Daily Archives: April 23, 2014

M13 phage genome structure – Video

Posted: April 23, 2014 at 10:43 am


M13 phage genome structure
For more information, log on to- http://shomusbiology.weebly.com/ This M13 phage lecture explains the M13 genome structure and the use of M13 genome in bacte...

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Genome Editing

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Above: The genomes of these twin infant macaques were modified with multiple mutations.

The ability to create primates with intentional mutations could provide powerful new ways to study complex and genetically baffling brain disorders.

The use of a genome-tool to create two monkeys with specific genetic mutations.

The ability to modify targeted genes in primates is a valuable tool in the study of human diseases.

By Christina Larson

Until recently, Kunming, capital of Chinas southwestern Yunnan province, was known mostly for its palm trees, its blue skies, its laid-back vibe, and a steady stream of foreign backpackers bound for nearby mountains and scenic gorges. But Kunmings reputation as a provincial backwater is rapidly changing. On a plot of land on the outskirts of the citywilderness 10 years ago, and today home to a genomic research facilityscientists have performed a provocative experiment. They have created a pair of macaque monkeys with precise genetic mutations.

Last November, the female monkey twins, Mingming and Lingling, were born here on the sprawling research campus of Kunming Biomedical International and its affiliated Yunnan Key Laboratory of Primate Biomedical Research. The macaques had been conceived via in vitro fertilization. Then scientists used a new method of DNA engineering known as CRISPR to modify the fertilized eggs by editing three different genes, and they were implanted into a surrogate macaque mother. The twins healthy birth marked the first time that CRISPR has been used to make targeted genetic modifications in primatespotentially heralding a new era of biomedicine in which complex diseases can be modeled and studied in monkeys.

CRISPR, which was developed by researchers at the University of California, Berkeley, Harvard, MIT, and elsewhere over the last several years, is already transforming how scientists think about genetic engineering, because it allows them to make changes to the genome precisely and relatively easily (see Genome Surgery, March/April). The goal of the experiment at Kunming is to confirm that the technology can create primates with multiple mutations, explains Weizhi Ji, one of the architects of the experiment.

Ji began his career at the government-affiliated Kunming Institute of Zoology in 1982, focusing on primate reproduction. China was a very poor country back then, he recalls. We did not have enough funding for research. We just did very simple work, such as studying how to improve primate nutrition. Chinas science ambitions have since changed dramatically. The campus in Kunming boasts extensive housing for monkeys: 75 covered homes, sheltering more than 4,000 primatesmany of them energetically swinging on hanging ladders and scampering up and down wire mesh walls. Sixty trained animal keepers in blue scrubs tend to them full time.

The lab where the experiment was performed includes microinjection systems, which are microscopes pointed at a petri dish and two precision needles, controlled by levers and dials. These are used both for injecting sperm into eggs and for the gene editing, which uses guide RNAs that direct a DNA-cutting enzyme to genes. When I visited, a young lab technician was intently focused on twisting dials to line up sperm with an egg. Injecting each sperm takes only a few seconds. About nine hours later, when an embryo is still in the one-cell stage, a technician will use the same machine to inject it with the CRISPR molecular components; again, the procedure takes just a few seconds.

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Genome Editing

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Rainbow Trout Genome Sequenced By International Team Of Researchers

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April 22, 2014

By Eric Sorensen, Washington State University

Using fish bred at Washington State University, an international team of researchers has mapped the genetic profile of the rainbow trout, a versatile salmonid whose relatively recent genetic history opens a window into how vertebrates evolve.

The 30-person team, led by Yann Guiguen of the French National Institute for Agricultural Research, reports its findings this week in Nature Communications.

Recent doubling enables study

The investigators focused on the rate at which genes have evolved since a rare genome doubling event occurred in the rainbow trout approximately 100 million years ago. Unlike most evolutionary processes involving mutations and the selection of advantageous traits, a doubling event acts like the copied draft of a piece of writing that can be edited and recast without the risk of destroying the earlier version.

Ordinarily, the consequences of such doubling events are lost to science as they get cast out by selective forces in subsequent generations. But because 100 million years is a relatively short time, evolutionarily speaking, the trout researchers could in effect glimpse the fishs evolutionary editing process.

In humans and most vertebrates the duplication events were older so there are fewer duplicated genes still present, said Gary Thorgaard, a co-author and WSU biologist with four decades of experience peering into the trouts genes. Most of the duplicated genes get lost or modified so much that they are no longer recognizable as duplicates over time. In the trout and salmon we can see an earlier stage in the process and many duplicated genes are still present.

A versatile fish

The rainbow trout, Oncorhynchus mykiss, is one of lifes great success stories. It has straddled the worlds of nature and nurture, naturally thriving in a range of temperatures and water quality while responding to domestication so well that it has been spread by human hand from the Pacific Rim to thrive in waters on six continents.

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9 Ways To Cure Eczema – Video

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9 Ways To Cure Eczema
Read More About It, Here:- http://www.findhomeremedy.com/9-ways-to-cure-eczema/

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How to Shower Eczema Child – More or Less? Video by EczemaBlues – Video

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How to Shower Eczema Child - More or Less? Video by EczemaBlues
Bath, Shower tips for Babies and Children at http://EczemaBlues.com Follow MarcieMom at http://twitter.com/marciemom Quick guide to parents on how to shower ...

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Qu es la psoriasis? – Video

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Qu es la psoriasis?
Buenos das, 16 de abril del 2014.

By: Televisa Tijuana Oficial

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Coloured Paranoa – Psoriasis "Chemical Notes" – Video

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Coloured Paranoa - Psoriasis "Chemical Notes"
Third Track of "Chemical Notes" - Psoriasis Credit: I #39;ve remixed a track named november on is website: http://www.maxrichtermusic.com/en/index.php.

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Psoriatic arthritis affects many people

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People who suffer from psoriasis or have a family history of this skin condition may be at risk for psoriatic arthritis, a serious disease that causes extensive swelling and joint pain.

The Psoriasis and Psoriatic Arthritis Education Center notes that up to 30 percent of people with psoriasis also develop psoriatic arthritis. Psoriasis is an auto-immune skin condition in which the skin reproduces cells at an accelerated rate. This causes patches of flaky, irritated skin, also known as plaques. Psoriatic arthritis can develop at any time, but it is common between the ages of 30 and 50. Environmental factors, genes and immune system responses play a role in the onset of the disease. Patients with psoriatic arthritis can develop inflammation of their tendons, cartilage, eyes, lung lining, and sometimes aorta.

Psoriasis and psoriatic arthritis do not necessarily occur at the same time. Psoriasis generally comes first and then is followed by the joint disease. The skin ailment precedes the arthritis in nearly 80 percent of patients. Psoriatic arthritis is a rheumatic disease that can affect body tissues as well as joints. Psoriatic arthritis shares many features with several other arthritic conditions, such as ankylosing spondylitis, reactive arthritis and arthritis associated with Crohns disease and ulcerative colitis.

The rate of onset of psoriatic arthritis varies among people. For some it can develop slowly with mild symptoms. Others find it comes on quickly and is severe. Symptoms of the disease also vary, but may include the following;

* generalized fatigue

* swollen fingers and toes

* stiffness, pain, throbbing, swelling, and tenderness in joints

* reduced range of motion

* changes in fingernails

* redness and pain of the eyes

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Bioinformatics Profiling Identifies a New Mammalian Clock Gene

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PHILADELPHIA - Over the last few decades researchers have characterized a set of clock genes that drive daily rhythms of physiology and behavior in all types of species, from flies to humans. Over 15 mammalian clock proteins have been identified, but researchers surmise there are more. A team from the Perelman School of Medicine at the University of Pennsylvania wondered if big-data approaches could find them.

To accelerate clock-gene discovery, the investigators, led by John Hogenesch, PhD, professor of Pharmacology and first author Ron Anafi, MD, PhD, an instructor in the department of Medicine, used a computer-assisted approach to identify and rank candidate clock components. This approach found a new core clock gene, which the team named CHRONO. Their findings appear this week in PLOS Biology.

Hogenesch likens their approach to online profiling of movie suggestions for customers: Think of Netflix. Based on your personalized movie profile, it predicts what movies you may want to watch in the future based on what you watched in the past. He thought the team could use this approach to identify new clock genes, given criteria already established from the behavior of known clock genes identified in the past two decades:

Clock genes cause oscillations at the messenger RNA and protein level. Clock proteins physically interact with other clock proteins to form complexes that control daily rhythm inside cells. Disruption of clock genes in cell models cause changes in observable behavioral and metabolic traits on a 24-hour cycle. Clock genes are conserved across 600 million years of evolution from fruitflies to humans.

We used a simple form of machine learning to integrate biologically relevant, genome-scale data and ranked genes based on their similarity to known clock proteins, explains Hogenesch. Using biological big data such as that found in the Circadian Expression Profile Data Base (CircaDB) to search for new clock genes, the Penn team evaluated the features of 20,000 human genes to isolate other genes that have the same clock-gene characteristics. The hypothesis is that other genes that functionally resemble known clock genes are more likely to be clock genes themselves, just like movies that resemble your old favorites are more likely to become new favorites, says Anafi.

They found that several of the genes they identified physically interact with known clock proteins and modulate the daily rhythm of cells. One candidate, dubbed Gene Model 129, interacted with BMAL1, a well-known core clock component, and repressed the key driver of molecular rhythms, the BMAL1/CLOCK protein complex that guides the daily transcription of other proteins in a complicated system of genes that switch on and off over the course of the 24-hour day.

Given these results, the team renamed Gene Model 129, CHRONO, for computationally highlighted repressor of the network oscillator. The litmus test for identifying clock genes, however, is whether they regulate behavior: In mice in which CHRONO had been knocked out, Hogenesch found that the mice had a prolonged circadian period.

A companion study by colleagues at RIKEN in Japan and the University of Michigan, using a genome-wide analysis instead of a machine-learning approach, produced similar findings. Both studies link CHRONO to BMAL1. In the future, Anafi and Hogenesch will be investigating whether CHRONO regulates sleep, as most clock genes influence this behavior.

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Penn Bioinformatics Profiling Identifies a New Mammalian Clock Gene

Posted: at 10:42 am

PHILADELPHIA Over the last few decades researchers have characterized a set of clock genes that drive daily rhythms of physiology and behavior in all types of species, from flies to humans. Over 15 mammalian clock proteins have been identified, but researchers surmise there are more. A team from the Perelman School of Medicine at the University of Pennsylvania wondered if big-data approaches could find them.

To accelerate clock-gene discovery, the investigators, led by John Hogenesch, PhD, professor of Pharmacology and first author Ron Anafi, MD, PhD, an instructor in the department of Medicine, used a computer-assisted approach to identify and rank candidate clock components. This approach found a new core clock gene, which the team named CHRONO. Their findings appear this week in PLOS Biology.

Hogenesch likens their approach to online profiling of movie suggestions for customers: Think of Netflix. Based on your personalized movie profile, it predicts what movies you may want to watch in the future based on what you watched in the past. He thought the team could use this approach to identify new clock genes, given criteria already established from the behavior of known clock genes identified in the past two decades:

We used a simple form of machine learning to integrate biologically relevant, genome-scale data and ranked genes based on their similarity to known clock proteins, explains Hogenesch. Using biological big data such as that found in the Circadian Expression Profile Data Base (CircaDB) to search for new clock genes, the Penn team evaluated the features of 20,000 human genes to isolate other genes that have the same clock-gene characteristics. The hypothesis is that other genes that functionally resemble known clock genes are more likely to be clock genes themselves, just like movies that resemble your old favorites are more likely to become new favorites, says Anafi.

They found that several of the genes they identified physically interact with known clock proteins and modulate the daily rhythm of cells. One candidate, dubbed Gene Model 129, interacted with BMAL1, a well-known core clock component, and repressed the key driver of molecular rhythms, the BMAL1/CLOCK protein complex that guides the daily transcription of other proteins in a complicated system of genes that switch on and off over the course of the 24-hour day.

Given these results, the team renamed Gene Model 129, CHRONO, for computationally highlighted repressor of the network oscillator. The litmus test for identifying clock genes, however, is whether they regulate behavior: In mice in which CHRONO had been knocked out, Hogenesch found that the mice had a prolonged circadian period.

A companion study by colleagues at RIKEN in Japan and the University of Michigan, using a genome-wide analysis instead of a machine-learning approach, produced similar findings. Both studies link CHRONO to BMAL1. In the future, Anafi and Hogenesch will be investigating whether CHRONO regulates sleep, as most clock genes influence this behavior.

This work is supported by the National Institute of Neurological Disorders and Stroke (1R01NS054794-06), the Defense Advanced Research Projects Agency (DARPA-D12AP00025), the American Sleep Medicine Foundation Grant to RCA, the National Institute on Aging (2P01AG017628-11), and the National Heart, Lung, and Blood Institute (5K12HL090021-05). This project is also funded, in part, by the Penn Genome Frontiers Institute under a HRFF grant with the Pennsylvania Department of Health, which disclaims responsibility for any analyses, interpretations or conclusions.

Co-authors are Yool Lee, Trey K. Sato, Anand Venkataraman, Jacqueline P. Growe, Andrew C. Liu, and Junhyong Kim, all from Penn, as well as Chidambaram Ramanathan, University of Memphis; Ibrahim H. Kavakli, Koc University, Istanbul, Turkey; Michael E. Hughes, University of Missouri-St. Louis, and Julie E. Baggs, Morehouse School of Medicine, Atlanta, GA

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Penn Bioinformatics Profiling Identifies a New Mammalian Clock Gene

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