Selection among and within full-sib families of elephant grass for energy purposes

Silva, Verônica Brito da; Daher, Rogério Figueiredo; Menezes, Bruna Rafaela da Silva; Gravina, Geraldo de Amaral; Araújo, Maria do Socorro Bezerra De; Carvalho Júnior, Almir Ribeiro de; Cruz, Derivaldo Pureza da; Almeida, Brunno de Oliveira; Tardin, Flávio Dessaune

doi:10.1590/1984-70332018v18n1a12

Abstract

Pennisetum purpureum Schum. has been a key alternative as an energy source in Brazil because of its higher dry matter accumulation and fiber content. This research aimed to select superior individuals of P. purpureum for energy purposes using among-and-within family selection. The study was carried out in Campos dos Goytacazes- RJ (Brazil), using eight full-sib families. Plants were individually assessed during two pasture cuttings, one in 2014, and another in 2015. The dry matter production (DMP) was correlated with the number of tillers, stem diameter, plant height, and neutral detergent fiber content. Plant selection criteria in both cuts were through direct and indirect selections, and Smith and Hazel index. A joint analysis of variance showed significant differences for all five traits assessed in both cuts. The results achieved with Smith and Hazel index were promising for simultaneous selection of the evaluated traits, favoring selection of superior families and individuals them.

Key words:
Pennisetum purpureum Schum; biomass; selection gain; heritability; Smith and Hazel index

INTRODUCTION

After the Paris COP 21 Climate Conference in 2015 (COP 21), efforts towards carbon emission and global warming reductions have been strengthened. In this sense, vegetal biomass has become a safe and sustainable energy alternative since it is renewable, and has low production cost. In addition, unlike other sources as oil or coal, this material has no contribution to the greenhouse effect as it reduces carbon dioxide emissions through absorption during photosynthesis (Anderson et al. 2008Anderson WF, Dien BS, Brandon SK and Peterson JD (2008) Assessment of Bermuda grass and bunch grasses as feedstocks for conversion to ethanol. Applied Biochemistry Biotechnology 145: 13-2., Lee et al. 2010Lee MK, Tsai WT, Tsai YL and Lin SH (2010) Pyrolysis of Napier grass in an induction-heating reactor. Journal of Analytical and Applied Pyrolysis 88: 110-116.).

In Brazil, the interest of researchers was aroused by elephant grass. This relevance comes from being highly efficient in fixing atmospheric CO₂ during photosynthesis (Azevedo et al. 2012Azevedo ALS, Costa PP, Machado JC, Machado MA, Pereira AV and Ledo FJS (2012) Cross species amplification of Pennisetum glaucum microsatellite markers in Pennisetum purpureum and genetic diversity of Napier grass accessions. Crop Science 52: 1776-1785., Flores et al. 2012Flores RA, Urquiaga SS, Alves BJR, Collier LS and Boddey RM (2012) Yield and quality of elephant grass biomass produced in the Cerrados region for bioenergy. Engenharia Agrícola 32: 831-839., Rossi et al. 2014Rossi DA, Menezes BRS, Daher RF, Gravina GA, Lima RSN, Lédo FJ S, Gottardo R D, Campostrini E and Souza CLM (2014) Canonical correlations in elephant grass for energy purposes. African Journal Biotechnology 36: 3666-3671.). This plant is African in origin and has traits benefiting biomass quality such as fast growth, small farm plots for cultivation, high dry matter accumulation, high fiber content, and high calorific power (Daher at al. 2014Daher RF, Souza LB, Gravina GA, Machado JC, Ramos HCC, Silva VQR, Menezes BRS, Schneider LSA, Oliveira MLF and Gottardo RD (2014) Use of elephant grass for energy production in Campos dos Goytacazes-RJ, Brazil. Genetics and Molecular Research 13: 10898-10908.).

As elephant grass cultivation has increased for energy production, a significant raise in acreage will be consistent (Cunha et al. 2013Cunha MV, Lira MA , Santos MVF, Dubeux Júnior JCB, Mello ACL and Freitas EV(2013) Adaptabilidade e estabilidade da produção de forragem por meio de diferentes metodologias na seleção de clones de Pennisetum spp. Revista Brasileira de Ciências Agrárias 8: 681-686., Pereira et al. 2017Pereira AV, Lédo FJS and Machado MA (2017) BRS Kurumi and BRS Capiaçu - New elephant grass cultivars for grazing and cut-and-carry system. Crop Breeding and Applied Biotechnology 17: 59-62.); therefore, studies on genetic improvement of this species should consider new selection criteria (Pereira et al. 2008Pereira AV, Machado MA, Azevedo ALS, Nascimento CS, Campos AL and Lédo FJS (2008) Diversidade genética entre acessos de capim-elefante obtida com marcadores moleculares. Revista Brasileira de Zootecnia 37: 1216-1221., Benin et al. 2013Benin G, Storck L, Marchioro VS, Franco FA and Trevizan DVM (2013) Improving the precision of genotype selection in wheat performance trials. Crop Breeding and Applied Biotechnology 13: 234-240.), exploring variability within species (Cavalcante and Lira 2010Cavalcante M and Lira MA (2010) Variabilidade genética em Pennisetum purpureum Schumacher. Revista Caatinga 23: 153-163.).

Selection of superior phenotypes of individuals or families is an important practice in breeding programs, making it feasible since improved populations are generated from selection and recombination at individual and family levels (Cruz et al. 2014Cruz CD, Carneiro PCS and Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa, 668p. , Salgado et al. 2014Salgado SML, Rezende JC and Nunes JAR (2014) Selection of coffee progenies for resistance to nematode Meloidogyne paranaensis in infested area. Crop Breeding and Applied Biotechnology 14: 94-10.). In this context, among-and-within-family selection becomes a great option, mainly for considering only one character of interest, being simple to be applied. Moreover, using selection indexes consists of providing a new trait, which is a linear combination of all traits involved, whose weighting coefficients are estimated so as to maximize the correlation between the index and a genotypic aggregate (true breeding values for selection candidates) (Cruz et al. 2012Cruz CD, Regazzi AJ and Carneiro PCS (2012) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa , 514p. ). However, to date, there have been no studies involving the selection of elephant grass full-sib families using such method.

This study had, therefore, the aim to estimate and compare the predicted genetic gains by means of direct and indirect selections, as well as through a classical selection index, thus selecting the most promising families and individuals within full-sib families of elephant grass for energy purposes.

MATERIAL AND METHODS

The experiment was conducted at the Rio de Janeiro State Research Unit for Agro-Energy and Waste Exploitation (PESAGRO) (lat 21° 19' 23'' S, long 41º 19' 40'' W and alt 20 m asl), in Campos dos Goytacazes, RJ, Brazil. According to the Köppen’s classification, the local climate is an Aw type, which stands for a hot and humid tropical climate with annual rainfall of around 1152 mm. The soil is classified as a dystrophic Argisol (Ultisol) (Santos et al. 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VÁ, Lumbreras JF, Coelho MR, Almeida JÁ, Cunha TJF and Oliveira JB (2013) Sistema brasileiro de classificação de solos. 3rd edn, Embrapa, Brasília, 353p.).

Eight elephant grass accessions donated by the germplasm bank of the State University of North Rio de Janeiro were used in the experiment. The female parental plants were IJ7139, CPAC, and IAC-Campinas, while male parental ones were Cameroon, Cubano Pinda, BAG-86, Capim cana D´Africa, and Vrukwona. These accessions were directly crossed among each other for promising hybrid combinations, selecting parents for late flowering, high dry matter production, and thick stems (Lima et al. 2011Lima RSN, Daher RF, Gonçalves LSA, Rossi DA, Amaral Júnior AT, Pereira MG and Lédo FJS (2011) RAPD and ISSR markers in the evaluation of genetic divergence among accessions of elephant grass. Genetics and Molecular Research 10: 1304-1313.).

Crossings were performed following the method described by Silva et al. (2011Silva VQR, Damer RF, Amaral Gravina G, Silva Ledo FJ, Tardin FD and Souza MC (2011) Capacidade combinatória de capim-elefante com base em caracteres morfoagronômicos. Boletim de Indústria Animal 71: 63-70.). It consisted of collecting pollen grains from elephant grass genotypes (male parents), in paper bags, and then taking them to the female flowers, when inflorescence stigmas (protected by a paper bag) were receptive. There was no need for emasculation because of flower protogyny (Passos et al. 2005Passos LP, Machado MA, Vidigal MC and Campos AL (2005) Molecular characterization of elephant-grass accessions through RAPD markers. Ciência e Agrotecnologia 29: 568-574.). The crossings were carried out between 8 and 10 in the morning, in 2013. Afterwards, seeds were sown in 128-cell trays filled with forest substrate. Field transplanting was held when seedlings reached 20 cm in height, nearly 40 days after germination, in December 2013.

The experimental design was a randomized block design with three replications; each block consisted of eight full-sib families. Only 15 seeds were obtained for each family due to a loss of seed viability. Each plot was composed of five plants spaced in 1 m between and within planting rows, according to Silva et al. (2017Silva FHL, Viana AP, Santos EA, Freitas JCO, Rodrigues DL and Amaral Júnior AT (2017) Prediction of genetic gains by selection indexes and REML/BLUP methodology in a population of sour passion fruit under recurrent selection. Acta Scientiarum. Agronomy 39: 183-190.). The evaluations were carried out in two periods (cuts), the first made after 12 months of sowing (2014), and the second 8 months after the first (2015). For Rengsirikul et al. (2011Rengsirikul K, Ishii Y, Kangvansaichol K, Pripanapong P, Sripichitt P, Punsuvon V, Vaithanomsat P, Nakamanee G and Tudsri S (2011) Effects of inter-cutting interval on biomass yield, growth components and chemical composition of napier grass (Pennisetum purpureum Schumach) cultivars as bioenergy crops in Thailand. Grassland Science 57: 135-141.), elephant grass dry matter production decreases after a 12-month cutting interval.

The assessed traits were correlated to the dry matter production (Menezes et al. 2014Menezes BRF, Daher RF, Gravina GA, Amaral Junior AT, Oliveira AV, Schneider LSA and Silva VB (2014) Correlações e análise de trilha em capim-elefante para fins energéticos. Revista Brasileira Ciências Agrárias 9: 465-470.): number of tillers - NT (of every individual prior to harvest), stem diameter - SD (in cm, using three plants from each individual clump, at 10 cm above the soil with a digital caliper), plant height - PH (in m, measuring three random plants from each individual clump with a graduated ruler). The biomass quality traits were assessed at the Laboratory of Animal Science, Darcy Ribeiro State University of North Rio de Janeiro (LZO/UENF). DMP was estimated using the percentage of dry matter and the weight of tillers from individual plants, as described by Daher et al. (2014Daher RF, Souza LB, Gravina GA, Machado JC, Ramos HCC, Silva VQR, Menezes BRS, Schneider LSA, Oliveira MLF and Gottardo RD (2014) Use of elephant grass for energy production in Campos dos Goytacazes-RJ, Brazil. Genetics and Molecular Research 13: 10898-10908.). Yet the percentage of neutral detergent fiber (%NDF) was determined as described by Mertens (2002Mertens DR (2002) Gravimetric determination of amylase-treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: collaborative study. Journal of AOAC International 85: 1217-1231.), using a filter bag Technique (Ankom^TM).

These data underwent individual analysis of variance, based on the following random model: Y _ijk = m + G _i + B _j + D _ij + E _ijk ; wherein: Y_ijk:observation in the k ^th individual of the i ^th full-sib family (FSF) assessed in the j ^th block; m: overall average; G _i: random effect of the i ^th FSF; B ^j: effect of the j ^th block; D _ij: random effect of the variation between plots; E _ijk: random effect of the variation between plants within the plot.

A combined analysis of variance was performed according to a statistical model considering each cut and each genotype as a random effect, as follows: Y _ijlm = m + b _j/k + G _i + C _k + (GC) _ik + e _ijk + d _ijkl , wherein, m: general mean; G _i: effect of the j ^-th FSF; C _k: effect of the k ^-th cut; (GC) _ik: interaction effect of the FSF with the k ^-th cut; e _ijk: effect of experimental error of the plots, d _ijkl: deviation inherent to plant l of FSF i, in replication j at cut k. Considering the model for combined analysis of randomized blocks, the expected mean squares [E (MS)] were based on Cruz et al. (2014Cruz CD, Carneiro PCS and Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa, 668p. ).

To select the traits to be used in the selection index, a multicollinearity diagnosis was performed among them. For this, a matrix correlation method was used, resulting in a weak collinearity. All assessed traits had a condition number of 7 (CN - the ratio between the largest and smallest eigenvalue of the correlation matrix). According to Cruz et al. (2014Cruz CD, Carneiro PCS and Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa, 668p. ), collinearity is classified as weak when CN < 100.

According to Cruz et al. (2014Cruz CD, Carneiro PCS and Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa, 668p. ), gain estimates are seen in a direct selection based on the estimator: ${G S}_{x} = {D S}_{x} h_{x}^{2}$ ; wherein: GS _x is the direct gain predicted in the variable X; DS _x is the selection variable differential X, and $h_{x}^{2}$ is the heritability coefficient of the variable X, in a broad sense. Selection gain rates were determined by the following expression: GS _x % = (GS _x % * 100)/X ₀ .

The gain estimates obtained by indirect selection were calculated according to the following estimator: ${G S}_{y (x)} = {D S}_{y (x)} . h_{y}^{e}$ ; wherein: GS _y(x) is the selection gain in Y by selecting the variable X; DS _y(x) is the differential of indirect selection, in which the average of selected ones is obtained as a function of the progenies, which show superiority for the auxiliary variable X, and $h_{y}^{e}$ is the heritability coefficient of the main variable Y. The rate of selection gain was estimated according to the following expression: GS _y(x) % = (GS _x(y) * 100)/X ₀ .

We used the classical index proposed by Smith (1936Smith HF (1936) A discriminant function for plant selection. Annals Eugenics 7: 240-250.) and Hazel (1943Hazel LN (1943) The genetic basis for constructing selection indexes. Genetics 28: 476-490.). In these indexes both the selection index (I) and the genotypic aggregate (H) are described by: $I = b_{1} x_{1} + b_{2} x_{2} + \dots + b_{n} x_{n} = \sum_{i = 1}^{n} b_{i} x_{i} = b ’ x a n d H = a_{1} g_{1} + a_{2} g_{2} + \dots + a_{n} g_{n} = \sum_{i = 1}^{n} a_{i} g_{i} = a ’ g$ ; wherein: n is the number of evaluated traits; b’ is the vector (1 x n) of the weighting coefficients of the selection index to be estimated; x is the matrix (n x p) of trait means; a’, is the vector (1 x n) of previously established economic weights; and g is the matrix (n x p) of unknown genetic values of the n traits considered. The indexes were established by the following equation system: Pb = Ga; wherein: P is the matrix of phenotypical covariance; G is the matrix of phenotypical covariance; a is the vector of economic weights, and b is the vector of coefficients of the selection index.

When using a classical index, the genetic variation coefficient (CVg), genetic standard deviation (SD) and random weights of each trait were considered as economic weights. For both cuts, the random weights were 100, 90, 90, 80, and 100 for the variables DMP, NT, PH, SD, and NDF, respectively. The selection intensity applicable among individuals was 15%, corresponding to 18 selected individuals. All statistical analyses were performed using the Genes software (Cruz et al. 2013Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy 35: 271-276.).

RESULTS AND DISCUSSION

While DMP and NT presented significant differences among families in both cuts, SD and NDF showed significant differences only in the second cut (Table 1). Such difference points out to a genetic variability among FSFs, besides a potential for selection. This fact confirms this species diversity for biomass production. Likewise, Daher et al. (2014Daher RF, Souza LB, Gravina GA, Machado JC, Ramos HCC, Silva VQR, Menezes BRS, Schneider LSA, Oliveira MLF and Gottardo RD (2014) Use of elephant grass for energy production in Campos dos Goytacazes-RJ, Brazil. Genetics and Molecular Research 13: 10898-10908.) had observed variability among 16 hybrids concerning the same agronomic traits related to energy purposes.

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Table 1
Summary of the variance analysis of dry matter production (DMP), number of tillers (NT), stem diameter (SD), plant height (PH), and neutral detergent fiber (NDF) for full-sib families of elephant grass in two harvest cuts (C)

At the family level, the heritability coefficient exceeded those obtained at the individual level within a family for all measured traits (Table 1). The highest estimates were observed for traits in the second cut. These results can be explained by a great unevenness in the first cut evaluations, which decreases with the course of crop establishment in the field. NT and NDF reached estimates of 0.95 and 0.86, respectively, which indicates high perspectives of genetic gain by selection. However, the estimates for heritability within families ranged from 19 to 74%.

Rosado et al. (2009Rosado AM, Rosado TB, Júnior MFRR, Bhering LL and Cruz CD (2009) Ganhos genéticos preditos por diferentes métodos de seleção em progênies de Eucalyptus urophylla. Pesquisa Agropecuária Brasileira 44: 1653-1659.) claimed that, when considering the same selection intensity, averages of families should be more efficient than the within-family ones. In this case, both among and within selections can be combined to explore variability properly, raising the total genetic gain. It is noteworthy that all negative heritability was regarded as null (zero). PH showed a heritability equal to zero, which, as stated by Jung et al. (2008Jung MS, Vieira EA, Brancker A and Nodari RO (2008) Herdabilidade e ganho genético em caracteres do fruto do maracujazeiro-doce. Revista Brasileira de Fruticultura 30: 209-214.), features a low genetic variance (Table 1).

The joint analysis of variance showed significant differences among families for all traits (Table 2). These variations indicate good prospects for selections among families and for continuity in the elephant grass genetic breeding program. The effects of family x cut interactions and of the cut itself were significant for all traits except for DMP and SD, and DMP, respectively. Conversely, significant interactions indicate that the families showed distinct responses in the different sections. Such a result can be explained by the long periods through which evaluations were carried out; thus, the families were longer exposed to edaphic and climatic variations, especially irregular precipitation. Nevertheless, there were no significant differences for dry matter production, which had a greater participation in the genotype variance than did the environmental range.

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Table 2
Summary of the variance analysis of dry matter production (DMP), number of tillers (NT), stem diameter (SD), plant height (PH), and neutral detergent fiber (NDF) for full-sib families of elephant grass in two harvest cuts (C)

Comparing Tables 3 and 4, we observed for most of the assessed traits that direct gains by selection among-and-within-family were greater than were the indirect ones. Direct selection among-and-within-family provided total gains as expected for the first cut concerning DMP (5.74), NT (5.27), and for the second cut for DMP (6.42) and NT (5.08). It is worthy highlighting that, in the present study, evaluations occurred at different plant ages; therefore, different sets of genes could be responsible for the phenotypic expression of genotype at each plant age.

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Table 3
Predicted gains by direct selection for dry matter production (DMP), number of tillers (NT), stem diameter (SD), plant height (PH), and neutral detergent fiber (NDF) in full-sib families of elephant grass in two harvest cuts (C)

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Table 4
Predicted gains (SG %) by among (SGa) and within (SGw) selection criterion, and total gains (SGt) by indirect selection of dry matter production (DMP), number of tillers (NT), stem diameter (SD), plant height (PH), and neutral detergent fiber (NDF) for full-sib families of elephant grass in two harvest cuts (C)

Nevertheless, in certain cases, it must be highlighted here that indirect gains exceeded direct ones in both cuts, regarding SD (2.57 and 8.57) and NDF (11.7 and 15.5), as shown in Table 4. This finding becomes possible whether heritability of an auxiliary trait is greater than the target one (under selection), and when the genetic correlation between them is of major magnitude. In contrast, indirect gains for selection of PH were low, and for some other variables, were negative. Therefore, performing an indirect selection for one variable to obtain a gain in another one is unfeasible, since there might be a loss in the first one (Verardi et al. 2009Verardi CK, Resende MDZV, Costa RB and Gonçalves PS (2009) Adaptabilidade e estabilidade da produção de borracha e seleção em progênies de seringueira. Pesquisa Agropecuária Brasileira 44: 1277-1282.).

Based on the classical index, predicted gains were maximized for all traits when it was used genetic variation coefficient, standard deviation, and heritability coefficient at the family level, as economic weights (Table 5). Teixeira et al. (2012Teixeira DHL, Oliveira MDSP, Gonçalves FMA and Nunes JAR (2012) Índices de seleção no aprimoramento simultâneo dos componentes da produção de frutos em açaizeiro. Pesquisa Agropecuária Brasileira 47: 237-243.) evaluated 25 progenies of açaí palm and observed small fruit production gains when the genetic variation coefficient and average progeny heritability were used as economic weights. By using selection intensity indexes of 15% within FSF, direct gains were observed only for DMP and NT in both cuts (Table 5). This result was already expected since the selection was carried out giving priority to traits with high heritability coefficients and genetic variance, which are considered most important.

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Table 5
Predicted selection gains (SG%) by the classical selection index of Smith & Hazel (SH) for dry matter production (DMP), number of tillers (NT), stem diameter (SD), plant height (PH), and neutral detergent fiber (NDF) in full-sib families of elephant grass in two harvest cuts (C)

Taking into account the Smith and Hazel index, in which standard deviation (SD) was used as an economic weight, we observed higher gains for NT in the first and second cuts (47.66% and 76.99%) (Table 5), being higher than those of direct and indirect selection for the same trait. Likewise, the same result was reported when using families of other crops such as popcorn (Amaral Junior et al. 2010Amaral Júnior AT, Freitas Júnior SP, Rangel RM, Pena GF, Ribeiro RM, Morais RC and Schuelter AR (2010) Improvement of a popcorn population using selection indexes from a fourth cycle of recurrent selection program carried out in two different environments. Genetics and Molecular Research 9: 340-347., Freitas et al. 2013Freitas ILJ, Amaral Junior AT, Viana AP, Pena GF, Cabral PS, Vittorazzi C and Silva TRC (2013) Ganho genético avaliado com índices de seleção e com REML/BLUP em milho-pipoca. Pesquisa Agropecuária Brasileira 48: 1464-1471.) and wheat (Cargnin et al. 2007Cargnin A, Souza MA, Machado CG and Pimentel AJB (2007) Genetic gain prediction for wheat with different selection criteria. Crop Breeding and Applied Biotechnology 7: 334-339.). Moreover, Costa et al. (2008Costa MM, Di Mauro AO, Unêda-Trevisoli SH, Arriel NHC, Bárbaro IM, Silveira GD and Muniz FRS (2008) Analysis of direct and indirect selection and indices in soybean segregating populations. Crop Breeding and Applied Biotechnology 8: 47-55.) reported high genetic gains by selection index in 32 soybean families using SD as economic weight.

In both cuts, advantageous results were provided to the selection process when it was used random weights (RA) as economic weight, reaching positive gains for SD (0.21% and 0.32%), also bringing superior results for NDF (2.16% and 2.38%) and PH (5.75% and 6.19%). Furthermore, selection index promoted most satisfactory estimates and greater genetic gains for SD, NDF, and PH if compared to direct and indirect selections (Table 5). Costa et al. (2008Costa MM, Di Mauro AO, Unêda-Trevisoli SH, Arriel NHC, Bárbaro IM, Silveira GD and Muniz FRS (2008) Analysis of direct and indirect selection and indices in soybean segregating populations. Crop Breeding and Applied Biotechnology 8: 47-55.), performing an among-and-within-FSF selection in soybeans, observed direct gains similar to those obtained by selection indexes, as observed in our study.

Although poorly differentiated, the results attained using different economic weights for Smith and Hazel index showed to be advantageous if compared to direct and indirect selections, since the predicted gains reached by those were higher than the latter for all assessed traits. The differences in all traits between cuttings can be explained by environmental changes from one year to the other, where the better conditions in the second year might have favored a larger tillering.

Among the evaluated families, family 1 (Table 6) stood out for its better genetic gains. Within this family, the individuals 4, 6, and 7 were considered the most thriving ones for both cuts. Hence, these individuals should be highlighted as promising in terms of biomass production for superior genotype selection.

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Table 6
Selection of families and individuals by direct and indirect selection methods and by Smith and Hazel index in two harvest cuts (C)

CONCLUSIONS

The gains predicted by the classic index of Smith and Hazel were higher for all the assessed traits, especially for dry matter production.

Stem diameter showed major gains through indirect selection by means of dry matter production and the number of tillers.

Family 1 and its individuals 4, 6, and 7 were pointed out as the most promising ones for energy purposes when assessing selection among- and within-families using the Smith and Hazel index.

REFERENCES

Amaral Júnior AT, Freitas Júnior SP, Rangel RM, Pena GF, Ribeiro RM, Morais RC and Schuelter AR (2010) Improvement of a popcorn population using selection indexes from a fourth cycle of recurrent selection program carried out in two different environments. Genetics and Molecular Research 9: 340-347.
Anderson WF, Dien BS, Brandon SK and Peterson JD (2008) Assessment of Bermuda grass and bunch grasses as feedstocks for conversion to ethanol. Applied Biochemistry Biotechnology 145: 13-2.
Azevedo ALS, Costa PP, Machado JC, Machado MA, Pereira AV and Ledo FJS (2012) Cross species amplification of Pennisetum glaucum microsatellite markers in Pennisetum purpureum and genetic diversity of Napier grass accessions. Crop Science 52: 1776-1785.
Benin G, Storck L, Marchioro VS, Franco FA and Trevizan DVM (2013) Improving the precision of genotype selection in wheat performance trials. Crop Breeding and Applied Biotechnology 13: 234-240.
Cargnin A, Souza MA, Machado CG and Pimentel AJB (2007) Genetic gain prediction for wheat with different selection criteria. Crop Breeding and Applied Biotechnology 7: 334-339.
Cavalcante M and Lira MA (2010) Variabilidade genética em Pennisetum purpureum Schumacher. Revista Caatinga 23: 153-163.
Costa MM, Di Mauro AO, Unêda-Trevisoli SH, Arriel NHC, Bárbaro IM, Silveira GD and Muniz FRS (2008) Analysis of direct and indirect selection and indices in soybean segregating populations. Crop Breeding and Applied Biotechnology 8: 47-55.
Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy 35: 271-276.
Cruz CD, Carneiro PCS and Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa, 668p.
Cruz CD, Regazzi AJ and Carneiro PCS (2012) Modelos biométricos aplicados ao melhoramento genético. Editora UFV, Viçosa , 514p.
Cunha MV, Lira MA , Santos MVF, Dubeux Júnior JCB, Mello ACL and Freitas EV(2013) Adaptabilidade e estabilidade da produção de forragem por meio de diferentes metodologias na seleção de clones de Pennisetum spp. Revista Brasileira de Ciências Agrárias 8: 681-686.
Daher RF, Souza LB, Gravina GA, Machado JC, Ramos HCC, Silva VQR, Menezes BRS, Schneider LSA, Oliveira MLF and Gottardo RD (2014) Use of elephant grass for energy production in Campos dos Goytacazes-RJ, Brazil. Genetics and Molecular Research 13: 10898-10908.
Flores RA, Urquiaga SS, Alves BJR, Collier LS and Boddey RM (2012) Yield and quality of elephant grass biomass produced in the Cerrados region for bioenergy. Engenharia Agrícola 32: 831-839.
Freitas ILJ, Amaral Junior AT, Viana AP, Pena GF, Cabral PS, Vittorazzi C and Silva TRC (2013) Ganho genético avaliado com índices de seleção e com REML/BLUP em milho-pipoca. Pesquisa Agropecuária Brasileira 48: 1464-1471.
Hazel LN (1943) The genetic basis for constructing selection indexes. Genetics 28: 476-490.
Jung MS, Vieira EA, Brancker A and Nodari RO (2008) Herdabilidade e ganho genético em caracteres do fruto do maracujazeiro-doce. Revista Brasileira de Fruticultura 30: 209-214.
Lee MK, Tsai WT, Tsai YL and Lin SH (2010) Pyrolysis of Napier grass in an induction-heating reactor. Journal of Analytical and Applied Pyrolysis 88: 110-116.
Lima RSN, Daher RF, Gonçalves LSA, Rossi DA, Amaral Júnior AT, Pereira MG and Lédo FJS (2011) RAPD and ISSR markers in the evaluation of genetic divergence among accessions of elephant grass. Genetics and Molecular Research 10: 1304-1313.
Menezes BRF, Daher RF, Gravina GA, Amaral Junior AT, Oliveira AV, Schneider LSA and Silva VB (2014) Correlações e análise de trilha em capim-elefante para fins energéticos. Revista Brasileira Ciências Agrárias 9: 465-470.
Mertens DR (2002) Gravimetric determination of amylase-treated neutral detergent fiber in feeds with refluxing in beakers or crucibles: collaborative study. Journal of AOAC International 85: 1217-1231.
Passos LP, Machado MA, Vidigal MC and Campos AL (2005) Molecular characterization of elephant-grass accessions through RAPD markers. Ciência e Agrotecnologia 29: 568-574.
Pereira AV, Lédo FJS and Machado MA (2017) BRS Kurumi and BRS Capiaçu - New elephant grass cultivars for grazing and cut-and-carry system. Crop Breeding and Applied Biotechnology 17: 59-62.
Pereira AV, Machado MA, Azevedo ALS, Nascimento CS, Campos AL and Lédo FJS (2008) Diversidade genética entre acessos de capim-elefante obtida com marcadores moleculares. Revista Brasileira de Zootecnia 37: 1216-1221.
Rengsirikul K, Ishii Y, Kangvansaichol K, Pripanapong P, Sripichitt P, Punsuvon V, Vaithanomsat P, Nakamanee G and Tudsri S (2011) Effects of inter-cutting interval on biomass yield, growth components and chemical composition of napier grass (Pennisetum purpureum Schumach) cultivars as bioenergy crops in Thailand. Grassland Science 57: 135-141.
Rosado AM, Rosado TB, Júnior MFRR, Bhering LL and Cruz CD (2009) Ganhos genéticos preditos por diferentes métodos de seleção em progênies de Eucalyptus urophylla Pesquisa Agropecuária Brasileira 44: 1653-1659.
Rossi DA, Menezes BRS, Daher RF, Gravina GA, Lima RSN, Lédo FJ S, Gottardo R D, Campostrini E and Souza CLM (2014) Canonical correlations in elephant grass for energy purposes. African Journal Biotechnology 36: 3666-3671.
Salgado SML, Rezende JC and Nunes JAR (2014) Selection of coffee progenies for resistance to nematode Meloidogyne paranaensis in infested area. Crop Breeding and Applied Biotechnology 14: 94-10.
Santos HG, Jacomine PKT, Anjos LHC, Oliveira VÁ, Lumbreras JF, Coelho MR, Almeida JÁ, Cunha TJF and Oliveira JB (2013) Sistema brasileiro de classificação de solos. 3^rd edn, Embrapa, Brasília, 353p.
Silva FHL, Viana AP, Santos EA, Freitas JCO, Rodrigues DL and Amaral Júnior AT (2017) Prediction of genetic gains by selection indexes and REML/BLUP methodology in a population of sour passion fruit under recurrent selection. Acta Scientiarum. Agronomy 39: 183-190.
Silva VQR, Damer RF, Amaral Gravina G, Silva Ledo FJ, Tardin FD and Souza MC (2011) Capacidade combinatória de capim-elefante com base em caracteres morfoagronômicos. Boletim de Indústria Animal 71: 63-70.
Smith HF (1936) A discriminant function for plant selection. Annals Eugenics 7: 240-250.
Teixeira DHL, Oliveira MDSP, Gonçalves FMA and Nunes JAR (2012) Índices de seleção no aprimoramento simultâneo dos componentes da produção de frutos em açaizeiro. Pesquisa Agropecuária Brasileira 47: 237-243.
Verardi CK, Resende MDZV, Costa RB and Gonçalves PS (2009) Adaptabilidade e estabilidade da produção de borracha e seleção em progênies de seringueira. Pesquisa Agropecuária Brasileira 44: 1277-1282.

Publication Dates

Publication in this collection
Jan-Mar 2018

History

Received
08 Feb 2017
Accepted
09 June 2017

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

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[22] Pereira AV, Lédo FJS and Machado MA (2017) BRS Kurumi and BRS Capiaçu - New elephant grass cultivars for grazing and cut-and-carry system. Crop Breeding and Applied Biotechnology 17: 59-62.

[23] Pereira AV, Machado MA, Azevedo ALS, Nascimento CS, Campos AL and Lédo FJS (2008) Diversidade genética entre acessos de capim-elefante obtida com marcadores moleculares. Revista Brasileira de Zootecnia 37: 1216-1221.

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[25] Rosado AM, Rosado TB, Júnior MFRR, Bhering LL and Cruz CD (2009) Ganhos genéticos preditos por diferentes métodos de seleção em progênies de Eucalyptus urophylla Pesquisa Agropecuária Brasileira 44: 1653-1659.

[26] Rossi DA, Menezes BRS, Daher RF, Gravina GA, Lima RSN, Lédo FJ S, Gottardo R D, Campostrini E and Souza CLM (2014) Canonical correlations in elephant grass for energy purposes. African Journal Biotechnology 36: 3666-3671.

[27] Salgado SML, Rezende JC and Nunes JAR (2014) Selection of coffee progenies for resistance to nematode Meloidogyne paranaensis in infested area. Crop Breeding and Applied Biotechnology 14: 94-10.

[28] Santos HG, Jacomine PKT, Anjos LHC, Oliveira VÁ, Lumbreras JF, Coelho MR, Almeida JÁ, Cunha TJF and Oliveira JB (2013) Sistema brasileiro de classificação de solos. 3^rd edn, Embrapa, Brasília, 353p.

[29] Silva FHL, Viana AP, Santos EA, Freitas JCO, Rodrigues DL and Amaral Júnior AT (2017) Prediction of genetic gains by selection indexes and REML/BLUP methodology in a population of sour passion fruit under recurrent selection. Acta Scientiarum. Agronomy 39: 183-190.

[30] Silva VQR, Damer RF, Amaral Gravina G, Silva Ledo FJ, Tardin FD and Souza MC (2011) Capacidade combinatória de capim-elefante com base em caracteres morfoagronômicos. Boletim de Indústria Animal 71: 63-70.

[31] Smith HF (1936) A discriminant function for plant selection. Annals Eugenics 7: 240-250.

[32] Teixeira DHL, Oliveira MDSP, Gonçalves FMA and Nunes JAR (2012) Índices de seleção no aprimoramento simultâneo dos componentes da produção de frutos em açaizeiro. Pesquisa Agropecuária Brasileira 47: 237-243.

[33] Verardi CK, Resende MDZV, Costa RB and Gonçalves PS (2009) Adaptabilidade e estabilidade da produção de borracha e seleção em progênies de seringueira. Pesquisa Agropecuária Brasileira 44: 1277-1282.

		DMP (t ha^-1 year^-1)		NT (tillers)		SD (mm)		PH (m)		NDF (%)
SV	df	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂
Block	2	40.10	141.10	264.07	60.31	9.07	20.48	0.97	0.49	25.00	40.80
Families	7	1562.50*	1717.80**	1175.80**	1030.20*	3.28	55.70**	0.55	2.79	88.50	218.00**
Among	14	512.40	273.47	131.41	117.21	7.80	8.61	0.48	0.53	41.80	28.80
Within	96	355.90	370.11	138.55	125.55	4.39	2.16	0.22	0.17	29.60	28.30
Mean		59.20	57.07	31.79	26.52	14.99	12.35	3.03	3.49	68.40	77.00
CV (%)		17.08	12.95	16.12	11.58	8.33	10.62	10.20	9.36	2.42	3.12
h² _m		0.67	0.84	0.88	0.95	0	0.84	0	0	0	0.86
h² d		0.19	0.26	0.50	0.52	0	0.74	0	0	0	0.52

		Mean Squares
SV	df	DMP (t ha^-1 year^-1)	NT (tillers)	PH (m)	SD (mm)	NDF (%)
Blocks	2	17.12	253.12	0.80	11.63	62.68
Families (F)	7	2958.10**	2119.24*	2.68*	40.80**	200.23*
Error A	14	642.12	136.68	0.83	6.85	51.20
Cut (C)	1	289.23	1664.37**	12.71 **	419.44**	4427.11**
Error B	16	146.35	45.61	0.25	10.62	17.53
F x C	7	322.24	86.86**	0.660*	18.26	107.09*
Residue Within	192	363.03	132.05	0.20	3.28	19.00

	DMP (t ha^-1 year^-1)		NT (tillers)		PH (m)		SD (mm)		NDF (%)
Estimates	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂
X_o	59.2	57.07	31.79	26.52	3.03	3.49	14.49	12.35	68.42	77.01
X_s	67.8	64.71	37.73	31.85	3.17	3.74	15.02	12.95	69.6	78.81
h₂	67.2	84.08	88.82	95.41	12.42	80.82	-137.9	84.56	52.67	86.79
SG_t	5.74	6.42	5.27	5.08	0.01	0.2	-0.03	0.5	0.62	1.55
SG (%)	9.69	11.26	16.6	19.15	0.58	5.83	-0.25	4.08	0.91	2.02

Trait		DMP (t ha^-1 year^-1)		NT (tillers)		PH (m)		SD (mm)		NDF (%)
	SG (%)	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂	C₁	C₂
DMP	SG_a	-	-	4.73	4.39	0.11	0.26	0.11	0.86	0.86	2.09
(t ha^-1year^-1)	SG_w	-	-	5.64	5.46	0.13	0.32	0.13	5.07	1.02	2.6
	SG_t	-	-	10.4	9.85	0.24	0.58	0.24	5.93	1.88	4.69
NT	SG_a	4.52	5.37	-	-	0.065	0.37	0.04	0.39	0.365	1.32
(tillers)	SG_w	5.92	9.6	-	-	0.086	0.2	0.58	0.7	0.478	2.37
	SG_t	10.4	15	-	-	0.151	0.57	0.62	1.09	0.843	3.69
PH	SG_a	5.92	5.34	3.49	3.5	-	-	-0.1	0.81	0.69	1.75
(m)	SG_w	0.96	5.62	0.56	3.68	-	-	0	0.85	0.11	1.84
	SG_t	6.88	11	4.05	7.18	-	-	-0.1	1.66	0.8	3.59
SD	SG_a	2.17	3.58	0.89	11.3	-0.05	0.16	-	-	-0.19	1.64
(mm)	SG_w	0.4	4.99	0.16	1.86	-0.01	0.22	-	-	-0.03	2.29
	SG_t	2.57	8.57	1.05	13.2	-0.06	0.38	-	-	-0.22	3.93
NDF	SG_a	5.74	4.75	4.73	2.27	0.11	0.19	0.11	0.9	-	-
(%)	SG_w	5.92	10.8	7.15	5.59	0.086	0.44	0.06	2.04	-	-
	SG_t	11.7	15.5	11.9	7.86	0.196	0.63	0.17	2.94	-	-

	SG C₁			SG C₂
Trait	SD	CVg	RW	SD	CVg	RW
DMP (T ha^-1year^-1)	25.38	25.09	24.78	35.53	30.71	31.9
NT (tillers)	47.66	49.95	45.85	76.99	71.43	68.12
PH (m)	4.33	5.23	5.75	5.07	5.52	6.19
SD (mm)	-0.52	-0.248	0.21	-0.89	-0.28	0.32
NDF (%)	1.71	1.69	2.16	2.04	1.76	2.38