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==<big>'''POEM@HOME'''</big>==
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{{Infobox Project
预测蛋白质结构的项目
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| name =POEM@HOME
<BR>
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| logo =[[Image:POEM_at_HOME_Logo.png|230px]]
POEM@HOME implements a novel approach to understand these aspects of protein structure, which lends itself very well to worldwide distributed computing. The scientific approach behind POEM@HOME is a computational realization of the thermodynamic hypothesis that won C. B. Anfinsen the Nobel Prize in Chemistry in 1972.
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| screenshot =
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| caption =无屏保图形
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| developer =FZK-INT
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| released =2007年10月
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| operating system =Windows/Linux/Mac
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| platform =[[BOINC]]
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| program info =
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| work unit info =
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| status =运行中/开放注册
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| genre =生命科学类
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| optimization =无
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| website =http://boinc.fzk.de/poem/
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}}
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[[POEM@HOME]] implements a novel approach to understand these aspects of protein structure, which lends itself very well to worldwide distributed computing. The scientific approach behind POEM@HOME is a computational realization of the thermodynamic hypothesis that won C. B. Anfinsen the Nobel Prize in Chemistry in 1972.
  
 
POEM@HOME is a purely academic, non-profit projects to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be published in international peer reviewed journals with proper credit to the POEM@HOME volunteers.  
 
POEM@HOME is a purely academic, non-profit projects to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be published in international peer reviewed journals with proper credit to the POEM@HOME volunteers.  
 
<BR><BR>
 
<BR><BR>
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{{JoinBoincProject
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|Project=POEM@HOME
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|URL=http://boinc.fzk.de/poem/
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}}
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==='''Project Detail'''===
 
==='''Project Detail'''===
 
[[Image:Protein-cut.png|right|thumb|The figure illustrates the predicted (red) and the experimental (green) structure of the bacillus suptilus major cold shock protein, an universal nucleic acid binding domain. Such proteins are important for gene regulation under environmental stress.]]
 
[[Image:Protein-cut.png|right|thumb|The figure illustrates the predicted (red) and the experimental (green) structure of the bacillus suptilus major cold shock protein, an universal nucleic acid binding domain. Such proteins are important for gene regulation under environmental stress.]]
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By joining this project you will contribute to a computational approach to
 
By joining this project you will contribute to a computational approach to
 
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*predict the biologically active structure of proteins
    * predict the biologically active structure of proteins
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*understand the signal-processing mechanisms when the proteins interact with one another
    * understand the signal-processing mechanisms when the proteins interact with one another
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*understand diseases related to protein malfunction or aggregation
    * understand diseases related to protein malfunction or aggregation
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*develop new drugs on the basis of the three-dimensions structure of biologically important proteins.
    * develop new drugs on the basis of the three-dimensions structure of biologically important proteins.
 
  
 
POEM@HOME implements a [http://iwrwww1.fzk.de/biostruct/ProteinFolding/psp_main.htm novel approach] to understand these aspects of protein structure, which lends itself very well to [http://boinc.berkeley.edu/ worldwide distributed computing]. The scientific approach behind POEM@HOME is a computational realization of the [http://en.wikipedia.org/wiki/Anfinsen%27s_dogma thermodynamic hypothesis] that won [http://en.wikipedia.org/wiki/Christian_B._Anfinsen C. B. Anfinsen] the Nobel Prize in Chemistry in 1972.
 
POEM@HOME implements a [http://iwrwww1.fzk.de/biostruct/ProteinFolding/psp_main.htm novel approach] to understand these aspects of protein structure, which lends itself very well to [http://boinc.berkeley.edu/ worldwide distributed computing]. The scientific approach behind POEM@HOME is a computational realization of the [http://en.wikipedia.org/wiki/Anfinsen%27s_dogma thermodynamic hypothesis] that won [http://en.wikipedia.org/wiki/Christian_B._Anfinsen C. B. Anfinsen] the Nobel Prize in Chemistry in 1972.
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POEM@HOME is a purely academic, non-profit project to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be [http://iwrwww1.fzk.de/biostruct/People/ww_pub.htm published] in international peer reviewed journals with proper credit to the POEM@HOME volunteers.  
 
POEM@HOME is a purely academic, non-profit project to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be [http://iwrwww1.fzk.de/biostruct/People/ww_pub.htm published] in international peer reviewed journals with proper credit to the POEM@HOME volunteers.  
 
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<br><br>
 
=='''相关链接'''==
 
=='''相关链接'''==
 
*[http://boinc.fzk.de/poem/index.php POEM@HOME官方站点]
 
*[http://boinc.fzk.de/poem/index.php POEM@HOME官方站点]
 
*[http://www.equn.com/forum/viewthread.php?tid=16982&highlight=POEM%40HOME POEM@HOME项目新闻&讨论]
 
*[http://www.equn.com/forum/viewthread.php?tid=16982&highlight=POEM%40HOME POEM@HOME项目新闻&讨论]
 
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<br><br>
 
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[[category:分布式计算项目]][[category:生命科学类项目]][[category:BOINC 平台上的项目]][[category:POEM@HOME]][[category:待翻译]]
[[category:分布式计算项目]][[category:生命科学类项目]][[category:BOINC 平台上的项目]][[category:POEM@HOME]]
 

2009年11月30日 (一) 18:54的版本

POEM@HOME

POEM at HOME Logo.png
POEM@HOME logo

无屏保图形
开发者 FZK-INT
版本历史 2007年10月
运算平台 Windows/Linux/Mac
项目平台 BOINC
程序情况
任务情况
项目状态 运行中/开放注册
项目类别 生命科学类
优化程序
计算特点 CPU密集:

支持0分享率

支持GPU计算

官方网址 POEM@HOME
{{{rss}}} [{{{rss}}} 通过 RSS 获取项目新闻]


POEM@HOME implements a novel approach to understand these aspects of protein structure, which lends itself very well to worldwide distributed computing. The scientific approach behind POEM@HOME is a computational realization of the thermodynamic hypothesis that won C. B. Anfinsen the Nobel Prize in Chemistry in 1972.

POEM@HOME is a purely academic, non-profit projects to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be published in international peer reviewed journals with proper credit to the POEM@HOME volunteers.

如何加入项目

该项目基于 BOINC 平台,简要的加入步骤如下(已完成的步骤可直接跳过):

  1. 下载并安装 BOINC 的客户端软件(官方下载页面程序下载
  2. 点击客户端简易视图下的“Add Project”按钮,或高级视图下菜单中的“工具->加入项目”,将显示向导对话框
  3. 点击下一步后在项目列表中找到并单击选中 POEM@HOME 项目(如未显示该项目,则在编辑框中输入项目网址:http://boinc.fzk.de/poem/ ),然后点击下一步
  4. 输入您可用的电子邮件地址,并设置您在该项目的登录密码(并非您的电子邮件密码)
  5. 再次点击下一步,如项目服务器工作正常(并且有适合自身操作系统的计算程序),即已成功加入项目

更详细的加入方法说明,请访问 BOINC 新手指南BOINC 使用教程

本站推荐您加入 Team China 团队,请访问项目官方网站的 团队检索页面,搜索(Search)并进入 Team China 的团队页面,点击页面中的 Join 并输入用户登录信息即可加入!

Project Detail

The figure illustrates the predicted (red) and the experimental (green) structure of the bacillus suptilus major cold shock protein, an universal nucleic acid binding domain. Such proteins are important for gene regulation under environmental stress.

Proteins are the nanoscale machinery of all the known cellular life. Amazingly, these large biomolecules with up to 100,000 atoms fold into unique three-dimensional shapes in which they function. These functions include all cellular chemistry (metabolism), energy conversion (photosynthesis) and transport (oxygen transport), signal processing in the brain (neurons), immune response and many others, often with an efficiency unmatched by any man-made process. Protein malfunction is often related to diseases and thousands disease-related proteins have been identified to date, many with still unknown structure. To understand, control or even design proteins we need to study protein structure, which is experimentally much harder to obtain than the information about the chemical composition (sequence) of a specific protein.

By joining this project you will contribute to a computational approach to

  • predict the biologically active structure of proteins
  • understand the signal-processing mechanisms when the proteins interact with one another
  • understand diseases related to protein malfunction or aggregation
  • develop new drugs on the basis of the three-dimensions structure of biologically important proteins.

POEM@HOME implements a novel approach to understand these aspects of protein structure, which lends itself very well to worldwide distributed computing. The scientific approach behind POEM@HOME is a computational realization of the thermodynamic hypothesis that won C. B. Anfinsen the Nobel Prize in Chemistry in 1972.

So please help us, by joining POEM@HOME, solve the scientific mysteries described above and decipher the biological information encoded in proteins of unknown structure.

POEM@HOME is a purely academic, non-profit project to improve our understanding of biomolecular structure and function. All substantial result of POEM@HOME will be published in international peer reviewed journals with proper credit to the POEM@HOME volunteers.

相关链接