From e34e7da50fc0ff5ed41e8bdaf2b1d41c9e9cf534 Mon Sep 17 00:00:00 2001 From: Bonface Date: Thu, 15 Feb 2024 06:09:54 -0600 Subject: Update dataset RTF Files. --- general/datasets/B139_K_1206_R/experiment-design.rtf | 3 --- 1 file changed, 3 deletions(-) delete mode 100644 general/datasets/B139_K_1206_R/experiment-design.rtf (limited to 'general/datasets/B139_K_1206_R/experiment-design.rtf') diff --git a/general/datasets/B139_K_1206_R/experiment-design.rtf b/general/datasets/B139_K_1206_R/experiment-design.rtf deleted file mode 100644 index b80f1da..0000000 --- a/general/datasets/B139_K_1206_R/experiment-design.rtf +++ /dev/null @@ -1,3 +0,0 @@ -
A typical genetical genomics experiment results in four separate data sets; genotype, gene expression, higher-order phenotypic data and metadata that describe the protocols, processing and the array platform. Used in concert, these data sets provide the opportunity to perform genetic analysis at a systems level. Their predictive power is largely determined by the gene expression dataset where tens of millions of data points can be generated using currently available mRNA profiling technologies. Such large, multidimensional data sets often have value beyond that extracted during their initial analysis and interpretation, particularly if conducted on widely distributed reference genetic materials. Besides quality and scale, access to the data is of primary importance as accessibility potentially allows the extraction of considerable added value from the same primary dataset by the wider research community. Although the number of genetical genomics experiments in different plant species is rapidly increasing, none to date has been presented in a form that allows quick and efficient on-line testing for possible associations between genes, loci and traits of interest by an entire research community.
- -By integrating barley genotypic, phenotypic and mRNA abundance data sets directly within GeneNetwork's analytical environment we provide simple web access to the data for the research community. In this environment, a combination of correlation analysis and linkage mapping provides the potential to identify and substantiate gene targets for saturation mapping and positional cloning. By integrating datasets from an unsequenced crop plant (barley) in a database that has been designed for an animal model species (mouse) with a well established genome sequence, we prove the importance of the concept and practice of modular development and interoperability of software engineering for biological data sets.
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