Progeny evaluation and early selection for plant height in <i>Acacia mearnsii</i> improve genetic gains

Bisognin, Dilson Antônio; Lencina, Kelen Haygert; Greff, Henrique Pinton; Tonetto, Thaise; Gazzana, Denise

doi:10.1590/1984-70332022v22n4a48

Abstract

Acacia mearnsii De Wild. is one of the most widely cultivated forest species in Brazil. Despite its importance, studies on breeding strategies for this species are scarce. Therefore, the aim of this study was to evaluate the progeny and develop early selection strategies for A. mearnsii. Individuals of half-sib progenies were classified according to their genotypic value and selected based on their relative performance. The additive effect was only significant for plant height. The best progenies and plants should be selected based on plant height after approximately 60 days of being in nursery and 2 years of field cultivation. This strategy eliminates the worse progenies, discards inferior genotypes in the nursery, eliminates unselected genotypes based on plant height before flowering, and intercrosses only the best plants in field cultivation. This resulted in an annual genetic gain of 3% for plant height and 2% for diameter at breast height.

Keywords:
Forest breeding; nursery; progeny test; intercrossing; indirect gain

INTRODUCTION

The genus Acacia may be found growing naturally in southeastern Australia, with approximately 120-130 species cultivated in all regions of the world, except Europe and Antarctica (Turnbull et al. 1998Turnbull JW, Midgley SJ, Cossalter C1998 Tropical acacias planted in Asia: An overview. Recent Developments in Acacia Planting 82:14-28). Acacia mearnsii De Wild. has hermaphroditic flowers with either male and female reproductive organs, or only male functional reproductive organs (Grant et al. 1994Grant JE, Moran GF, Moncur MW1994 Pollination studies and breeding system in Acacia mearnsii In Australian tree species research in China. ACIAR, Camberra, p. 165-170). It is a crosspollinated species with partial self-compatibility (Crong and Fuller 1995), and is mainly insect-pollinated (Grant et al. 1994). Plants may start to flower at 2 years of age (Sherry 1971Sherry SP1971 The Black wattle (Acacia mearnsii De Wild.) University of Natal Press, Pietermaritzburg, p. 424), with seeds being available for collection, for 2-3 weeks, only 12-14 months later (Searle 1997Searle SD1997 Acacia mearnsii De Wild. (black wattle) in Australia. In Brown AG and Ho CK (eds) Black wattle and its utilisation. Rural Industries Research and Development Corporation, Camberra, p. 1-12).

In Brazil, A. mearnsii was introduced in Rio Grande do Sul in 1918, where almost all of its cultivation is still carried out (Ageflor 2020). However, little information is available regarding adaptations made to germplasm introduction and evaluation for Brazilian growing conditions. Acacia mearnsii is cultivated in an area of approximately 75,900 hectares in Rio Grande do Sul and is used for wood production and its bark is used for tannin extraction (Ageflor 2020Ageflor2020 O Setor de base florestal no Rio Grande do Sul 2020 - Ano base 2019. Associação Gaúcha de Empresas Florestais, Porto Alegre, 84p). Studies indicate the possibility of obtaining multiple uses from A. mearnsii and diversification of its products, both timber and non-timber products. In addition, this species is indicated for use in the afforestation of parks and gardens because of its ornamental characteristics (Lorenzi et al. 2018Lorenzi H, Souza HM, and Torres MAV2018 Árvores e arvoretas exóticas no Brasil: madeireiras, ornamentais e aromáticas. Instituto Plantarum, Nova Odessa, 600p).

Because of the growing demand for raw materials, A. mearnsii cultivation has become increasingly important in the forest-based industrial market, leading to an increase in the area of fast-growing homogeneous forest plantations (Machado et al. 2014Machado LM, Costa EC, Magistrali IC, Boscardin J, Machado DN, Garlet J2014 Escolitíneos associados a uma população de acácia-negra (Acacia mearnsii De Wild). Revista Biotemas 27:57-63). New plantations are most commonly established using seedlings, the seeds of which are collected from areas of commercial production with little or no genetic control, resulting from crossing related individuals, which promotes inbreeding depression (Chan et al. 2015Chan JM, Day P, Feely J, Thompson R, Little KM, Norris CH2015 Acacia mearnsii industry overview: current status, key research and development issues. Southern Forests: a Journal of Forest Science 77:19-30). In addition, most of the seeds are collected from anthills (Chan et al. 2015Chan JM, Day P, Feely J, Thompson R, Little KM, Norris CH2015 Acacia mearnsii industry overview: current status, key research and development issues. Southern Forests: a Journal of Forest Science 77:19-30), which compromises their physiological and sanitary qualities.

To improve perennial cross-fertilized species such as A. mearnsii, it is essential to define a selection strategy that maximizes genetic gain and reduces the time required to complete each cycle. Progeny tests are the most appropriate improvement strategy because they evaluate the performance of the selected plants based on estimated genetic values, thereby facilitating the selection of the best progenies and plants (Pires et al. 2013Pires VCM, Martins K, Bôas OV, Freitas MLM, Sebbenn AM2013 Variabilidade genética de caracteres silviculturais em progênies de polinização aberta de Pinus caribaea var. bahamensis. Scientia Forestalis 41:113-119, Costa et al. 2015Costa RB, Martinez DT, Silva JC, Almeida BC2015 Variabilidade e ganhos genéticos com diferentes métodos de seleção em progênies de Eucalyptus camaldulensis. Revista de Ciências Agrárias 58:69-74). Progeny evaluation allows for the estimation of genetic parameters for all traits of interest, as well as the definition of the best selection strategy based on the genetic gain (Kubota et al. 2015Kubota TYK, Moraes MA, Silva ECB, Pupin S, Aguiar AV, Moraes MLT, Freitas MLM, Sato AS, Machado JAR, Sebbenn AM2015 Variabilidade genética para caracteres silviculturais em progênies de polinização aberta de Balfourodendron riedelianum (Engler). Scientia Forestalis 43:407-415). It also enables the assessment of genetic diversity to guide management and conservation strategies (Duarte et al. 2012Duarte RI, Silva FALS, Schultz J, Silva JZ, Reis MS2012 Características de desenvolvimento inicial em teste de progênie de uma população de Araucária na flona de Três Barras - SC. Revista Biodiversidade Brasileira 2:114-123). Based on the definition and use of more efficient strategies, a mixed linear model analysis via restricted maximum likelihood (REML) best linear unbiased prediction (BLUP) has been used in plant breeding programs (Borges et al. 2010Borges V, Soares AA, Reis MS, Resende MDV, Cornélio VMO, Leite NA, Vieira AR2010 Desempenho genotípico de linhagens de arroz de terras altas utilizando metodologia de modelos mistos. Bragantia 69:833-841).

Considering the relevance of A. mearnsii production chains to the forestry sector, and the need for a breeding method that can maximize genetic gain, this study aimed to evaluate the progeny and develop early selection strategies for A. mearnsii to improve genetic gain.

MATERIAL AND METHODS

The experiments were conducted by the Federal University of Santa Maria, in partnership with SETA S/A Company, between December 2015 and December 2019. We evaluated half-sib progenies of 32 selected plants from a progeny test of 139 plants introduced from Australia in a nursery located in Montenegro and in a field at Encruzilhada do Sul. Both are located in Rio Grande do Sul, Brazil.

For seedling production, approximately 200 seeds of each selected plant were sown in 280 cm³ polypropylene tubes filled with pine bark substrate. This was done in December 2015. The height of the seedlings was evaluated 22 days after sowing, which was measured from the level of the substrate to the tip of the last leaf. Plant height and stem diameter were measured 51, 76, and 125 days after sowing.

The best seedlings of each progeny were planted in the field on September 19, 2016. Each progeny was divided into replicates comprising three individuals. Each replicate was located at a maximum distance in the field to avoid parental crosses. Plant height was evaluated 85 days after planting, whereas height and diameter (stem diameter or diameter at breast height (DBH)) were evaluated 280, 434, 799, and 1100 days after planting. The absolute average increment in plant height was obtained because the same genotype was used in both the nursery and in field cultivation. The experiment was conducted in an incomplete block design with six replications of three plants.

The data were subjected to deviance analysis (Resende 2002Resende MDV2002 Genética biométrica e estatística no melhoramento de plantas perenes. Embrapa Informação Tecnológica, Brasília, 975p), and the likelihood ratio was used to test the difference significance in the fit of different models, defined as follows: $λ = 2 [{L o g}_{e} L_{p + 1} - {L o g}_{e} L_{p}$ ], where $L_{p + 1}$ and ${e L}_{p}$ represent peaks of the likelihood function associated with the full and reduced model, respectively. $λ$ is compared with the probability density function (χ²), considering the number of degrees of freedom and the error probability.

The REML method was used to estimate the variance components, and the BLUP method was used to estimate the phenotypic and genotypic values (Resende 2002Resende MDV2002 Genética biométrica e estatística no melhoramento de plantas perenes. Embrapa Informação Tecnológica, Brasília, 975p) with the help of the Selegen REML/BLUP software (Resende 2016Resende MDV2016 Software Selegen-REML/BLUP: a useful tool for plant breeding. Crop Breeding and Applied Biotechnology 16:330-339). Model 67 (progenies and individuals), based on repeated measures, was used for the selection of families, while Model 6, which considers each assessment separately, was used for the identification of superior individuals or genotypes.

Statistical model 67 corresponds to the design in incomplete blocks, expressed by $y = X m + Z a + W p + Q s + T b + e$ , where $y$ is the data vector; $m$ is the vector of the effects of measurement-repetition combinations (fixed) added to the overall mean; $a$ is the vector of individual additive genetic effects (random); $p$ is the vector of plot effects (random); $s$ is the vector of permanent (random) effects; $b$ is the vector of block effects (random); and $e$ is the vector of errors or (random) residuals.

Statistical model 6 corresponds to the design in incomplete blocks, expressed by $y = X r + Z a + W p + T b + e$ , where $y$ is the data vector; $r$ is the vector of the repetition effects (fixed) added to the general mean; $a$ is the vector of additive genetic effects (random); $p$ is the vector of plot effects (random); repeatability $b$ is the vector of block effects (random); and $e$ is the vector of errors or residuals (random). Capital letters represent the incidence matrices for the effects of each statistical model.

The permanent phenotypic effects (mean components) of the 32 A. mearnsii progenies were obtained to classify and identify the best families. For all progenies and individuals, the genotypic value represents the general mean of the experiment, added to the genotypic effect. Furthermore, the genetic gain is the average of the predicted genetic effects of each selected genotype, which, when added to the general mean, results in the mean of the improved population. The relative performance represents the relationship between the means of the improved population and the genotype with the highest genetic value. Both progenies and genotypes that presented a relative performance greater than 80% for the genotypic value were selected.

Based on the selected individuals, the genetic gain for plant height and diameter was calculated as the difference between the original mean and the mean of the selected genotypes. The selection gains (G) and percentages (G%) were calculated using the following formulas: $G = (MS˗MO)$ and $G (%) = [\frac{(MS-MO)}{MO}] ×100$ , respectively, where MS is the mean of the selected genotype and MO is the original mean.

RESULTS AND DISCUSSION

Deviance analysis showed that the additive and permanent effects were significant for both plant height and diameter (Table 1). These results explain most of the variation observed in the plant traits analyzed and indicate the existence of genetic variability among progenies. Knowledge of the genetic variability in populations enables the development of selection strategies that can be adopted in breeding programs (Otsubo et al. 2015Otsubo HCB, Moraes MLT, Moraes MA, Neto MJ, Freitas MLM, Costa RB, Resende MDV, Sebbenn AM2015 Variação genética para caracteres silviculturais em três espécies arbóreas da região do Bolsão Sul-Mato-Grossense. Cerne 21:535-544). Notably, in addition to indicating the possibility of genetic gain due to selection for plant height, additive effects are heritable by subsequent generations and, therefore, should be considered a crucial parameter in the genetic improvement of populations. The random effects of plot and block (evaluations) were not significant for any of the evaluated traits (Table 1), indicating that they have little effect on the observed variation and that it is possible to perform individual analyses to identify the best time for the selection of individual plants or genotypes.

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Table 1
Analysis of deviance (ANADEV), variance components, and genetic parameters for plant height (cm) and diameter (mm) of 32 Acacia mearnsii progenies cultivated in a nursery (three evaluations) and field (four evaluations)

Regarding the variance components, all individual phenotypic variances for plant height were explained by residual variance (71.6%; environmental and non-additive genetics) and additive variance (16.9%) (Table 1). Regarding plant diameter, the majority of the individual phenotypic variance was explained by residual variance (59.4%) and the variance of permanent effects (33.4%). The fact that the residual variance was greater than the genotypic variance indicates that the environment (residual effect) had a significant influence on phenotypic variance.

Although both traits were greatly influenced by the environment, plant height showed an adequate value of additive variance, which consists of the heritable portion of the genotypic variance that guarantees genetic gain from selection. Therefore, the variance components and genetic parameters indicate that plant height can be used to select the best A. mearnsii progenies and plants. This is a relevant result, as it shows that A. mearnsii plants can be selected based on one of the most important silvicultural traits for yield, which favors and increases the efficiency of field work, eliminates unnecessary evaluations, and enables direct and indirect gains from selection. This is an operational advantage because the plantation evaluation process is one of the most time-consuming and costly steps in genetic improvement programs. Furthermore, as Resende et al. (1991Resende MDV, Souza SM, Higa AR, Stein PP1991 Estudos da variação genética e métodos de seleção em teste de progênies de Acacia mearnsii no Rio Grande do Sul. Embrapa/CNPF, Colombo, p. 45-59) observed, plant height and diameter are highly correlated. This suggests that selection for one trait promotes indirect selection gains for the other. Plant height was also found to be suitable for the early selection of Jatropha curcas plants (Borges et al. 2014Borges CV, Ferreira FB, Rocha RB, Santos AR, Laviola BG2014 Capacidade produtiva e progresso genético de pinhão-manso. Ciência Rural 44:64-70).

Environmental variance was an important component that negatively affected the heritability estimates (Table 1). Because of the high values of residual variance, the individual repeatability coefficients ( $r$ ), which represent heritability in a broad sense, are classified as low magnitude for plant height and medium magnitude for plant diameter (Resende 2016Resende MDV2016 Software Selegen-REML/BLUP: a useful tool for plant breeding. Crop Breeding and Applied Biotechnology 16:330-339). In perennial plants such as J. curcas, low repeatability values are expected, mainly for productivity (Laviola et al. 2013Laviola BG, Oliveira AMC, Bhering LL, Alves AA, Rocha RB, Gomes BEL, Cruz CD2013 Estimates of repeatability coefficients and selection gains in Jatropha indicate that higher cumulative genetic gains can be obtained by relaxing the degree of certainty in predicting the best families. Industrial Crops and Products 51:70-76), which corroborates the importance of its estimation. Low values for yield repeatability have also been obtained for other perennial species such as Annona muricata (Sanchéz et al. 2017Sanchéz CFB, Alves RS, Garcia ADP, Teodoro PE, Peixoto LA, Silva LA, Bhering LL, Resende MDV2017 Estimates of repeatability coefficients and the number of the optimum measure to select superior genotypes in Annona muricata L. Genetics and Molecular Research 16:1-8), Poncirus trifoliata, and Citrus unshiu (Imai et al. 2016Imai A, Kuniga T, Yoshioka T, Nonaka K, Mitani N, Fukamachi H, Hiehata N, Yamamoto M, Hayashi T2016 Evaluation of the best linear unbiased prediction method for breeding values of fruit-quality traits in citrus. Tree Genetics & Genomes 12:119).

Considering that plant height had a significant additive effect (Table 1), the 32 A. mearnsii progenies were ranked based on average components (individual BLUPs) (Table 2). All the evaluated progenies showed a relative performance greater than 85%, thereby confirming their superiority for having been previously selected, and indicating that all progenies should be maintained for selecting genotypes within them.

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Table 2
Individual additive genetic effects (a), selection gain (SG), new mean (Nm), and relative performance (RP%) estimated for plant height (cm) of 32 Acacia mearnsii progenies cultivated in a nursery (three evaluations) and field (four evaluations)

In a selection program, plants within progenies should be selected as early as possible to reduce the time needed to complete each cycle. As shown in this study, the best A. mearnsii progenies and plants, in terms of plant height, must be identified, and individual analysis would indicate the best time to conduct the selection process. The analysis of plant height in each evaluation showed that the additive effect was significant for all evaluations, except at cultivation days 280 and 434 in the field (Table 3). The high heritability estimates of individual additive ( $h_{a}^{2}$ ≥ 0.5) and progeny mean ( $h_{m p}^{2}$ > 0.9) indicate the possibility of obtaining genetic gain based on plant height during nursery cultivation. Moreover, the relative coefficients of variation were higher for nurseries than for field evaluation. The narrow-sense individual heritability coefficients adjusted for plot effects were similar between the nursery and field evaluations, but a high estimate ( $h_{a j}^{2}$ = 0.873) was obtained at day 799 of field cultivation. These results indicate that plants should be selected based on plant height in the nursery 51 days after sowing and 799 days after planting in the field. These two time points for the selection of A. mearnsii plants corresponded to the maximum absolute average increase in plant height between the evaluations in the nursery (Figure 1A) and field (Figure 1B), indicating that the plants should be selected approximately 60 days after sowing in the nursery and approximately 2 years after planting in the field.

Figure 1
Mean absolute increment in plant height (cm) of 32 progenies of Acacia mearnsii in nursery cultivation for 120 days (A) and in field cultivation for 1100 days (B). Plants were evaluated at 51, 76, 103, and 125 days of nursery cultivation and at 85, 280, 434, 799, and 1100 days of field cultivation.

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Table 3
Analysis of deviance (ANADEV), variance components, and genetic parameters for plant height (cm) of 32 Acacia mearnsii progenies cultivated in a nursery (three evaluations) and field (four evaluations)

Selection based on only one evaluation of plant height in the nursery and field is sufficient to facilitate breeding. At 799 days in the field, plant height showed a positive correlation (r = 0.571, p < 0.001) with diameter at breast height, suggesting an indirect gain from selection. These traits are easily measured and provide a growth advantage to the plants during field development (Pinto et al. 2015Pinto JR, Davis AS, Leary JJK, Aghai MM2015 Stocktype and grass suppression accelerate the restoration trajectory of Acacia koa in Hawaiian montane ecosystems. New Forests 46:855-867) because they are important traits for plantlet quality (Grossnickle and McDonald 2018Grossnickle SC, McDonald JE2018 Why seedlings grow: influence of plant attributes. New Forests 49:1-34). In forest species, selection is usually based on one evaluation at the earliest possibility to maximize genetic gain (Resende and Barbosa 2005Resende MDV, Barbosa MHP2005 Melhoramento genético de plantas de propagação assexuada. Embrapa Florestas, Colombo, 130p). In A. mearnsii, unselected plants can be eliminated at 2 years old, just before they start flowering (Sherry 1971Sherry SP1971 The Black wattle (Acacia mearnsii De Wild.) University of Natal Press, Pietermaritzburg, p. 424), thereby improving the gain from selection.

Similar results were obtained for Myrocarpus frondosus, in which plant height selected at 60 days of nursery cultivation resulted in indirect gains in the relationship between plant height and stem diameter (Bisognin et al. 2020Bisognin DA, Lencina KH, Aimi SC, Araújo MM, Burin C2020 Progeny selection of Myrocarpus frondosus for improved growth vigor of seedlings. Ciência e Natura 42:1-16). Early selection of eucalyptus hybrid clones for diameter at breast height can be performed after 3 years of cultivation, which led to a high correlation with diameter at breast height and plant height after 7 years of cultivation (Beltrame et al. 2012Beltrame R, Bisognin DA, Mattos BD, Cargnelutti Filho A, Haselein CR, Gatto DA, Santos GA2012 Desempenho silvicultural e seleção precoce de clones de híbridos de eucalipto. Pesquisa Agropecuária Brasileira 47:791-796). Selection at 3 years of cultivation for diameter at breast height and plant height was indicated for E. urophylla clones (Pinto et al. 2014Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD2014 Seleção precoce para características de crescimento em testes clonais de Eucalyptus urophylla. Scientia Forestalis 42:251-157), whereas selection at 2 years of cultivation for diameter at breast height was indicated in eucalyptus clonal tests (Massaro et al. 2010Massaro RAM, Bonine CAV, Scarpinati EA, Paula RC2010 Viabilidade de aplicação da seleção precoce em testes clonais de Eucalyptus spp. Ciência Florestal 20:597-609).

The permanent phenotypic effects of the 32 A. mearnsii progenies were obtained for plant height to classify and identify the best genotypes in each of the evaluations that showed a significant additive effect. In this experiment, repeated measurements of plant height were used for progeny selection and for identifying the best plants within each progeny for field planting. The high relative performance (> 85%) observed in all progenies (Table 2) and plants indicated that the selection of the best progenies with the best genotypes to be planted in the field constitutes an efficient strategy and should be performed approximately 60 days after sowing. As field selection should be performed 799 days after planting (approximately 2 years), the plants were evaluated for relative performance, with the lowest percentage being 73.4% (P038-15). At day 1100 of field cultivation, the lowest percentage of relative performance was 88.41% (P075-20), indicating the high growth vigor of all evaluated plants. Based on these criteria, 108 plants were selected with a relative performance above 80.2%, corresponding to 40.1% of the evaluated plants. The strategy of selecting 108 plants for intercrossing would result in a direct gain of 11.8% for plant height and an indirect gain of 8.1% for diameter at breast height (Table 4). The best 20 E. camaldulensis progenies ranked by BLUP resulted in a direct genetic gain of 19.6% for the diameter of breast height at 2 years (Costa et al. 2015Costa RB, Martinez DT, Silva JC, Almeida BC2015 Variabilidade e ganhos genéticos com diferentes métodos de seleção em progênies de Eucalyptus camaldulensis. Revista de Ciências Agrárias 58:69-74). In contrast, a genetic gain of 10.9% was estimated in eucalyptus hybrid clones for the diameter at breast height at 3 years (Beltrame et al. 2012Beltrame R, Bisognin DA, Mattos BD, Cargnelutti Filho A, Haselein CR, Gatto DA, Santos GA2012 Desempenho silvicultural e seleção precoce de clones de híbridos de eucalipto. Pesquisa Agropecuária Brasileira 47:791-796).

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Table 4
Genetic gain by selection of 32 Acacia mearnsii progenies for plant height (m) and diameter at breast height (cm) based on plant height at 799 days of field cultivation

The results of this study support an early selection strategy for A. mearnsii progenies to identify the best progenies, and genotypes within progenies, for intercrossing. Deviance analysis, variance components, and genetic parameters indicate that plant height should be used for progeny and genotype selection. The selection of plants in the juvenile stage reduces the number of genotypes to be evaluated in the field and maximizes the genetic gain in woody perennial species (Bisognin et al. 2020Bisognin DA, Lencina KH, Aimi SC, Araújo MM, Burin C2020 Progeny selection of Myrocarpus frondosus for improved growth vigor of seedlings. Ciência e Natura 42:1-16). The evaluation of plant height, which is easy to measure and positively correlated with the diameter at breast height, results in an operational advantage and enables direct and indirect genetic gains. In this early selection strategy, the best progenies and genotypes were selected based on plant height at approximately 60 days of nursery cultivation, and the best plants within the progenies were identified after 2 years of field cultivation. This strategy eliminates the worse progenies, discards inferior and/or inbreeding genotypes based on plant height during nursery cultivation, and eliminates unselected plants before flowering at 2 years of age (Sherry 1971Sherry SP1971 The Black wattle (Acacia mearnsii De Wild.) University of Natal Press, Pietermaritzburg, p. 424) to facilitate intercrossing only selected plants. During interbreeding in the field, parental crosses are sidestepped based on the distance between selected plants of the same family. As A. mearnsii seeds are available for collection approximately 1 year after flowering (Searle 1997Searle SD1997 Acacia mearnsii De Wild. (black wattle) in Australia. In Brown AG and Ho CK (eds) Black wattle and its utilisation. Rural Industries Research and Development Corporation, Camberra, p. 1-12), a new cycle of selection can be started every 4 years. The proposed strategy allowed an annual genetic gain of approximately 3% in plant height and 2% in diameter at breast height in A. mearnsii plants (Table 4). This genetic gain was estimated by selecting the best 108 plants, which were sufficient to maintain high genetic variability, both for the selection of other traits and for conducting successive cycles of selection.

REFERENCES

Ageflor2020 O Setor de base florestal no Rio Grande do Sul 2020 - Ano base 2019. Associação Gaúcha de Empresas Florestais, Porto Alegre, 84p
Beltrame R, Bisognin DA, Mattos BD, Cargnelutti Filho A, Haselein CR, Gatto DA, Santos GA2012 Desempenho silvicultural e seleção precoce de clones de híbridos de eucalipto. Pesquisa Agropecuária Brasileira 47:791-796
Bisognin DA, Lencina KH, Aimi SC, Araújo MM, Burin C2020 Progeny selection of Myrocarpus frondosus for improved growth vigor of seedlings. Ciência e Natura 42:1-16
Borges CV, Ferreira FB, Rocha RB, Santos AR, Laviola BG2014 Capacidade produtiva e progresso genético de pinhão-manso. Ciência Rural 44:64-70
Borges V, Soares AA, Reis MS, Resende MDV, Cornélio VMO, Leite NA, Vieira AR2010 Desempenho genotípico de linhagens de arroz de terras altas utilizando metodologia de modelos mistos. Bragantia 69:833-841
Chan JM, Day P, Feely J, Thompson R, Little KM, Norris CH2015 Acacia mearnsii industry overview: current status, key research and development issues. Southern Forests: a Journal of Forest Science 77:19-30
Costa RB, Martinez DT, Silva JC, Almeida BC2015 Variabilidade e ganhos genéticos com diferentes métodos de seleção em progênies de Eucalyptus camaldulensis. Revista de Ciências Agrárias 58:69-74
Duarte RI, Silva FALS, Schultz J, Silva JZ, Reis MS2012 Características de desenvolvimento inicial em teste de progênie de uma população de Araucária na flona de Três Barras - SC. Revista Biodiversidade Brasileira 2:114-123
Grant JE, Moran GF, Moncur MW1994 Pollination studies and breeding system in Acacia mearnsii In Australian tree species research in China. ACIAR, Camberra, p. 165-170
Grossnickle SC, McDonald JE2018 Why seedlings grow: influence of plant attributes. New Forests 49:1-34
Imai A, Kuniga T, Yoshioka T, Nonaka K, Mitani N, Fukamachi H, Hiehata N, Yamamoto M, Hayashi T2016 Evaluation of the best linear unbiased prediction method for breeding values of fruit-quality traits in citrus. Tree Genetics & Genomes 12:119
Kubota TYK, Moraes MA, Silva ECB, Pupin S, Aguiar AV, Moraes MLT, Freitas MLM, Sato AS, Machado JAR, Sebbenn AM2015 Variabilidade genética para caracteres silviculturais em progênies de polinização aberta de Balfourodendron riedelianum (Engler). Scientia Forestalis 43:407-415
Laviola BG, Oliveira AMC, Bhering LL, Alves AA, Rocha RB, Gomes BEL, Cruz CD2013 Estimates of repeatability coefficients and selection gains in Jatropha indicate that higher cumulative genetic gains can be obtained by relaxing the degree of certainty in predicting the best families. Industrial Crops and Products 51:70-76
Lorenzi H, Souza HM, and Torres MAV2018 Árvores e arvoretas exóticas no Brasil: madeireiras, ornamentais e aromáticas. Instituto Plantarum, Nova Odessa, 600p
Machado LM, Costa EC, Magistrali IC, Boscardin J, Machado DN, Garlet J2014 Escolitíneos associados a uma população de acácia-negra (Acacia mearnsii De Wild). Revista Biotemas 27:57-63
Massaro RAM, Bonine CAV, Scarpinati EA, Paula RC2010 Viabilidade de aplicação da seleção precoce em testes clonais de Eucalyptus spp. Ciência Florestal 20:597-609
Otsubo HCB, Moraes MLT, Moraes MA, Neto MJ, Freitas MLM, Costa RB, Resende MDV, Sebbenn AM2015 Variação genética para caracteres silviculturais em três espécies arbóreas da região do Bolsão Sul-Mato-Grossense. Cerne 21:535-544
Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD2014 Seleção precoce para características de crescimento em testes clonais de Eucalyptus urophylla. Scientia Forestalis 42:251-157
Pinto JR, Davis AS, Leary JJK, Aghai MM2015 Stocktype and grass suppression accelerate the restoration trajectory of Acacia koa in Hawaiian montane ecosystems. New Forests 46:855-867
Pires VCM, Martins K, Bôas OV, Freitas MLM, Sebbenn AM2013 Variabilidade genética de caracteres silviculturais em progênies de polinização aberta de Pinus caribaea var. bahamensis. Scientia Forestalis 41:113-119
Resende MDV2002 Genética biométrica e estatística no melhoramento de plantas perenes. Embrapa Informação Tecnológica, Brasília, 975p
Resende MDV2016 Software Selegen-REML/BLUP: a useful tool for plant breeding. Crop Breeding and Applied Biotechnology 16:330-339
Resende MDV, Barbosa MHP2005 Melhoramento genético de plantas de propagação assexuada. Embrapa Florestas, Colombo, 130p
Resende MDV, Souza SM, Higa AR, Stein PP1991 Estudos da variação genética e métodos de seleção em teste de progênies de Acacia mearnsii no Rio Grande do Sul. Embrapa/CNPF, Colombo, p. 45-59
Sanchéz CFB, Alves RS, Garcia ADP, Teodoro PE, Peixoto LA, Silva LA, Bhering LL, Resende MDV2017 Estimates of repeatability coefficients and the number of the optimum measure to select superior genotypes in Annona muricata L. Genetics and Molecular Research 16:1-8
Searle SD1997 Acacia mearnsii De Wild. (black wattle) in Australia. In Brown AG and Ho CK (eds) Black wattle and its utilisation. Rural Industries Research and Development Corporation, Camberra, p. 1-12
Sherry SP1971 The Black wattle (Acacia mearnsii De Wild.) University of Natal Press, Pietermaritzburg, p. 424
Turnbull JW, Midgley SJ, Cossalter C1998 Tropical acacias planted in Asia: An overview. Recent Developments in Acacia Planting 82:14-28

Publication Dates

Publication in this collection
13 Feb 2023
Date of issue
2022

History

Received
18 Aug 2022
Accepted
23 Nov 2022
Published
24 Dec 2022

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

[1] Ageflor2020 O Setor de base florestal no Rio Grande do Sul 2020 - Ano base 2019. Associação Gaúcha de Empresas Florestais, Porto Alegre, 84p

[2] Beltrame R, Bisognin DA, Mattos BD, Cargnelutti Filho A, Haselein CR, Gatto DA, Santos GA2012 Desempenho silvicultural e seleção precoce de clones de híbridos de eucalipto. Pesquisa Agropecuária Brasileira 47:791-796

[3] Bisognin DA, Lencina KH, Aimi SC, Araújo MM, Burin C2020 Progeny selection of Myrocarpus frondosus for improved growth vigor of seedlings. Ciência e Natura 42:1-16

[4] Borges CV, Ferreira FB, Rocha RB, Santos AR, Laviola BG2014 Capacidade produtiva e progresso genético de pinhão-manso. Ciência Rural 44:64-70

[5] Borges V, Soares AA, Reis MS, Resende MDV, Cornélio VMO, Leite NA, Vieira AR2010 Desempenho genotípico de linhagens de arroz de terras altas utilizando metodologia de modelos mistos. Bragantia 69:833-841

[6] Chan JM, Day P, Feely J, Thompson R, Little KM, Norris CH2015 Acacia mearnsii industry overview: current status, key research and development issues. Southern Forests: a Journal of Forest Science 77:19-30

[7] Costa RB, Martinez DT, Silva JC, Almeida BC2015 Variabilidade e ganhos genéticos com diferentes métodos de seleção em progênies de Eucalyptus camaldulensis. Revista de Ciências Agrárias 58:69-74

[8] Duarte RI, Silva FALS, Schultz J, Silva JZ, Reis MS2012 Características de desenvolvimento inicial em teste de progênie de uma população de Araucária na flona de Três Barras - SC. Revista Biodiversidade Brasileira 2:114-123

[9] Grant JE, Moran GF, Moncur MW1994 Pollination studies and breeding system in Acacia mearnsii In Australian tree species research in China. ACIAR, Camberra, p. 165-170

[10] Grossnickle SC, McDonald JE2018 Why seedlings grow: influence of plant attributes. New Forests 49:1-34

[11] Imai A, Kuniga T, Yoshioka T, Nonaka K, Mitani N, Fukamachi H, Hiehata N, Yamamoto M, Hayashi T2016 Evaluation of the best linear unbiased prediction method for breeding values of fruit-quality traits in citrus. Tree Genetics & Genomes 12:119

[12] Kubota TYK, Moraes MA, Silva ECB, Pupin S, Aguiar AV, Moraes MLT, Freitas MLM, Sato AS, Machado JAR, Sebbenn AM2015 Variabilidade genética para caracteres silviculturais em progênies de polinização aberta de Balfourodendron riedelianum (Engler). Scientia Forestalis 43:407-415

[13] Laviola BG, Oliveira AMC, Bhering LL, Alves AA, Rocha RB, Gomes BEL, Cruz CD2013 Estimates of repeatability coefficients and selection gains in Jatropha indicate that higher cumulative genetic gains can be obtained by relaxing the degree of certainty in predicting the best families. Industrial Crops and Products 51:70-76

[14] Lorenzi H, Souza HM, and Torres MAV2018 Árvores e arvoretas exóticas no Brasil: madeireiras, ornamentais e aromáticas. Instituto Plantarum, Nova Odessa, 600p

[15] Machado LM, Costa EC, Magistrali IC, Boscardin J, Machado DN, Garlet J2014 Escolitíneos associados a uma população de acácia-negra (Acacia mearnsii De Wild). Revista Biotemas 27:57-63

[16] Massaro RAM, Bonine CAV, Scarpinati EA, Paula RC2010 Viabilidade de aplicação da seleção precoce em testes clonais de Eucalyptus spp. Ciência Florestal 20:597-609

[17] Otsubo HCB, Moraes MLT, Moraes MA, Neto MJ, Freitas MLM, Costa RB, Resende MDV, Sebbenn AM2015 Variação genética para caracteres silviculturais em três espécies arbóreas da região do Bolsão Sul-Mato-Grossense. Cerne 21:535-544

[18] Pinto DS, Resende RT, Mesquita AGG, Rosado AM, Cruz CD2014 Seleção precoce para características de crescimento em testes clonais de Eucalyptus urophylla. Scientia Forestalis 42:251-157

[19] Pinto JR, Davis AS, Leary JJK, Aghai MM2015 Stocktype and grass suppression accelerate the restoration trajectory of Acacia koa in Hawaiian montane ecosystems. New Forests 46:855-867

[20] Pires VCM, Martins K, Bôas OV, Freitas MLM, Sebbenn AM2013 Variabilidade genética de caracteres silviculturais em progênies de polinização aberta de Pinus caribaea var. bahamensis. Scientia Forestalis 41:113-119

[21] Resende MDV2002 Genética biométrica e estatística no melhoramento de plantas perenes. Embrapa Informação Tecnológica, Brasília, 975p

[22] Resende MDV2016 Software Selegen-REML/BLUP: a useful tool for plant breeding. Crop Breeding and Applied Biotechnology 16:330-339

[23] Resende MDV, Barbosa MHP2005 Melhoramento genético de plantas de propagação assexuada. Embrapa Florestas, Colombo, 130p

[24] Resende MDV, Souza SM, Higa AR, Stein PP1991 Estudos da variação genética e métodos de seleção em teste de progênies de Acacia mearnsii no Rio Grande do Sul. Embrapa/CNPF, Colombo, p. 45-59

[25] Sanchéz CFB, Alves RS, Garcia ADP, Teodoro PE, Peixoto LA, Silva LA, Bhering LL, Resende MDV2017 Estimates of repeatability coefficients and the number of the optimum measure to select superior genotypes in Annona muricata L. Genetics and Molecular Research 16:1-8

[26] Searle SD1997 Acacia mearnsii De Wild. (black wattle) in Australia. In Brown AG and Ho CK (eds) Black wattle and its utilisation. Rural Industries Research and Development Corporation, Camberra, p. 1-12

[27] Sherry SP1971 The Black wattle (Acacia mearnsii De Wild.) University of Natal Press, Pietermaritzburg, p. 424

[28] Turnbull JW, Midgley SJ, Cossalter C1998 Tropical acacias planted in Asia: An overview. Recent Developments in Acacia Planting 82:14-28

Effects	Height	Diameter
Additive	22457.89**	8787.51
Plot	22443.46	8787.22
Permanent	22500.06**	9030.93**
Block	22441.09	8786.83
Full model	22441.04	8786.83
Component/Parameter¹
$V_{a}$	804.959152	6.647374
$V_{p l o t}$	67.197728	1.086394
$V_{p e r m}$	475.528671	36.290074
$V_{b l o c k}$	7.452678	0.066163
$V_{e}$	3411.500861	64.401656
$V_{p}$	4766.639089	108.491661
$h_{a}^{2}$	0.168874 ± 0.0472	0.061271 ± 0.0349
$c_{p l o t}^{2}$	0.014098	0.010014
$c_{p e r m}^{2}$	0.099762	0.334496
$c_{b l o c k}^{2}$	0.001564	0.000610
r	0.284296 ± 0.0307	0.406391 ± 0.0449
Overall mean	347.641679	45.971451

Progenies	a	SG	Nm	RP (%)
P060	57.4109	57.4109	405.0525	100.0
P102-2	45.9865	51.6987	399.3404	98.6
P135-2	29.7762	44.3912	392.0329	96.8
P012-1	26.5594	39.9332	387.5749	95.7
P119-2	25.1096	36.9685	384.6102	95.0
P037-1	20.158	34.1668	381.8084	94.3
P135-1	14.7054	31.3866	379.0283	93.6
P027-2	12.1788	28.9856	376.6273	93.0
P097-1	10.9559	26.9823	374.624	92.5
P011	9.0352	25.1876	372.8293	92.0
P113	5.9036	23.4345	371.0762	91.6
P032-1	5.3607	21.9284	369.57	91.2
P102-1	4.4661	20.5851	368.2268	90.9
P014-1	2.6632	19.305	366.9466	90.6
P016-1	1.7565	18.1351	365.7767	90.3
P030-1	-3.1539	16.8045	364.4462	90.0
P021	-3.6736	15.5999	363.2416	89.7
P014-2	-6.4065	14.3773	362.019	89.4
P020-1	-8.3021	13.1837	360.8254	89.1
P116-1	-8.9902	12.075	359.7167	88.8
P055-2	-9.5533	11.0451	358.6867	88.6
P133-1	-9.7257	10.1009	357.7426	88.3
P025	-10.5253	9.2041	356.8458	88.1
P027-1	-14.5025	8.2164	355.858	87.9
P140	-14.6444	7.3019	354.9436	87.6
P002-1	-18.4711	6.3107	353.9523	87.4
P119-3	-20.4015	5.3213	352.963	87.1
P119-1	-21.3619	4.3684	352.01	86.9
P055-1	-24.0517	3.3884	351.03	86.7
P001v	-24.4198	2.4614	350.1031	86.4
P075	-33.6764	1.2957	348.9374	86.1
P038	-40.1661	0	347.641	85.8

Effect	Plant height in nursery (cm)			Plant height in field (m)
Effect	51 days	76 days	125 days	280days	434 days	799 days	1100 days
Additive	1207.64**	1320.42**	1395.69**	-10.63	137.49	378.99**	428.72*
Parcel	1134.15	1227.53	1295.34	-8.8*	139.4	370.98*	422.1
Permanent	1134.33	1227.46	1295.33	-12.92	137.17	366.01	421.9
Full model	1134.13	1227.44	1295.33	-12.92	137.17	365.8	421.9
Component/ Parameter¹
$V_{a}$	85.558	165.179	199.080	0.085	0.051	1.091	0.699
$V_{p l o t}$	0.339	0.838	0.270	0.060	0.082	0.276	0.065
$V_{b l o c k}$	0.306	0.115	0.026	0.000	0.001	0.019	0.000
$V_{e}$	-45.278	-98.113	-114.880	0.191	0.447	0.158	0.976
$V_{p}$	40.925	68.019	84.496	0.336	0.580	1.545	1.741
$h_{a}^{2}$	0.500	0.537	0.539	0.173	0.102	0.290	0.218
$h_{a j}^{2}$	0.212	0.246	0.236	0.308	0.102	0.873	0.417
$c_{p l o t}^{2}$	0.008	0.012	0.003	0.177	0.141	0.179	0.038
$c_{b l o c k}^{2}$	0.007	0.002	0.000	0.001	0.001	0.013	0.000
CVgi (%)	24.484	25.767	21.760	10.092	4.601	11.344	7.065
CVgp (%)	12.242	12.884	10.880	5.046	2.301	5.672	3.533
CVe (%)	3.661	3.464	2.733	9.837	7.114	6.490	3.688
CVr	3.344	3.719	3.982	0.513	0.323	0.874	0.958
$h_{m p}^{2}$	0.985	0.988	0.990	0.612	0.386	0.821	0.846
$h_{a d}^{2}$	3.397	4.807	4.337	0.250	0.079	0.838	0.349
Acprog	0.993	0.994	0.995	0.782	0.621	0.906	0.920
Mean	37.78	49.88	64.84	2.89	4.91	9.21	11.83

Values	Height (m)	Diameter (cm)
Original mean	9.3	7.4
Improved mean	10.4	8.0
Selection gain	1.1	0.6
Selection gain (%)	11.8	8.1

Brasil

Brasil

Progeny evaluation and early selection for plant height in Acacia mearnsii improve genetic gains

Abstract

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

REFERENCES

Publication Dates

History