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2017Äê01ÆÚ

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26-29

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2017-01-05

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Title:

Cloning and sequence analysis of DHQ/SDH gene in pomegranate peel

×÷Õß:

·ëÁ¢¾ê¹;  ½¹ÆäÇì¹;  ÒüÑàÀ×¹;  Àî¼×Áº²

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Author(s):

Feng Lijuan; et al

¹Ø¼ü´Ê:

ʯÁñ; DHQ/SDH»ùÒò; ¿Ë¡; ÐòÁзÖÎö

Keywords:

-

·ÖÀàºÅ:

S665.401£»Q785

DOI:

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ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

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Abstract:

-

²Î¿¼ÎÄÏ×/References:

£Û1£ÝZhao X E£¬Yuan Z H£¬Feng L J£¬et al. Cloning and expression of anthocyanin biosynthetic genes in red and white pomegranate£ÛJ£Ý. Journal of Plant Research£¬2015£¬128(4)£º687-696.
£Û2£ÝSchuck A G£¬Weisburg J H£¬Esan H£¬et al. Cytotoxic and proapoptotic activities of gallic acid to human oral cancer HSC-2 cells£ÛJ£Ý. Oxidants and Antioxidants in Medical Science£¬2013£¬2(4)£º265-274.
£Û3£ÝQiu X B£¬Takemura G£¬Koshiji M£¬et al. Gallic acid induces vascular smooth muscle cell death via hydroxyl radical production£ÛJ£Ý. Heart and Vessels£¬2000£¬15(2)£º90-99.
£Û4£ÝZaidi-Yahiaoui R£¬Zaidi F£¬Bessai A A. Influence of gallic and tannic acids on enzymatic activity and growth of Pectobacterium chrysanthemi(Dickeya chrysanthemi bv. chrysanthemi)£ÛJ£Ý. African Journal of Biotechnology£¬2008£¬7(4)£º482-486.
£Û5£ÝKhalil R S. Influence of gallic acid and catechin polyphenols on probiotic properties of Streptococcus thermophilus CHCC 3534 strain£ÛJ£Ý. World Journal of Microbiology and Biotechnology£¬2010£¬26(11)£º2069-2079.
£Û6£Ý·ëÁ¢¾ê£¬ÒüÑàÀ×£¬ÕÐÑ©Ç磬µÈ. ʯÁñûʳ×ÓËá´úлÓë±£½¡¹¦ÄÜÑо¿½øÕ¹£ÛJ£Ý. ¹ûÊ÷ѧ±¨£¬2014£¬31(4)£º710-716.
£Û7£ÝWerner R A£¬Rossmann A£¬Schwarz C£¬et al. Biosynthesis of gallic acid in Rhus typhina£ºdiscrimination between alternative pathways from natural oxygen isotope abundance£ÛJ£Ý. Phytochemistry£¬2004£¬65(20)£º2809-2813.
£Û8£ÝOssipov V£¬Salminen J P£¬Ossipova S£¬et al. Gallic acid and hydrolysable tannins are formed in birch leaves from an intermediate compound of the shikimate pathway£ÛJ£Ý. Biochemical Systematics and Ecology£¬2003£¬31(1)£º3-16.
£Û9£ÝSingh S A£¬Christendat D. The DHQ-dehydroshikimate-SDH-shikimate-NADP(H) complex£ºinsights into metabolite transfer in the shikimate pathway£ÛJ£Ý. Crystal Growth & Design£¬2007£¬7(11)£º2153-2160.
£Û10£ÝSingh S A£¬Christendat D. Structure of arabidopsis dehydroquinate dehydratase-shikimate dehydrogenase and implications for metabolic channeling in the shikimate pathway£ÛJ£Ý. Biochemistry£¬2006£¬45(25)£º7787-7796.
£Û11£ÝMagalh¢‚es M B£¬Pereira C P£¬Basso L A£¬et al. Cloning and expression of functional shikimate dehydrogenase (EC 1.1.1.25) from Mycobacterium tuberculosis H37Rv£ÛJ£Ý. Protein Expression and Purification£¬2002£¬26(1)£º59-64.
£Û12£ÝZhang X L£¬Zhang S B£¬Hao F£¬et al. Expression£¬purification and properties of shikimate dehydrogenase from Mycobacterium tuberculosis£ÛJ£Ý. Journal of Biochemistry and Molecular Biology£¬2005£¬38(5)£º624-631.
£Û13£ÝKubota T£¬Tanaka Y£¬Hiraga K£¬et al. Characterization of shikimate dehydrogenase homologues of Corynebacterium glutamicum£ÛJ£Ý. Applied Microbiology and Biotechnology£¬2013£¬97(18)£º8139-8149.
£Û14£ÝDeka R K£¬Anton I A£¬Dunbar B£¬et al. The characterisation of the shikimate pathway enzyme dehydroquinase from Pisum sativum£ÛJ£Ý. FEBS Letters£¬1994£¬349(3)£º397-402.
£Û15£ÝDing L£¬Hofius D£¬Hajirezaei M R£¬et al. Functional analysis of the essential bifunctional tobacco enzyme 3-dehydroquinate dehydratase/shikimate dehydrogenase in transgenic tobacco plants£ÛJ£Ý. Journal of Experimental Botany£¬2007£¬58(8)£º2053-2067.
£Û16£ÝBischoff M£¬Schaller A£¬Bieri F£¬et al. Molecular characterization of tomato 3-dehydroquinate dehydratase-shikimate£ºNADP oxidoreductase£ÛJ£Ý. Plant Physiology£¬2001£¬125(4)£º1891-1900.
£Û17£ÝHan J W£¬Lee K P£¬Yoon M£¬et al. Cold stress regulation of a bi-functional 3-dehydroquinate dehydratase/shikimate dehydrogenase (DHQ/SDH)-like gene in the freshwater green alga Spirogyra varians£ÛJ£Ý. Botanica Marina£¬2009£¬52(2)£º178-185.
£Û18£ÝTzin V£¬Galili G. New insights into the shikimate and aromatic amino acids biosynthesis pathways in plants£ÛJ£Ý. Molecular Plant£¬2010£¬3(6)£º956-972.

ÏàËÆÎÄÏ×/References:

[1]ÌÕ¼ªº®,ÕÐÑ©Çç,Ô·Õ׺Í,µÈ.ʯÁñDFR»ùÒòµÄͬԴ¿Ë¡¼°·ÖÎö[J].½­ËÕÅ©Òµ¿Æѧ,2013,41(04):22.
[2]¹ùÎÄçù,ÕÅÅàͨ,Àî´ººê,µÈ.Ñغ£Ì²Í¿ÂÌ»¯Ê÷ÖÖÑ¡ÔñºÍÄÍÑÎÐÔÆÀ¼Û[J].½­ËÕÅ©Òµ¿Æѧ,2014,42(10):175.
¡¡Guo Wenqi,et al.Selection and evaluation on salt tolerance of gardening tree species in coastal beach areas[J].Jiangsu Agricultural Sciences,2014,42(01):175.
[3]³Â³É,ÍôºéÌÎ.ɽé«Ê¯Áñ¸´ºÏ¹û¾Æ·¢½Í¹¤ÒÕµÄÑо¿[J].½­ËÕÅ©Òµ¿Æѧ,2013,41(07):248.
¡¡Chen Cheng,et al.Study on fermentation technology of hawthorn and pomegranate compound fruit wine[J].Jiangsu Agricultural Sciences,2013,41(01):248.
[4]µËÖ¾ÓÂ,Îâ¹ðÈÝ,Ñî³ÌÏÔ.Æê³È-ʯÁñ¸´ºÏ¹û¾ÆÄðÔ칤ÒÕµÄÑо¿[J].½­ËÕÅ©Òµ¿Æѧ,2015,43(02):266.
¡¡Deng Zhiyong,et al.Study on brewing technology of compound wine of navel orange and pomegranate[J].Jiangsu Agricultural Sciences,2015,43(01):266.
[5]·¶´ºÀö,ÂÞÇà.¸ÉºµÐ²ÆÈÏÂÍâÔ´Ìð²Ë¼î¶ÔʯÁñ¹âºÏ×÷Óá¢Éø͸µ÷½Ú¼°±£»¤Ã¸»îÐÔµÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(11):229.
¡¡Fan Chunli,et al.Effects of exogenous glycinebetaine on photosynthesis£¬osmotic adjustment ability and protective enzyme activity of Punica granatum under drought stress[J].Jiangsu Agricultural Sciences,2016,44(01):229.
[6]³º£¾Õ,ÀîºÓ,Ê·ÊçÁx,µÈ.ÔÆÄÏʡʯÁñ¸É¸¯²¡²¡¾úÉúÎïѧÌØÐÔ¼°Æä·ÀÖÎÒ©¼Áɸѡ[J].½­ËÕÅ©Òµ¿Æѧ,2017,45(01):99.
¡¡Lu Haiju,et al.Study on biological characteristics of pathogen of pomegranate dry rot from Yunnan Province and its control fungicides[J].Jiangsu Agricultural Sciences,2017,45(01):99.
[7]²ÜÉÐÒø,Å£¾ê,ÕŽÜ,µÈ.2ÖÖµ°°×ÖÊ×éѧ·½·¨ÔÚʯÁñÖеÄÓ¦ÓñȽÏ[J].½­ËÕÅ©Òµ¿Æѧ,2017,45(20):68.
¡¡Cao Shangyin,et al.A comparative study on application of two proteomics methods in pomegranate[J].Jiangsu Agricultural Sciences,2017,45(01):68.
[8]ÖÜÒøÀö,¹ù½¨Î°,Ñîΰ,µÈ.¼ä×÷ÌÒÊ÷¶ÔʯÁñÔ°¿Ýή²¡ÍÁÈÀ̼´úл¶àÑùÐÔµÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2018,46(14):106.
¡¡Zhou Yinli,et al.Influences of intercropping peach trees on fusarium wilt soil carbon metabolism diversity in pomegranate garden[J].Jiangsu Agricultural Sciences,2018,46(01):106.
[9]Íõ˶,ÀîµÂÉú,ÖìÐã½õ,µÈ.ʯÁñ¶ÔïÓ¡¢Ç¦¡¢Ð¿¸´ºÏÎÛȾÍÁÈÀµÄÐÞ¸´Ð§¹û[J].½­ËÕÅ©Òµ¿Æѧ,2019,47(02):250.
¡¡Wang Shuo,et al.Remediation effect of pomegranate on Cd£¬Pb and Zn combined pollution soil[J].Jiangsu Agricultural Sciences,2019,47(01):250.
[10]·½Çì.²»Í¬ÇïË®ÏÉËØ´¦Àí¶ÔʯÁñÖÖ×Ó·¢Ñ¿¼°Ó×ÃçÉú³¤µÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2019,47(19):142.
¡¡Fang Qing.Effects of different colchicine treatments on seed germination and seedling growth of pomegranate species[J].Jiangsu Agricultural Sciences,2019,47(01):142.

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