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2014 | 36 | 10 |

Tytuł artykułu

The responses of spatial situation, surface structure characteristics of leaves and sensitivity of two local rice cultivars to enhanced UV-B radiation under terraced agricultural ecosystem

Autorzy

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
Under the situ terraced field experiments, effects of artificial UV-B radiation enhancement (0, 2.5, 5.0, 7.5 kJ m⁻²) on spatial situation and surface structure of leaves and responses index of two local cultivars rice (Oryza sativa L.)—Yuelianggu and Baijiaolaojin in Yuanyang County, China in shooting stage were studied. The results showed that: (1) due to the enhanced UV-B radiation, leaf apex–base distance, leaf pedestal height, leaf rolling degree and wax content in leaves increased, while leaf apex–stem distance, distance between leaves and leaf angle decreased. The response index of growth was positive when UV-B levels were 2.5 and 5.0 kJ m⁻², which showed some adaptation. (2) The enhanced UV-B radiation resulted in smaller stomata with higher density and more papilla for both rice cultivars. (3) The enhanced UV-B radiation also leaded to larger silica cells and significantly increases the amount of papilla, spike and epidermal hair for both rice cultivars. (4) Yuelianggu cultivar showed an excellent adaptation on the aspect of spatial situation with UV-B radiation of 2.5 and 5.0 kJ m⁻², while Baijiaolaojin exhibited better adaptation respecting the surface structure of leaves when UV-B was 2.5 kJ m⁻². By changing spatial situation of leaves, structure and density of stomata, and non-stomatal structures (wax layer, silica cell, cork cell, papilla, spike and epidermal hair), two self-retention rice cultivars could adapt to the increased UV-B radiation. On the aspect of the response index, Baijiaolaojin showed better adaptation than Yuelianggu did when the UV-B was 2.5 kJ m⁻².

Słowa kluczowe

Wydawca

-

Rocznik

Tom

36

Numer

10

Opis fizyczny

p.2755-2766,fig.,ref.

Twórcy

autor
  • College of Resources and Environment, Yunnan Agricultural University, Kunming, 650201, People’s Republic of China
autor
  • College of Resources and Environment, Yunnan Agricultural University, Kunming, 650201, People’s Republic of China
autor
  • College of Resources and Environment, Yunnan Agricultural University, Kunming, 650201, People’s Republic of China
autor
  • College of Resources and Environment, Yunnan Agricultural University, Kunming, 650201, People’s Republic of China

Bibliografia

  • Allen LH, Gausman HW, Allen WA (1975) Solar ultraviolet radiation in terrestrial plant communities. Environ Qual 4:285–294
  • An LZ, Feng HY, Wang XL (2001) Effects of The enhanced UV-B radiation on the growth of some crops. Acta Ecol Sin 21(2): 249-153
  • Bao LL, He YM, Zu YQ, Li Y, Gao GX, He YZ (2013) Effects of the enhanced UV-B radiation on the leaf morphology and anatomical structure of two local rice varieties in Yuanyang terraced fields, Yunnan Province of southwest China. Chin J Ecol 32(4):882–889
  • Barnes PW, Shinkle JR, Flint SD, Ryel RJ (2005) UV-B radiation photomorphogensis and plant-plant interaction. Prog Bot 66:313–340
  • Bei JH, Wang KR, Chu ZD, Chen B, Li SK (2005) Comparative study on the measure methods of the leaf area. J Shihezi Uni (Natural Sci) 23(2):216–218
  • Biggs RH, Kouthus SV (1978) Effects of ultraviolet-B radiation enhancements under field condition. UV-B biological and climate effects research (BACER)
  • Bourdenx B, Bemard A, Domergue F, Pascal S, Leger A, Roby D, Pervent M, Vile D, Haslam RP, Napier JA, Joubes J (2011) Overexpression of Arabidopsis EC promotes wax very-longchain alkane biosynthesis and influences plant response to biotic and abiotic stresses. Plant Physiol 156:29–45
  • Caldwell MM, Ballare CL, Bornman JF, Flint SD, Björn LO, Teramura AH, Kulandaivelu G, Tevini M (2007) Terrestrial ecosystems, increased solar ultraviolet radiation, and interactions with other climate change factors. Photochem Photobiol Sci 6(3):252–266
  • Cao X, Xia HP, Peng SL (2007) Effects of the enhanced UV-B radiation on plants. Ecol Environ 16(3):1044–1052
  • Coleman RS, Day TA (2004) Response of cotton and sorghum to several levels of subambient solar UV-B radiation: a test of the saturation hypothesis. Physiol Plant 122:362–372
  • Correia CM, Coutinho JF, Bacelar EA, Goncalves BM, Bjorn LO (2012) Ultraviolet-B radiation and nitrogen affect nutrient concentrations and the amount of nutrients acquired by aboveground organs of maize. Sci World J. doi:10.1100/2012/608954
  • Dai Q, Peng SB, Chavea AQ, Vergara BS (1994) Intraspecific responses of 188 rice cultivars to the enhanced UV-B radiation. Environ Exp Bot 34:433–442
  • Day TA, Vogelmann TC, Delucia EH (1992) Are some plant life forms more effective than others in screening out ultraviolet-B radiation.Ecologies 92: 513-519
  • Deng SF (2008) Chin a hybrid Japonica rice. China Agriculture Press, Beijing
  • Feng HY, Xu SA, An LZ, Liu ZJ, Wang XL (2001) Effects of increased UV-B radiation on seed germination and seedlings growth of eight cultivars of Glycine max. Acta Bat Boreal Occident Sin 21(1):14–20
  • Gao D, Mao RZ, Zhu YY (2010) Comparative analysis of intravarietal heterogeneity between rice landraces and improved varieties. Mol Plant Breed 8(3):432–438
  • Gao XX, Gao ZH, Zu YQ, Chen JJ, Li Y (2009) Effects and mechanism of UV-B radiation on rice growth. J Anhui Agric Sci 37(26):12447–12450, 12524
  • Gausman HW, Rodriguez RR, Escobar DE (1975) Ultraviolet radiation reflectance, transmittance, and absorptance by plant leaf epidermises. Agron J 67(5):720–724
  • He YM, Zhan FD, Gao ZH, Zu YQ, Li Y (2012) Differences of UV-B radiation sensitivity of rice. Ecol Environ 21(3):489–495
  • He YM, Zhan FD, Zu YQ, Liu C, Li Y (2014) Effect of elevated UV-B radiation on the antioxidant system of two rice landrace in paddy field on Yuanyang terrace. Int J Agric Biol 16(3):585–590
  • Hidema J, Kumagai T (2006) Sensitivity of rice to ultraviolet-B radiation. Ann Bot 97(6):933–942
  • Hou YJ (2007) An investigation on the origination of Honghe Hani terraced fields. Nankai J 3(53–61):112
  • Hu N, Yao KM, Zhang XC, Lu CG (2011a) Effect and simulation of plant type on canopy structure and radiation transmission in rice. Chin J Rice Sci 25(5):535–543
  • Hu Y, Chu HJ, Li JQ (2011b) Response of leaf anatomy characteristics and its plasticity to different soil-water conditions of Medicago rathenica in four populations. Plant Sci J 29(2):218–225
  • Jiao JY, Yin CY, Chen K (2011) Effects of soil water and nitrogen supply on the photosynthetic characteristics of Jatropha curcas seedlings. Chin J Plant Ecology 35(1):91–99
  • Kakani VG, Reddy KR, Zhao D, Sailaja K (2003) Effect of UV-B radiation on cotton (Gossypium hirsutum L) morphology and anatomy. Ann Bot 91(77):817–826
  • Kolattukudy PE (1996) Biosynthetic pathways of cutin and waxes and their sensitivity to environmental stresses. G. kerstiens. Plant cuticles. BIOS Scientific Publishers, Oxford, pp 83–108
  • Kosma DK, Bourdenx B, Bernard A, Parsons EP, Lu SY, Joubes J, Jenks MS (2009) The impact of water deficiency on leaf cuticle lipids of Arabidopsis. Plant Physiol 151:1918–1929
  • Kostina E, Wulff Atutto RJ (2001) Growth, structure, response and secondary metabolites of birch seedlings (Betula pendula) under elevated UV-B radiation in the field. Trees 15:483–491
  • Laposi R, Veres S, Lakatos G, Olah V, Fieldsend A, Meszaros I (2009) Responses of leaf traits of European beech (Fagus sylvatica L.) saplings to supplemental UV-B radiation and UV-B exclusion. Agric Forest Meteor 149:745–755
  • Li FL, Bao WK (2005) Responses of the morphological and anatomical structure of the plant leaf to environmental change. Chin Bull Bot 22(B08):118–127
  • Li Y, Wang XL (1998) The effect of the enhanced UV-B radiation on the physiological indicator, yield and quality of wheat. Acta Sci Circumst 18(5):504–509
  • Li ZL (1996) Plant tissue biopsies. Beijing University Press, Beijing
  • Liu M (2008) An introduction to spermatophyte morphology and anatomy. Science Press, Beijing
  • Mariani C, Wolters M (2000) Complex waxes. Plant Cell 12:1795–1798
  • Mckenzier CB, Bodeker G (1999) Increased summer time UV-B radiation in New Zealand in response to ozone loss. Sci 285:1709–1711
  • Pan CH, Li L, Chen ZX, Xue X, Zhang YF, Zuo SM, Dai ZY, Pan XB, Ma YY (2011) Fine mapping of a rolled leaf gene S511.03 in rice. Chin J Rice Sci 25(5):455–460
  • Rozema J, Van De SJ, Tosserams M (1997) Effects of UV-B radiation on plants from agro and natural ecosystem.In:Lumsden PJ (ed) Plants and UV-B responses to environmental change. Cambridge University Press, Cambridge, pp 213–232
  • Shepherd RG, Grifiths DA, Bircht NE, Ducan G (1995) Effects of environment on the composition of epicuticular wax from Kale and Swede. Phytochem 40:407–417
  • Sieber P, Schorderet M, Ryser U, Et AL (2000) Transgenic Arabidopsis plants expressing a fungal cutinase show alterations in the structure and properties of the cuticle and postgenital organ fusion. Plant Cell 12:721–737
  • Singh S, Kumari R, Agrawal M, Agrawal SB (2009) Modification of growth and yield responses of amaranthus tricolor to UV-B under varying mineral nutrient supply. Sci Hortic 120(2): 173–180
  • The Yuanyang County Annals Compiling Committee of Yunnan Province (1990) Yuanyang county annals. Guizhou Minorties Press, Guiyang
  • Wang HX, Liu WZ (2011) Effects of the enhanced UV-B radiation on leaf morphology and structure and pigment contents of Camptotheca acuminate. Chin Agric Sci Bull 27(5):209–213
  • Wei CX, Xie PS, Zhou WD, Chen YF, Zhang J, Huai HY (2008) Comparison of preparing slice techniques of convexo-concave leaf epidermis. J Biol 25(2):63–66
  • Wu XC, Lin WX, Huang ZL (2007) Influence of enhanced ultraviolet-B radiation on photosynthetic physiologies and surface structure of leaves in two different resistivity rice cultivars. Acta Ecol Sin 27(2):554–564
  • Yan HQ, Li Q (2008) Study on naturalist hani’s Rice cultivation and its sustainable development. Agric Hist China 3:33–44
  • Yang BY, Chen XF, Liu XD, Guo HB (2006) Observation of silicon cells on the leave surface in different varieties of rices. J Chin Electron Microsc Soc 25(2):146–150
  • Zepp RG, Erickson DJ, Paul ND (2007) Interactive effects of solar UV radiation and climate change on biogeochemical cycling. Photochem Photobiol Sci 6:286–300
  • Zhang FC, Zheng YF, He YH, Wang CH (2003) Effect of enhanced UV-B radiation on wheat. J Nanjing Inst Meteor 26(4):545–551
  • Zhang JY, Qiu ZB, Wang XL, Yue M (2007) Physiological and biochemical changes in the petal of Petunia hybrida exposed to enhanced ultraviolet-B radiation. Acta Bat Boreal Occident Sin 28(8):37–42
  • Zhang LP, Zhang LB (1990) Observation on leaf structure of rice. J Chin Electron Microsc Soc 9:43
  • Zhang WX (1995) The observation of sub aerostructure on leaves-back in Oryza. Chin J Rice Sci 9(2):71–76
  • Zhang YC, Yan TZ (2003) Study on relationship between anatomical structure of leaves of Karelinia capsis (Pall) Less and ecological environment. J Ningxia Agric Coll 8(1):31–33
  • Zhao P, Zeng XP, Sun GC (2004) A review: response of terrestrial plants to enhanced UV-B radiation. Chin J Appl Environ Biol 10:122–127
  • Zheng YF, Yan JY, Wan CJ, Huang JD (1996) Effects of enhanced ultraviolet radiation on crops and its counter measures. Chin J Agrometeor 17(4):51–53
  • Zhou XY, Chen XB, Xu X, Li LL, Zou J, Gao GF (2007) On comparison of extraction methods of epicuticular wax and content of rice leaves. J Hunan Agric Univ 33(3):273–276

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

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