Combining ability of physiological traits in forrage maize

Redivo, Greice Daiane Rodrigues Gomes; Faria, Marcos Ventura; Rosa, Jocimar Costa; Ono, Elizabeth Orika; Rodrigues, João Domingos; Adriano, Elisa

doi:10.1590/1413-7054202044018520

ABSTRACT

The exploitation of the existing genetic variability for the physiological traits related to the yield and quality of maize forage can assist in the development of superior inbred lines and hybrids. The objective of this work was to evaluate the general and the specific combining ability and the nature of gene effects of physiological and chemical traits of forage maize genotypes. Two groups of genotypes and 16 hybrids resulting from a 4x4 partial diallel scheme were evaluated. Group I consisted of two commercial hybrids (AG8025, P30B39) and two elite inbred lines (LEM2 and LEM3). Group II consisted of four experimental inbred lines originated from different populations of forage maize breeding program. In total, 24 treatments were evaluated, formed by the genotypes of both groups and the respective crossings. The traits evaluated were: CO₂ assimilation (A), stomatal conductance (gs), internal CO₂ concentration (Ci), transpiration (E), calculated activity of Rubisco (A/Ci) and efficiency of water use (A/E). Forage acid detergent fiber (ADF), neutral detergent fiber (NDF) and digestibility in situ were obtained. There was a predominance of non-additive gene effects for most of the chemical and physiological traits. Crossings LEM2 x 203-218.3, LEM3 x 201-107.2, LEM2 x 101-7.2 and LEM3 x 101-7.2 stood out regarding CO₂ assimilation, and are indicated for future research considering the physiological traits. Inbred lines 101-7.2 and 203-218.3 presented high concentration of favorable alleles to increase carboxylation efficiency, in which inbred line 101-7.2 stood out for NDF, ADF and DIG. Inbred line 201-107.2 has a high concentration of favorable alleles for efficiency of water use. Physiological parameters can assist the selection of inbred lines and hybrids in maize breeding for forage purpose.

Index terms:
CO₂ assimilation; stomatal conductance; internal CO₂ concentration; water efficiency; gaseous exchanges.

RESUMO

A exploração da variabilidade genética existente para características fisiológicas relacionadas com a produtividade e a qualidade da forragem de milho pode auxiliar no desenvolvimento de linhagens e híbridos superiores. O objetivo deste trabalho foi avaliar a capacidade geral e específica de combinação e a natureza dos efeitos genicos de características fisiológicas e químicas de genótipos de milho forrageiro. Foram avaliados dois grupos de genótipos e 16 híbridos resultantes dos cruzamentos em esquema de dialelo parcial 4x4. O grupo I foi constituído por dois híbridos comerciais (AG8025, P30B39) e duas linhagens elite (LEM2 e LEM3). O grupo II foi constituído por quatro linhagens experimentais oriundas de diferentes populações do programa de melhoramento do milho forrageiro da UNICENTRO. No total foram avaliados 24 tratamentos, constituídos pelos genótipos de ambos os grupos e os respectivos cruzamentos. As características avaliadas foram assimilação de CO₂ (A), condutância estomática (gs), concentração interna de CO₂ (Ci), transpiração (E), atividade calculada da Rubisco (A/Ci) e eficiência de uso da água (A/E). Foram obtidos os teores de fibra em detergente ácido (FDA), fibra em detergente neutro (FDN) e a digestibilidade in situ da forragem. Houve predomínio de efeitos gênicos não aditivos para a maioria das características químicas e fisiológicas. Os cruzamentos LEM2 x 203-218,3, LEM3 x 201-107,2, LEM2 x 101-7,2 e LEM3 x 101-7,2 se destacaram quanto à assimilação de CO2, sendo indicados para pesquisas futuras considerando as características fisiológicas. As linhagens 101-7.2 e 203-218.3 apresentaram alta concentração de alelos favoráveis para aumentar a eficiência da carboxilação, em que a linhagem 101-7.2 se destacou para NDF, ADF e DIG. A linhagem endogâmica 201-107.2 possui alta concentração de alelos favoráveis para eficiência do uso da água. Parâmetros fisiológicos podem auxiliar na seleção de linhagens e híbridos no melhoramento do milho forrageiro.

Termos de indexação:
Assimilação de CO₂; condutância estomática; concentração interna de CO₂; eficiência hídrica; trocas gasosas.

INTRODUCTION

Physiological and chemical variables are important to understand the differences in the performance of vegetal species and selection of superior genotypes. These traits are used to verify the culture adaptation to new environments, interspecific competition and effects of handling systems, in addition to the yield potential of different genotypes (Alvarez; Crusciol; Nascente, 2012ALVAREZ, C. F.; CRUSCIOL, C. A. C.; NASCENTE, A. S. Análise de crescimento e produtividade de cultivares de arroz de terras altas dos tipos tradicional, intermediário e moderno. Pesquisa Agropecuária Tropical, 42(4):397-406, 2012.; Chen et al., 2018CHEN, T. et al. Genetic and environmental dissection of biomass accumulation in multi-genotype maize canopies. Journal of Experimental Botany, 70(9):2523-2534, 2018.).

The interaction of environmental factors such as light, temperature, CO₂ concentration and availability and use of water and nutrients affect several traits substantially, being determining factors in the selection of genotypes with greater photosynthetic efficiency, better water use and, as a result, higher productivity, since more efficient genotypes in physiological and chemical traits tend to present higher yield potential (Alvarez; Crusciol; Nascente, 2012ALVAREZ, C. F.; CRUSCIOL, C. A. C.; NASCENTE, A. S. Análise de crescimento e produtividade de cultivares de arroz de terras altas dos tipos tradicional, intermediário e moderno. Pesquisa Agropecuária Tropical, 42(4):397-406, 2012.; Lins et al., 2017LINS, F. J. A. et al. Crescimento de genótipos experimentais de milho em função de doses crescentes de nitrogênio. Revista Ciência Agrícola, 15(2):19-27, 2017.).

Vegetables absorb carbon dioxide from the atmospheric air together with light and water electrons, performing the photosynthesis, which, in short, is the reduction of this atmospheric CO₂ in organic carbon, giving origin to organic molecules for growth and development (Taiz; Zeiger, 2013TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5° ed. Porto Alegre: Artmed, 2013, 918p.).

Plants intercept the necessary light for the photosynthesis by the leaves, and the gaseous exchange takes place through the stomatal pores on the foliar surface. The process of opening and closing of the stomata mainly related to light intensity and the hydration state of the leaf. Propitious conditions to carbon fixation favor the opening of the stoma, while the propitious conditions to water loss promote its closing (Taiz; Zeiger, 2013TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5° ed. Porto Alegre: Artmed, 2013, 918p.).This mechanism limits the flow of CO₂ to the internal side of the leaf and may limit the CO₂diffusion rate to the internal part of the leaf, with direct effects on photosynthesis and growth, while it restricts the water flow of the leaf to the atmosphere, decreasing transpiration and directly influencing plant productivity (Huang et al., 2017HUANG, S. et al. Influence of plant architecture on maize physiology and yield in the Heilonggang River valley.The Crop Journal, 5(1):52-62, 2017.; Sun et al., 2014SUN, Y. et al. Impact of mesophyll diffusion on estimated global land CO2 fertilization. PNAS, 111(44):15774-15779, 2014.).

Maize is a C4 plant, characterized by a mechanism of CO₂concentration that involves a coordinated functioning between the mesophile and the bundle sheath cells (Retta et al., 2016RETTA, M. et al. A two-dimensional microscale model of gas exchange during photosynthesis in maize ( Zea mays L.) leaves. Plant Science, 246:37-51, 2016.). It presents a low point of CO₂compensation, a high photosynthetic rate and low water consumption for the formation of fresh matter (Hlatywayo et al., 2016HLATYWAYO, R. et al. Response of maize (Zea mays L.) secondary growth parameters to conservation agriculture and conventional tillage systems in zimbabwe. Journal of Agricultural Science, 8(11):112-126, 2016.; Huang et al., 2017HUANG, S. et al. Influence of plant architecture on maize physiology and yield in the Heilonggang River valley.The Crop Journal, 5(1):52-62, 2017.). This functioning confers a higher photosynthetic net rate if compared to a C3 plant, since it presents low water loss, it can be cultivated in hot environments with high luminous intensity, and it adapts well to the tropical climate due to its low or null photorespiration (Wu et al., 2016WU, L. et al. Comparative proteomic analysis of the response of maize (Zea mays L.) Leaves to long photoperiod condition. Frontiers in Plant Science , 7:752, 2016.).

Studies on gene effects and combining ability on physiological traits in forage maize are not very common. Ali et al. (2015ALI, Q. et al. Genetic analysis of Zea mays genotypes for various physiological and plant growth related traits to improve fodder yield. American-Eurasian Journal of Agriculture & Environmental Science, 15(8):1530-1543, 2015.) carried out a genetic analysis of forage maize genotypes for several physiological traits and concluded that the selection of genotypes with a higher photosynthetic rate, better efficiency of gaseous exchanges and water use can be determining in the increase of forage yield and productivity, which justifies more studies on this area.

The evaluation of physiological and chemical parameters can also be used in an attempt to explain differences of a genetic order (Peixoto et al., 2011PEIXOTO, C. P. et al. Análise quantitativa do crescimento de plantas: Conceitos e prática. Enciclopédia Biosfera, 7(13):51-76, 2011.). The current search for more efficiency in water use can be applied in the production of forage of good quality, since physiological factors influence and condition plant development and forage maturation (Guarda; Campos, 2014GUARDA, V. D. A.; CAMPOS, L. J. M. Bases ecofisiológicas da assimilação de carbono e suas implicações na produção de forragem. Palmas: Embrapa Pesca e Aquicultura, 2014, 47p.).

The aim of this work was to evaluate the general and specific combining ability and the nature of gene effects of physiological and chemical traits of forage maize genotypes.

MATERIAL AND METHODS

Two groups of genotypes and 16 hybrids were evaluated, resulting from the crossings between the groups, in a 4x4 partial diallel scheme. Group I consisted of two commercial hybrids (AG8025, P30B39), and two inbred lines (LEM2 and LEM3), used as testers of the inbred lines of group II. Group II consisted offour experimental inbred lines originated from different populations of the breeding program of forage maize of the UNICENTRO. In total, 24 treatments were evaluated, formed by genotypes of both groups and the respective crossings.

The parcels were formed by 2 lines of 5 meters, with spacing of 0.80 m, resulting in a final density equivalent to 69.200 plants ha^-1.

In the first and second crop season, 250 kg ha^-1of the NPK 04-20-20 formulation was used in basis fertilization. The nitrogen fertilizations in top dressing were carried out when the plants reached between 3 leaves (V3 stage) and 5 leaves (V5 stage), with an application of 280 kg ha^-1of urea (46% of N) in each stage, totaling 257,6 kg ha^-1of N.

Three evaluations were carried out in the first crop season, at 42, 63 and 84 days after emergence (DAE), and two evaluations in the second crop season, at 21 and 63 DAE, due to the fact that the crop cycle is shorter. The 21 DAE corresponded to phenological stages V3-V4, when the definition of productive potential takes place; 42 DAE corresponded to V11-V12, when the number of grains and spike size are defined; 63 DAE corresponded to the VT stage, when flowering and pollination took place and; 84 DAE corresponded to the beginning of grain filling (Cañas et al., 2017CAÑAS, R. A. et al. Exploiting the genetic diversity of maize using a combined metabolomic, enzyme activity profiling, and metabolic modeling approach to link leaf physiology to kernel yield. The Plant Cell, 29(5):919-943, 2017.).

Measurements of gaseous exchanges were carried out with the Infra Red Gas Analyser - IRGA, equipment, LI-6400, LI-COR model. The measurements were carried out between 9 and 11 o’clock on sunny days, in leaves fully expanded from the plants of each parcel. The CO₂ concentration and the light used during the evaluations were the ones existing in the environment. The values of CO₂ assimilation rate (A) (µmol CO₂ m^-2s^-1) and of the transpiration rate (E) (mmol water vapor m^-2s^-1) were obtained. The internal CO₂ concentration (Ci) (µmol CO₂ mol^-1 air) and the stomatal conductance (g _s ) (mol m^-2s^-1) were calculated by the general equation of gaseous exchanges of Von Caemmerer and Farquhar (1981VON CAEMMERER, S.; FARQUHAR, G. D. Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta, 153(4):376-387, 1981. ).

The efficiency of water use (A/E) (µmolCO₂/mmol H₂O^-1) was determined through the ratio between the CO₂assimilation rate and the transpiration rate, and the carboxylation efficiency or the calculated activity of Rubisco (A/Ci) (µmol m^-2 s^-1 Pa^-1) was determined through the ratio between the CO₂assimilation rate and the internal CO₂ concentration in the leaf, according to Pimentel (2011PIMENTEL, C. Carbon metabolism of crops and the increase of atmospheric CO2 and O3 situation and previsions. Bragantia, 70(1):1-12, 2011.).

The forage was obtained with the plants in the reproductive stages from pasty to chalky grain, at the point of – of the milkline, which corresponds to the silage point. Acid detergent fiber (ADF-%) and neutral detergent fiber (NDF-%) were evaluated according to Van Soest, Robertson and Lewis (1991VAN SOEST, P. J.; ROBERTSON, J. B.; LEWIS, B. A. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of dairy science, 74(10):3583-3597, 1991.). The digestibility in situ of the forage dry mass (DIG-%) was evaluated in accordance with Pereira et al. (2004PEREIRA, M. N. et al. Ruminal degradability of hard or soft texture corn grain at three maturity stages. Scientia Agricola, 61(4):358-363, 2004.).

After verifying the normality of errors and homogeneity of the variances by the Bartlett test, the individual and joint analyses of variance were carried out. The individual and joint partial diallel analyses were performed according to method 2 and model 1 proposed by Griffing (1956GRIFFING, B. Concept of general and specific combining ability in relation to diallel crossing systems. Australian Journal of Biology Science, 9(3):463-493, 1956.) and adapted for partial diallels by Geraldi and Miranda Filho (1988GERALDI, I. O.; MIRANDA FILHO, J. B. Adapted models for the analysis of combining ability of varieties in partial diallel crosses. Revista Brasileira de Genética,11(2):419-430, 1988.), aiming at estimating the general combining ability (GCA) of the genitors and the specific combining ability (SCA) from the pq hybrid combinations, where p inbred lines of group I were crossed with q tester genotypes of group II. The statistical software GENES was used (Cruz, 2013CRUZ, C. D. GENES - A softaware package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, 35(3):271-276, 2013.).

RESULTS AND DISCUSSION

The mean squares regarding the general combining ability (GCA) and specific combining ability (SCA) (Tables 1 and 2), when significant, indicate that the genitors of both groups differed from each other in the frequency of favorable alleles, and indicate that the traits evaluated can be used as parameters of selection aiming at the obtainment of hybrids with better physiological efficiency (Ali et al., 2014ALI, Q. et al. Combining ability analysis for various physiological, grain yield and quality traits of Zea mays L. Life Science Journal, 11(8):540-551, 2014a.a; Peixoto et al., 2011PEIXOTO, C. P. et al. Análise quantitativa do crescimento de plantas: Conceitos e prática. Enciclopédia Biosfera, 7(13):51-76, 2011.; Tiwari et al., 2014TIWARI, D. K. et al. Interfacing carbon nanotubes (CNT) with plants: Enhancement of growth, water and ionic nutrient uptake in maize (Zea mays) and implications for nanoagriculture. Applied Nanoscience, 4(5):577-591, 2014.).

In the several evaluations, for most of the traits there was the predominance of non-additive effects, since the quadratic components of the SCA were higher than those of the GCA (Tables 1 and 2), agreeing with the results by Ali et al. (2014ALI, Q. et al. Study of gene action for various physiological traits in Zea mays. Report and Opinion, 6(4):71-83, 2014b.b), which favors the high complementarity of parentals considering physiological efficiency. The SCA is expressed because of the effects of dominance, overdominance and epistasis and of the differences in the allelic frequencies of the genitors for the loci involved in the control of a certain trait (Hallauer; Carena; Miranda Filho, 2010HALLAUER, A. R.; CARENA, J. M.; MIRANDA FILHO, J. B. Quantitative genetics in maize breeding. New York: Springer, 2010, 500p.; Wang et al., 2018WANG, F. et al. Effects of biochar amendment, CO2 elevation and drought on leaf gas exchange, biomass production and water use efficiency in maize. Pakistan Journal of Botany, 50(4):1347-1353, 2018.). The predominance of genes of non-additive effects was also verified for forage traits, such as acid detergent fiber (ADF), neutral detergent fiber (NDF) and digestibility by Rosa et al. (2020ROSA, J. C. et al. Forage potential of S3 corn progenies in topcrosses and selection of testers of different genetic bases. Pesquisa Agropecuária Brasileira, 55:e01283, 2020. ), so that the selection based on genes of non-additive effects is efficient for both physiological traits and traits related to forage quality.

For the the CO₂ assimilation rate (A) there were significant effects of the genotypes and SCA, at 42 days after emergence in the first crop season (42 DAE-1). There were significant effects for all sources of variation in the evaluation carried out at 63 DAE-1 (Table 1). At 63 days after emergence, in the second crop season (63 DAE-2), there were significant effects for GCA-I and GCA-II (Table 2).

Thumbnail

Table 1:
Summary of the partial diallel analysis related to traits CO₂ assimilation (A) (µmol CO₂ m^-2s^-1), stomatal condunctance (gs) (mol m^-2s^-1), internal CO₂ concentration (Ci) (µmol CO₂ mol^-1 air), transpiration (E) (mmol water vapor m^-2s^-1), calculated activity of Rubisco (A/Ci) (µmol m^-2 s^-1 Pa^-1) and efficiency of water use (A/E) (µmol CO₂/mmol H₂O^-1), evaluated at 42, 63 and 84 days after emergence in the first crop season (DAE-1).

Thumbnail

Table 2:
Summary of the individual partial diallel analysis related to traits CO₂ assimilation (A) (µmol CO_2.m^-2s^-1), stomatal conductance (gs) (mol m^-2s^-1), internal CO₂ concentration (Ci) (µmol CO₂ mol^-1 air), transpiration (E) (mmol water vapor m^-2s^-1), calculated activity of Rubisco (A/Ci) (µmol m^-2 s^-1 Pa^-1) and efficiency of water use (A/E) (µmol CO₂/mmol H₂O^-1), evaluated at 21 and 63 days after emergence in the second crop season (DAE-2).

For stomatal conductance (gs), in the evaluation carried out at 42 DAE-1, there was no significant effect only for GCA of group II (Table 1). For internal CO₂ concentration (Ci), at 42 DAE-1, there was a significant effect of groups and of the GCA - I. In the evaluation carried out at 63 DAE-1 there was no significant effect only for the SCA and, in contrast, at 84 DAE-1 only SCA was significant (Table 1). At 21 DAE-2 there was a significant effect for the groups, GCA-I and SCA. At 63 DAE-2 there was a significant effect only for GCA-I (Table 2).

For transpiration (E), at 42 DAE-1, there was a significant effect of genotypes GCA-I and SCA. At 63 DAE-1 there was a significant effect of genotypes GCA-II and SCA. At 84 DAE-1 there was significance only for GCA-II (Table 1). In the evaluation, at 21 DAE-2, the effect was significant for genotypes GCA-I, GCA-II and SCA, and at 63 DAE-2 of the GCA- I (Table 2). For the (A/Ci) ratio there was a significant effect of GCA-II at 63 DAE-1 and of GCA-I at 84 DAE-1, (Table 1). At 21 DAE-2, there was a significant effect for genotypes, groups, GCA-I and GCA-II, and at 63 DAE-2, it was significant for groups and SCA (Table 2).

For the ratio between CO₂ assimilation and transpiration (A/E), at 42 DAE-1, there was a significant effect of genotypes, groups, of GCA II and SCA, as well as of the SCA at 63 DAE-1. At 84 DAE-1 there was no significant effect only for GCA I (Table 1). There was a significant effect for GCA of both groups at 63 DAE-2 (Table 2).

The estimates of the effects of the SCA of CO₂ assimilation (A), at 42 DAE-1, demonstrated a good performance of crossing LEM2 x 203-218.3 (ŝ_ij = 3.93 µmol CO_2.m^-2s^-1) (Table 3), which presented the highest CO₂ assimilation rate (A) at 42 DAE-1 (68.25 µmol CO₂ m^-2s^-1) among all the evaluated genotypes (Supplement 1). The crossing LEM2 x 201-107.2 also had favorable estimates of SCA (A) at 42 DAE-1 (Table 3).

Thumbnail

Table 3:
Estimates of general combining ability (ĝ _i and ĝ _j ) and specific combining ability (ŝ_ij) of CO₂ assimilation (A) (µmol CO₂ m^-2s^-1), of 24 maize genotypes evaluated in a 4x4 partial diallel at 42 and 63 days after emergence in the first crop season (DAE-1) and at 63 days after emergence in the second crop season (DAE-2), in Guarapuava-PR.

Hybrid combinations with favorable estimates of SCA, whose genitors have presented favorable estimates of the GCA, are desirable, as well (Oliboni et al., 2013OLIBONI, R. et al. Análise dialélica na avaliação do potencial de híbridos de milho para a geração de populações-base para obtenção de linhagens. Semina: Ciências Agrárias, 34(1):7-18, 2013.). In this sense, crossing LEM2 x 101-7.2 (ŝ_ij = 4.92 µmol CO_2. m^-2s^-1, Table 3) stood out at 63 DAE-1, with (A) mean value of 39.06 µmol CO_2.m^-2s^-1 (Supplement 1), considering that both genitors had positive estimates of GCA (A) (Table 3). The increase of CO₂ assimilation is directly related to photosynthetic efficiency and, consequently, to dry mass yield and grain yield, directly reflecting on forage production (Pimentel, 2011PIMENTEL, C. Carbon metabolism of crops and the increase of atmospheric CO2 and O3 situation and previsions. Bragantia, 70(1):1-12, 2011.), as it can be observed in Figure 1, where the most efficient genotypes in CO₂ assimilation presented better forage quality.

Figure 1:
Means of variables neutral detergent fiber (NDF), acid detergent fiber (ADF) and digestibility (DIG), evaluated in two crops seasons in Guarapuava-PR.

At 63 DAE-2, the inbred line LEM3 had the highest GCA(A) estimate among the testers of group I (ĝ _i = 4.24 µmol CO_2.m^-2s^-1) and the experimental inbred line 201-107.2 (group II) also had favorable estimate of GCA(A) at 63 DAE-2 (ĝ _j = 4.87 µmol CO_2.m^-2s^-1) (Table 3). The highest SCA (A) originated from at least one genitor with positive GCA was from crossing AG8025 x 201-107.2 (ŝ_ij = 5.03 µmol CO_2.m^-2s^-1) (Table 3), as well as the highest (A) mean observed, with a value of 38.24 µmol CO_2.m^-2s^-1 (Supplement1).

The predominance of additive effects in the control of (A) verified in the evaluations at 42 DAE-1 and at 63 DAE-2 (Table 1) implies that in the present work there are potentially favorable genitors to the increase of CO₂ assimilation (Coelho et al., 2014COELHO, C. C. R. et al. Aspectos ecofisiológicos e crescimento em plantas de milho submetidas ao alagamento. Revista Agroecossistemas, 5(2):41-46, 2014.). It is worth pointing out that it is important to improve CO₂ assimilation, since about 90% of the plant dry mass originates from CO₂ fixation, through the photosynthesis process and the regulation of photosynthetic efficiency (Ali et al., 2014ALI, Q. et al. Genetic correlation and hybrid vigor for physiological traits of Zea mays. Nature and Science, 12(12):1-12, 2014.a; Magalhaes; Souza, 2009; Minow et al., 2018MINOW, M. A. A. et al. Distinct gene networks modulate floral induction of autonomous maize and photoperiod-dependent teosinte. Journal of Experimental Botany , 69(12):2937-2952, 2018.).

The highest estimates of the SCA of stomatal conductance (gs) at 42 DAE-1 occurred in crossings LEM2 x 202-160.1 (0.21 mol m^-2s^-1) and LEM2 x 203-218.3 (0.19 mol m^-2s^-1), but they originate from genitors with GCA estimates negative or close to zero (Table 4), with moderate means (Supplement 2), indicating that the performnce of these genitors was not different from the general mean of the other genitors involved in the crossings (Hallauer; Carena; Miranda Filho, 2010HALLAUER, A. R.; CARENA, J. M.; MIRANDA FILHO, J. B. Quantitative genetics in maize breeding. New York: Springer, 2010, 500p.; Hlatywayo et al., 2016HLATYWAYO, R. et al. Response of maize (Zea mays L.) secondary growth parameters to conservation agriculture and conventional tillage systems in zimbabwe. Journal of Agricultural Science, 8(11):112-126, 2016.).

Thumbnail

Table 4:
Estimates of general combining ability (ĝ _i and ĝ _i ) and specific combining ability (ŝ_ij) for stomatal conductance (gs) (mol m^-2s^-1), of 24 maize genotypes evaluated in a 4x4 partial diallel on 42 days after emergence in the first crop season (DAE-1), in Guarapuava-PR.

In the evaluation carried out at 42 DAE-1, the crossing P30B39 x 201-107.2 presented the highest SCA(Ci) estimate (ŝ_ij= 2.48 µmol CO₂ mol^-1 air) in which both parents had favorable estimates of GCA(Ci) (Table 5) and, also, the highest mean among the genotypes, with 229.76 µmol CO₂ mol^-1 (Supplement 3).

Thumbnail

Table 5:
Estimates of general combining ability (ĝ _i and ĝ _j ) and specific combining ability (ŝ_ij) of internal CO₂ concentration (Ci) (µmol CO₂ mol^-1 air), of 24 maize genotypes evaluated in a 4x4 partial diallel at 42, 63 and 84 days after emergence in the first season (DAE-1) and at 21 and 63 days after emergence in the second crop season (DAE-2), in Guarapuava-PR.

At 63 DAE-1, tester inbred line LEM2 presented the highest estimate of GCA(Ci) among the genotypes of group I (ĝ _i = 18.59 µmol CO₂ mol^-1 air) and participated in the crossing of a high SCA(Ci) estimate, LEM2 x 202-160.1 (ŝ_ij = 30.07 µmol CO₂ mol^-1 air). At 84 DAE-1, the highest estimate of SCA (Ci) in which both parents had favorable estimates of GCA (Ci) occurred in crossing LEM3 x 202-160.1, whose s_ij estimate was greater than twice the standard deviation (ŝ_ij =31.65 µmol CO₂ mol^-1 air) (Table 5).

Genitor P30B39 had favorable estimates of GCA(Ci) at 21 DAE-2 (ĝ _i = 9.18 µmol CO₂ mol^-1 air) and at 63 DAE-2 CGC (ĝ _i = 8,64 46 µmol CO₂ mol^-1 air) and participated in crossing P30B39 x 202-160.1, which had high SCA estimates in the respective evaluations (ŝ_ij = 16.55 µmol CO₂ mol^-1 air and ŝ_ij = 10.78 µmol CO₂ mol^-1 air), demonstrating that tester P30B39 allowed to discriminate the most favorable inbred line to improve Ci. Also, at 63 DAE-2, the tester P30B39 participated in the crossing of the highest estimate of SCA (P30B39 x 203-218.3; ŝ_ij = 23.46 µmol CO₂ mol^-1 air) (Table 5).

Ali et al. (2014ALI, Q. et al. Study of gene action for various physiological traits in Zea mays. Report and Opinion, 6(4):71-83, 2014b.b) indicated that the selection based on internal CO₂ concentration can be useful in the development of maize hybrids with forage purpose, since the authors verified a direct relationship between the Ci and the accumulation of dry mass.

As for group II, at 63 DAE-1, the estimates of GCA (E) that stand out were from inbred lines 101-7.2 (ĝ _i = 0.55 mmol water vapor m^-2s^-1) and 202-160-1 (ĝ _i = 0.46 mmol water vapor m^-2s^-1). At 63 DAE-1, the crossing LEM-3 x 202-160.1, in which both parents had favorable estimates of GCA( E), presented the highest estimate of SCA (E) (Table 6) and high mean of transpiration (E) (Supplement 4).

Thumbnail

Table 6:
Estimates of general combining ability (ĝ _i and ĝ _j ) and specific combining ability (ŝ_ij) of transpiration (E) (mmol water vapor m^-2s^-1), of 24 maize genotypes evaluated in a 4x4 partial diallel at 42, 63 and 84 days after emergence in the first crop season (DAE-1) and at 21 days after emergence in the second crop season (DAE-2), in Guarapuava-PR.

The highest estimate of the GCA of transpiration (E) at 42 DAE-1 was from tester LEM2 (ĝ _i = 0.33 mmol water vapor m^-2s^-1) (Table 6) which generate the hybrid LEM-2 x 202-160.1 of both parents with favorable estimates of GCA (ŝ_ij = 0.58 mmol water vapor m^-2s^-1). Regarding the SCA of transpiration (E), the hybrid combination that stood out was LEM3 x 201-107.2 (ŝ_ij = 1.02 mmol water vapor m^-2s^-1), whose genitors had positive estimates of GCA(E) at 42 DAE-1, and also high means (Supplement 4).

At 21 DAE-2, the inbred lines LEM 3 (ĝ _i = 0.31 mmol water vapor m^-2s^-1) and 203-218.3 (ĝ _i = 0.39 mmol water vapor m^-2s^-1) had the highest estimates of GCA(E) (Table 6). The evaluation of transpiration rate of young plants can be effective in the selection of maize genotypes aiming at better photosynthetic efficiency, as higher stomatal conductance causes the increase of E, which increases internal CO₂concentration and, consequently, causes an increase of the photosynthetic rate, directly reflecting on forage quality (Ali et al., 2013ALI, Q. M. et al. Genetic variability and correlation among morphological traits of maize (Zea mays L) seedling. The Albanian Journal of Agricultural Sciences, 12(3):405-410, 2013.).

Tester AG8025 obtained the highest estimates of GCA (A/Ci) at 84 DAE-1 (ĝ _i = 0,28), and at 21 DAE-2 (ĝ _i = 0,95). Also, at 21 DAE-2 inbred line 203-218.3 (ĝ _j = 1.41) participated in the crossing with the highest SCA (LEM3 x 203-218.3) (ŝ_ij = 4.34 µmol m^-2 s^-1 Pa^-1) (Table 7). The A/Ci ratio reveals the carboxylation efficiency of the 1.5-bisphophate carboxylase enzyme ribulose (Rubisco), that is, how much CO₂ was reduced in the photosynthesis process (Chen; Mi, 2018CHEN, Y.; MI, G. Physiological mechanisms underlying post-silking nitrogen use efficiency of high-yielding maize hybrids differing in nitrogen remobilization efficiency. Journal of Plant Nutrition and Soil Science, 181(6):923-931, 2018.; Muraya et al., 2017MURAYA, M. M. et al. Genetic variation of growth dynamics in maize (Zea maysL.) revealed through automated non-invasive phenotyping. The Plant Journal, 89(2):366-380, 2017.). Therefore, high and positive estimates of GCA and SCA are desireble. The experimental inbred line 101-7.2 (ĝ _j = 0.37) had the highest estimate of GCA(A/Ci) at 63 DAE-1 (Table 7) and the highest mean of A/Ci was observed in crossing LEM3 x 202-160.1(0.86 µmol m^-2 s^-1 Pa^-1) (Supplement 5), as well as the highest SCA (A/Ci) (ŝ_ij = 0.56 µmol m^-2 s^-1 Pa^-1).

The A/E ratio reveals the efficiency of water use and reflects the plant’s ability to limit water loss and, at the same time, allows CO₂ absorption (Taiz; Zeiger, 2013TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5° ed. Porto Alegre: Artmed, 2013, 918p.).

Thumbnail

Table 7:
Estimates of general combining ability (g_i and g _j ) and specific combining ability (ŝ_ij) for calculated activity of Rubisco (A/Ci) (µmol m^-2 s^-1 Pa^-1), of 24 maize genotypes evaluated in a 4x4 partial diallel at 63 and 84 days after emergence in the first crop season (DAE-1) and at 21 and 63 days after emergence in the second crop season (DAE-2), in Guarapuava-PR.

At 42 DAE-1 the inbred line 203-218.3 (ĝ _j = 0.17µmol CO₂/mmol H₂O^-1) stood out, as well as the crossing P30B39 x 203-218.3 (ŝ_ij = 0.24 µmol CO₂/mmol H₂O^-1) (Table 8), which obtained the highest mean of A/E (3.45 µmol CO₂/mmol H₂O^-1) (Supplement 6).

Thumbnail

Tabela 8:
Estimates of general combining ability (g_i and g_j) and specific combining ability (ŝ_ij) of the efficiency of water use (A/E) (µmol CO₂/mmol H₂O^-1) of 24 maize genotypes evaluated in a 4x4 partial diallel at 42, 63 and 84 days after emergence in the first crop season (DAE-1) and at 63 days after emergence in the second crop season (DAE-2), in Guarapuava-PR.

The inbred line 201-107.2 presented high GCA (A/E) estimate at 63 DAE-1 (ĝ _j = 2.21 µmol CO₂/mmol H₂O^-1) and was the only of group II that presented positive estimates of GCA (A/E) at 84 DAE-1 (ĝ _j = 0.48 µmol CO₂/mmol H₂O^-1) and at 63 DAE-2 (ĝ _j = 0.38 µmol CO₂/mmol H₂O^-1) (Table 8 and Supplement 6).

The inbred line 201-107.2 participated in the crossing with the highest estimate of SCA (A/E) at 63 DAE-1 (AG8025 x 201-107.2; ŝ_ij = 13.85 µmol CO₂/mmol H₂O^-1), in which both parents had favorable estimates of GCA (A/E). Considering at least one genitor with favorable GCA (A/E), significant estimates of SCA (A/E) were obtained for the crossings involving inbred line 201-107.2, i.e. LEM2 X 201-107.2 (ŝ_ij = 1.44µmol CO₂/mmol H₂O^-1) at 84 DAE-1 and P30B39 x 201-107.2 (ŝ_ij = 0.71µmol CO₂/mmol H₂O^-1) at 63 DAE-2 (Table 8).

The high efficiency in water use is directly related to the stomatal opening time, since while the plant absorbs CO₂ for the photosynthesis, water is lost by transpiration, with varied intensity, depending on the potential gradient between the foliar surface and the atmosphere, following a chain of water potentials (Muraya et al., 2017MURAYA, M. M. et al. Genetic variation of growth dynamics in maize (Zea maysL.) revealed through automated non-invasive phenotyping. The Plant Journal, 89(2):366-380, 2017.; Silva et al., 2015SILVA, F. G. et al. Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista Brasileira de Engenharia Agrícola e Ambiental, 19(10):946-952, 2015.). Thus, it is assumed that more efficient genotypes in water use tend to produce higher amounts of dry mass per gram of transpired water, directly affecting forage performance (Ali et al., 2013ALI, Q. M. et al. Genetic variability and correlation among morphological traits of maize (Zea mays L) seedling. The Albanian Journal of Agricultural Sciences, 12(3):405-410, 2013.).

Given the above, hybrid LEM2 x 101-7.2 presented the highest rate of CO₂ assimilation, in addition to desirable values for neutral detergent fiber (NDF) and acid detergent fiber (ADF), in the evaluation of both crop seasons, as well as good digestibility (DIG) (Figure 1). The contents of fiber and digestibility directly reflect on forage quality and it is essential to study them to obtain promising genotypes, justifying the study of both physiological and chemical components, and their effects on forage quality (Ali et al., 2013ALI, Q. M. et al. Genetic variability and correlation among morphological traits of maize (Zea mays L) seedling. The Albanian Journal of Agricultural Sciences, 12(3):405-410, 2013.).

The inbred lines which most contributed to improve DIG, considering the mean values, were the tester LEM2 (group I) and the experimental inbred line 201-107.2 (group II) (Figure 1). Consequently, they presented high CO₂ assimilation and high efficiency of water use, which reasserts the relationship of physiological traits with qualitative bromatological traits of the forage, (Figure 1), justifying this study.

CONCLUSIONS

There was a predominance of non-additive gene effects for most of the chemical and physiological traits. Elite inbred lines LEM2 and LEM3 were the best testers to discriminate the relative merit of the experimental inbred lines. Crossings LEM2x203-218.3, LEM3 x 201-107.2, LEM2 x 101-7.2 and LEM3 x 101-7.2 stood out regarding CO₂ assimilation, and are indicated for future research considering the physiological traits. Inbred lines 101-7.2 and 203-218.3 presented the high concentration of favorable alleles to increase carboxylation efficiency, in which inbred line 101-7.2 stood out for NDF, ADF and DIG. Inbred line 201-107.2 has a high concentration of favorable alleles for efficiency of water use. Physiological parameters can assist the selection of inbred lines and hybrids in maize breeding for forage purpose.

ACKNOWLEDGEMENTS

To Fundação Araucária, Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Financiadora de Estudos e Projetos - FINEP and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Capes, Finance Code 001), for financial support.

REFERENCES

ALI, Q. et al. Genetic correlation and hybrid vigor for physiological traits of Zea mays Nature and Science, 12(12):1-12, 2014.
ALI, Q. et al. Combining ability analysis for various physiological, grain yield and quality traits of Zea mays L. Life Science Journal, 11(8):540-551, 2014a.
ALI, Q. et al. Study of gene action for various physiological traits in Zea mays Report and Opinion, 6(4):71-83, 2014b.
ALI, Q. M. et al. Genetic variability and correlation among morphological traits of maize (Zea mays L) seedling. The Albanian Journal of Agricultural Sciences, 12(3):405-410, 2013.
ALI, Q. et al. Genetic analysis of Zea mays genotypes for various physiological and plant growth related traits to improve fodder yield. American-Eurasian Journal of Agriculture & Environmental Science, 15(8):1530-1543, 2015.
ALVAREZ, C. F.; CRUSCIOL, C. A. C.; NASCENTE, A. S. Análise de crescimento e produtividade de cultivares de arroz de terras altas dos tipos tradicional, intermediário e moderno. Pesquisa Agropecuária Tropical, 42(4):397-406, 2012.
CAÑAS, R. A. et al. Exploiting the genetic diversity of maize using a combined metabolomic, enzyme activity profiling, and metabolic modeling approach to link leaf physiology to kernel yield. The Plant Cell, 29(5):919-943, 2017.
CHEN, T. et al. Genetic and environmental dissection of biomass accumulation in multi-genotype maize canopies. Journal of Experimental Botany, 70(9):2523-2534, 2018.
CHEN, Y.; MI, G. Physiological mechanisms underlying post-silking nitrogen use efficiency of high-yielding maize hybrids differing in nitrogen remobilization efficiency. Journal of Plant Nutrition and Soil Science, 181(6):923-931, 2018.
COELHO, C. C. R. et al. Aspectos ecofisiológicos e crescimento em plantas de milho submetidas ao alagamento. Revista Agroecossistemas, 5(2):41-46, 2014.
CRUZ, C. D. GENES - A softaware package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, 35(3):271-276, 2013.
GERALDI, I. O.; MIRANDA FILHO, J. B. Adapted models for the analysis of combining ability of varieties in partial diallel crosses. Revista Brasileira de Genética,11(2):419-430, 1988.
GRIFFING, B. Concept of general and specific combining ability in relation to diallel crossing systems. Australian Journal of Biology Science, 9(3):463-493, 1956.
GUARDA, V. D. A.; CAMPOS, L. J. M. Bases ecofisiológicas da assimilação de carbono e suas implicações na produção de forragem. Palmas: Embrapa Pesca e Aquicultura, 2014, 47p.
HUANG, S. et al. Influence of plant architecture on maize physiology and yield in the Heilonggang River valley.The Crop Journal, 5(1):52-62, 2017.
HALLAUER, A. R.; CARENA, J. M.; MIRANDA FILHO, J. B. Quantitative genetics in maize breeding. New York: Springer, 2010, 500p.
HLATYWAYO, R. et al. Response of maize (Zea mays L.) secondary growth parameters to conservation agriculture and conventional tillage systems in zimbabwe. Journal of Agricultural Science, 8(11):112-126, 2016.
LINS, F. J. A. et al. Crescimento de genótipos experimentais de milho em função de doses crescentes de nitrogênio. Revista Ciência Agrícola, 15(2):19-27, 2017.
MINOW, M. A. A. et al. Distinct gene networks modulate floral induction of autonomous maize and photoperiod-dependent teosinte. Journal of Experimental Botany , 69(12):2937-2952, 2018.
MURAYA, M. M. et al. Genetic variation of growth dynamics in maize (Zea maysL.) revealed through automated non-invasive phenotyping. The Plant Journal, 89(2):366-380, 2017.
OLIBONI, R. et al. Análise dialélica na avaliação do potencial de híbridos de milho para a geração de populações-base para obtenção de linhagens. Semina: Ciências Agrárias, 34(1):7-18, 2013.
PEIXOTO, C. P. et al. Análise quantitativa do crescimento de plantas: Conceitos e prática. Enciclopédia Biosfera, 7(13):51-76, 2011.
PEREIRA, M. N. et al. Ruminal degradability of hard or soft texture corn grain at three maturity stages. Scientia Agricola, 61(4):358-363, 2004.
PIMENTEL, C. Carbon metabolism of crops and the increase of atmospheric CO₂ and O₃ situation and previsions. Bragantia, 70(1):1-12, 2011.
RETTA, M. et al. A two-dimensional microscale model of gas exchange during photosynthesis in maize ( Zea mays L.) leaves. Plant Science, 246:37-51, 2016.
ROSA, J. C. et al. Forage potential of S₃ corn progenies in topcrosses and selection of testers of different genetic bases. Pesquisa Agropecuária Brasileira, 55:e01283, 2020.
SILVA, F. G. et al. Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista Brasileira de Engenharia Agrícola e Ambiental, 19(10):946-952, 2015.
SUN, Y. et al. Impact of mesophyll diffusion on estimated global land CO₂ fertilization. PNAS, 111(44):15774-15779, 2014.
TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5° ed. Porto Alegre: Artmed, 2013, 918p.
TIWARI, D. K. et al. Interfacing carbon nanotubes (CNT) with plants: Enhancement of growth, water and ionic nutrient uptake in maize (Zea mays) and implications for nanoagriculture. Applied Nanoscience, 4(5):577-591, 2014.
VAN SOEST, P. J.; ROBERTSON, J. B.; LEWIS, B. A. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of dairy science, 74(10):3583-3597, 1991.
VON CAEMMERER, S.; FARQUHAR, G. D. Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta, 153(4):376-387, 1981.
WANG, F. et al. Effects of biochar amendment, CO₂ elevation and drought on leaf gas exchange, biomass production and water use efficiency in maize. Pakistan Journal of Botany, 50(4):1347-1353, 2018.
WU, L. et al. Comparative proteomic analysis of the response of maize (Zea mays L.) Leaves to long photoperiod condition. Frontiers in Plant Science , 7:752, 2016.

Publication Dates

Publication in this collection
23 Nov 2020
Date of issue
2020

History

Received
26 Aug 2020
Accepted
21 Oct 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALI, Q. et al. Genetic correlation and hybrid vigor for physiological traits of Zea mays Nature and Science, 12(12):1-12, 2014.

[2] ALI, Q. et al. Combining ability analysis for various physiological, grain yield and quality traits of Zea mays L. Life Science Journal, 11(8):540-551, 2014a.

[3] ALI, Q. et al. Study of gene action for various physiological traits in Zea mays Report and Opinion, 6(4):71-83, 2014b.

[4] ALI, Q. M. et al. Genetic variability and correlation among morphological traits of maize (Zea mays L) seedling. The Albanian Journal of Agricultural Sciences, 12(3):405-410, 2013.

[5] ALI, Q. et al. Genetic analysis of Zea mays genotypes for various physiological and plant growth related traits to improve fodder yield. American-Eurasian Journal of Agriculture & Environmental Science, 15(8):1530-1543, 2015.

[6] ALVAREZ, C. F.; CRUSCIOL, C. A. C.; NASCENTE, A. S. Análise de crescimento e produtividade de cultivares de arroz de terras altas dos tipos tradicional, intermediário e moderno. Pesquisa Agropecuária Tropical, 42(4):397-406, 2012.

[7] CAÑAS, R. A. et al. Exploiting the genetic diversity of maize using a combined metabolomic, enzyme activity profiling, and metabolic modeling approach to link leaf physiology to kernel yield. The Plant Cell, 29(5):919-943, 2017.

[8] CHEN, T. et al. Genetic and environmental dissection of biomass accumulation in multi-genotype maize canopies. Journal of Experimental Botany, 70(9):2523-2534, 2018.

[9] CHEN, Y.; MI, G. Physiological mechanisms underlying post-silking nitrogen use efficiency of high-yielding maize hybrids differing in nitrogen remobilization efficiency. Journal of Plant Nutrition and Soil Science, 181(6):923-931, 2018.

[10] COELHO, C. C. R. et al. Aspectos ecofisiológicos e crescimento em plantas de milho submetidas ao alagamento. Revista Agroecossistemas, 5(2):41-46, 2014.

[11] CRUZ, C. D. GENES - A softaware package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, 35(3):271-276, 2013.

[12] GERALDI, I. O.; MIRANDA FILHO, J. B. Adapted models for the analysis of combining ability of varieties in partial diallel crosses. Revista Brasileira de Genética,11(2):419-430, 1988.

[13] GRIFFING, B. Concept of general and specific combining ability in relation to diallel crossing systems. Australian Journal of Biology Science, 9(3):463-493, 1956.

[14] GUARDA, V. D. A.; CAMPOS, L. J. M. Bases ecofisiológicas da assimilação de carbono e suas implicações na produção de forragem. Palmas: Embrapa Pesca e Aquicultura, 2014, 47p.

[15] HUANG, S. et al. Influence of plant architecture on maize physiology and yield in the Heilonggang River valley.The Crop Journal, 5(1):52-62, 2017.

[16] HALLAUER, A. R.; CARENA, J. M.; MIRANDA FILHO, J. B. Quantitative genetics in maize breeding. New York: Springer, 2010, 500p.

[17] HLATYWAYO, R. et al. Response of maize (Zea mays L.) secondary growth parameters to conservation agriculture and conventional tillage systems in zimbabwe. Journal of Agricultural Science, 8(11):112-126, 2016.

[18] LINS, F. J. A. et al. Crescimento de genótipos experimentais de milho em função de doses crescentes de nitrogênio. Revista Ciência Agrícola, 15(2):19-27, 2017.

[19] MINOW, M. A. A. et al. Distinct gene networks modulate floral induction of autonomous maize and photoperiod-dependent teosinte. Journal of Experimental Botany , 69(12):2937-2952, 2018.

[20] MURAYA, M. M. et al. Genetic variation of growth dynamics in maize (Zea maysL.) revealed through automated non-invasive phenotyping. The Plant Journal, 89(2):366-380, 2017.

[21] OLIBONI, R. et al. Análise dialélica na avaliação do potencial de híbridos de milho para a geração de populações-base para obtenção de linhagens. Semina: Ciências Agrárias, 34(1):7-18, 2013.

[22] PEIXOTO, C. P. et al. Análise quantitativa do crescimento de plantas: Conceitos e prática. Enciclopédia Biosfera, 7(13):51-76, 2011.

[23] PEREIRA, M. N. et al. Ruminal degradability of hard or soft texture corn grain at three maturity stages. Scientia Agricola, 61(4):358-363, 2004.

[24] PIMENTEL, C. Carbon metabolism of crops and the increase of atmospheric CO₂ and O₃ situation and previsions. Bragantia, 70(1):1-12, 2011.

[25] RETTA, M. et al. A two-dimensional microscale model of gas exchange during photosynthesis in maize ( Zea mays L.) leaves. Plant Science, 246:37-51, 2016.

[26] ROSA, J. C. et al. Forage potential of S₃ corn progenies in topcrosses and selection of testers of different genetic bases. Pesquisa Agropecuária Brasileira, 55:e01283, 2020.

[27] SILVA, F. G. et al. Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista Brasileira de Engenharia Agrícola e Ambiental, 19(10):946-952, 2015.

[28] SUN, Y. et al. Impact of mesophyll diffusion on estimated global land CO₂ fertilization. PNAS, 111(44):15774-15779, 2014.

[29] TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5° ed. Porto Alegre: Artmed, 2013, 918p.

[30] TIWARI, D. K. et al. Interfacing carbon nanotubes (CNT) with plants: Enhancement of growth, water and ionic nutrient uptake in maize (Zea mays) and implications for nanoagriculture. Applied Nanoscience, 4(5):577-591, 2014.

[31] VAN SOEST, P. J.; ROBERTSON, J. B.; LEWIS, B. A. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of dairy science, 74(10):3583-3597, 1991.

[32] VON CAEMMERER, S.; FARQUHAR, G. D. Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta, 153(4):376-387, 1981.

[33] WANG, F. et al. Effects of biochar amendment, CO₂ elevation and drought on leaf gas exchange, biomass production and water use efficiency in maize. Pakistan Journal of Botany, 50(4):1347-1353, 2018.

[34] WU, L. et al. Comparative proteomic analysis of the response of maize (Zea mays L.) Leaves to long photoperiod condition. Frontiers in Plant Science , 7:752, 2016.

Source of variation	DF	CO₂ Assimilation rate (A)	Stomatal condunctance (gs)	Internal CO₂ concentration (Ci)	Transpiration (E)	A/Ci	A/E
1^st Crop Season -Evaluation at 42 DAE-1
SV	DF	MS
Genotypes	23	26.64*	0.07*	55.52	1.21*	0.01	0.06*
Groups	1	49.56*	0.29*	169.65*	0.10	0.00	0.09*
GCA - I	3	8.73	0.10*	229.65*	2.43*	0.01	0.00
GCA - II	3	10.19	0.01	26.69	0.49	0.00	0.06*
SCA	16	31.65*	0.06*	21.14	1.19*	0.02	0.06*
Residue	23	16.68	0.03	65.15	1.10	0.00	0.04
Quadratic Components (%)
GCA %		52.86	23.02	69.45	31.59	41.62	17.08
SCA %		47.14	76.98	30.55	68.41	58.38	82.92
1^st Crop Season -Evaluation at 63 DAE-1
SV	DF	MS
Genotypes	23	102.88*	0.06	1.586.90*	2.42*	0.24	1.81
Groups	1	299.29*	0.02	2.936.82*	1.12	0.19	0.00
GCA - I	3	80.43*	0.00	2.755.63*	0.36	0.16	1.37
GCA - II	3	180.12*	0.01	1.579.51*	5.67*	0.63*	1.37
SCA	16	80.34*	0.01	1.284.78	2.36*	0.18	2.09*
Residue	23	58.55	0.01	1.496.94	1.69	0.28	1.83
Quadratic Components (%)
GCA %		37.81	41.34	86.35	32.37	44.83	19.70
SCA %		62.19	58.66	13.65	67.63	55.17	80.30
1^st Crop Season - Evaluation at 84 DAE-1
SV	DF	MS
Genotypes	23	72.37	0.01	733.25	2.66	0.45	0.98*
Groups	1	55.76	0.01	53.32	0.01	0.01	1.15*
GCA - I	3	27.06	0.03	145.88	2.52	0.63*	0.26
GCA - II	3	97.58	0.02	266.03	4.29*	0.45	1.79*
SCA	16	77.18	0.01	973.48*	2.54	0.44	0.96*
Residue	23	98.80	0.01	880.31	4.14	0.46	0.64
Quadratic Components (%)
GCA %		23.24	29.87	7.35	33.41	31.65	28.55
SCA %		76.76	70.13	92.65	66.59	68.35	71.45

Source of variation	DF	CO₂ Assimilation (A)	Stomatal condunctance (gs)	Internal CO₂ concentration (Ci)	Transpiration (E)	A/Ci	A/E
2^nd Crop Season -Evaluation at 21 DAE-2
SV	DF	MS
Genotypes	23	38.91	0.02	309.71*	1.36*	12.92*	0.40
Groups	1	23.20	0.01	872.22*	0.56	46.22*	0.00
GCA - I	3	45.38	0.03	800.65*	1.48*	19.08*	0.46
GCA - II	3	41.33	0.02	91.19	1.11*	16.59*	0.21
SCA	16	38.22	0.01	223.47*	1.43*	8.99	0.44
Residue	46	50.70	0.01	173.02	1.10	12.63	0.47
Quadratic Components (%)
GCA %		29.84	28.13	42.80	25.40	42.65	22.14
SCA %		70.16	71.87	57.20	74.60	57.35	77.86
2^nd Crop Season -Evaluation at 63 DAE-2
SV	DF	MS
Genotypes	23	81.60	0.03	518.09	2.25	79.05	0.50
Groups	1	2.37	0.01	502.08	0.87	196.74*	0.13
GCA - I	3	205.32*	0.01	1.047.03*	7.52*	48.79	0.69*
GCA - II	3	194.78*	0.02	130.33	1.40	42.93	1.13*
SCA	16	42.14	0.00	492.62	1.51	84.14*	0.37
Residue	46	105.56	0.01	732.4	7.59	83.37	0.54
Quadratic Components (%)
GCA %		64.03	7.55	30.95	52.46	16.97	47.58
SCA %		35.97	92.45	69.05	47.54	83.03	52.42

Evaluation 42 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	0.26	0.24	-1.16	0.65
	LEM3	-0.15	-0.45	3.84	2.16	2.32
	LEM2	0.64	-0.80	3.80	1.89	3.93
	AG8025	-0.97	1.76	2.24	2.04	2.42
	P30B39	0.49	2.63	0.26	5.20	-1.00
	SD(s_jj):1.05		SD(s_ij): 2.53
Evaluation 63 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	2.64	-3.02	3.15	-2.77
	LEM3	1.45	1.94	8.58	1.07	-12.45
	LEM2	2.33	4.92	-8.13	1.29	6.09
	AG8025	-1.50	3.73	-0.51	1.91	-0.11
	P30B39	-2.28	4.00	-9.43	-5.84	0.97
	SD(s_jj): 3.66		SD(s_ij): 4.75
Evaluation 63 DAE-2 2^nd Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	-3.41	4.87	-0.87	-0.57
	LEM3	4.24	0.65	0.24	-3.05	-2.32
	LEM2	1.03	-3.99	-8.95	1.82	0.92
	AG8025	-0.97	-6.03	5.03	1.60	5.88
	P30B39	-4.30	2.39	2.08	-1.90	-6.90
	SD(s_jj): 4.91		SD(s_ij): 3.37

Evaluation 42 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	0.00	-0.01	0.02	-0.01
	LEM3	-0.06	0.01	0.16	0.09	0.00
	LEM2	-0.04	0.05	0.13	0.21	0.19
	AG8025	-0.00	0.03	-0.01	0.09	0.12
	P30B39	0.10	0.04	0.01	0.08	-0.10
	SD(s_jj): 0.93		SD(s_ij): 0.12

Evaluation 42 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	-0.67	0.25	1.69	-1.27
	LEM3	-2.72	4.96	-2.11	2.20	-2.54
	LEM2	-3.68	2.65	0.83	-0.69	-3.35
	AG8025	2.34	0.15	-5.62	-0.95	2.60
	P30B39	4.07	-1.56	2.48	-5.43	0.58
	SD(S_jj): 3.86		SD(S_ij): 4.01
Evaluation 63 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	-5.45	14.43	-7.46	-1.51
	LEM3	-10.33	12.37	0.32	-16.78	38.53
	LEM2	18.59	-28.59	-36.40	30.07	-35.75
	AG8025	-0.25	-15.45	-6.03	8.38	-9.09
	P30B39	-8.00	26.00	5.24	12.39	-8.95
	SD(S_jj): 13.52		SD(S_ij): 24.01
Evaluation 84 DAE-1 1^st Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	1.89	-3.73	4.83	-3.00
	LEM3	3.17	-13.08	-23.67	31.65	15.59
	LEM2	-3.66	47.41	27.37	-21.75	-18.97
	AG8025	1.61	4.78	-19.31	14.56	-2.52
	P30B39	-1.12	7.48	-7.44	4.47	3.54
	SD(S_jj): 14.20		SD(S_ij): 13.41
Evaluation 21 DAE-2 2^nd Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	1.52	-0.45	2.10	-3.17
	LEM3	-3.92	-7.78	-4.20	-5.61	-1.54
	LEM2	1.64	14.75	0.03	-13.54	-3.91
	AG8025	-6.90	6.53	2.40	2.40	-1.53
	P30B39	9.18	-23.86	0.62	16.55	13.78
	SD(S_jj): 6.29		SD(S_ij): 8.16
Evaluation 63 DAE-2 2^nd Crop Season			Group II
	Group I		101-7.2	201-107.2	202-160.1	203-218.3
		GCA	-0.20	-3.49	3.48	0.21
	LEM3	-10.66	4.24	-5.92	6.05	4.73
	LEM2	2.72	-15.43	8.95	17.73	14.38
	AG8025	-0.70	22.83	-3.67	-15.11	-14.58
	P30B39	8.64	-0.13	-24.97	10.78	23.46
	SD(S_jj): 12.95		SD(S_ij): 16.80

Brasil

Brasil

Combining ability of physiological traits in forrage maize

Capacidade combinatória de caracteristicas fisiológicas em milho forrageiro

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSIONS

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History