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¡¶±±·½Ô°ÒÕ¡·[ISSN:1001-0009/CN:23-1247/S]

Issue:

2017Äê15

Page:

7-12

Research Field:

Publishing date:

Info

Title:

Effect of Exogenous Hydrogen Sulfide on Resistance of ª¤ Drought Stress of Chestnut Seedlings

Author(s):

SUN Xiaoli1; ZHANG Xinrong2; TIAN Shoule1; SHEN Guangning1; XU Lin1

(1.Shandong Institute of Pomology£¬Tai¡äan£¬Shandong 271000£»2.Dongying City Kenley Area Forestry Bureau£¬Dongying£¬Shandong 257041)ª¤

Keywords:

chesnut; NaHS; drought stress

PACS:

-

DOI:

10.11937/bfyy.20165060

Abstract:

One-year-old seedling of chestnut ¡®Huangpeng¡¯was used as test material£¬a hydroponic experiment was carried out to study the effects of exogenous hydrogen sulfide at the concentration of 0.5 mmol?L-1 and 1.0 mmol?L-1 on the chlorophyll content under 15%PEG stress£¬malondialdehyde(MDA)£¬proline(Pro) and the activities of antioxidant enzymes of chesnut seedlings were studied£¬to investigate the related mechanisms of exogenous hydrogen sulfide regulation of drought stress of chesnut.The results showed that under drought stress spraying exogenous hydrogen sulfide obviously reduced the content of MDA£¬and significantly increased the contents of chlorophyll and proline£¬and the activities of SOD£¬POD£¬CAT.The previous evidence showed that exogenous hydrogen sulfide was favorable to decrease the damage degree of cell membrane under drought stress£¬which enhance the ability of resisting drought stress in chenut leaves.0.5 mmol?L-1 NaHS concentration was better.

References:

 

[1]ÌïÊÙÀÖ,Éò¹ãÄþ,ÐíÁÖ,µÈ.²»Í¬½ÚË®¹à¸È·½Ê½¶Ô¸ÉºµÉ½µØ°åÀõÉú³¤½áʵµÄÓ°Ïì[J].Ó¦ÓÃÉú̬ѧ±¨,2012,23(3)£º639-644.ª¤

[2]RHIZOPOULOU S£¬PSARAS G K.Development and structure of drought-tolerant leaves of the Mediterranean shrubª« Capparis spinosaª« L.[J].Ann Bot,2003,92:377-383.ª¤

[3]SRIVASTAVA A K£¬LOKHANDE V H£¬PATADE V Y£¬et al.Comparative evaluation of hydro-£¬chemo-,and hormonal-priming methods for imparting salt and PEG stress tolerance in Indian mustard (ª«Brassica junceaª« L.)[J].Acta Physiol Plant,2010,32:1135-1144.ª¤

[4]ZHANG H£¬JIAO H£¬JIANG C X£¬et al.Hydrogen sulfide protects soybean seedlings against drought-induced oxidative stress[J].Acta Physiologiae Plantarum,2010,32(5):849-857.ª¤

[5]ZHANG H£¬YE Y K£¬WANG S H£¬et al.Hydrogen sulfide counteracts chlorophyll loss in sweet potato seedling leaves and alleviates oxidative damage against osmotic stress[J].Plant Growth Regulation,2009,58(3):243-250.ª¤

[6]JIN Z P£¬SHEN J J£¬QIAO Z J£¬et al.Hydrogen sulfide improves drought ristance in ª«Arabidopsis thalianaª«[J].Biochem Biophys Res Commun,2011,414(3):481-486.ª¤

[7]µ¥³¤¾í,ÕÔÔªÔö.ÍâÔ´Áò»¯Çâ¶Ô¸ÉºµÐ²ÆÈÏÂÓñÃ×Ó×ÃçË®·ÖÉúÀíÌØÐÔµÄÓ°Ïì[J].¸ÉºµµØÇøÅ©ÒµÑо¿,2015,33(5):80-84.ª¤

[8]ÀîºÏÉú.Ö²ÎïÉúÀíÉú»¯ÊµÑéÔ­ÀíºÍ¼¼Êõ[M].±±¾©:¸ßµÈ½ÌÓý³ö°æÉç,2003.ª¤

[9]BAILLY C£¬BENAMAR A£¬CORBINEAU F£¬et al.Changes in malondialdehyde content and in superoxide dismutase£¬catalase and glutathione reductase activities in sunflower seed as related to deterioration during accelerated aging[J].Plant Physio,1996,197:104-110.ª¤

[10]Åá×Úƽ,ÓàÀòÁÕ,ÍôÔƼ×,µÈ.4ÖָɺµÇøÉú̬ÐÞ¸´Ö²ÎïµÄÃçÆÚ¿¹ºµÐÔÑо¿[J].¸ÉºµÇø×ÊÔ´Óë»·¾³,2014,28(3)£º204-208.ª¤

[11]KISHORE K,MONG Z,MIAO G H,et al.Overexpression of pyrroline-5-carboxy-latesynt hetase increases proline production and confers osmotolerance in transgenic plants[J].Plant Physiology,1995,108(4)£º1387-1394£®ª¤

[12]ÀîÓÀÉú,·½ÓÀ·á,Àî«h,µÈ.ÍâÔ´Áò»¯Çâ¶ÔPEGÄ£Äâ¸ÉºµÐ²ÆÈÏÂÓñÃ×ÖÖ×ÓÃÈ·¢¼°Ó×ÃçÉú³¤µÄÓ°Ïì[J].ºËũѧ±¨,2016,30(4):813-821.ª¤

[13]ÑÕÊçÔÆ,ÖÜÖ¾Óî,×ÞÀöÄÈ,µÈ.¸ÉºµÐ²ÆȶÔ×ÏËë»±Ó×ÃçÉúÀíÉú»¯ÌØÐÔµÄÓ°Ïì[J].¸ÉºµÇøÑо¿£¬2011,28(1):139-144.ª¤

[14]ÖÜÁá,ÍõÄ˽­.¸ÉºµÐ²ÆÈÏÂÎĹڹûÓ×ÃçҶƬµÄÉúÀíÏìÓ¦[J].Î÷±±ÁÖѧԺѧ±¨,2012,27(3):7-11.ª¤

[15]YORDANOVA R Y£¬CHRISTOV K N£¬PETROVA L P.Antioxidative enzymes in barley plants subjected to soil flooding[J].Environmental and Experimental Botany,2004,51:93-101.ª¤

[16]½ðÖÒÃñ,ɳΰ,ê°Íþ,µÈ.¸ÉºµÐ²Æȶ԰×ÈýÒ¶Ó×Ãç±£»¤Ã¸µÄÓ°Ïì[J].¶«±±ÁÖÒµ´óѧѧ±¨,2010,38(7):52-53.

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