Growth analysis, photosynthate partition and nodulation in bean and soybean

Portes, Tomás de Aquino; Araújo, Bárbara Regina Brandão de; Melo, Hyrandir Cabral de

doi:10.1590/0103-8478cr20210282

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SOIL SCIENCE • Cienc. Rural 52 (10) • 2022 • https://doi.org/10.1590/0103-8478cr20210282 copy

Growth analysis, photosynthate partition and nodulation in bean and soybean

Análise de crescimento, partição de fotoassimilados e nodulação em feijão e soja

Authorship SCIMAGO INSTITUTIONS RANKINGS

ABSTRACT:

Photoassimilate partition and allocation among plant organs varies throughout their development and is also influenced by factors inherent to the genotype and the environment. Nodulation in the soybean-diazotrophic bacteria interaction is more effective than in the bean-diazotrophic bacteria interaction. This investigation studied growth and photoassimilate partitioning throughout the bean and soybean cycles and inferred how much it could affect the nodulation of the roots. For this purpose, an experiment with two treatments was carried out, soybean (cultivar BRS GO - 7760 - RR) and bean (cultivar BRS Estilo), with four replications, conducted in pots and entirely randomized. The seeds were inoculated with commercial rhizobia specific for bean and soybean LeguMax^® (Novozymes-Turfal). Plants were analyzed throughout their cycles based on leaf area and dry mass of all organs, including nodules. Mathematical models were fitted to the data and based on them, the instantaneous physiological indicators of growth were estimated, and the percentages of photoassimilate partition among organs were evaluated. Crop growth rate, relative growth rates, net assimilation rate as well as net photosynthesis rate had higher values in soybean compared to bean, following the pattern of leaf area and total dry mass. For both species, the highest rates occurred at the beginning of the cycle, decreasing with age. Unlike the bean, soybean has a high capacity to supply photosynthates to all of its organs throughout its entire cycle, favoring the maintenance of nodule growth and explaining its greater capacity for nitrogen assimilation.

Key words:
Phaseolus vulgaris; Glycine max; biomass; nodule; photosynthesis

Universidade Federal de Santa Maria Universidade Federal de Santa Maria, Centro de Ciências Rurais , 97105-900 Santa Maria RS Brazil , Tel.: +55 55 3220-8698 , Fax: +55 55 3220-8695 - Santa Maria - RS - Brazil
E-mail: cienciarural@mail.ufsm.br

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[1] E-mail: portes.icb.ufg@gmail.com. ^*Corresponding author

Variable	Bean	r	P
LA	$y = {44.8014 Exp}^{(3.2913 10^{- 2} x + 8.9172 * 10^{- 4} x^{2} - 1.5439 * 10^{- 5} x^{3})}$	0.9864	≤ 0.01
DMleaves	$y = {0.1984 Exp}^{({2.920 10}^{- 2} x + 1.105 * 10^{- 3} x^{2} - 1.693 * 10^{- 5} x^{3})}$	0.9977	≤ 0.01
DMstems	$y = {2.5512 * 10^{- 2} Exp}^{(0.1007 x - 4.8948 10^{- 4} x^{2} - 3.0540 * 10^{- 6} x^{3})}$	0.9901	≤ 0.01
DMpetioles	$y = {4.8241 * 10^{- 3} Exp}^{(0.1674 x - 1.450 * 10^{- 3} x^{2} + 4.1603 * 10^{- 8} x^{3})}$	0.9929	≤ 0.01
DMroots	$y = {7.4424 * 10^{- 2} Exp}^{(0.1706 x - 2.756 * 10^{- 3} x^{2} + 1.491 * 10^{- 5} x^{3})}$	0.9956	≤ 0.01
DMbranches	$y = {6.1712 * 10^{- 7} Exp}^{(0.399 x - 3.180 10^{- 3} x^{2})}$	0.8877	≤ 0.05
DMpods	$y = - 15.390 + 0.456 x - 3.00 * 10^{- 3} x^{2}$	0.9947	≤ 0.05
TDM	$y = {0.2640 Exp}^{(0.109 x - 1.047 { 10}^{- 3} x^{2} + 2.357 * 10^{- 6} x^{3})}$	0.9980	≤ 0.01
----------------------------------------------------------------------------Soybean-------------------------------------------------------------------------------
LA	$y = {4.9225 Exp}^{(0.2157 x - 2.8319 10^{- 3} x^{2} + 1.1283 * 10^{- 5} x^{3})}$	0.9961	≤ 0.01
DMleaves	$y = {1.6333 * 10^{- 2} Exp}^{(0.2139 x - 2.5472 10^{- 3} x^{2} + 9.040 * 10^{- 6} x^{3})}$	0.9976	≤ 0.01
DMstems	$y = {2.0225 * 10^{- 2} Exp}^{(0 ∙ 1420 x - 9.9317 10^{- 4} x^{2} + 6.4343 * 10^{- 7} x^{3})}$	0.9968	≤ 0.01
DMpetioles	$y = {1.7469 * 10^{- 4} Exp}^{(0.371 x - 4.830 { 10}^{- 3} x^{2} + 2.01 * 10^{- 5} x^{3})}$	0.9982	≤ 0.01
DMroots	$y = {0.4310 * Exp}^{(- 2.360 * 10^{- 2} x + 2.4332 * 10^{- 3} x^{2} - 2.136 * 10^{- 5} x^{3})}$	0.9530	≤ 0.01
DMbranches	$y = {3.414 * 10^{- 4} Exp}^{(0.228 x - 1.548 { 10}^{- 3} x^{2})}$	0.9828	≤ 0.01
DMpods	$y = {4.230 * 10^{- 9} Exp}^{(0.494 x - 3.016 10^{- 3} x^{2})}$	0.9998	≤ 0.01
TDM	${y = 0.424 * 10^{- 2} Exp}^{(0.203 x - 2.09 10^{- 3} x^{2} + 6.35 * 10^{- 6} x^{3})}$	0.9981	≤ 0.01

	Equations
Interaction	Bean (b)	Correlation
n vs c (yb)	${yb = 1.343 * 10}^{- 3} {Exp}^{(2.690 X - 0.338 X^{2})}$	r = 0.93^*
n vs l (zb)	$zb = 0.397 - 0.504 X + 0.270 X^{2}$	r = 0.65 (ns)
n vs r (jb)	$jb = 1.203 * 10^{- 17} {Exp}^{(29.45 X - 5.753 X^{2})}$	r = 0.97^**
--------------------------------------------------------------------------Soybean (s)----------------------------------------------------------------------------
n vs c (ys)	$ys = 2.70 * 10^{- 4} {Exp}^{(1.320 X - 5.10 * 10^{- 2} X^{2})}$	r =0.97^**
n vs l (zs)	$zs = 8.780 * 10^{- 7} {Exp}^{(6.643 X - 0.791 X^{2})}$	r=0.78 (ns)
n vs r (js)	$js = 2.575 * 10^{- 3} {Exp}^{(1.904 X - 0.143 X^{2})}$	r=0.94^**