Multivariate best linear unbiased predictor as a tool to improve multi-trait selection in sugarcane

Carvalho, Ivan Ricardo; Szareski, Vinícius Jardel; Silva, José Antônio Gonzalez da; Nunes, Andrei Caíque Pires; Rosa, Tiago Corazza da; Barbosa, Maurício Horbach; Magano, Deivid Araújo; Conte, Giordano Gelain; Caron, Braulio Otomar; Souza, Velci Queiróz de

doi:10.1590/S1678-3921.pab2020.v55.00518

Abstract:

The objective of this work was to evaluate the use of the multivariate best linear unbiased predictor (BLUP) method for multi-trait selection, to estimate the genetic parameters in sugarcane (Saccharum officinarum) genotypes. The experiment was carried out in a randomized complete block design with 21 sugarcane genotypes, in seven crop years, in a factorial arrangement with three replicates. The measured traits were: total yield of stems per hectare, total volume of juice per hectare, production of total soluble sugars, and stem length. The source variation in the crop years strongly contributed for the obtention of the expected values of the sum of squares, without causing distortions in the variance components and genetic variables. The measured traits showed genetic variability and allowed of efficient univariate and multivariate selections. The highest selection efficiency was obtained by using more than eight measurements, since they favored the estimates of heritability, accuracy, and repeatability. The 'IAC873396', 'Nova Iraí', 'IACSP 93-6006', and 'RB 835089' genotypes were superior as to the traits tested, regardless of the crop year. The BLUP multivariate technique for multi-trait selection is robust and allows of the increasing of the selection gains, accuracy, and reliability of predictions for sugarcane breeding.

Index terms:
Saccharum officinarum; multi-trait selection; multivariate models; repeatability

Resumo:

O objetivo deste trabalho foi avaliar o uso do método multivariado de melhor preditor linear não viesado (BLUP), para estimar os parâmetros genéticos em genótipos de cana-de-açúcar (Saccharum officinarum). O experimento foi realizado em delineamento de blocos ao acaso, com 21 genótipos de cana-de-açúcar, em sete anos agrícolas, em arranjo fatorial com três repetições. As características medidas foram: rendimento total de caules por hectare, volume total de suco por hectare, produção de açúcares solúveis totais e comprimento do caule. A variação da fonte nos anos agrícolas contribuiu fortemente para a obtenção dos valores esperados da soma dos quadrados, sem causar distorções das estimativas dos componentes de variância e parâmetros genéticos. As características medidas apresentaram variabilidade genética e permitiram seleções univariada e multivariada eficientes. A maior eficiência de seleção foi obtida com o uso de mais de oito medições, pois elas favoreceram as estimativas de herdabilidade, precisão e repetibilidade. Os genótipos 'IAC873396', 'Nova Iraí', 'IACSP 93-6006' e 'RB 835089' foram superiores para as características testadas, independentemente do ano agrícola. A técnica multivariada BLUP para a seleção multicaracterísticas é robusta e permite aumentar os ganhos de seleção, a acurácia e a confiabilidade das predições para o melhoramento da cana-de-açúcar.

Termos para indexação:
Saccharum officinarum; seleção multicaracterísticas; modelos multivariados; repetibilidade

Introduction

Brazil stands out as the largest producer of sugarcane (Saccharum officinarum) worldwide (FAO, 2017FAO. Food and Agriculture Organization of the United Nations. Faostat: statistics. Available at: <Available at: http://www.fao.org/statistics/ >. Accessed on: Oct. 8 2017.
http://www.fao.org/statistics/... ). Currently, nearly nine million hectares of sugarcane is established in Brazil, with 657 million tons of phytomass production. The volume of national production is highly influenced by the Southeast region expressiveness, which represents 65% of it, followed by the Midwest (21%), Northeast (7%), South (6%), and North (1%) regions (Acompanhamento…, 2016ACOMPANHAMENTO DA SAFRA BRASILEIRA [DE] CANA-DE-AÇÚCAR: safra 2016/17: segundo levantamento, v.3, n.2, ago. 2016. Available at: <Available at: https://www.conab.gov.br/info-agro/safras/cana/boletim-da-safra-de-cana-de-acucar?start=10 > Accessed on: Oct. 8 2019.
https://www.conab.gov.br/info-agro/safra... ).

The sugarcane cultivation requires some specific edaphoclimatic conditions, in order to achieve high yields, and maximize the use of available resources. This crop requires 1,500 mm of rainfall (Neupane & Guo, 2019NEUPANE, J.; GUO, W. Agronomic basis and strategies for precision water management: a review. Agronomy, v.9, art.87, 2019. DOI; https://doi.org/10.3390/agronomy9020087.
https://doi.org/10.3390/agronomy9020087... ). The maximum yield requires thermal amplitude between 20ºC and 38ºC, which is considered the optimal range for growth and development of the plants. Sugarcane has a large capacity of extracting soil nutrients such as potassium, nitrogen, calcium, magnesium, phosphorus, sulfur, iron, zinc, manganese, and boron (Silva & Silva, 2012SILVA, J.P.N. da; SILVA, M.R.N. da. Noções da cultura da cana-de-açúcar. Inhumas: IFG; Santa Maria: Universidade Federal de Santa Maria, 2012. 105p.).

Brazilian growing regions show many varied conditions and edaphoclimatic features; therefore, there is a need to identify which genotypes are superior for yield, quality, and yield stability. To maximize the success of genetic breeding programs, the use of the multi-trait index has been applied in plant breeding and has led to an increase in the selection efficiency of traits desirable, looking for economically important traits (Pelegrin et al., 2017PELEGRIN, A.J. de; CARVALHO, I.R.; NUNES, A.C.P.; DEMARI, G.H.; SZARESKI, V.J.; BARBOSA, M.H.; ROSA, T.C.; FERRARI, M.; NARDINO, M.; SANTOS, O.P. dos; RESENDE, M.D.V. de; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Adaptability, stability and multivariate selection by mixed models. American Journal of Plant Sciences, v.8, p.3324-3337, 2017. DOI: https://doi.org/10.4236/ajps.2017.813224.
https://doi.org/10.4236/ajps.2017.813224... ). Similarly, genetic gains in sugarcane breeding programs are dependent on the choice of traits, the magnitude of heritability, and the spatial and temporal repeatability of these parameters (Eeuwijk et al., 2019EEUWIJK, F.A. van; BUSTOS-KORTS, D.; MILLET, E.J.; BOERA, M.P.; KRUIJER, W.; THOMPSON, A.; MALOSETTI, M.; IWATA, H.; QUIROZ, R.; KUPPE, C.; MULLER, O.; BLAZAKIS, K.N.; YU, K.; TARDIEU, F.; CHAPMAN, S.C. Modelling strategies for assessing and increasing the effectiveness of new phenotyping techniques in plant breeding. Plant Science, v.282, p.23-39, 2019. DOI: https://doi.org/10.1016/j.plantsci.2018.06.018.
https://doi.org/10.1016/j.plantsci.2018.... ).

A strategy to solve questions on cultivar selections is based on the adoption of mathematical models. In this sense, according to Vittorazzi et al. (2017)VITTORAZZI, C.; AMARAL JUNIOR, A.T.; GUIMARÃES, A.G.; VIANA, A.P.; SILVA, F.H.L.; PENA, G.F.; DAHER, R.F.; GERHARDT, I.F.S.; OLIVEIRA, G.H.F.; PEREIRA, M.G. Indices estimated using REML/BLUP and introduction of a super-trait for the selection of progenies in popcorn. Genetics and Molecular Research, v.16, gmr16039769, 2017. DOI: https://doi.org/10.4238/gmr16039769.
https://doi.org/10.4238/gmr16039769... , the best linear unbiased prediction (BLUP) is a standard method for estimating the random effects of a mixed model. This method was originally developed in animal breeding, for the estimation of breeding values. It is now widely used in many areas of research. However, there are no reports on the use of a BLUP multivariate selection, to estimate a joint value of heritability for sugarcane. The use of this approach could allow of the selection of sugarcane genotypes with greater efficiency, adaptability, and stability. It performs better than other conventional methods, such as linear models, nonlinear models, regression bi-segmented models, and it is also better than methods combining additive effects and multiplicative interactions that could not describe the behavior of multi-trait quality with excellent fit for sugarcane production.

The objective of this work was to evaluate the multivariate best linear unbiased predictor method (BLUP) for a multi-trait selection to estimate the genetic parameters in sugarcane genotypes.

Materials and Methods

The study was carried out in the experimental area of the Universidade Federal de Santa Maria, Campus Frederico Westphalen (27^o39'56"S, 53^o42'94"W, at 490 m altitude), in the state of Rio Grande do Sul, Brazil, in seven crop years - 2010, 2011, 2012, 2013, 2014, 2015, and 2016 (Table 1).

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Table 1.
Crop years and sugarcane genotypes evaluated in the experimental area.

The soil of the experimental area is classified as a Latossolo Vermelho distrófico típico (Oxisols) according Santos et al., (2018)SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de LUMBRERAS, J.F.; COELHO, M.R.; ALMEIDA, J.A. de; ARAUJO FILHO, J.C. de; OLIVEIRA, J.B. de; CUNHA, T.J.F. Sistema brasileiro de classificação de solos. 5.ed. rev. e ampl. Brasília: Embrapa, 2018. 356p.. The climate, according to the Köppen-Geiger’s classification, is a subtropical Cfa.

The experimental design was in a randomized complete block, in a factorial arrangement, with seven crop year cultivations × 21 sugarcane genotypes, with three replicates (Table 1).

The following traits were measured between August 15^th and September 7^th, in each one of the seven crop years: total yield of stems per hectare (TYSH); total volume of juice per hectare (TVJH); production of total soluble sugars (PTSS); and stem length (LENG). The TYSH was obtained by count, harvest, and determination of the mass of the total number of stems per experimental unit. Then, calculations were performed for the ratio between total mass of stems per experimental unit, and the number of stems. The results (Mg ha^-1) were adjusted to the population density employed.

For TVJH, the stems harvested in the experimental unit were cleaned and milled, and the magnitude of the liquid extracted was measured in a graduated cylinder. The results obtained for juice yield per stem (L ha^-1) were adjusted to the population density employed.

For PTSS, the stems located in the useful area of the experimental unit were selected, and two representative stems were chosen, which were sent to the laboratory for evaluation of the Brix degree by an analogical refractometer RHB62 (AKSO Measurement Instruments, São Leopoldo, RS, Brazil), at the basal, medium and superior portion of each stem. After this evaluation, the results (kg ha^-1) were adjusted through the magnitude of juice per unit of area.

The LENG was evaluated by measuring 10 stems (cm) from their basal (cutting point) to the apical extremity (point of meristems differentiation) per experimental unit. All growing treats were carried out in a standardized way for the crop years, and the experimental units were constituted by five lines of plants spaced at 1.2 m, with 6 m length, which resulted in a population density of 25,000 viable plants ha^-1.

The data were subjected to the analysis of variance, at 5% of probability, in order to verify the assumptions of the model (Ramalho et al., 2012RAMALHO, M.A.P.; SANTOS, J.B. dos; PINTO, C.A.B.P.; SOUZA, E.A. de; GONÇALVES, F.M.A.; SOUZA, J.C. de. Genética na agropecuária. 5.ed. rev. Lavras: UFLA, 2012. 566p.). Subsequently, the joint analysis was carried out to identify the presence of interaction between the crop year cultivations × sugarcane genotypes at 5% of probability. The traits that showed significant interactions were subjected to the method of the relative contribution for interaction of the mean-square expected values, in order to understand which levels of treatment are determinant for the significance of the results (Carvalho et al., 2017CARVALHO, I.R.; NARDINO, M.; DEMARI, G.H.; PELEGRIN, A.J. de; FERRARI, M.; SZARESKI, V.J.; OLIVEIRA, V.F. de; BARBOSA, M.H.; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Components of variance and inter-relation of important traits for maize (Zea mays) breeding. Australian Journal Crop Science, v.11, p.982-988, 2017. DOI: https://doi.org/10.21475/ajcs.17.11.08.pne474.
https://doi.org/10.21475/ajcs.17.11.08.p... ). Subsequently, a multi-trait index was applied, combining the TYSH and PTSS effects, since these traits show a similar economic importance and should be selected simultaneously. Later, a multi-trait phenotypic index with a single tendency (Nunes et al., 2017NUNES, A.C.P.; RESENDE, M.D.V. de; SANTOS, G.A. dos; ALVES, R.S. Evaluation of different selection indices combining Pilodyn penetration and growth performance in Eucalyptus clones. Crop Breeding and Applied Biotechnology, v.17, p.206-213, 2017. DOI: https://doi.org/10.1590/1984-70332017v17n3a32.
https://doi.org/10.1590/1984-70332017v17... ) was calculated with the following equation:

P I = (T Y S H / S_T Y S H) \times (P T S S / S_P T S S)

The data were subjected to the deviance analysis, at 5% of probability, by the chi-square test (Resende, 2007RESENDE, M.D.V. de. SELEGEN-REML/BLUP: sistema estatístico e seleção genética computadorizada via modelos lineares mistos. Colombo: Embrapa Florestas, 2007. 359p.), which bases the significance and reliability of parameters obtained by mixed statistical models. Subsequently, the components of variance and the genetic parameters were estimated through the restricted maximum likelihood method (REML), by the statistical model

Y = X r + Z g + W i + e,

in which: Y refers to the data vector of each trait; r is the effect of replicates (fixed); g is the effect of genotypes (random); i is the effect attributed to the interaction genotypes × environments (random); and e represents the residues (random).

This approach allowed of the following estimations for: the individual broad sense heritability (ĥ²g); repeatability of the parameter (r); coefficient of determination of the permanent effects (C²perm); coefficient of determination for the genotype × crop year interaction (C²gm); genotypic correlation between the crop years (rgmed); the broad sense heritability free from the effects of the interaction genotypes × crop years (ĥ²mg); the accuracy (Ac); and the overall mean of the traits.

The definition of the genetic parameters made it possible to use the best linear unbiased predictor (BLUP) method to predict the genetic values (Henderson, 1975HENDERSON, C.R. Best linear unbiased estimation and prediction under a selection model. Biometrics, v.31, p.423-447, 1975. DOI: https://doi.org/10.2307/2529430.
https://doi.org/10.2307/2529430... ). This allowed of the ranking of the genotypes through the multi-trait phenotypic index (PI), and, then, the TYSH, TVJH, PTSS, LENG, and the phenotypic index (TYSH × PTSS) used to compose the genetic index of the selection, which is derived from the five conjugated traits, based on the following equation:

G I = b_{1} g o + b_{2} g a_{1} + b_{3} g a_{2} + b_{4} g a_{3} + b_{5} g a_{4}

in which: GI represents the multi-trait genetic index; go represents the standardized genotypic value for the objective trait (PI = TYSH × PTSS); and gai represents the standardized genotypic value of the auxiliary traits (TYSH, TVJH, PTSS and LENG). The weighting coefficients (bi) of the index are given by Viana & Resende (2014)VIANA, A.P.; RESENDE, M.D.V. de. Genética quantitativa no melhoramento de fruteiras. Rio de Janeiro: Interciência, 2014. 282p. by the equation b = P - 1 C, in which:

P = [\begin{matrix} r_{\hat{g} o}^{2} & r_{\hat{g} o}^{2} r_{\hat{g} a 1}^{2} r_{\hat{g} o g a 1} & r_{\hat{g} o}^{2} r_{\hat{g} a 2}^{2} r_{\hat{g} o \hat{g} a 2} & r_{\hat{g} o}^{2} r_{\hat{g} a 3}^{2} r_{\hat{g} o \hat{g} a 3} & r_{\hat{g} o}^{2} r_{\hat{g} a 4}^{2} r_{\hat{g} o \hat{g} a 4} \\ r_{\hat{g} a 1}^{2} & r_{\hat{g} a 1}^{2} r_{\hat{g} a 2}^{2} r_{\hat{g} a 1 \hat{g} a 2} & r_{\hat{g} a 1}^{2} r_{\hat{g} a 3}^{2} r_{\hat{g} a 1 \hat{g} a 3} & r_{\hat{g} a 1}^{2} r_{\hat{g} a 4}^{2} r_{\hat{g} a 1 \hat{g} a 4} \\ r_{\hat{g} a 2}^{2} & r_{\hat{g} a 2}^{2} r_{\hat{g} a 3}^{2} r_{\hat{g} a 2 \hat{g} a 3} & r_{\hat{g} a 2}^{2} r_{\hat{g} a 4}^{2} r_{\hat{g} a 2 \hat{g} a 4} \\ Sim & r_{\hat{g} a 3}^{2} & r_{\hat{g} a 3}^{2} r_{\hat{g} a 4}^{2} r_{\hat{g} a 3 \hat{g} a 4} \\ r_{\hat{g} a 4}^{2} \end{matrix}]

C = [\begin{matrix} r_{\hat{g} o}^{2} \\ r_{\hat{g} a 1}^{2} r_{\hat{g} o \hat{g} a 1} \\ r_{\hat{g} a 2}^{2} r_{\hat{g} o \hat{g} a 2} \\ r_{\hat{g} a 3}^{2} r_{\hat{g} o \hat{g} a 3} \\ r_{\hat{g} a 4}^{2} r_{\hat{g} o \hat{g} a 4} \end{matrix}]

After defining the parameters, the genetic covariance between the predicted genetic value of the trait PI (TYSH × PTSS) and the five informational traits that represent the predicted genetic values standardized the target (PI) and auxiliary traits (TYSH, TVJH, PTSS and LENG), in which: r(ĝo)² represents the reliability of the selection based on the objective trait (PI); r(ĝa1)² evidences the reliability of selection based on the auxiliary trait TYSH; r(ĝa₂)² is the reliability of selection based on the auxiliary trait TVJH; r(ĝoĝa₁) represents the genetic correlation between the objective trait and the auxiliary trait TYSH; r(ĝoĝa₂) refers to the genetic correlation between the objective trait (PI) and the auxiliary TVJH; and r(ĝa1ĝa₂) is evidenced as the genetic correlation between the two auxiliary traits. The reliability of the index is given by the ratio between the variance of the index (GI) and the genetic variance of the PI trait as rgg²=Var (index)/σg², with the standardization of the predicted genetic values, σg²=1 andrgg²=Var (index). Therefore, the index variance is given by Var (index)= b’Pb.

Consequently, the accuracy of GI is given by the square root of the reliability. In order to correlate the rankings of the genotypes using the multi-trait approach, through the phenotypic index (PI), the predicted genotypic value (u+g) was employed with the genotypic value added to the average interaction (u+g+gem). This operation made it possible to express the estimates of stability (MHVG), adaptability (PRVG), as well as to express simultaneously those of stability, adaptability, and yield (MHPRVG*MG). These combined procedures evidenced the presence of variability for the genotype ranking. To perform the statistical analyses, the software’s SAS (SAS Institute Inc., Cary, NC, USA), Genes (Cruz, 2013CRUZ, C.D. GENES: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, v.35, p.271-276, 2013. DOI: https://doi.org/10.4025/actasciagron.v35i3.21251.
https://doi.org/10.4025/actasciagron.v35... ), R (R Core Team, 2015R CORE TEAM. R: a language and environment for statistical computing. Vienna: R Foundation for Statistical Computing, 2015.), and Selegen (Resende, 2007RESENDE, M.D.V. de. SELEGEN-REML/BLUP: sistema estatístico e seleção genética computadorizada via modelos lineares mistos. Colombo: Embrapa Florestas, 2007. 359p.) were used.

Results and Discussion

There was a significant interaction between crop years and sugarcane genotypes. The traits TYSH, TVJH, and PTSS showed no interaction between the different sources of variability. However, there was an intrinsic variability for principal effects by crop years and sugarcane genotypes (Table 2). Due to the method of the relative contribution of expected values of the sum of squares for the interaction based on the presence of simple effects, its use was possible only for the LENG trait. The 'IACSP 93-6006' (G1), 'IAC87-3396' (G3), 'IAC91-5155' (G4), 'Nova Iraí' (G8), 'Pernambucana' (G10), 'Preguiçosa' (G15), and 'IAC873396' (G19) genotypes contributed 6.1% average for the effects of genotype × environment interactions. Probably, these genotypes express abrupt variations of plant growth and development. In contrast, the 'RB 855453' (2.6%), 'SP716163' (3.4%) and 'RB 765418' (2.80%) genotypes showed the lower contributions for the interaction of expected values of the sum of squares. These genotypes were considered most stable phenotypically, whereas, stem length showed a lower phenotypic plasticity.

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Table 2.
Variance analysis for the traits total yield of stems per hectare (TYSH), total volume of juice per hectare (TVJH), production of total soluble sugars (PTSS), and stem length (LENG) measured in sugarcane genotypes grown in seven crop years.

The crop years 2011, 2013, and 2015 contributed 18.1% for the effects of genotypes × environments interactions. These results are essential to understand the abrupt effects on phenotypic modification of traits caused by edaphoclimatic variations of growing environments. Although the present study is based on seven crop years, using sugarcane clones, an oscillation in the magnitude was verified, which influences the estimation and repeatability of parameters of interest.

There were significance and reliability for the variance components and genetic parameters obtained by the REML method for TYSH, PTSS, LENG and PI (Table 3). The highest magnitudes of individual broad sense heritability (h²g) were obtained through the LENG. These estimates are indicative of the presence of genetic variability available for selection among the studied genotypes.

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Table 3.
Estimates of genetic parameters (REML) for the multi-trait phenotypic index (PI), total yield of stems per hectare (TYSH), total volume of juice per hectare (TVJH), production of total soluble sugars (PTSS), and stem length (LENG), measured in 21 sugarcane genotypes grown in seven crop years.

For all traits, the magnitudes of estimates increased, except for the broad-sense parameter heritability free from the effects of the interaction genotypes × crop years (ĥ²mg). These results show that there is an inclination to h²g. The magnitudes of mg²mg showed up higher than h²g because that crop year has exerted on traits under the phenotypic manifestation for the 7 years in evaluation. Usually, the genetic breeding involves only the phenotypic manifestation of traits, which is of extreme importance to identify and quantify the effects of crop years, or growing environments, on the phenotype, allowing of achieving estimates and reliable predictions of the genetic value of certain genotype. In this study, the traits YSH, PTSS, and LENG were considered more stable throughout the breeding generations, irrespectively of the repeatability of genetic parameters.

Regarding repeatability, Pelegrin et al. (2017)PELEGRIN, A.J. de; CARVALHO, I.R.; NUNES, A.C.P.; DEMARI, G.H.; SZARESKI, V.J.; BARBOSA, M.H.; ROSA, T.C.; FERRARI, M.; NARDINO, M.; SANTOS, O.P. dos; RESENDE, M.D.V. de; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Adaptability, stability and multivariate selection by mixed models. American Journal of Plant Sciences, v.8, p.3324-3337, 2017. DOI: https://doi.org/10.4236/ajps.2017.813224.
https://doi.org/10.4236/ajps.2017.813224... , classified as high (r> 0.60), intermediate (0.30 <r<0.60), and low (r<0.30). According to this classification, all measured traits showed low repeatability in the present study. The increment of a trait’s repeatability maximizes the precision of selection strategies. Both the coefficient of determination of the permanent effects (c²perm) and the coefficient of determination of the genotypes × environments interaction effects (c²gm) are low, indicating that intrinsic features of each crop year influence these sugarcane genotypes. Therefore, the phenotypic plasticity of this crop should be considered.

The obtained estimates showed moderate but reliable accuracies due to the study’s representativeness. Resende & Duarte (2007)RESENDE, M.D.V. de; DUARTE, J.B. Precisão e controle de qualidade em experimentos de avaliação de cultivares. Pesquisa Agropecuária Tropical, v.37, p.182-194, 2007. classified the accuracy according to its magnitudes as of low precision (Ac<0,50), moderate (Ac≥0,50), high (Ac≥0.70), and very high (Ac≥0.90). According to Della Bruna et al. (2012)DELLA BRUNA, E.; MORETO, A.L.; DALBÓ, M.A. Uso do coeficiente de repetibilidade na seleção de clones de pessegueiro para o litoral sul de Santa Catarina. Revista Brasileira de Fruticultura, v.34, p.206-215, 2012. DOI: https://doi.org/10.1590/S0100-29452012000100028.
https://doi.org/10.1590/S0100-2945201200... , higher-accuracy magnitudes for traits of interest increase the confidence in the prediction of a genotype’s genetic value.

When the efficiency was analyzed for the number of measurements, or evaluations (m) performed in the present work, it was observed that the estimate efficiency (EF) incremented with the increase of the number of measurements, and this made it possible to obtain a plateau after eight measurements. The estimated efficiency (EF) is represented by the maximization of broad-sense heritability, free from the effects of genotypes × environments interaction, looking for repeatability, and higher accuracy. In this sense, when at least 8 to 10 measurements (m) are performed, it is possible to obtain a plateau of accuracy and, then, potentiate the repeatability of genetic parameters along the crop years of sugarcane crop (Table 4).

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Table 4.
Genetic correlations among crop years referring to the multi-trait phenotypic index (PI).

All magnitudes were higher than rg = 0.95, which is a clue that multi-trait selection can be used irrespectively of the crop year. However, PI magnitudes would be predominantly affected by genetic effects. Regardless of the crop year, the genotypes considered ideal were those that showed a positive individual gain with the PI overall mean in the experiment, which made it possible to select ten genotypes (Table 5).

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Table 5.
Ordering of sugarcane genotypes by genotypic value free from the interaction between crop years (u+g), genotypic values added of an average effect of interaction between crop years (u+g+gem) and predicted gains for the multi-trait phenotypic index (PI), representing the joint analysis regarding crop years.

Gains of 29.68% were observed in 'IAC873396' (G19), that was the best ranked genotype in the simultaneous selection for increasing the total yield of stem per hectare and the production of total soluble sugars. The selection gains in the comparison of the effects u+g+gem were higher than gains obtained through effects u+g (Table 5). The multivariate BLUP allows of the identification of superior genotypes, minimizing the distortions induced by oscillations of crop years and growing environments, since it method capitalizes the average effects among crop years (u+g+gem). This result shows the usefulness of the mixed model method and the REML/BLUP procedures to carry out the genetic selections in a sugarcane-breeding program.

The estimates MHVG, PRVG, stability, and MHPRVG*MG showed similarity and ranked the three best genotypes: 'IAC873396', 'Nova Iraí', and 'IACSP 93-6006' (Table 6). Therefore, irrespectively of the crop year, these are high-yielding genotypes for total yield of stem and production of total soluble sugars, besides being phenotypically stable and adapted to the tested region. The other genotypes showed some distortions through the different techniques of ranking based on harmonic means by genotypic values.

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Table 6.
Estimate ranking for stability (MHVG), adaptability (PRVG), simultaneous expression of stability, and adaptability (MHPRVG*MG) for the multi-trait phenotypic index (PI).

Genotypes organized through the MHPRVG*MG are ideal to indicate the best genotypes at the end of the selection generations, as it simultaneously considers stability, adaptability, and yield of the genotypes throughout different evaluations or crop years. In the present study, the use of this multivariate approach, expanded to five traits, enabled this method to select the best genotypes. The genetic index (GI) was composed by the multi-trait (PI) and four auxiliary traits that were weighted by their accuracy, broad-sense heritability, and genetic correlations.

The multi-trait selection using a genetic index (GI) allowed of the selection of four superior genotypes for total stem yield and production of total soluble sugars (PI), as follows: 'IAC873396', 'Nova Iraí', 'IACSP 93-6006', and 'RB 835089'. In contrast, when promoting the estimates of a multivariate BLUP, by weighing the accuracies, genetic correlations, and heritabilities, it was possible to isolate unrecognized biases and to select four genotypes, which resulted in the 11.05% gain, outperforming the overall mean of the genetic index. The selective accuracy of GI was 0.83, with a superiority of 73.49% of the multi-trait PI that showed 0.61 of individual accuracy. A differential ranking of the genotypes selected by the multi-trait PI was observed in the selection by the genetic index (GI). Therefore, the genotype ordering through the genetic index (GI) may be considered for the final recommendation of genotypes, as GI is more accurate than a phenotypic multi-trait, since it aggregates information of the auxiliary traits, genotypic correlations, and genotypic values, increasing the selection reliability for sugarcane breeding.

Conclusions

The use of the multivariate best linear unbiased predictor (BLUP) method increases the selection gains, accuracy, and reliability of predictions for sugarcane breeding.
The high efficiency of selection with the use of the BLUP method for multi-trait selection is reached with more than eight measurements.
The multi-trait selection for total stem yield and production of total soluble sugars is efficient to define the superiority of genotypes regardless of the crop year.

References

ACOMPANHAMENTO DA SAFRA BRASILEIRA [DE] CANA-DE-AÇÚCAR: safra 2016/17: segundo levantamento, v.3, n.2, ago. 2016. Available at: <Available at: https://www.conab.gov.br/info-agro/safras/cana/boletim-da-safra-de-cana-de-acucar?start=10 > Accessed on: Oct. 8 2019.
» https://www.conab.gov.br/info-agro/safras/cana/boletim-da-safra-de-cana-de-acucar?start=10
CARVALHO, I.R.; NARDINO, M.; DEMARI, G.H.; PELEGRIN, A.J. de; FERRARI, M.; SZARESKI, V.J.; OLIVEIRA, V.F. de; BARBOSA, M.H.; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Components of variance and inter-relation of important traits for maize (Zea mays) breeding. Australian Journal Crop Science, v.11, p.982-988, 2017. DOI: https://doi.org/10.21475/ajcs.17.11.08.pne474.
» https://doi.org/10.21475/ajcs.17.11.08.pne474
CRUZ, C.D. GENES: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, v.35, p.271-276, 2013. DOI: https://doi.org/10.4025/actasciagron.v35i3.21251.
» https://doi.org/10.4025/actasciagron.v35i3.21251
DELLA BRUNA, E.; MORETO, A.L.; DALBÓ, M.A. Uso do coeficiente de repetibilidade na seleção de clones de pessegueiro para o litoral sul de Santa Catarina. Revista Brasileira de Fruticultura, v.34, p.206-215, 2012. DOI: https://doi.org/10.1590/S0100-29452012000100028.
» https://doi.org/10.1590/S0100-29452012000100028
EEUWIJK, F.A. van; BUSTOS-KORTS, D.; MILLET, E.J.; BOERA, M.P.; KRUIJER, W.; THOMPSON, A.; MALOSETTI, M.; IWATA, H.; QUIROZ, R.; KUPPE, C.; MULLER, O.; BLAZAKIS, K.N.; YU, K.; TARDIEU, F.; CHAPMAN, S.C. Modelling strategies for assessing and increasing the effectiveness of new phenotyping techniques in plant breeding. Plant Science, v.282, p.23-39, 2019. DOI: https://doi.org/10.1016/j.plantsci.2018.06.018.
» https://doi.org/10.1016/j.plantsci.2018.06.018
FAO. Food and Agriculture Organization of the United Nations. Faostat: statistics. Available at: <Available at: http://www.fao.org/statistics/ >. Accessed on: Oct. 8 2017.
» http://www.fao.org/statistics/
HENDERSON, C.R. Best linear unbiased estimation and prediction under a selection model. Biometrics, v.31, p.423-447, 1975. DOI: https://doi.org/10.2307/2529430.
» https://doi.org/10.2307/2529430
NEUPANE, J.; GUO, W. Agronomic basis and strategies for precision water management: a review. Agronomy, v.9, art.87, 2019. DOI; https://doi.org/10.3390/agronomy9020087.
» https://doi.org/10.3390/agronomy9020087
NUNES, A.C.P.; RESENDE, M.D.V. de; SANTOS, G.A. dos; ALVES, R.S. Evaluation of different selection indices combining Pilodyn penetration and growth performance in Eucalyptus clones. Crop Breeding and Applied Biotechnology, v.17, p.206-213, 2017. DOI: https://doi.org/10.1590/1984-70332017v17n3a32.
» https://doi.org/10.1590/1984-70332017v17n3a32
PELEGRIN, A.J. de; CARVALHO, I.R.; NUNES, A.C.P.; DEMARI, G.H.; SZARESKI, V.J.; BARBOSA, M.H.; ROSA, T.C.; FERRARI, M.; NARDINO, M.; SANTOS, O.P. dos; RESENDE, M.D.V. de; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Adaptability, stability and multivariate selection by mixed models. American Journal of Plant Sciences, v.8, p.3324-3337, 2017. DOI: https://doi.org/10.4236/ajps.2017.813224.
» https://doi.org/10.4236/ajps.2017.813224
R CORE TEAM. R: a language and environment for statistical computing. Vienna: R Foundation for Statistical Computing, 2015.
RAMALHO, M.A.P.; SANTOS, J.B. dos; PINTO, C.A.B.P.; SOUZA, E.A. de; GONÇALVES, F.M.A.; SOUZA, J.C. de. Genética na agropecuária. 5.ed. rev. Lavras: UFLA, 2012. 566p.
RESENDE, M.D.V. de. SELEGEN-REML/BLUP: sistema estatístico e seleção genética computadorizada via modelos lineares mistos. Colombo: Embrapa Florestas, 2007. 359p.
RESENDE, M.D.V. de; DUARTE, J.B. Precisão e controle de qualidade em experimentos de avaliação de cultivares. Pesquisa Agropecuária Tropical, v.37, p.182-194, 2007.
SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de LUMBRERAS, J.F.; COELHO, M.R.; ALMEIDA, J.A. de; ARAUJO FILHO, J.C. de; OLIVEIRA, J.B. de; CUNHA, T.J.F. Sistema brasileiro de classificação de solos. 5.ed. rev. e ampl. Brasília: Embrapa, 2018. 356p.
SILVA, J.P.N. da; SILVA, M.R.N. da. Noções da cultura da cana-de-açúcar. Inhumas: IFG; Santa Maria: Universidade Federal de Santa Maria, 2012. 105p.
VIANA, A.P.; RESENDE, M.D.V. de. Genética quantitativa no melhoramento de fruteiras. Rio de Janeiro: Interciência, 2014. 282p.
VITTORAZZI, C.; AMARAL JUNIOR, A.T.; GUIMARÃES, A.G.; VIANA, A.P.; SILVA, F.H.L.; PENA, G.F.; DAHER, R.F.; GERHARDT, I.F.S.; OLIVEIRA, G.H.F.; PEREIRA, M.G. Indices estimated using REML/BLUP and introduction of a super-trait for the selection of progenies in popcorn. Genetics and Molecular Research, v.16, gmr16039769, 2017. DOI: https://doi.org/10.4238/gmr16039769.
» https://doi.org/10.4238/gmr16039769

Publication Dates

Publication in this collection
17 Aug 2020
Date of issue
2020

History

Received
05 Feb 2018
Accepted
14 Apr 2020

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

[1] ACOMPANHAMENTO DA SAFRA BRASILEIRA [DE] CANA-DE-AÇÚCAR: safra 2016/17: segundo levantamento, v.3, n.2, ago. 2016. Available at: <Available at: https://www.conab.gov.br/info-agro/safras/cana/boletim-da-safra-de-cana-de-acucar?start=10 > Accessed on: Oct. 8 2019.
» https://www.conab.gov.br/info-agro/safras/cana/boletim-da-safra-de-cana-de-acucar?start=10

[2] CARVALHO, I.R.; NARDINO, M.; DEMARI, G.H.; PELEGRIN, A.J. de; FERRARI, M.; SZARESKI, V.J.; OLIVEIRA, V.F. de; BARBOSA, M.H.; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Components of variance and inter-relation of important traits for maize (Zea mays) breeding. Australian Journal Crop Science, v.11, p.982-988, 2017. DOI: https://doi.org/10.21475/ajcs.17.11.08.pne474.
» https://doi.org/10.21475/ajcs.17.11.08.pne474

[3] CRUZ, C.D. GENES: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, v.35, p.271-276, 2013. DOI: https://doi.org/10.4025/actasciagron.v35i3.21251.
» https://doi.org/10.4025/actasciagron.v35i3.21251

[4] DELLA BRUNA, E.; MORETO, A.L.; DALBÓ, M.A. Uso do coeficiente de repetibilidade na seleção de clones de pessegueiro para o litoral sul de Santa Catarina. Revista Brasileira de Fruticultura, v.34, p.206-215, 2012. DOI: https://doi.org/10.1590/S0100-29452012000100028.
» https://doi.org/10.1590/S0100-29452012000100028

[5] EEUWIJK, F.A. van; BUSTOS-KORTS, D.; MILLET, E.J.; BOERA, M.P.; KRUIJER, W.; THOMPSON, A.; MALOSETTI, M.; IWATA, H.; QUIROZ, R.; KUPPE, C.; MULLER, O.; BLAZAKIS, K.N.; YU, K.; TARDIEU, F.; CHAPMAN, S.C. Modelling strategies for assessing and increasing the effectiveness of new phenotyping techniques in plant breeding. Plant Science, v.282, p.23-39, 2019. DOI: https://doi.org/10.1016/j.plantsci.2018.06.018.
» https://doi.org/10.1016/j.plantsci.2018.06.018

[6] FAO. Food and Agriculture Organization of the United Nations. Faostat: statistics. Available at: <Available at: http://www.fao.org/statistics/ >. Accessed on: Oct. 8 2017.
» http://www.fao.org/statistics/

[7] HENDERSON, C.R. Best linear unbiased estimation and prediction under a selection model. Biometrics, v.31, p.423-447, 1975. DOI: https://doi.org/10.2307/2529430.
» https://doi.org/10.2307/2529430

[8] NEUPANE, J.; GUO, W. Agronomic basis and strategies for precision water management: a review. Agronomy, v.9, art.87, 2019. DOI; https://doi.org/10.3390/agronomy9020087.
» https://doi.org/10.3390/agronomy9020087

[9] NUNES, A.C.P.; RESENDE, M.D.V. de; SANTOS, G.A. dos; ALVES, R.S. Evaluation of different selection indices combining Pilodyn penetration and growth performance in Eucalyptus clones. Crop Breeding and Applied Biotechnology, v.17, p.206-213, 2017. DOI: https://doi.org/10.1590/1984-70332017v17n3a32.
» https://doi.org/10.1590/1984-70332017v17n3a32

[10] PELEGRIN, A.J. de; CARVALHO, I.R.; NUNES, A.C.P.; DEMARI, G.H.; SZARESKI, V.J.; BARBOSA, M.H.; ROSA, T.C.; FERRARI, M.; NARDINO, M.; SANTOS, O.P. dos; RESENDE, M.D.V. de; SOUZA, V.Q. de; OLIVEIRA, A.C. de; MAIA, L.C. da. Adaptability, stability and multivariate selection by mixed models. American Journal of Plant Sciences, v.8, p.3324-3337, 2017. DOI: https://doi.org/10.4236/ajps.2017.813224.
» https://doi.org/10.4236/ajps.2017.813224

[11] R CORE TEAM. R: a language and environment for statistical computing. Vienna: R Foundation for Statistical Computing, 2015.

[12] RAMALHO, M.A.P.; SANTOS, J.B. dos; PINTO, C.A.B.P.; SOUZA, E.A. de; GONÇALVES, F.M.A.; SOUZA, J.C. de. Genética na agropecuária. 5.ed. rev. Lavras: UFLA, 2012. 566p.

[13] RESENDE, M.D.V. de. SELEGEN-REML/BLUP: sistema estatístico e seleção genética computadorizada via modelos lineares mistos. Colombo: Embrapa Florestas, 2007. 359p.

[14] RESENDE, M.D.V. de; DUARTE, J.B. Precisão e controle de qualidade em experimentos de avaliação de cultivares. Pesquisa Agropecuária Tropical, v.37, p.182-194, 2007.

[15] SANTOS, H.G. dos; JACOMINE, P.K.T.; ANJOS, L.H.C. dos; OLIVEIRA, V.A. de LUMBRERAS, J.F.; COELHO, M.R.; ALMEIDA, J.A. de; ARAUJO FILHO, J.C. de; OLIVEIRA, J.B. de; CUNHA, T.J.F. Sistema brasileiro de classificação de solos. 5.ed. rev. e ampl. Brasília: Embrapa, 2018. 356p.

[16] SILVA, J.P.N. da; SILVA, M.R.N. da. Noções da cultura da cana-de-açúcar. Inhumas: IFG; Santa Maria: Universidade Federal de Santa Maria, 2012. 105p.

[17] VIANA, A.P.; RESENDE, M.D.V. de. Genética quantitativa no melhoramento de fruteiras. Rio de Janeiro: Interciência, 2014. 282p.

[18] VITTORAZZI, C.; AMARAL JUNIOR, A.T.; GUIMARÃES, A.G.; VIANA, A.P.; SILVA, F.H.L.; PENA, G.F.; DAHER, R.F.; GERHARDT, I.F.S.; OLIVEIRA, G.H.F.; PEREIRA, M.G. Indices estimated using REML/BLUP and introduction of a super-trait for the selection of progenies in popcorn. Genetics and Molecular Research, v.16, gmr16039769, 2017. DOI: https://doi.org/10.4238/gmr16039769.
» https://doi.org/10.4238/gmr16039769

Year	Genotype
2010	G₁ (IACSP 93-6006)	G₈ Nova Iraí	G₁₅ Preguiçosa
2011	G₂ IAC91-2218	G₉ Ligeirinha Roxa	G₁₆ Tucumã
2012	G₃ IAC87-3396	G₁₀ Pernambucana	G₁₇ Pingo de Mel
2013	G₄ IAC91-5155	G₁₁ SP716163	G₁₈ Palhuda
2014	G₅ IAC91-2195	G₁₂ RB 785750	G₁₉ IAC873396
2015	G₆ RB 855453	G₁₃ NA 56792	G₂₀ RB 835089
2016	G₇ RB 85506	G₁₄ IAC915035	G₂₁ RB 765418

Variation source	Mean square
Variation source	TYSH⁺	TVJH	PTSS	LENG
Crop years (CY)	19,881,168,178.0*	4,210,541,180.0*	180,679,417.0*	121,167.14*
Genotypes (G)	1,022,692,925.9*	249,779,591.0*	4,975,824.0*	4,360.76*
CYx G	348,743,143.8	87,635,847.0	2,181,938.0	1,014.38*
Block	2,258,774,785.4*	4,068,244,430.0*	10,174,882.0*	1,029.96
CV (%)	49.13	53.78	55.74	18.07

Genetic parameter	PI	TYSH	TVJH	PTSS	LENG
ĥ²g	0.04	0.05	0.05	0.04	0.14
r	0.08	0.17	0.15	0.1	0.23
c²perm	0.04	0.12	0.1	0.06	0.09
c²gm	0.01	0.05	0.03	0.04	0.16
rgmed	0.73	0.51	0.6	0.52	0.48
h²mg	0.37	0.34	0.35	0.34	0.6
Accuracy	0.61	0.59	0.59	0.59	0.77
Average	2.5	37.25	17,492.3	2,591.03	142.84

Crop year	2010	2011	2012	2013	2014	2015	2016
2010	1.00	0.99	0.99	0.99	0.98	0.98	1.00
2011		1.00	0.98	0.98	0.96	0.96	0.99
2012			1.00	0.98	0.95	0.96	0.98
2013				1.00	0.96	0.97	0.99
2014					1.00	0.98	0.98
2015						1.00	0.99
2016							1.00
LENG (%)	6.80	16.60	11.00	18.70	13.24	19.20	14.40

Ranking	Genotype	u + g	CG (%)	IV (%)	U+G+GEM	CG U+G+GEM (%)	IG U+G+GEM (%)	RC of the sum of squares (%)
1	G₁₉ (IAC873396)	3.24	29.68	29.68	3.28	31.28	31.28	6.00
2	G₈ (Nova Iraí)	2.98	24.40	19.13	3.00	25.72	20.16	7.00
3	G₁ (IACSP93-6006)	2.96	22.38	18.34	2.98	23.59	19.33	5.70
4	G₂₀ (RB 835089)	2.82	20.01	12.91	2.84	21.09	13.60	4.70
5	G₃ (IAC87-3396)	2.72	17.77	8.78	2.73	18.72	9.25	5.50
6	G₂ (IAC91-2218)	2.62	15.63	4.94	2.63	16.47	5.20	3.90
7	G₁₃ (NA 56792)	2.58	13.88	3.39	2.59	14.63	3.57	4.00
8	G₉ (Ligeirinha Roxa)	2.56	12.46	2.49	2.56	13.13	2.62	4.20
9	G₅ (IAC91-2195)	2.52	11.18	0.93	2.52	11.78	0.98	3.80
10	G₁₄ (IAC915035)	2.52	10.15	0.90	2.52	10.69	0.95	5.20
11	G₄ (IAC91-5155)	2.46	9.10	-1.37	2.46	9.59	-1.44	7.30
12	G₁₈ (Palhuda)	2.46	8.22	-1.44	2.46	8.67	-1.51	4.80
13	G₁₇ (Pingo de Mel)	2.43	7.37	-2.91	2.42	7.76	-3.07	4.80
14	G₁₀ (Pernambucana)	2.41	6.60	-3.37	2.41	6.95	-3.55	5.50
15	G₇ (RB 85506)	2.39	5.88	-4.15	2.39	6.20	-4.37	4.60
16	G₁₅ (Preguiçosa)	2.32	5.08	-6.96	2.31	5.35	-7.34	5.90
17	G₁₆ (Tucumã)	2.29	4.30	-8.20	2.28	4.53	-8.64	4.10
18	G₁₂ (RB 785750)	2.27	3.55	-9.09	2.26	3.75	-9.58	3.90
19	G₂₁ (RB 765418)	1.99	2.30	-20.30	1.96	2.42	-21.39	2.80
20	G₆ (RB 855453)	1.98	1.15	-20.70	1.95	1.21	-21.81	2.60
21	G₁₁ (SP716163)	1.92	0.00	-22.99	1.89	0.00	-24.22	3.40

Stability			Adaptability			Stability and adaptability
Ranking	Genotype	MHVG	Genotypes	PRVG	PRVG*MG	Genotypes	MHPRVG	MHPRVG*MG
1	IAC873396	1.9	IAC873396	2.5	6.24	IAC873396	1.62	4.05
2	Nova Iraí	1.5	Nova Iraí	1.98	4.96	Nova Iraí	1.48	3.69
3	IACSP93-6006	1.44	IACSP93-6006	1.92	4.78	IACSP93-6006	1.45	3.61
4	RB 835089	1.2	RB 835089	1.65	4.12	RB 765418	1.44	3.59
5	IAC87-3396	0.99	IAC87-3396	1.43	3.58	RB 855453	1.4	3.5
6	Tucumã	0.92	IAC91-2218	1.24	3.11	RB 835089	1.35	3.37
7	IAC91-2218	0.78	NA 56792	1.16	2.9	SP716163	1.3	3.25
8	NA 56792	0.69	Ligeirinha Roxa	1.12	2.8	IAC87-3396	1.26	3.16
9	Ligeirinha Roxa	0.64	IAC915035	1.05	2.63	Preguiçosa	1.22	3.04
10	IAC915035	0.55	IAC91-2195	1.04	2.61	IAC91-2218	1.18	2.94
11	IAC91-2195	0.53	Palhuda	0.93	2.32	NA 56792	1.13	2.82
12	IAC91-5155	0.37	IAC91-5155	0.93	2.31	Ligeirinha Roxa	1.1	2.74
13	Palhuda	0.36	Pernambucana	0.84	2.09	IAC915035	1.05	2.62
14	RB 785750	0.29	Pingo de Mel	0.83	2.07	IAC91-2195	1.04	2.6
15	Pingo de Mel	0.2	RB 85506	0.79	1.97	Palhuda	0.91	2.29
16	Pernambucana	0.2	Preguiçosa	0.66	1.64	IAC91-5155	0.91	2.28
17	RB 85506	0.08	Tucumã	0.59	1.46	Tucumã	0.81	2.03
18	Preguiçosa	-0.92	RB 785750	0.55	1.38	Pingo de Mel	0.74	1.85
19	RB 765418	-1.48	RB 765418	-0.02	-0.05	Pernambucana	0.72	1.79
20	RB 855453	-1.58	RB 855453	-0.05	-0.12	RB 785750	0.56	1.4
21	SP716163	-2.14	SP716163	-0.16	-0.39	RB 85506	0.43	1.08

Brasil

Brasil

Multivariate best linear unbiased predictor as a tool to improve multi-trait selection in sugarcane

Melhor preditor multivariado linear não viesado como ferramenta para a seleção multicaracterísticas em cana-de-açúcar

Abstract:

Resumo:

Introduction

Materials and Methods

Results and Discussion

Conclusions

References

Publication Dates

History