Dynamics, diversity and experimental precision in final irrigated rice testing: a time meta-analysis

Costa, Weverton Gomes da; Oliveira, Aluizio Borém de; Cruz, Cosme Damião; Rosado, Renato Domiciano Silva; Soares, Plínio César

doi:10.1590/1984-70332020v20n4a55

Abstract

The objective of this study was to investigate diversity, experimental conditions and dynamics of the Irrigated Rice Breeding Program of Minas Gerais - Brazil, by meta-analysis. The target traits were grain yield, plant height and days to flowering. Evaluations were based on estimates of 376 genotypes grown at three locations, in two final comparative trials, in 14 growing seasons. Stability of the overall averages of the traits plant height and days to flowering was observed, indicating an adequate plant height and medium cycle. High average yields (>5,000 kg ha^-1), good experimental accuracy and genetic variability were recorded. However, the genetic variability of all traits decreased over time, indicating the need to increase genotypic diversity. The parameter estimates of the morphoagronomic traits studied in time meta-analysis indicated the dynamic nature and good accuracy of the Irrigated Rice Breeding Program of Minas Gerais.

Keywords:
Meta-analytic estimates; Oryza sativa L.; plant breeding; time analysis.

INTRODUCTION

Rice (Oryza sativa L.) is the staple food of more than half of the human population. Reportedly, global rice consumption increased by 8.8% in the past decade. However, to meet the rising food demand of the growing world population, rice production will have to be increased by more than 30% over the next 30 years in the same cultivation area (Rejesus et al. 2012Rejesus RM, Mohanty S and Balagtas JV (2012) Forecasting global rice consumption. Department of Agricultural and Resource Economics, North Carolina State University, Raleigh, 40p., Mieulet et al. 2016Mieulet D, Jolivet S, Rivard M, Cromer L, Vernet A, Mayonove P, Pereira L, Droc G, Courtois B, Guiderdoni E and Mercier R (2016) Turning rice meiosis into mitosis. Cell Research 26: 1242-1254., Sandhu et al. 2018Sandhu N, Dixit S, Swamy BPM, Vikram P, Venkateshwarlu C, Catolos M and Kumar A (2018) Positive interactions of major-effect QTLs with genetic background that enhances rice yield under drought. Scientific Reports 8: 1-13.).

The results of agricultural experiments with rice or any other crop, compiled in databases, can be analyzed together to understand the breadth of information and the data dynamics in a temporal evaluation. The dynamics of plant breeding programs have been analyzed based on the genotype replacement rate over time (Reis et al. 2015Reis GG, Fritsche-Neto R, Soares PC, Cornélio VMO, Reis MS, Morais OP and Marques TS (2015) Accuracy and genetic progress of agronomic traits in irrigated rice program in Brazil. African Journal of Agricultural Research 10: 4032-4038., Follmann et al. 2017Follmann DN, Cargnelutti Filho A, Lúcio AD, Souza VQ, Caraffa M and Wartha CA (2017) Genetic progress in homogeneous regions of wheat cultivation in Rio Grande do Sul State, Brazil. Genetics and Molecular Research 16: 1-9., Silva Júnior et al. 2019Silva Júnior AC, Carneiro VQ, Santos IG, Costa WG, Rosado RDS, Cruz CD and Soares PC (2019) Performance of a breeding program for irrigated rice in southeast Brazil. Genetics and Molecular Research 18: 1-10.), which is calculated from the inclusion, exclusion and renewal of cultivars and is considered the most efficient way to assess the dynamics of performance (Federizzi et al. 2012Federizzi LC, Carbonell SAM, Pacheco MT and Nava IC (2012) Breeders’ work after cultivar development: the stage of recommendation. Crop Breeding and Applied Biotechnology 12: 67-74., Ceccarelli 2015Ceccarelli S (2015) Efficiency of plant breeding. Crop Science Society of America 55: 87-97.).

However, this form of evaluation does not directly represent the pillars of genetic breeding, e.g., the diversity of plant material or accuracy of experimental performance, among other parameters. Estimates of genetic parameters are essential for inference of the predicted gains from selection and guide different selection strategies that allow breeders to make most efficient use of these parameters (Otoboni et al. 2020Otoboni MEF, Oliveira DJLSF, Vargas PF, Pavan BE and Andrade MI (2020) Genetic parameters and gain from selection in sweet potato genotypes with high beta-carotene content. Crop Breeding and Applied Biotechnology 20: 1-9.). To be able to draw consistent conclusions, all aspects of the entire experiments must be evaluated. Nevertheless, some factors within an experiment may cause greater variability between experiments, which can affect the results (e.g., weather, locations, pests and diseases, sampling errors). In this case, data recorded under different conditions must be combined to enable more accurate and precise conclusions than can be drawn from a single source of information. An effective and accurate form of analyzing this accumulated information is by meta-analysis.

This kind of analysis is a statistical approach to combine multiple, independent studies, carried out under experimental conditions that differ in terms of growing season, location, soil texture, timeframe and other aspects, to assess the consistency of results (Fisher 2015Fisher M (2015) Moving science forward through: Meta-analysis. CSA News 60: 4-9., Toler et al. 2019Toler HD, Augé RM, Benelli V, Allen FL and Ashworth AJ (2019) Global meta-analysis of cotton yield and weed suppression from cover crops. Crop Science Society of America 59: 1248-1260.). Meta-analyses are extensively used, exploiting information compiled in systematic reviews, particularly in the field of medicine. Yet, in plant breeding programs, meta-analyses can also be used for combined analyses of specific and restricted experimental data, since, according to Eloy et al. (2018Eloy L, Pötter L, Lobato J, Bremm C and Laca E (2018) Reproductive performance of cattle: a meta-analytical approach. Journal of Animal Science 96: 376-376.), they can enhance the precision of evaluations of treatment effects and help consolidate isolated results. In this context, meta-analyses are based on summarizing specific information from experimental analyses in a single measure. The combined estimate is also called meta-analytic estimate and such combined analyses based on long-term experimentation are named time meta-analysis.

Meta-analysis is commonly used in animal breeding programs (Azevêdo et al. 2010Azevêdo JAG, Valadares Filho CS, Pina DS, Chizzotti ML and Valadares RFD (2010) A meta-analysis of dry matter intake in Nellore and Zebu-crosses cattle. Revista Brasileira de Zootecnia 39: 1801-1809., Del Claro et al. 2011Del Claro AC, Mercadante MEZ and Silva JAIV (2011) Meta‑análise de parâmetros genéticos relacionados ao consumo alimentar residual e a suas características componentes em bovinos. Pesquisa Agropecuaria Brasileira 47: 302-310., Vieira et al. 2013Vieira PSA, Pereira LGR, Azevêdo JAG, Neves ALA, Dantas MLR, Araújo GGL, Mistura C and Chaves AV (2013) Development of mathematical models to predict dry matter intake in feedlot Santa Ines rams. Small Ruminant Research 112: 78-84., Eloy et al. 2018Eloy L, Pötter L, Lobato J, Bremm C and Laca E (2018) Reproductive performance of cattle: a meta-analytical approach. Journal of Animal Science 96: 376-376.) to increase their efficiency. However, for plant breeding, meta-analysis is not yet as widely applied. For rice studies in Brazil, meta-analysis has been used for upland (Breseghello et al. 2011Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923.) and for irrigated rice (Streck et al. 2018Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.) in the central north and southern regions of Brazil, respectively. To fill this gap, this study evaluated the experimental conditions, diversity and dynamics of the Irrigated Rice Breeding Program of Minas Gerais, from 2004 to 2018, based on meta-analytic estimates of parameters related to experimental accuracy, genetic variability and averages of morpho-agronomic rice traits.

MATERIAL AND METHODS

Data collection

The evaluated data were the result of the last two comparative trials of the irrigated rice breeding program in Minas Gerais, Brazil, i.e., the Preliminary Comparative Trials (PCT) and Advanced Comparative Trials (ACT) or trials for the Value for Cultivation and Use (VCU), carried out by the Agricultural Research Company of Minas Gerais (EPAMIG). The PCAs were carried out at the Experimental Station Leopoldina (CELP) in Leopoldina, MG (lat 21° 31’ 48.01” S, long 42° 38’ 24.00” W, alt 257.19 m asl) and at the Experimental Station Lambari (CELB) in Lambari, MG (lat 21° 58’ 11.24” S, long 45° 20.60’ 59” W; alt 887.55 m asl).

The VCU trials were carried out at three locations: Leopoldina, Lambari and Nova Porteirinha, MG, the latter at the Experimental Station Gorotuba (CEGR) (lat 15° 48’ 0.77” S, long 43° 17’ 59.09” W, alt 533.77 m asl). The trials were set up between the spring and summer growing seasons (between October and March), with 25 entries (lines and cultivars) in the VCUs and 36 in the PCTs, except in 2013/14 and 2017/18, when 30 entries were tested in the PCTs. Altogether, from 2004/2005 to 2017/18, 376 lines and cultivars (Supplementary Table 1) were evaluated in 60 experiments, over a period of 14 growing seasons.

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Table 1. Intercept
(β₀) and slope (β₁) estimated by the simple, fixed and mixed regression models

For the statistical analyses, a triple lattice design was used for PCTs and of randomized blocks for VCUs with three replications. The PCT plots consisted of four 5-m rows, spaced 0.3 m apart, and the evaluated area of the middle 4 m of two center rows, to exclude any border effects. In the VCUs, from 2004 to 2007 the experimental plots consisted of six rows and from 2008 onwards of five rows, 5 m long, spaced 0.3 m apart, and the assessed area was given by the middle 4 m of three center rows, to ensure the absence of border effects.

The trials were planted on floodplain soils under continuous flood irrigation. The agronomic management was applied according to the typical agronomic recommendations for these regions (EMBRAPA 1977). Evaluations were performed for grain yield (kg ha^-1) adjusted to 13% moisture, plant height at maturity by measuring the main stem length (cm) and days to flowering, i.e., the number of days from emergence to 50% flowering. The experimental plots were harvested manually.

Statistical analyses

Data were subjected to individual analysis of variance (ANOVA), in analyses of each trial of each location in each year, to determine the average parameters (μ), heritability (h²) and coefficient of variation (CV) specifically for each trait. Subsequently, an exploratory analysis of each parameter set was performed to analyze the distribution, summary of the main data set statistics and the presence of outliers by the box-plot graph (Bussab and Morettin 2017Bussab WO and Morettin PA (2017) Estatística básica. Saraiva, São Paulo, 576p.). For the analyses, the data were grouped according to the locations. The datasets were also analyzed for possible study effects, to check for variability between studies (locations), as recommended by Koricheva and Gurevitch (2014Koricheva J and Gurevitch J (2014) Uses and misuses of meta-analysis in plant ecology. Journal of Ecology 102: 828-844.) in a long-term systematic review.

Meta-analysis

Simple, fixed and mixed regression models were used to identify the most appropriate for meta-analytic estimation. The Akaike (AIC) and Bayesian (BIC) information criteria and the log-likelihood ratio (logLik) were used to compare the regression models in meta-analysis, as well as the likelihood ratio test to check the differences between regression models, as recommended by Viechtbauer (2010Viechtbauer W (2010) Conducting meta-analisys in R with metafor package. Journal of Statistical Software 36: 1-48.). For all analyses, software Genes (Cruz 2016Cruz CD (2016) Genes software - extended and integrated with the R, Matlab and Selegen. Acta Scientiarum - Agronomy 38: 547-552.) and R (R Core Team 2020) were used.

Simple regression model

The simple regression model was used to demonstrate the presence of variability between studies (locations), since this model does not take this variability into account. Thus, the simple regression model was given by:

$Y_{i} = β_{0} + β_{1} X_{i} + e_{i}$

where Y _i is the plot-level data; β₀ is the intercept; β₁ is the slope (of the year-centered mean); X _i is the parameter value in experiment i; and e _i is the residual error, $e_{i} ~ N (0, σ^{2})$ .

The intercept values (β₀) reflect the meta-analytic estimates of the parameter over the years of assessment and the slope value (β₁) (weighting coefficient of the variable year) indicates the magnitude and direction of the variation of a parameter, and thus the gain for the characteristic. The genetic gain was calculated as the slope/intercept ratio, as proposed by Breseghello et al. (2011Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923.).

Fixed regression model: fixed effect + effect between studies

In the fixed-effects model, it was assumed that the various studies contributing to the problem of interest share the same true effect size, so that the estimated parameter is a common effect size for all studies (Sangnawakij et al. 2019Sangnawakij P, Böhning D, Niwitpong SA, Adams S, Stanton M and Holling H (2019) Meta-analysis without study-specific variance information: Heterogeneity case. Statistical Methods in Medical Research 28: 196-210.). In this context, the effect caused by the data derived from different studies was taken into account as homogeneous in the fixed-effects model. Thus, the fixed-effects model was given by:

$Y_{i j} = β_{0} + S_{i} + β_{1} X_{i j} + {β_{i} X_{i j} + e}_{i j}$

where Y _i is the plot-level data; β₀ is the intercept; Si is the fixed effect of group i; β₁ is the slope (of year-centered mean); Xij is the parameter value in experiment j of study i; β_i is the fixed effect of study i on the slope; and e _i is the residual error, $e_{i} ~ N (0, σ^{2})$ .

Mixed regression model: fixed effect + random effect + effect between studies

In contrast to the fixed regression model, the random-effects model treats the true effect size of the studies involved in the meta-analysis as a random sample of the population effect size distribution so that each group can contribute with a different effect (Sangnawakij et al. 2019Sangnawakij P, Böhning D, Niwitpong SA, Adams S, Stanton M and Holling H (2019) Meta-analysis without study-specific variance information: Heterogeneity case. Statistical Methods in Medical Research 28: 196-210.). In this context, the mixed regression model, similar to the fixed-effects model, takes into account the effect factor between groups (studies). Moreover, it also takes into account other effects than those related to the fixed part of the model, called random effects, caused by the heterogeneity between studies (locations). In this model, the meta-analytic estimates were obtained by the Maximum Restricted Likelihood (REML) method. The mixed regression model was described by:

$Y_{i j} = β_{0} + β_{1} X_{i j} + s_{i}^{*} + {b_{i}^{*} X_{i j} + e}_{i j}$

where Y _i is the plot-level data; β ₀ is the intercept; β ₁ is the slope (of year-centered mean); X _ij is the parameter value in experiment j of study i; $s_{i}^{*}$ is the random effect of study i; $b_{i}^{*}$ is the random effect of study i on the slope; e _i is the residual error, $e_{i} ~ N (0, σ^{2})$ ; and $[\begin{matrix} s_{i}^{*} \\ b_{i}^{*} \end{matrix}] ~ N [(\frac{0}{0}), Σ]$ ; $Σ = [\begin{matrix} σ_{s}^{2} & σ_{s b} \\ σ_{s b} & σ_{b}^{2} \end{matrix}]$ .

RESULTS AND DISCUSSION

Univariate analysis of variance of the traits indicated significant differences (by the F test at 5% probability) for the traits in most of the experiments. This indicates the presence of genetic variability among the different evaluated entries, justifying the use of meta-analysis to establish combined parameter estimates.

As suggested by Bussab and Morettin (2017Bussab WO and Morettin PA (2017) Estatística básica. Saraiva, São Paulo, 576p.), prior to the experimental analysis, an exploratory analysis of the data was performed with removal of all outliers, and the distribution and statistics of the data set were analyzed. Only for the average parameter estimates (μ) for grain yield, plant height and grain yield heritability (h ² ) no outliers were found (Figure 1A). The outliers were removed since they lead to larger errors in the residues and consequently increase the standard deviation of the intercept (β ₀ ) in regression analyses (Viechtbauer 2010Viechtbauer W (2010) Conducting meta-analisys in R with metafor package. Journal of Statistical Software 36: 1-48.). The presence of outliers indicates errors that weaken trials due to the inherent variability in plant material and/or data collection problems and ultimately, outliers can mask important results and influence the final inferences (Freitas et al. 2008Freitas AR, Barioni Júnior W, Ferreira RP, Cruz CD, Moreira A and Vilela D (2008) Técnicas de análises exploratórias em dados de cultivares de alfafa exploratory data analysis techniques in cultivars of alfalfa Material e Métodos. Revista Brasileira de Zootecnia 37: 1531-1536.).

Figure 1. Box-plot
of the original data of estimates of heritability (h ² ), coefficient of variation (CV), and average (μ) for grain yield, plant height, and days to flowering (A). Box-plot of the data excludes the outliers of the parameter estimates (B).

High amplitudes of variation for the parameter estimates were observed, especially for those based on datasets including outliers (Figure 1A). This shows the great variation between experiments, requiring the combination of specific information from these experiments to establish more accurate parameter estimates. After outlier removal, the respective amplitudes of the estimates decreased considerably (Figure 1B), eliminating possible biases. Interestingly, the exclusion of outliers for h ² of days to flowering decreased the amplitude of variation by approximately 80% (Figure 1). Without the outliers, the database of the breeding program proved representative of the different rice cultivation conditions, due to the variation and magnitudes of the estimates (Breseghello et al. 2011Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923., Morais Júnior et al. 2015Morais Júnior OP, Melo PGS, Morais OP, Castro AP, Breseghello F, Utumi MM, Pereira JA, Wruck FJ and Colombari Filho JM (2015) Genetic progress after cycles of upland rice recurrent selection. Scientia Agricola 72: 297-305., Streck et al. 2018Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105., Santos et al. 2019Santos IG, Carneiro VQ, Silva Júnior AC, Cruz CD and Soares PC (2019) Self-organizing maps in the study of genetic diversity among irrigated rice genotypes. Acta Scientiarum - Agronomy 41: 1-9.).

Based on the time meta-analysis, meta-analytical estimates of parameters indispensable for breeding were established, which reflect the diversity of the studied plant material, the experimental precision and the dynamics of the Irrigated Rice Breeding Program of Minas Gerais from 2004 to 2017.

Simple regression model

The results of the simple regression analysis (Table 1) showed that the estimated intercept (β₀) corresponded to the respective arithmetic means of the parameter estimates. Likewise, the estimated slope values (β₁) were given by the respective arithmetic means of slopes between locations.

Fixed regression model

In the fixed regression model, the signal of the estimated slope (Table 1) for the CV of grain yield (0.04) and of μ for days to flowering (0.06) was opposite to that obtained by the simple regression model (-0.0007 and -0.05, respectively). Although the magnitude of these values does not differ between the models on a larger scale, the results from the simple model could be misinterpreted, due to the direction of the slope value. According to Toler et al. (2019Toler HD, Augé RM, Benelli V, Allen FL and Ashworth AJ (2019) Global meta-analysis of cotton yield and weed suppression from cover crops. Crop Science Society of America 59: 1248-1260.), changes in the study effect could potentially result from publication bias, changes in the methodology or from real biological changes. For grain yield however, in view of the magnitudes of the intercepts and biological interpretation of the parameters, the simple regression model allowed the conclusion of a gain of 34 kg year^-1, while the gain by the fixed regression model would be 4.22 kg year^-1. In other words, the simple model indicated an eight times greater average yield gain per year than the fixed regression model.

This conclusion could have a direct impact on the objectives of the program, i.e., the decision-making process and conclusions about the effectiveness of the breeding program could be affected. In addition, the standard deviations for both intercept and slope of most parameters of the fixed were lower than of the simple model (Table 1). The implication of these results justifies the choice of a model that takes into account the variability among locations to ensure correct analysis results.

Mixed regression model

The analysis of the mixed regression model (Table 1) showed that the intercept and slope values of the parameter estimates do not differ largely from those obtained by the fixed regression model. The intercept and slope standard deviations of the parameters for the mixed were higher than for the fixed models (Table 1). The standard deviation for the random effects estimate in the mixed model is wider than the standard deviation for the fixed effect estimate in the fixed model (Schwarzer et al. 2015Schwarzer G, Carpenter JR and Rücker G (2015) Meta-analysis with R. Springer Cham, Heidelberg, 252p.). This can be explained by the estimation method of the mixed model that considers the existence of heterogeneity among locations.

Comparison of fitting between models

The fixed regression model proved advantageous, since the h² and μ estimates for the three traits and CV of grain yield had lower AIC and BIC criteria and higher logLik values (Table 2). With regard to the CV estimates for plant height and flowering days, the likelihood-ratio test showed no significant difference (p > 0.05) between the models (Table 2). In these cases, the fixed-effects model was also preferable, due to the higher coefficient of determination (R²) (Table 2). Therefore, the fixed regression model was the most adequate to predict all parameter estimates for all three traits over the years.

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Table 2. Comparison
between the models by the Akaike information criterion (AIC), Bayesian information criterion (BIC), logLik, statistical coefficient of determination (R ² ) and likelihood ratio (LR) test

In other studies, model comparisons were made to improve model fitting for the prediction of meta-analytic estimates of the parameters (Azevêdo et al. 2010Azevêdo JAG, Valadares Filho CS, Pina DS, Chizzotti ML and Valadares RFD (2010) A meta-analysis of dry matter intake in Nellore and Zebu-crosses cattle. Revista Brasileira de Zootecnia 39: 1801-1809., Vieira et al. 2013Vieira PSA, Pereira LGR, Azevêdo JAG, Neves ALA, Dantas MLR, Araújo GGL, Mistura C and Chaves AV (2013) Development of mathematical models to predict dry matter intake in feedlot Santa Ines rams. Small Ruminant Research 112: 78-84.) or to evaluate animal performance by meta-analysis (Eloy et al. 2018Eloy L, Pötter L, Lobato J, Bremm C and Laca E (2018) Reproductive performance of cattle: a meta-analytical approach. Journal of Animal Science 96: 376-376.). Adopting the AIC and BIC criteria, these authors concluded that the best option was the mixed model (random effect). Compared to this study, those results can be explained by the greater number of studies (groups) included, which increased the heterogeneity among them.

In general, the results of our study showed that after outlier exclusion, the magnitudes of the intercepts and slopes of the parameter estimates were similar by any regression model. However, the fixed and mixed models are better predictors of meta-analytic estimates, since these models also take into account the variability among locations. In addition, as the fixed effects model was advantageous, this variability is small, i.e. the variance among locations can be considered homogeneous.

A meta-analysis of a historical series must be used when specific information on the program management style and transitions in the breeding process are expected. This kind of critical analysis of the program efficiency would obtain more reliable results to help draft new actions and strategies for the development and release of new cultivars (Streck et al. 2018Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.). Therefore, the meta-analysis technique proved most appropriate to evaluate long-term parameters in breeding programs, for not only taking into account the average of the parameters, but also their variation in the groups over the course of time.

According to the time meta-analysis, the Irrigated Rice Breeding Program of Minas Gerais has been exploiting good genetic variability in relation to total variability (heritability) for grain yield (h ² = 53.74%) and high variability for plant height (h ² = 74.17%) and days to flowering (h ² = 91.62%). These results show that the progenies of high-performing parents will also tend to have a high performance (Borem et al. 2017Borem A, Miranda G and Fritsche-neto R (2017) Melhoramento de plantas. Editora UFV, Viçosa, 543p.), indicating a greater chance of success with selection in the breeding program (Vasconcelos et al. 2012Vasconcelos ES, Reis MS, Sediyama T and Cruz CD (2012) Estimativas de parâmetros genéticos da qualidade fisiológica de sementes de genótipos de soja produzidas em diferentes regiões de Minas Gerais. Semina: Ciencias Agrarias 33: 65-76.). However, this heritability value decreased over time (Figure 2), suggesting which the narrowing of the genetic base of rice mentioned for Busanello et al. (2020Busanello C, Venske E, Stafen CF, Pedrolo AM, Luz VK, Pedron T, Paniz FP, Batista BL, Magalhães Júnior AM, Oliveira AC and Pegoraro C (2020) Is the genetic variability of elite rice in southern brazil really disappearing? Crop Breeding and Applied Biotechnology 20: 1-9.) in southern Brazil also was confirmed in the Minas Gerais, requiring an effort to increase parental diversity. Aside from the search for alternatives to increase genetic variability, superior cultivars must be crossed to form a base population, as recommended by Santos et al. (2019Santos IG, Carneiro VQ, Silva Júnior AC, Cruz CD and Soares PC (2019) Self-organizing maps in the study of genetic diversity among irrigated rice genotypes. Acta Scientiarum - Agronomy 41: 1-9.).

Figure 2
Genetic progress based on the coefficient of variation, heritability, and mean for grain yield by year estimated using time meta-analysis in the period of 2004 the 2017. The points represent the mean of the experimental plots developed at the locations by year. The red line represents the regression estimated by the meta-analysis. CELP = Experimental Station Leopoldina; CELB = Experimental Station Lambari; CEGR = Experimental Station Gorotuba.

The experimental accuracy of the program proved adequate for grain yield (CV = 15.68%) and excellent for the other traits, according to the coefficients of variation. Moreover, it was stable (Figure 2), demonstrating the quality of the experimental installation and performance, allowing the expression of the variability and ensuring good data accuracy.

The annual gain for grain yield of the evaluated genotypes was 4.22 kg year^-1 (Table 2), indicating the contribution of the selected genotypes to a higher rice yield. The genetic progress for grain yield evidenced by time meta-analysis and location means from 2004 to 2017 is shown in Figure 2. The variation in the averages according to the evaluated environment and year was wide and the annual genetic progress for grain yield was 0.08%. Thus, it is necessary to reinforce the need to establish new breeding strategies to develop superior cultivars to the already released. However, in the studied period, the intensification of selection for grain quality attributes decreased the gain for grain yield (Streck et al. 2018Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.). It noteworthy that, breeding programs seek to obtain genotypes with high productivity (Woyann et al. 2019Woyann LG, Zdziarski AD, Baretta D, Meira D, Dallacorte LV and Benin G (2019) Selection of high-yielding, adapted and stable wheat lines in preliminary trials. Crop Breeding and Applied Biotechnology 19: 412-419) and despite this magnitude of genetic gain, the average grain yield (5,058.10 kg ha^-1) produced by the breeding program was almost double the mean rice grain yield recorded in Minas Gerais in the 2018/2019 growing season (CONAB 2019CONAB - Companhia Nacional de Abastecimento (2019) Boletim da safra de grãos. Available at <Available at https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos >. Accessed on April 25, 2020.
https://www.conab.gov.br/info-agro/safra... ).

The stable averages of plant height and days to flowering show that the program has contributed to develop genotypes with adequate plant height and medium cycle in the period from 2004 to 2017, which is critical for a better crop establishment and competition with weeds (Borem and Nakano 2015Borem A and Nakano PH (2015) Arroz: do plantio à colheita. Editora UFV, Viçosa, 242p.). In this period (2004 - 2017), compared with irrigated rice of the southern region (Streck et al. 2018Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.) and upland rice in the central-north region (Breseghello et al. 2011Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923.), the genetic gain of the varieties of Minas Gerais was lower for grain yield, whereas the plants were shorter and the cycle later.

The Irrigated Rice Breeding Program of Minas Gerais carried out by the partner institutions EPAMIG, Embrapa Rice and Beans and UFLA was efficient in the analyzed period (2004 to 2017). Nine rice cultivars were released, five of which destined for cultivation on irrigated floodplains and four for rice in upland areas (irrigated by rain or sprinkler irrigation) (Soares et al. 2018Soares PC, Soares AA, Reis MS, Cornélio VMO, Condê ABT and Torga PP (2018) Adaptabilidade e aceitabilidade das cultivares de arroz recomendadas para Minas Gerais, por produtores, indústrias e consumidores. Informe Agropecuário 301: 35-46.).

ACKNOWLEDGEMENTS

The authors thank the Fundação de Amparo à Pesquisa do Estado de Minas Gerais - FAPEMIG, Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001 and the Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPq for financial support. Supplementary Table available at wevertonufv@gmail.com with Weverton Gomes da Costa.

REFERENCES

Azevêdo JAG, Valadares Filho CS, Pina DS, Chizzotti ML and Valadares RFD (2010) A meta-analysis of dry matter intake in Nellore and Zebu-crosses cattle. Revista Brasileira de Zootecnia 39: 1801-1809.
Borem A, Miranda G and Fritsche-neto R (2017) Melhoramento de plantas. Editora UFV, Viçosa, 543p.
Borem A and Nakano PH (2015) Arroz: do plantio à colheita. Editora UFV, Viçosa, 242p.
Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923.
Busanello C, Venske E, Stafen CF, Pedrolo AM, Luz VK, Pedron T, Paniz FP, Batista BL, Magalhães Júnior AM, Oliveira AC and Pegoraro C (2020) Is the genetic variability of elite rice in southern brazil really disappearing? Crop Breeding and Applied Biotechnology 20: 1-9.
Bussab WO and Morettin PA (2017) Estatística básica. Saraiva, São Paulo, 576p.
Ceccarelli S (2015) Efficiency of plant breeding. Crop Science Society of America 55: 87-97.
CONAB - Companhia Nacional de Abastecimento (2019) Boletim da safra de grãos. Available at <Available at https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos >. Accessed on April 25, 2020.
» https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos
Cruz CD (2016) Genes software - extended and integrated with the R, Matlab and Selegen. Acta Scientiarum - Agronomy 38: 547-552.
Del Claro AC, Mercadante MEZ and Silva JAIV (2011) Meta‑análise de parâmetros genéticos relacionados ao consumo alimentar residual e a suas características componentes em bovinos. Pesquisa Agropecuaria Brasileira 47: 302-310.
Eloy L, Pötter L, Lobato J, Bremm C and Laca E (2018) Reproductive performance of cattle: a meta-analytical approach. Journal of Animal Science 96: 376-376.
EMBRAPA (1977) Manual de métodos de pesquisa em arroz. EMBRAPA/CNPAF, Goiânia, 106p.
Federizzi LC, Carbonell SAM, Pacheco MT and Nava IC (2012) Breeders’ work after cultivar development: the stage of recommendation. Crop Breeding and Applied Biotechnology 12: 67-74.
Fisher M (2015) Moving science forward through: Meta-analysis. CSA News 60: 4-9.
Follmann DN, Cargnelutti Filho A, Lúcio AD, Souza VQ, Caraffa M and Wartha CA (2017) Genetic progress in homogeneous regions of wheat cultivation in Rio Grande do Sul State, Brazil. Genetics and Molecular Research 16: 1-9.
Freitas AR, Barioni Júnior W, Ferreira RP, Cruz CD, Moreira A and Vilela D (2008) Técnicas de análises exploratórias em dados de cultivares de alfafa exploratory data analysis techniques in cultivars of alfalfa Material e Métodos. Revista Brasileira de Zootecnia 37: 1531-1536.
Koricheva J and Gurevitch J (2014) Uses and misuses of meta-analysis in plant ecology. Journal of Ecology 102: 828-844.
Mieulet D, Jolivet S, Rivard M, Cromer L, Vernet A, Mayonove P, Pereira L, Droc G, Courtois B, Guiderdoni E and Mercier R (2016) Turning rice meiosis into mitosis. Cell Research 26: 1242-1254.
Morais Júnior OP, Melo PGS, Morais OP, Castro AP, Breseghello F, Utumi MM, Pereira JA, Wruck FJ and Colombari Filho JM (2015) Genetic progress after cycles of upland rice recurrent selection. Scientia Agricola 72: 297-305.
Otoboni MEF, Oliveira DJLSF, Vargas PF, Pavan BE and Andrade MI (2020) Genetic parameters and gain from selection in sweet potato genotypes with high beta-carotene content. Crop Breeding and Applied Biotechnology 20: 1-9.
R Core Team (2020) R: A Language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria.
Reis GG, Fritsche-Neto R, Soares PC, Cornélio VMO, Reis MS, Morais OP and Marques TS (2015) Accuracy and genetic progress of agronomic traits in irrigated rice program in Brazil. African Journal of Agricultural Research 10: 4032-4038.
Rejesus RM, Mohanty S and Balagtas JV (2012) Forecasting global rice consumption. Department of Agricultural and Resource Economics, North Carolina State University, Raleigh, 40p.
Sandhu N, Dixit S, Swamy BPM, Vikram P, Venkateshwarlu C, Catolos M and Kumar A (2018) Positive interactions of major-effect QTLs with genetic background that enhances rice yield under drought. Scientific Reports 8: 1-13.
Sangnawakij P, Böhning D, Niwitpong SA, Adams S, Stanton M and Holling H (2019) Meta-analysis without study-specific variance information: Heterogeneity case. Statistical Methods in Medical Research 28: 196-210.
Santos IG, Carneiro VQ, Silva Júnior AC, Cruz CD and Soares PC (2019) Self-organizing maps in the study of genetic diversity among irrigated rice genotypes. Acta Scientiarum - Agronomy 41: 1-9.
Schwarzer G, Carpenter JR and Rücker G (2015) Meta-analysis with R. Springer Cham, Heidelberg, 252p.
Silva Júnior AC, Carneiro VQ, Santos IG, Costa WG, Rosado RDS, Cruz CD and Soares PC (2019) Performance of a breeding program for irrigated rice in southeast Brazil. Genetics and Molecular Research 18: 1-10.
Soares PC, Soares AA, Reis MS, Cornélio VMO, Condê ABT and Torga PP (2018) Adaptabilidade e aceitabilidade das cultivares de arroz recomendadas para Minas Gerais, por produtores, indústrias e consumidores. Informe Agropecuário 301: 35-46.
Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.
Toler HD, Augé RM, Benelli V, Allen FL and Ashworth AJ (2019) Global meta-analysis of cotton yield and weed suppression from cover crops. Crop Science Society of America 59: 1248-1260.
Vasconcelos ES, Reis MS, Sediyama T and Cruz CD (2012) Estimativas de parâmetros genéticos da qualidade fisiológica de sementes de genótipos de soja produzidas em diferentes regiões de Minas Gerais. Semina: Ciencias Agrarias 33: 65-76.
Viechtbauer W (2010) Conducting meta-analisys in R with metafor package. Journal of Statistical Software 36: 1-48.
Vieira PSA, Pereira LGR, Azevêdo JAG, Neves ALA, Dantas MLR, Araújo GGL, Mistura C and Chaves AV (2013) Development of mathematical models to predict dry matter intake in feedlot Santa Ines rams. Small Ruminant Research 112: 78-84.
Woyann LG, Zdziarski AD, Baretta D, Meira D, Dallacorte LV and Benin G (2019) Selection of high-yielding, adapted and stable wheat lines in preliminary trials. Crop Breeding and Applied Biotechnology 19: 412-419

Publication Dates

Publication in this collection
11 Dec 2020
Date of issue
2020

History

Received
02 Dec 2019
Accepted
27 Apr 2020
Published
15 Oct 2020

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

[1] Azevêdo JAG, Valadares Filho CS, Pina DS, Chizzotti ML and Valadares RFD (2010) A meta-analysis of dry matter intake in Nellore and Zebu-crosses cattle. Revista Brasileira de Zootecnia 39: 1801-1809.

[2] Borem A, Miranda G and Fritsche-neto R (2017) Melhoramento de plantas. Editora UFV, Viçosa, 543p.

[3] Borem A and Nakano PH (2015) Arroz: do plantio à colheita. Editora UFV, Viçosa, 242p.

[4] Breseghello F, Morais OP, Pinheiro PV, Silva ACS, Castro EM, Guimarães ÉP, Castro AP, Pereira JA, Lopes AM, Utumi MM and Oliveira JP (2011) Results of 25 years of upland rice breeding in Brazil. Crop Science Society of America 51: 914-923.

[5] Busanello C, Venske E, Stafen CF, Pedrolo AM, Luz VK, Pedron T, Paniz FP, Batista BL, Magalhães Júnior AM, Oliveira AC and Pegoraro C (2020) Is the genetic variability of elite rice in southern brazil really disappearing? Crop Breeding and Applied Biotechnology 20: 1-9.

[6] Bussab WO and Morettin PA (2017) Estatística básica. Saraiva, São Paulo, 576p.

[7] Ceccarelli S (2015) Efficiency of plant breeding. Crop Science Society of America 55: 87-97.

[8] CONAB - Companhia Nacional de Abastecimento (2019) Boletim da safra de grãos. Available at <Available at https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos >. Accessed on April 25, 2020.
» https://www.conab.gov.br/info-agro/safras/graos/boletim-da-safra-de-graos

[9] Cruz CD (2016) Genes software - extended and integrated with the R, Matlab and Selegen. Acta Scientiarum - Agronomy 38: 547-552.

[10] Del Claro AC, Mercadante MEZ and Silva JAIV (2011) Meta‑análise de parâmetros genéticos relacionados ao consumo alimentar residual e a suas características componentes em bovinos. Pesquisa Agropecuaria Brasileira 47: 302-310.

[11] Eloy L, Pötter L, Lobato J, Bremm C and Laca E (2018) Reproductive performance of cattle: a meta-analytical approach. Journal of Animal Science 96: 376-376.

[12] EMBRAPA (1977) Manual de métodos de pesquisa em arroz. EMBRAPA/CNPAF, Goiânia, 106p.

[13] Federizzi LC, Carbonell SAM, Pacheco MT and Nava IC (2012) Breeders’ work after cultivar development: the stage of recommendation. Crop Breeding and Applied Biotechnology 12: 67-74.

[14] Fisher M (2015) Moving science forward through: Meta-analysis. CSA News 60: 4-9.

[15] Follmann DN, Cargnelutti Filho A, Lúcio AD, Souza VQ, Caraffa M and Wartha CA (2017) Genetic progress in homogeneous regions of wheat cultivation in Rio Grande do Sul State, Brazil. Genetics and Molecular Research 16: 1-9.

[16] Freitas AR, Barioni Júnior W, Ferreira RP, Cruz CD, Moreira A and Vilela D (2008) Técnicas de análises exploratórias em dados de cultivares de alfafa exploratory data analysis techniques in cultivars of alfalfa Material e Métodos. Revista Brasileira de Zootecnia 37: 1531-1536.

[17] Koricheva J and Gurevitch J (2014) Uses and misuses of meta-analysis in plant ecology. Journal of Ecology 102: 828-844.

[18] Mieulet D, Jolivet S, Rivard M, Cromer L, Vernet A, Mayonove P, Pereira L, Droc G, Courtois B, Guiderdoni E and Mercier R (2016) Turning rice meiosis into mitosis. Cell Research 26: 1242-1254.

[19] Morais Júnior OP, Melo PGS, Morais OP, Castro AP, Breseghello F, Utumi MM, Pereira JA, Wruck FJ and Colombari Filho JM (2015) Genetic progress after cycles of upland rice recurrent selection. Scientia Agricola 72: 297-305.

[20] Otoboni MEF, Oliveira DJLSF, Vargas PF, Pavan BE and Andrade MI (2020) Genetic parameters and gain from selection in sweet potato genotypes with high beta-carotene content. Crop Breeding and Applied Biotechnology 20: 1-9.

[21] R Core Team (2020) R: A Language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria.

[22] Reis GG, Fritsche-Neto R, Soares PC, Cornélio VMO, Reis MS, Morais OP and Marques TS (2015) Accuracy and genetic progress of agronomic traits in irrigated rice program in Brazil. African Journal of Agricultural Research 10: 4032-4038.

[23] Rejesus RM, Mohanty S and Balagtas JV (2012) Forecasting global rice consumption. Department of Agricultural and Resource Economics, North Carolina State University, Raleigh, 40p.

[24] Sandhu N, Dixit S, Swamy BPM, Vikram P, Venkateshwarlu C, Catolos M and Kumar A (2018) Positive interactions of major-effect QTLs with genetic background that enhances rice yield under drought. Scientific Reports 8: 1-13.

[25] Sangnawakij P, Böhning D, Niwitpong SA, Adams S, Stanton M and Holling H (2019) Meta-analysis without study-specific variance information: Heterogeneity case. Statistical Methods in Medical Research 28: 196-210.

[26] Santos IG, Carneiro VQ, Silva Júnior AC, Cruz CD and Soares PC (2019) Self-organizing maps in the study of genetic diversity among irrigated rice genotypes. Acta Scientiarum - Agronomy 41: 1-9.

[27] Schwarzer G, Carpenter JR and Rücker G (2015) Meta-analysis with R. Springer Cham, Heidelberg, 252p.

[28] Silva Júnior AC, Carneiro VQ, Santos IG, Costa WG, Rosado RDS, Cruz CD and Soares PC (2019) Performance of a breeding program for irrigated rice in southeast Brazil. Genetics and Molecular Research 18: 1-10.

[29] Soares PC, Soares AA, Reis MS, Cornélio VMO, Condê ABT and Torga PP (2018) Adaptabilidade e aceitabilidade das cultivares de arroz recomendadas para Minas Gerais, por produtores, indústrias e consumidores. Informe Agropecuário 301: 35-46.

[30] Streck EA, Magalhaes Júnior AM, Aguiar GA, Facchinello PKH, Fagundes PRR, Franco DF, Nardino M and Oliveira AC (2018) Genetic progress in 45 years of irrigated rice breeding in Southern Brazil. Crop Science Society of America 58: 1094-1105.

[31] Toler HD, Augé RM, Benelli V, Allen FL and Ashworth AJ (2019) Global meta-analysis of cotton yield and weed suppression from cover crops. Crop Science Society of America 59: 1248-1260.

[32] Vasconcelos ES, Reis MS, Sediyama T and Cruz CD (2012) Estimativas de parâmetros genéticos da qualidade fisiológica de sementes de genótipos de soja produzidas em diferentes regiões de Minas Gerais. Semina: Ciencias Agrarias 33: 65-76.

[33] Viechtbauer W (2010) Conducting meta-analisys in R with metafor package. Journal of Statistical Software 36: 1-48.

[34] Vieira PSA, Pereira LGR, Azevêdo JAG, Neves ALA, Dantas MLR, Araújo GGL, Mistura C and Chaves AV (2013) Development of mathematical models to predict dry matter intake in feedlot Santa Ines rams. Small Ruminant Research 112: 78-84.

[35] Woyann LG, Zdziarski AD, Baretta D, Meira D, Dallacorte LV and Benin G (2019) Selection of high-yielding, adapted and stable wheat lines in preliminary trials. Crop Breeding and Applied Biotechnology 19: 412-419

Simple Regression Model
Parameters	Grain yield		Plant height		Days to flowering
Parameters	β ₀	β ₁	β ₀	β ₁	β ₀	β ₁
h ²	54.86 (±2.69)	-3.02 (±0.65)	76.06 (±2.04)	-0.09 (±0.49)	91.77 (±1.27)	-0.02 (±0.30)
CV	15.56 (±0.54)	-0.0007 (±0.13)	4.33 (±0.21)	-0.01 (±0.05)	1.55 (±0.15)	-0.03 (±0.04)
μ	4996.88 (±169.39)	34.00 (±41.87)	92.47 (±1.27)	0.56 (±0.31)	107.60 (±1.18)	0.05 (±0.29)
Fixed Regression Model
Parameters	Grain yield		Plant height		Days to flowering
Parameters	β ₀	β ₁	β ₀	β ₁	β ₀	β ₁
h ²	53.74 (±2.79)	-3.27 (±0.66)	74.17 (±1.97)	-0.09 (±0.47)	91.62 (±1.29)	-0.02 (±0.31)
CV	15.68 (±0.55)	0.04 (±0.13)	4.41 (±0.21)	-0.01 (±0.05)	1.59 (±0.16)	-0.02 (±0.04)
μ	5058.10 (±151.8)	4.22 (±37.49)	91.35 (±0.88)	0.37 (±0.21)	107.49 (±1.21)	-0.06 (±0.30)
Mixed Regression Model
Parameters	Grain yield		Plant height		Days to flowering
Parameters	β ₀	β ₁	β ₀	β ₁	β ₀	β ₁
h ²	54.65 (±2.65)	-3.19 (±0.91)	74.70 (±4.76)	-0.07 (±0.47)	91.68 (±1.87)	-0.02 (±0.41)
CV	15.64 (±0.86)	0.01 (±0.14)	4.38 (±0.34)	-0.01 (±0.08)	1.57 (±0.20)	-0.02 (±0.04)
μ	5048.19 (±595.95)	9.46 (±36.96)	91.35 (±4.89)	0.38 (±0.22)	107.58 (±1.64)	0.003 (±0.29)

Grain yield
Parameters	Model	AIC	BIC	logLik	R²(%)	LR test*		p-value
h ²	Simple¹	435.823	441.436	-214.911	31.38
	Fixed²	422.690	435.179	-204.345	38.13	1vs2	21.132	0.0003
	Mixed³	441.135	452.362	-214.567	35.93	2vs3	20.445	<0.0001
CV	Simple¹	268.096	273.582	-131.048	0.00
	Fixed²	266.028	278.192	-126.014	13.77	1vs2	10.068	0.0393
	Mixed³	272.791	283.763	-130.396	10.45	1vs2	8.763	0.0031
μ	Simple¹	1014.390	1020.571	-504.195	1.12
	Fixed²	951.120	965.043	-468.560	33.48	1vs2	71.270	<0.0001
	Mixed³	1004.824	1017.187	-496.412	33.14	2vs3	55.704	<0.0001
Plant height
Parameters	Model	AIC	BIC	logLik	R²(%)	LR test*		p-value
h ²	Simple¹	436.677	442.473	-215.338	0.07
	Fixed²	419.441	432.392	-202.721	20.72	1vs2	25.236	<0.0001
	Mixed³	437.795	449.386	-212.897	18.48	2vs3	20.354	<0.0001
CV	Simple¹	219.566	225.533	-106.783	0.08
	Fixed²	223.747	237.131	-104.873	14.11	1vs2	3.820	0.4310
	Mixed³	223.268	235.202	-105.634	12.09	2vs3	1.522	0.2174
μ	Simple¹	446.519	452.701	-220.259	5.25
	Fixed²	394.997	408.919	-190.498	61.63	1vs2	59.523	<0.0001
	Mixed³	409.337	421.699	-198.668	61.55	2vs3	16.340	0.0001
Days to flowering
Parameters	Model	AIC	BIC	logLik	R²(%)	LR test*		p-value
h ²	Simple¹	219.549	223.752	-106.774	0.03
	Fixed²	215.892	222.553	-102.946	9.95	1vs2	7.657	0.0217
	Mixed³	224.683	233.090	-106.341	8.94	2vs3	6.791	0.0092
CV	Simple¹	92.080	96.284	-43.040	1.75
	Fixed²	98.115	104.776	-44.057	7.53	1vs2	2.034	0.3616
	Mixed³	97.885	106.292	-42.943	5.66	2vs3	2.229	0.1354
μ	Simple¹	253.306	257.972	-123.653	0.07
μ	Fixed²	250.935	258.418	-120.468	5.63	1vs2	6.370	0.0414
Mixed³	259.046	268.378	-123.523	4.01	2vs3	6.111	0.0134