Abstract
In the present study, the physiological efficiencies of 181 mini-core peanut accessions (genotypes) were evaluated according to variability in their physiological performance in the field during summer (2012). Genotypes were categorized into groups of high, medium, and low physiological activity. Thirty-four genotypes showed high net photosynthetic rate (P N > 33 μmol m−2 s−1), 28 genotypes exhibited high stomatal conductance (g s > 0.54 mmol m−2 s−1), 33 genotypes manifested high transpiration rate (E > 11.8 mmol m−2 s−1), 30 genotypes performed with high water-use efficiency (WUE > 3.8), 30 genotypes reached high chlorophyll SPAD values (SCMR > 40), and 35 genotypes showed high maximum quantum yield of PSII (Fv/Fm > 0.86). In addition, few genotypes showed high values for multiple physiological traits. A total of 54 genotypes exhibited higher values in two, 20 genotypes showed a high value in three, and in eight genotypes, high values occurred in four different physiological traits. Interestingly, only two genotypes, NRCG 14493 and 14507, showed high values for five different traits. Positive correlation was observed between g s and P N, E, and g s, and between P N and Fv/Fm, while WUE and E showed a negative correlation. The genotypes with high P N, g s, and WUE coupled with high SCMR and Fv/Fm could be used in peanut crop improvement programme for yield enhancement as well as stress tolerance.
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Abbreviations
- Chl:
-
chlorophyll
- E :
-
transpiration rate
- Fv/Fm :
-
maximum photochemical efficiency of PSII
- g s :
-
stomatal conductance
- P N :
-
net photosynthetic rate
- SCMR:
-
soil-plant-analytical-development chlorophyll meter reading
- WUE:
-
water-use efficiency
References
Ainsworth, E.A., Long, S.P.: What have we learned from 15 years of free-air CO2 enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO2. — New Phytol. 165: 351–371, 2005.
Araus, J.L., Amaro, T., Voltas, J. et al.: Chlorophyll fluorescence as a selection criterion for grain yield in durum wheat under Mediterranean conditions. — Field Crop. Res. 55: 209–223, 1998.
Araus, J.L., Slafer, G.A., Reynolds, M.P., Royo, C.: Plant breeding and drought in C3 cereals: what should we breed for? — Ann. Bot. 89: 925–940, 2002.
Arnau, G., Monneveux, P., This, D., Alegre, L.: Photosynthesis of six barley genotypes as affected by water stress. — Photosynthetica 34: 67–76, 1997.
Belko, N., Zaman-Allah, M., Cisse, N. et al.: Lower soil moisture threshold for transpiration decline under water deficit correlates with lower canopy conductance and higher transpiration efficiency in drought-tolerant cowpea. — Funct. Plant Biol. 39: 306–322, 2012.
Bhagsari, A.S., Brown, R.H.: Translocation of photosynthetically assimilated 14C in peanut (Arachis) genotypes. — Peanut Sci. 3: 5–9, 1976.
Bindu Madhava, H., Sheshshayee, M.S., Shankar, A.G. et al.: Use of SPAD chlorophyll meter to assess transpiration efficiency of peanut. — In: Cruickshank, A.W., Rachaputi, N.C., Wright, G.C., Nigam, S.N. (ed): Breeding of Drought Resistant Peanuts. Proceedings of a Collaborative Review Meeting, Hyderabad, Andhra Pradesh, India, 25–27 Feb 2002. Pp. 3–9. ACIAR, Canberra 2003.
Boote, K.J.: Growth stages of peanut (Arachis hypogaea L.). — Peanut Sci. 9: 35–40, 1982.
Brown, A.H.D.: Core collections: A practical approach to genetic resources management. — Genome 31: 818–824, 1989.
Cao, T., Isoda, A.: Dry matter production of Japanese and Chinese high-yielding cultivars in peanut under high planting population in terms of intercepted radiation and its use efficiency. — Jpn. J. Crop Sci. 77: 41–47, 2008.
FAO: FAOSTAT database. http://faostat.fao.org/site/567.
Fracheboud, Y., Jompuk, C., Ribaut, J.M. et al.: Genetic analysis of cold-tolerance of photosynthesis in maize. — Plant Mol. Biol. 56: 241–253, 2004.
Frankel, O.H., Brown, A.H.D.: Plant genetic resources today: A critical appraisal. — In: Holden, J.H.W., Williams, J.T. (ed): Crop Genetic Resources: Conservation and Evaluation. Pp. 249–259. George Allen and Unwin, London, 1984.
Gregory, W.C., Smith, B.W., Yarbrough, J.A.: Structures and genetic resources of peanuts. — In: Peanuts — Culture and Uses. Pp. 47–133. American Peanut Research and Education Association Inc., Stillwater 1973.
Guo, P., Li, R.: Effects of high nocturnal temperature on photosynthetic organization in rice leaves. — Acta Bot. Sin. 42: 13–18, 2000.
Havaux, M.: Rapid photosynthetic adaptation to high temperature stress triggered in potato leaves by moderately elevated temperature. — Plant Cell Environ. 16: 461–467, 1993.
Krishnamurthy, L., Vandez, V., Jyotsanadevi, M. et al.: Variation in transpiration efficiency and its related traits in a groundnut mapping population. — Field Crop. Res. 103: 189–197, 2007.
Liu, G., Yang, C., Xu, K. et al.: Development of yield and some photosynthetic characteristics during 82 years of genetic improvement of soybean genotypes in northeast China. — Aust. J. Crop Sci. 6:1416–1422, 2012.
Mallikarjunaswamy, B.P., Upadhyaya, H.D., Kenchana Goudar, P.V.: Characterization for Asian core collection for morphological traits. — Ind. J. Crop Sci. 1: 129–134, 2006.
Nageshwara Rao, R.C., Talwar, H.S., Wright, G.C.: Rapid assessment of specific leaf area and leaf N in peanut (Arachis hypogaea L.) using chlorophyll meter. — J. Agron. Crop Sci. 189: 175–185, 2001.
Nautiyal, P.C., Ravindra, V., Joshi, Y.C.: Net photosynthesis rate in pea nut (Arachis hypogea L.): Influence of leaf position, time of day and reproductive sink — Photosynthetica 36: 129–138, 1999.
Nautiyal, P.C., Ravindra, V., Rathnakumar, A.L. et al.: Genetic variations in photosynthetic rate, pod yield and yield components in Spanish groundnut cultivars during three cropping seasons. — Field Crop. Res. 125: 83–91, 2012.
Nigam, S.N., Aruna, R.: Improving breeding efficiency for early maturity in peanut. — Plant Breed. Rev. 30: 295–322, 2008.
Nigam, S.N., Chandra, S., Sridevi, K.R. et al.: Efficiency of physiological trait-based and empirical selection approaches for drought tolerance in groundnut. — Ann. Appl. Biol. 146: 433–439, 2005.
Onfri, A.: Routine statistical analyses of field experiment by using an Excel extension. — In: Proceedings 6th National Conference, Italian Biometric Society, Pisa, 20–22 June 2007. Pp. 93–96. Italian Biometric Society, Pisa 2007.
Rahbarian, R., Khavari Nejad, R., Ali, G. et al.: Drought stress effects on photosynthesis, chlorophyll fluorescence and water relations in tolerant and susceptible chick pea (Cicer arietinum L.) genotypes. — Acta Biol. Cracov. 53: 47–56, 2011.
Roháček, K., Soukupová, J., Barták, M.: Chlorophyll fluorescence: A wonderful tool to study plant physiology and plant stress. — Plant Cell Comp. — Selected Topics 41–102, 2008.
Samdur, M.Y., Singh, A.L, Mathur, R.K. et al.: Field evaluation of chlorophyll meter for screening groundnut (Arachis hypogea L.) genotype tolerant to iron deficiency chlorosis. — Curr. Sci. 79: 211–214, 2000.
Saranga, Y., Flash, I., Paterson, A.H., Yakir, D.: Carbon isotope ratio in cotton varies with growth stage and plant organ. — Plant Sci. 142: 47–56, 1999.
Schreiber, U.: Pulse-amplitude-modulation (PAM) fluorometry and saturation pulse method: an overview. — In: Papageorgiou, G.C., Govindjee (ed.): Chlorophyll a Fluorescence: A Signature of Photosynthesis. Pp. 279–319. Springer, Dordrecht 2004.
Shahenshah, Isoda, A.: Effect of water stress on temperature and chlorophyll fluorescence parameters in cotton and peanut. — Plant Prod. Sci. 13: 269–278, 2010.
Sinclair, T.R.: Is transpiration efficiency a viable plant trait in breeding for crop improvement? — Funct. Plant Biol. 39: 359–365, 2012.
Singh, A.L.: Physiological basis for realizing yield potentials in groundnut. — In: Hemantranjan, A. (ed.): Advances in Plant Physiology. Pp. 131–242. Scientific Publishers, Jodhpur 2011.
Singh, A.L., Basu, M.S.: Integrated Nutrient Management in Groundnut — A Farmer’s Manual. Pp. 1–54. National Research Center for Groundnut (ICAR), Junagadh 2005.
Singh, A.L, Basu, M.S., Singh, N.B.: Iron Deficiency Chlorosis and its Management in Groundnut. Pp. 1–30. National Research Center for Groundnut (ICAR), Junagadh 2003.
Singh, A.L., Joshi, Y.C.: Comparative studies on the chlorophyll content, growth, N uptake and yield of groundnut varieties of different habit groups. — Oleagineux 48: 27–34, 1993.
Singh, R.S., Giri, J.D., Jain, B.L., Shyamaprasad, R.L.: Soil Resource Appraisal of Research Farm, National Research Centre for Groundnut, Junagadh. NBSS Report No. 550. Pp. 1–57. NBSS&LUP, Nagpur 2000.
Songsri, P., Jogloy, S., Holbrook, C.C. et al.: Association of root, specific leaf area and SPAD chlorophyll meter reading to water use efficiency of pea nut under different available soil water. — Agr. Water Manage. 96: 790–798, 2009.
Trachtenberg, C.H., McCloud, D.E.: Net photosynthesis rate of peanut leaves at varying light intensities and leaf ages. — P. Soil Crop Sci. Soc. 35: 54–55, 1976.
Upadhyaya, H.D., Bramel, P.J., Ortiz, R., Singh, S.: Developing a mini core of peanut for utilization of genetic resources. — Crop Sci. 42: 2150–2156, 2002.
Upadhyaya, H.D., Mukri, G., Nadaf, H.L., Singh, S.: Variability and stability analysis for nutritional traits in the mini core collection of peanut. — Crop Sci. 52: 168–178, 2012.
Upadhyaya, H.D., Ortiz, R.: A mini core subset for capturing diversity and promoting utilization of chickpea genetic resources. — Theor. Appl. Genet. 102: 1292–1298, 2001.
Upadhyaya, H.D., Sharma, S., Singh, S., Singh, M.: Inheritance of drought resistance related traits in two crosses of groundnut (Arachys hypogaea L.). — Euphytica 177: 55–66, 2011.
Upadhyaya, H.D.: Variability for drought resistance related traits in the mini core collection of peanut. — Crop Sci. 45: 1432–1440, 2005.
Wright, G.C., Nageswara Rao, R.C., Farquhar, G.D.: Water use efficiency and carbon isotope discrimination in pea nut under water deficit conditions. — Crop Sci. 34: 92–97, 1994.
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Acknowledgement: Authors gratefully acknowledge the Director of DGR for providing facilities, technical support from Mr. P.V. Zala, and Mr. C.B. Patel for raising and maintaining the crop.
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Singh, A.L., Nakar, R.N., Chakraborty, K. et al. Physiological efficiencies in mini-core peanut germplasm accessions during summer season. Photosynthetica 52, 627–635 (2014). https://doi.org/10.1007/s11099-014-0072-3
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DOI: https://doi.org/10.1007/s11099-014-0072-3