Application of camellia oleifera PAP gene in improvement of phosphorus absorptivity of plants

Application of camellia oleifera PAP gene in improvement of phosphorus absorptivity of plants

The invention belongs to the technical field of gene engineering, and particularly relates to application of a camellia oleifera PAP gene in improvement of phosphorus absorptivity of plants, and the PAP gene is any one of CoPAP1 and CoPAP2; the nucleotide sequence of the CoPAP1 gene is as shown in S...

Ausführliche Beschreibung

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Bibliographische Detailangaben
Hauptverfasser: LIU WENXIN, LIU YANAN, XIAO TAIPING, YE SICHENG
Format: Patent
Sprache:chi ; eng
Schlagworte:
AGRICULTURE
ANIMAL HUSBANDRY
BEER
BIOCHEMISTRY
CHEMISTRY
COMPOSITIONS THEREOF
CULTURE MEDIA
ENZYMOLOGY
FISHING
FORESTRY
HUMAN NECESSITIES
HUNTING
METALLURGY
MICROBIOLOGY
MICROORGANISMS OR ENZYMES
MUTATION OR GENETIC ENGINEERING
NEW PLANTS OR PROCESSES FOR OBTAINING THEM
PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
PROPAGATING, PRESERVING OR MAINTAINING MICROORGANISMS
SPIRITS
TRAPPING
VINEGAR
WINE
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Beschreibung
Zusammenfassung:The invention belongs to the technical field of gene engineering, and particularly relates to application of a camellia oleifera PAP gene in improvement of phosphorus absorptivity of plants, and the PAP gene is any one of CoPAP1 and CoPAP2; the nucleotide sequence of the CoPAP1 gene is as shown in SEQ ID1; the nucleotide sequence of the CoPAP2 gene is as shown in SEQ ID 2. CoPAP1 and CoPAP2 genes are cloned and are subjected to construction of a fusion GFP expression vector, real-time fluorescence quantification (qRT-PCR) is utilized to reveal an expression mode of responding to low phosphorus stress, and the phosphorus absorption capacity of arabidopsis thaliana is improved by transforming arabidopsis thaliana. 本发明属于基因工程技术领域,具体为油茶PAP基因在提高植物磷吸收性中的应用,所述PAP基因为CoPAP1、CoPAP2中的任一个;所述CoPAP1基因的核苷酸序列如SEQ ID1所示;所述CoPAP2基因的核苷酸序列如SEQ ID2所示。通过克隆CoPAP1、CoPAP2基因,并对其进行融合GFP表达载体的构建,利用实时荧光定量(qRT-PCR)揭示其响应低磷胁迫的表达模式,通过转化拟南芥提高了拟南芥的磷吸收能力。