals is far from straightforward. A few mutations are clearly associated with disease, but most are still tricky to interpret.

From a research perspective, however, the development is unequivocally exciting, experts say.

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Clinics Offer Expensive Whole-Genome Tests for Undiagnosed Disorders

With the new annotation of the human genome, researchers are finding that most of the code between genes is controlling crucial functions for life and health

iStockphoto/Kalawin

When the draft of the human genome was publishedin 2000, researchers thought that they had obtained the secret decoder ring for the human body. Armed with the code of 3 billion basepairs of As, Ts, Cs and Gs and the 21,000 protein-coding genes, they hoped to be able to find the genetic scaffolds of lifeboth in sickness and in health.

But in the 12 years since then, very few diseasesalmost all of them very rarehave been linked definitively to changes in the genes themselves. And large, genome-wide studies searching for genetic underpinnings for more common diseases, such as lung cancer or autism, have pointed to the nether regions of the genome between the protein-producing genesareas that were often thought to contain junk DNA that was not part of the pantheon of known genes.

An international consortium of hundreds of scientists has now deciphered a large portion of the strange language of this junk DNA and found it to be not junk at all. Rather it contains important signals for regulating our genes, determining disease risk, height and many of the other complex aspects of human biology that make each one of us different. The findings are described in 30 linked papers published online September 5 in Natureand other journals and described at the consortium's Web site. (Scientific Americanis part of Nature Publishing Group.)

Called the Encyclopedia of DNA Elements (ENCODE), the group is focused on understanding not just the elements of the genome but also how they work together. "The complexity of our biology resides not in the number of our genes but in the regulatory switches," Eric Green, director of the National Human Genome Research Institute and collaborator on the ENCODE project, said in a press briefing September 5. Through more than 1,600 separate experiments, analysis of more than 140 cell types and a massive amount of data analysis, the group found about 4 million of these so-called switches and can now assign functions to more than 80 percent of the entire genome. Compare that to the roughly 2 percent of the genome that is responsible for the protein-coding genes that researchers have been relying on to look for diseases and traits. "The genome project was about establishing the set of letters that make up the blueprint," Green said. "When we finally put that blueprint together, we realized we could only really understand very little of it."

These newly catalogued switches not only activate and de-activate genes, but also control how much of each protein gets made and when. They are involved in epigenetic changes, such as DNA methylation, which has been implicated in cardiovascular disease and other conditions. The new data promise to improve our understanding of many common diseases that might have similar genetic underpinnings. Genome-wide association studies (GWAS) have continuously come up short in identifying specific genes for common diseases, John Stamatoyannopoulos, associate professor of genome sciences at the University of Washington School of Medicine and ENCODE collaborator, said in the briefing. "Frustratingly, about 95 percent of information from these studies has been pointing to regions of the genome that do not make proteins," he said. But, now with the ENCODE data, they can begin to decipher what genetic switches and functions might be common within and among these diseases. "We're now exploring previously hidden connections between diseases that may explain similar clinical [symptoms]," he noted.

It will most likely be some time before these new findings, which are freely available, are put to use in approved therapies. "The pharmaceutical industry has largely given up on the genome," Stamatoyannopoulos said. "And I think this is going to tremendously reinvigorate the utility of the genome." These additional genetic elements, however, are already in use for screening and testing for diseases such as breast cancer, prostate cancer and autoimmune diseases, Richard Myers, president of HudsonAlpha Institute for Biotechnology in Ala., noted in the briefing.

The group has funding to continue their efforts and does not anticipate a slowdown in discoveries going forward. "Our blueprint is remarkably complicated, and we need to be committed for the long haul to understand it," Green said. Compared with the publication of draft human genome 12 years agoand with initial findings from the ENCODE project published over the past several years"the questions that we can now ask are more sophisticated," Green said. And hopefully, those better questions will lead to more satisfying and medically useful answers.

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"Junk" DNA Holds Clues to Common Diseases

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