Investigating the Alometric Relationships between Leaf Area and Some of Vegetative Characteristics in SC704 Corn Hybrid

Document Type : Research Article

Authors

Gorgan University of Agricultural Sciences and Natural Resources

Abstract

Introduction
Since the leaves are the main source of production of photosynthetic substances in plants, dry matter production and crop yield potential is largely dependent on the leaf surface, and many environmental changes affect growth and yield through changes in leaf area. Hence, green leaf area per plant and leaf area index is measured in almost all studies of crop physiology to understand the mechanism of yield alteration. However, measurement of leaf area compared with the other traits such as plant height and total plant dry weight is very difficult, need to precision instruments and spend more time and cost. Therefore, according to the allometric relationships in plants, extensive studies were done to find the relationship between leaf area and the other plant traits that their measurement is easier, faster and cheaper, and does not require expensive equipment. Using these relationships will be used to estimate plant leaf area with acceptable accuracy without measuring. Plant traits that have high correlation with leaf area and usually use to estimate the plant leaf area are the number of leaves or nodes per main stem, plant height, leaf dry weight and dry weight of vegetative parts of the plant. Allometric equations was used successfully to calculate leaf area for various crops such as cotton, wheat, chickpea, faba bean, peanuts, soybean and sweet sorghum.
This study was conducted to obtain the allometric relationships between green leaf area (cm2 per plant) with number of leaves or nodes per main stem, plant height, green leaf dry weight and dry weight of vegetative parts of the plant (gram per plant), and investigating the effect of plant density and planting date on these relationships in SC704 corn (Zea mays L.) hybrid.
Materials and Methods
This study was conducted at Gorgan University of Agricultural Sciences and Natural Resources farm located at latitude 36 o 51’ N, longitude 54 o27’ E and altitude of 13 meters above sea level in 2012. The experiment was carried out in a randomized complete block design as factorial with three replications. The experimental factors and their levels were, including plant density (4, 6, 8, 10 and 12 plants per square meter) and planting date (May 30 and June 30). Each plot was including 6 rows with 76 cm inter-row spacing and 6 m length. Corn hybrid SC704, a common hybrid in Iran and Gorgan region, was used in this study. Plant sampling was carried out once every 10 days from 15 days after planting to physiological maturity to measure leaf dry weight, plant green leaf area, the leaf (node) number per stem, dry weight of total vegetative plant parts and plant height. Green leaf area was measured using leaf area meter in laboratory. Plant samples were placed in an oven with 70 oC for 48 hours. To obtain allometric relationships various mathematical equations fitted to green leaf area against mentioned traits data. Fitting the functions to data and examining them was carried out in three steps: 1) Fitting function to each of the plant density in each planting date, 2) Fitting a function to all plant densities in each of two planting dates, separately, and 3) Fitting a function to all data. At each step, after fitting the functions and analysis of coefficients, if the differences were not significant, the next step was used. Statistical analysis was done using the software SAS and the graphs drew using Excel software.
Results and Discussion
The results showed that a non-linear segmented model can be used to describe the relationships between the number of leaves per stem with cumulative thermal units (R2= 0.94, RMSE =5.59%), and leaf area per plant with leaf dry weight per plant (R2= 0.98, RMSE =6.54%) and plant dry weight (R2= 0.95, RMSE =11.25%) in all plant densities and planting dates. Moreover, the results revealed that the effect of planting date and plant density on the phyllochron, time between the appearance of successive leaves on a shoot was not significant, and mean of the phyllochron was 72.33 thermal units in all treatments. In addition, the findings of this study indicated the significant effect of planting date and non-significant effect of plant densities on the relationship between leaf area per plant and number of leaves (nodes) per stem. Therefore, two individual power equations with R2= 0.99 (Y= X3.36 and Y= X0.286 for the first and second planting date, respectively) applied to describe this relationship in two planting dates. Similarly, a power equation (Y = X0.14, R2= 0.99) can be used to describe the relationship between leaf area index and plant height in all planting dates and densities.
Conclusions
Findings of this study showed that the obtained functions to describe the relationship between the leaf area have high accuracy to estimate green leaf area per plant. But among these relationships, relationships between plant green leaf area with plant green leaf dry weight and plant height had higher coefficient of determination, smaller root mean square, and subsequently higher estimation accuracy. Therefore, using these two traits, leaf area can be estimated more accurately. Moreover, since the relationship between green leaf area with green leaf dry weight per plant was more accurate than plant height, using this relationship in corn simulation models and for fast and easy estimating of leaf area, especially when the leaf area meter is not available, is recommended.

Keywords


1- Abendroth, L. J., Elmore, R.W., Boyer, and Marlay. S.K., 2011. Corn growth and development. PMR 1009. Iowa State University Extension. Ames, Iowa.
2- Akramghaderi, F., Soltani, A., Rezaii, J. 2004. Estimation of leaf area in cotton cultivars of the plant vegetative characteristics. Journal of Agricultural Sciences and Natural Resources 11(1): 30-39. (In Persian with English Abstract).
3- Bafkar, A., Boromand, S., Behzad, M., Farhadi, B., 2011. Predict production potential of grain corn in Mahidasht Kermanshah 704 C using a simulation model of crop growth WOFOST. Iranian Journal of Field Crop Science 42(4): 45-55. (In Persian with English Abstract).
4- Bakhshande, A., Soltani, A., Zainali, A., Kalatearabi, M., Ghadirian, R. 2011. Evaluation of allometric relationships leaf area and plant growth components in durum and bread wheat varieties. Iranian Journal of Crop Sciences 13(4): 55-87. (In Persian with English Abstract).
5- Bakhshandeh, E., Ghadiryan, R. and Kamkar, B. 2010. A rapid and non-destructive method to determine the leaflet, trifoliate and total leaf area of soybean. Asian. Australian Journal Plant Science. Biotechnology 4: 19-23. (In Persian with English Abstract).
6- Cavero, J., Farre, I., Debaeke, Ph. and Faci, J. M. 2000. Simulation of Maize Yield under Water Stress with the EPICphase and CROPWAT Models. Agronomy Journal 92. 12p.
7- Ghadirian, R., Soltani, A., Zainali, A., Kalatearabi, M., Bakhshande, A. 2011. Evaluation of non-linear regression models for use in wheat growth analysis. Electronic Journal of Crop Production 4: 55-77. (In Persian with English Abstract).
8- Hammer G. L., Carberry, P. S. and Muchow, R. C. 1993. Modeling genotype and environmental control of leaf area dynamics in grain sorghum. I. Whole plant level. Field Crops Research 33: 293-310.
9- Kumudini, S., Hume, D. J. and Chu, G. 2001. Genetic improvements in short season soybeans I. Dry matter accumulation, partitioning and leaf area duration. Crop Science 41:391–398.
10- Nehbandani, A., Soltani, A., Zeinali, E., Raeisi, S. and Najafi, R. 2013. Allometric relationships between leaf area and vegetative characteristics in soybean. IJACS Journal 6(16). 1127-1136 p.
11- Payne, W. A., C. W. Went, L. R. Hossner and C. E. Gates. 1991. Estimating pearl millet leaf area and specific leaf area. Agronomy Journal 83: 937-941.
12- Pengelly, B.C., Muchow, R.C. and Blamey, P.C. 1999. Predicting leaf area development in response to temperature in three tropical annual forage legumes. Australian Journal of Agricultural Research 50: 253-259.
13- Poorreza, J., Soltani, A., Rahemi, A., Galeshi, S., Zainali, A. 2007. Allometric relationships between plant height and growth traits in pea plants (Cicer arietinum). Journal of Agricultural Sciences and Natural Resources 14(5): 37-46. (In Persian with English Abstract).
14- Rahemi, A., Soltani, A., poorreza, J., Zainali, A., Sarparst, R. 2006. Allometric relationships between leaf and vegetative traits in pea plants. Journal of Agricultural Sciences and Natural Resources 13(5): 33-44.
15- Ranganathan, R., Chamhan, Y.S., Flower, D.J., Robertson, C. and Silim, S.N. 2001. Predicting growth and development of pigeonpea: Leaf area development. Field Crops Research 69: 163-127.
16- Retta, A., Armbrust, D. V., Hagen, L. J. and Skidmore, E. L. 2000. Leaf and stem area relationship to masses and their height distributions in native grasses. Agronomy Journal 92: 225-230.
17- Robertson, M.J., Carberry, P.S., Huth, N.I., Turpin, J.E., Probert, M.E., Poulton, P.L., Bell, M., Wright, G.C., Yeates, S.J. and Brinsmead, R.B. 2002. Simulation of growth and development of diverse legume species in APSIM. Australian Journal of Agricultural Research 53: 429– 446.
18- Sharrett, B. S. and Baker, D. G. 1985. Alfalfa leaf area as a function of dry matter. Crop Science 26: 1040-1042.
19- Sinclair T.R., Gilbert R.A., Perdomo R.E., Shine Jr. J.M., Powell G. and Montes G. 2004. Sugarcane leaf area development under field conditions in Florida, USA. Field Crops Research 88: 171–178.
20- Sinclair, T.R., 1984. Leaf area development in field-grown soybeans. Agronomy journal 76: 141-146.
21- Soltani, A. 2007. Application of SAS in statistical analysis. 2nd ed., JDM Press, Mashhad, Iran. p182. (In Persian).
22- Soltani, A. and Maddah, V. 2010. Applied, Simple programs for Education and Research in Agronomy. Iranian Society Ecological Agriculture, Tehran, Iran. (In Persian).
23- Soltani, A., and Sinclair, T. R. 2012. Modeling physiology of crop development, growth and yield: Cabi.
24- Soltani, A., Torabi, B. 2009. Modeling crop (case studies). Publications Jihad Mashhad University. Mashhad. 232, p.
25- Tsialtas J. T. and N. Maslaris. 2008. Leaf allometry and prediction of specific leaf area (SLA) in a sugar beet (Beta vulgaris L.) cultivars. Photosynthetica 46: 351-355.
26- Turpin, J.E., Robertson, M.J., Hillcoat, N.S. and Herridge, D.F. 2002. Faba bean (Vicia faba) in Australia’s northern grains belt: canopy development, biomass, and nitrogen accumulation and partitioning. Australian Journal of Agricultural Research 53: 227-237.
27- Zainali, A., Soltani, A., Torani, M., Khadempir, M. 2013. Study allometric relationships between leaf area and plant growth components in the Faba Bean. Journal of Plant Production 4: 18-44. (In Persian with English Abstract).
CAPTCHA Image
  • Receive Date: 16 October 2014
  • Revise Date: 10 February 2015
  • Accept Date: 25 February 2015
  • First Publish Date: 21 June 2016