PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
1997 | 19 | 3 |

Tytuł artykułu

Differences in drought tolerance between cultivars of field bean and field pea. A comparison of drought-resistant and drought-sensitive cultivars

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
Relatively little research has been conducted to determine different responses to drought among cultivars of the legume species. The objective of this study was to identify differences in seedlings growth, water relations and leaf conductances resulting from drought imposed on two field bean and two field pea cultivars that had been observed to differ in their drought tolerances, and special emphasis was placed on the root system development. Distinct differences between resistant and sensitive cultivars of field bean and field pea became evident in measurements of the characteristics of the lateral root. The drought treatment induced statistically significant decrease in the number of the developed laterals, their total length and dry matter. In the drought resistant cultivars (field bean Gobo and field pea Solara) this reduction was smaller in comparison with sensitive ones (field bean Victor and field pea Bareness). The effect of drought on growth of tap root in the drought resistant and drought sensitive cultivars was smaller and statistically not significant. The results showed that drought resistant cultivars when compared with drought sensitive one would demonstrate less abundance in the above-ground part and greater dimensions of the root system. The measurements of leaf water potential and stomata diffusive resistance measurements indicate that the physiological reasons for the different reactions to drought between the resistant and the sensitive field bean and field pea cultivars may be due to a more effective protection of the level of tissue hydration and due to increase stomata diffusive resistance in the resistant cultivars. During recovery period it has been also demonstrated that in the drought resistant cultivars a tendency exists for a more complete return to the level of the control plants.

Słowa kluczowe

Wydawca

-

Rocznik

Tom

19

Numer

3

Opis fizyczny

p.349-357

Twórcy

autor
  • Polish Academy of Sciences, Podluzna 3, 30-239 Cracow, Poland
autor
autor
autor

Bibliografia

  • Ciamparowa M. 1989. Recovery of ultrastructure in water stressed root epidermal cells of Zea mays L. Kluwer Acad. Publ. 263–267.
  • Galamay T.O., Yamauchi A., Nonoyama T., Kono Y. 1992. Acropetal lignification in protective tissues of cereal nodal root axes as affected by different soil moisture conditions. Jpn. J. Crop Sci., 61(3): 511–517.
  • Grzesiak S. 1990. Reaction to drought of inbreds and hybrids of maize (Zea mays L.) as evaluated in field and greenhouse experiments. Maydica, 35: 303–311.
  • Grzesiak S., de Barbaro A., Filek W. 1992. Assimilation, translocation and accumulation 14C in two maize (Zea mays L.) hybrids of different drought tolerance. Photosynthetica 27(3): 385–393.
  • Grzesiak S., Filek W., Pienkowski S., Niziol B. 1996a. Screening for drought resistance: Evaluation of drought susceptibility index of legume plants in natural growth conditions. J. Agr. and Crop Sci., 177: 237–252.
  • Grzesiak S., Filek W., Skrudlik G., Niziol B. 1996b. Screening for drought resistance: Evaluation of seed germination and seedling growth for drought resistance in legume plants. J. Agr. and Crop Sci., 177: 245–252.
  • Grzesiak S., Iijima M., Kono Y., Yamauchi A. 1997. Differences in drought tolerance between cultivars of field bean and field pea. Morphological characteristic, germination and seedlings growth. Acta Physiol. Plant., 19: 339–347.
  • Itoh R., Kumura A. 1986. Acclimation of soybean plants to water deficit II. Recovery of photosynthesis and leaf water status under prolonged water deficit. Jpn. J. Crop Sci., 55(3): 374–378.
  • Kiel C., Stamp P. 1992. Internal root anatomy of maize seedlings as influenced by temperature and genotype, Ann. Bot. 70: 125–128.
  • Kono Y., Yamauchi A., Nonoyama T., Tatsumi J., Kawamura N. 1987a. A revised system of root-soil interaction for laboratory work. Environ. Control in Biol. 25: 141–151.
  • Kono Y., Tomida K., Tatsumi J. 1987b. Effects of soil moisture conditions on development of root system of soybean plants (Glycine max Merr.). Jpn. J. Crop Sci., 56(4): 597–607.
  • Kono Y., Yamauchi., Kawamura N., Tatsumi J. 1987c. Interspecific differences of the capacities of waterlogging and drought tolerances among summer cereals. Jpn. J. Crop Sci., 56(1): 115–129.
  • Lorens G.F., Bennett J.M., Loggale L.B. 1987a. Differences in drought resistance between two corn hybrids. I. Water relations and root length density. Agron. J. 79(5): 802–807.
  • Lorens G.F., Bennett J.M., Loggale L.B. 1987b. Differences in drought resistance between two corn hybrids. II. Component analysis and growth rate. Agron. J. 79(5): 808–813.
  • McMichael L., Quisenberry J.E., Upchurch D.P. 1987. Lateral root development in exotic cottons., Env. Exp. Bot., 27: 499–502.
  • Michel B.E., Wiggins K.O., Outlow W.H.J. 1983. A quide to establishing water potential for aqueous two phase solutions (Polyethylene glycol plus dextran) by amendment with mannitol. Plant Physiol., 72: 60–65.
  • Nir I., Klein S., Poliakoff-Mayber A. 1969. Effect of moisture stress on submicroscopic structure of maize roots., Aust., J., Biol., Sci., 22: 17–23.
  • Passioura J.B. 1981. Water collection by roots., In, Paleg L.G., Aspinall D., (eds) The physiology and biochemistry of drought resistance in plants., Academic Press, Sydney New York, London, Toronto, San Francisco., 39–54.
  • Peterson C.A. 1989. Significance of exodermis in root function., In Structural and functional aspects of transport in roots. (eds.) B.C. Loughman, O. Gasparicowa, J. Kolek., Kluver Ac., Pub., London, 35–40.
  • Poljakoff-Mayber A. 1981. Ultrastructural consequences of drought. In, Paleg L.G., Aspinall D., (eds) The physiology and biochemistry of drought resistance in plants., Academic Press, Sydney New York, London, Toronto, San Francisco., 389–403.
  • Richards R.A., 1978. Variation between and within species of rapeseed (Brassica campestris and B. napus) in response to drought stress. III. Physiological and biochemistry characters. Aust. J. Agric. Res., 29: 495–501.
  • Ristic Z., Cass D.D. 1991. Leaf anatomy of Zea mays L. in response to water shortage and high temperature: a comparison of drought-resistant and drought-sensitive lines. Bot. Gaz. 152(2): 173–185.
  • Turner N.C. 1979. Drought resistance and adaptation to water deficit in crop plants. In Stress physiology in crop plants (Eds) H. Mussel, and R.C. Staples, Wiley, New York, 343–372.
  • Winter S.R., Musick J.T., Porter K.B. 1988. Evaluation of screening techniques for breeding drought-resistant winter wheat. Crop Sci., 28: 512–516.
  • Yamauchi A. 1993. Significance of root system structure in relation to the stress tolerance in cereal crops. Low-Input sustainable crop production system in Asia. Korean Soc. Crop Sci., Korea: 347–360
  • Yamauchi A., Kono Y., Tatsumi J. 1987a. Quantitative analysis on root system structures of upland rice and maize. Jpn. J. Crop Sci., 56: 608–617.
  • Yamauchi A., Kono Y., Tatsumi J. 1987b. Comparison of root system of 13 species of cereals, Jpn. J. Crop Sci., 56: 618–631.

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

bwmeta1.element.agro-article-9d778593-f8ea-484f-bef5-2bd07f9c0ffe
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.