[Objective] This study aimed to construct the full-length cDNA library for ger- minating seeds of Phyllostachys heterocycla [Method] Germinating seeds of P. hetero- cycla were used as experimental materials to constru...[Objective] This study aimed to construct the full-length cDNA library for ger- minating seeds of Phyllostachys heterocycla [Method] Germinating seeds of P. hetero- cycla were used as experimental materials to construct the full-length cDNA library by using Oligo-capping method. [Result] The constructed library has a total capacity of 6.5×10^6 recombinant clones, and a low proportion of clones without inserted frag- ments; the size of inserted fragments ranges between 0.3-5.0 kb, with strict classifi- cation and ideal consistency. Furthermore, the proportion of clones harboring long in- serted fragments (1.0-5.0 kb) is as high as 30%, achieving the standard for high- quality full-length cDNA library. [Conclusion] The full-length cDNA library of germinat- ing seeds of P. heterocycla was successfully constructed, which laid important foun- dation for the functional genomics research of bamboo plants.展开更多
With the accomplishment of the genome draft sequences, identification of functional elements in genome has become an urgent task. Full-length cDNAs provide an important resource for gene identification and their preci...With the accomplishment of the genome draft sequences, identification of functional elements in genome has become an urgent task. Full-length cDNAs provide an important resource for gene identification and their precise structural feature determination. It also provides a basis for genomic element definition. As many regulatory elements are around transcription start sites(TSSs), precise localization of TSSs in the genome becomes a critical step for identifying the associated core promoters. Massive parallel snapshot of TSSs at a particular time under a specific experimental condition makes it possible to globally analyze important regulatory elements around TSSs and further construct transcriptional regulatory networks. In this paper, we first reviewed two important full-length cDNA cloning techniques: cap-trapper technique and oligo-capping technique. Then,we introduced deepCAGE, a cap-trapper and deep sequencing-based TSS profiling technique, and its applications in the research of transcriptional regulation.展开更多
基金Supported by Specialized Fund for the Basic Research Operating Expenses Program of International Centre for Bamboo and Rattan(163201300812618-7)Special Fund for Research and Development of Forestry Nonprofit Industry(200704001)~~
文摘[Objective] This study aimed to construct the full-length cDNA library for ger- minating seeds of Phyllostachys heterocycla [Method] Germinating seeds of P. hetero- cycla were used as experimental materials to construct the full-length cDNA library by using Oligo-capping method. [Result] The constructed library has a total capacity of 6.5×10^6 recombinant clones, and a low proportion of clones without inserted frag- ments; the size of inserted fragments ranges between 0.3-5.0 kb, with strict classifi- cation and ideal consistency. Furthermore, the proportion of clones harboring long in- serted fragments (1.0-5.0 kb) is as high as 30%, achieving the standard for high- quality full-length cDNA library. [Conclusion] The full-length cDNA library of germinat- ing seeds of P. heterocycla was successfully constructed, which laid important foun- dation for the functional genomics research of bamboo plants.
基金the National Natural Science Foundation of China(Nos.1137420,91129000,21273148,91229108,31370750 and 21303104)the National Basic Research Program(973) of China(No.2010CB529205)
文摘With the accomplishment of the genome draft sequences, identification of functional elements in genome has become an urgent task. Full-length cDNAs provide an important resource for gene identification and their precise structural feature determination. It also provides a basis for genomic element definition. As many regulatory elements are around transcription start sites(TSSs), precise localization of TSSs in the genome becomes a critical step for identifying the associated core promoters. Massive parallel snapshot of TSSs at a particular time under a specific experimental condition makes it possible to globally analyze important regulatory elements around TSSs and further construct transcriptional regulatory networks. In this paper, we first reviewed two important full-length cDNA cloning techniques: cap-trapper technique and oligo-capping technique. Then,we introduced deepCAGE, a cap-trapper and deep sequencing-based TSS profiling technique, and its applications in the research of transcriptional regulation.
