Physiological efficiencies in mini-core peanut germplasm accessions during summer season

Photosynthetica

Volumn 52, Issue 4, 2014, Pages 627-635

  Singh, A L ^a   Nakar, R N ^a   Chakraborty, K ^a   Kalariya, K A ^a  

^a ICAR DIRECTORATE OF GROUNDNUT RESEARCH   (India)

Author keywords

chlorophyll fluorescence; core collection; crop productivity; gene bank

Indexed keywords

ARACHIS HYPOGAEA;

EID: 84912090134     PISSN: 03003604     EISSN: 15739058     Source Type: Journal    
DOI: 10.1007/s11099-014-0072-3     Document Type: Article

References (45)

1. 2. — New Phytol. 165: 351–371, 2005.
2. 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.
3. 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.
4. Arnau, G., Monneveux, P., This, D., Alegre, L.: Photosynthesis of six barley genotypes as affected by water stress. — Photosynthetica 34: 67–76, 1997.
5. 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.
6. 14C in peanut (Arachis) genotypes. — Peanut Sci. 3: 5–9, 1976.
7. 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.
8. Boote, K.J.: Growth stages of peanut (Arachis hypogaea L.). — Peanut Sci. 9: 35–40, 1982.
9. Brown, A.H.D.: Core collections: A practical approach to genetic resources management. — Genome 31: 818–824, 1989.
10. 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.
11. FAO: FAOSTAT database. http://faostat.fao.org/site/567.
12. 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.
13. 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.
14. 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.
15. Guo, P., Li, R.: Effects of high nocturnal temperature on photosynthetic organization in rice leaves. — Acta Bot. Sin. 42: 13–18, 2000.
16. Havaux, M.: Rapid photosynthetic adaptation to high temperature stress triggered in potato leaves by moderately elevated temperature. — Plant Cell Environ. 16: 461–467, 1993.
17. 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.
18. 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.
19. 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.
20. 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.
21. 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.
22. 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.
23. Nigam, S.N., Aruna, R.: Improving breeding efficiency for early maturity in peanut. — Plant Breed. Rev. 30: 295–322, 2008.
24. 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.
25. 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.
26. 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.
27. 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.
28. 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.
29. 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.
30. 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.
31. Shahenshah, Isoda, A.: Effect of water stress on temperature and chlorophyll fluorescence parameters in cotton and peanut. — Plant Prod. Sci. 13: 269–278, 2010.
32. Sinclair, T.R.: Is transpiration efficiency a viable plant trait in breeding for crop improvement? — Funct. Plant Biol. 39: 359–365, 2012.
33. 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.
34. 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.
35. 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.
36. 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.
37. 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.
38. 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.
39. 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.
40. 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.
41. 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.
42. 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.
43. 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.
44. Upadhyaya, H.D.: Variability for drought resistance related traits in the mini core collection of peanut. — Crop Sci. 45: 1432–1440, 2005.
45. 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.