Unraveling the genetic diversity of coffee processing traits in <i>Coffea canephora</i>

Silva, Adriele Nunes Rodrigues; Rocha, Rodrigo Barros; Moraes, Amanda de Oliveira; Espindula, Marcelo Curitiba; Teixeira, Alexsandro Lara; Alves, Enrique Anastácio

doi:10.1590/0103-8478cr20240056

ABSTRACT:

With advancements in coffee cultivation, several traits may be considered in selection of plants, which must exhibit a set of favorable characteristics. The outturn index, defined as the relationship between the mass of mature fruit and processed beans, emerges as a key factor influencing productivity. This study characterized the outturn over two harvests of 57 clones marketed in the public domain and 10 registered cultivars. The analysis considers the effects of genotypes, measurements, and genetic progress achieved through plant selection. According to the maturation cycle of each clone, washed samples of cherry coffee were collected considering a completely randomized factorial design for characterization of the effects of genotypes, years, and the genotype × years (GY) interaction. The drying, peeling, and the outturn index were individually assessed. Despite the significant effects of the GY interaction, genotypes demonstrated minimal alterations in their ranking across measurements. Clones with higher outturn, including LB30, BRS1216, LB12, N7, LB10, LB20, BRS3220, and AS5, exhibited an average outturn of 25.51%, reflecting a gain of 12.17%. Conversely, clones with lower outturn, such as BG180, GJ30, GJ20, AS7, AS10, P42, N1, and P60, had an average of 19.15%, indicating a reduction of 14.02% compared to the general mean. Analyzing the distribution of the outturn values, 19.4%, 62.7%, and 17.9% of genotypes were classified as high, medium, and low outturn, respectively, providing valuable insights for optimal cultivation strategies.

Key words:
Conilon; Robusta; outturn index; plant selection; breeding

RESUMO:

Com o avanço da cafeicultura, múltiplas características devem ser consideradas na seleção de plantas, que devem apresentar um conjunto de atributos favoráveis. O rendimento, definido como a relação de massas entre os frutos maduros e os grãos processados, é um importante componente da produtividade. Este estudo tem como objetivo caracterizar o rendimento ao longo de duas colheitas de 57 clones comercializados em domínio público e 10 cultivares registradas. A análise considera efeitos de genótipos, medições e estimativas de ganhos com a seleção. De acordo com o ciclo de maturação de cada clone, amostras de café cereja foram colhidas considerando um delineamento fatorial inteiramente ao acaso para a caracterização dos efeitos de genótipos, anos e interação genótipo × anos (GA). A secagem, o descascamento e o rendimento foram avaliados individualmente. Apesar dos efeitos significativos da interação GA, os genótipos apresentaram pequenas mudanças no ordenamento de uma medição para a outra. Clones com maior rendimento, entre eles, LB30, BRS1216, LB12, N7, LB10, LB20, BRS3220 e AS5 apresentaram rendimento médio de 25,51% associado a estimativas de ganho de 12,17%. Por outro lado, clones de menor rendimento, como BG180, GJ30, GJ20, AS7, AS10, P42, N1 e P60 tiveram uma média de 19,15% associada a uma redução de 14,02%. A partir da distribuição dos valores, 19,4, 62,7 e 17,9% dos genótipos apresentaram rendimento classificados como alto, médio e baixo, subsidiando o melhor cultivo dos genótipos avaliados.

Palavras-chave:
Conilon; Robusta; rendimento; ganho de seleção; melhoramento

INTRODUCTION

For many years, coffee plants of the Coffea canephora species have borne the unfortunate stigma of being associated with lower-quality produce, resulting in depressed market prices (VIENCZ et al., 2023). Consequently, producers have often opted for cost-minimization strategies, historically contributing to the cultivation of coffee characterized by inferior quality and indistinct characteristics (OLIVEIRA & ARAÚJO, 2015OLIVEIRA, S. J. M.; ARAÚJO, L. V. Economic aspects of coffee cultivation. In MARCOLAN, A. L; ESPINDULA, M.C. (Eds.), Café na Amazônia. Brasília: EMBRAPA, 2015. p.27-37. Available from: <Available from: https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1023755/cafe-na-amazonia >. Accessed: Feb. 05, 2024.
https://www.embrapa.br/busca-de-publicac... ).

However with increased adaptability to tropical climates, the cultivation of this coffee species has undergone a transformative modernization process. This transformation has been facilitated by the adoption of advanced management practices and the cultivation of high-performance genetic materials (PARTELLI et al., 2021PARTELLI, F. L. et al. Proportion of ripe fruit weight and volume to green coffee: Differences in 43 genotypes of Coffea canephora. Agronomy Journal, v.113, n.2, p.1050-1057, 2021. Available from: <Available from: https://doi.org/10.1002/agj2.20617 >. Accessed: Nov. 04, 2023. doi: 10.1002/agj2.20617.
https://doi.org/10.1002/agj2.20617... ; FERRÃO et al., 2021FERRÃO, M. A. G. et al. Characterization and genetic diversity of Coffea canephora accessions in a germplasm bank in Espírito Santo, Brazil. Crop Breeding and Applied Biotechnology, v.21, n.2, 2021. Available from: <Available from: https://doi.org/10.1590/1984-70332021v21n2a32 >. Accessed: Oct. 30, 2023. doi: 10.1590/1984-70332021v21n2a32.
https://doi.org/10.1590/1984-70332021v21... ). The evolution of coffee farming in the Amazon region finds a noteworthy example in Rondônia, marked by a substantial reduction in cultivated area and a remarkable surge in productivity. Over the period from 2001 to 2023, there was a staggering 78% reduction in cultivated area (from 318,000 to 70,000 hectares) and an approximately fourfold increase in productivity (from 9.0 to 50.3 bags of processed coffee per hectare) (ESPINDULA et al., 2022ESPINDULA, M. C. et al. The Amazonian Robusta coffee plants cultivated in Rondônia. 1.ed. Brasília: Embrapa, 2022. 144p. Available from: <Available from: https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1152388/robustas-amazonicos-os-cafeeiros-cultivados-em-rondonia >. Accessed: Nov. 03, 2023.
https://www.embrapa.br/busca-de-publicac... ; CONAB, 2023CONAB - Companhia Nacional de Abastecimento. Acompanhamento da safra brasileira de café, v.10, n.1, Brasília: CONAB, 2023. 42p. Available from: <Available from: https://www.conab.gov.br/ >. Accessed: Nov. 10, 2023.
https://www.conab.gov.br/... ). This enhanced cultivation efficiency is intricately linked to the improved management of coffee plantations and the judicious selection of genetically superior materials.

Clones cultivated in the Western Amazon region are distinguished by their hybrid nature, arising from the cross-pollination of plants from the Conilon and Robusta botanical varieties (OLIVEIRA et al., 2018OLIVEIRA, L. N. L. et al. Selection of Coffea canephora parents from the botanical varieties Conilon and Robusta for the production of intervarietal hybrids. Ciência Rural, v.48, 2018. Available from: <Available from: https://doi.org/10.1590/0103-8478cr20170444 >. Accessed: Nov. 20, 2023. doi: 10.1590/0103-8478cr20170444.
https://doi.org/10.1590/0103-8478cr20170... ; ROCHA et al., 2015ROCHA, R. B. et al. Improvement of Coffea canephora - Considerations and Methodologies In: ALAERTO L. M.; ESPINDULA, M. C. (Org.). Café na Amazônia. 1ed. Brasília, DF: Embrapa, 2015, v.1, p.99-126. Available from <Available from https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1040710/melhoramento-de-coffea-canephora-consideracoes-e-metodologias >. Accessed: Oct. 29, 2023.
https://www.embrapa.br/busca-de-publicac... ). These botanical varieties exhibit complementary agronomic traits. The Conilon botanical variety, originating from regions near sea level in the African continent is characterized by its smaller stature, heightened susceptibility to pests and diseases, and greater resilience to water deficits (MONTAGNON et al., 2012MONTAGNON, C. et al. Amélioration génétique du caféier Coffea canephora Pierre: connaissances acquises, stratégies et perspectives. Cahiers Agricultures, v.21, p.143-153, 2012. Available from: <Available from: https://doi.org/10.1684/agr.2012.0556 >. Accessed: Nov. 14, 2023. doi: 10.1684/agr.2012.0556.
https://doi.org/10.1684/agr.2012.0556... ; BERTHAUD & CHARRIER, 1998BERTHAUD, J.; CHARRIER, A. Genetics resources of Coffea. In: CLARKE, R.J.; MACRAE, R. Coffee: Agronomy. London: Elsevier Applied Science, 1988. p.1-41. Available from: <Available from: https://horizon.documentation.ird.fr/exl-doc/pleins_textes/pleins_textes_7/b_fdi_53-54/010020483.pdf >. Accessed: Oct. 30, 2023.
https://horizon.documentation.ird.fr/exl... ). Similarly sourced from equatorial forest regions of Africa, the Robusta botanical variety presents complementary characteristics, including a larger stature, lower resistance to water deficits, and increased resilience to pests and diseases (MONTAGNON et al., 2003MONTAGNON, C. et al. Heritability of Coffea canephora yield estimated from several mating designs. Euphytica, v.133, p.209-218, 2003. Available from <Available from https://doi.org/10.1023/A:1025543805652 >. Accessed: Nov. 14, 2023. doi: 10.1023/A:1025543805652.
https://doi.org/10.1023/A:1025543805652... ). In Amazon region, Conilon botanical variety seeds were introduced by local coffee farmers, while Robusta botanical variety seeds from the Campinas Agronomic Institute (IAC) were disseminated by Embrapa (ESPINDULA et al., 2022ESPINDULA, M. C. et al. The Amazonian Robusta coffee plants cultivated in Rondônia. 1.ed. Brasília: Embrapa, 2022. 144p. Available from: <Available from: https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1152388/robustas-amazonicos-os-cafeeiros-cultivados-em-rondonia >. Accessed: Nov. 03, 2023.
https://www.embrapa.br/busca-de-publicac... ).

As coffee farming has modernized, additional facets of production have come under scrutiny (PARTELLI et al., 2022PARTELLI, F. L. et al. Adaptability and stability of Coffea canephora to dynamic environments using the Bayesian approach. Scientific Reports, v.12, n.1, 2022. Available form: <Available form: https://doi.org/10.1038/s41598-022-15190-x >. Accessed: Oct. 30, 2023. doi: 10.1038/s41598-022-15190-x.
https://doi.org/10.1038/s41598-022-15190... ; ALKIMIM et al., 2021ALKIMIM, E. R. et al. Designing the best breeding strategy for Coffea canephora: Genetic evaluation of pure and hybrid individuals aiming to select for productivity and disease resistance traits. PLoS One, v.16, e0260997, 2021. Available from: <Available from: https://doi.org/10.1371/journal.pone.0260997 >. Accessed: Dec. 04, 2023. doi: 10.1371/journal.pone.0260997.
https://doi.org/10.1371/journal.pone.026... ). A new cultivar must possess a variety of advantageous characteristics to be considered worthwhile (SPINELLI et al., 2018SPINELLI, V. M. et al. Contribution ofagronomic traits to the yield of Coffea canephora Pierre ex a. Froehner hulled coffee. Coffee Science, v.13, n.3, 2018. Available from: <Available from: https://doi.org/10.25186/cs.v13i3.1452 >. Accessed: Nov. 12, 2023. doi: 10.25186/cs.v13i3.1452.
https://doi.org/10.25186/cs.v13i3.1452... ). In this context the outturn index, which represents the relationship between the masses of harvested ripe fruits and processed beans, may emerge as a key determinant of productivity (FIALHO et al., 2022FIALHO, G. S. et al. Conilon coffee outturn index: a precise alternative for estimating grain yield. Acta Scientiarum. Agronomy , v.44, 2022. Available from <Available from https://doi.org/10.4025/actasciagron.v44i1.54249 >. Accessed: Nov. 12, 2023. doi: 10.4025/actasciagron.v44i1.54249.
https://doi.org/10.4025/actasciagron.v44... ). This fruit-to-bean ratio may significantly influence crop productivity, as genotypes with similar productive potential may exhibit substantial variations in fruit husk content and moisture content (LOURENÇO et al., 2022LOURENÇO, J. L. R. et al. Genotype × Environment Interaction in the Coffee Outturn Index of Amazonian Robusta Cultivars. Agronomy, v.12, n.11, 2022. Available from: <Available from: https://doi.org/10.3390/agronomy12112874 >. Accessed: Nov. 03, 2023. doi: 10.3390/agronomy12112874.
https://doi.org/10.3390/agronomy12112874... ; ROCHA et al., 2015ROCHA, R. B. et al. Improvement of Coffea canephora - Considerations and Methodologies In: ALAERTO L. M.; ESPINDULA, M. C. (Org.). Café na Amazônia. 1ed. Brasília, DF: Embrapa, 2015, v.1, p.99-126. Available from <Available from https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1040710/melhoramento-de-coffea-canephora-consideracoes-e-metodologias >. Accessed: Oct. 29, 2023.
https://www.embrapa.br/busca-de-publicac... ).

Two distinct stages are part of the processing of fruits: drying and hulling. In the first stage, during drying, the fruit loses most of its water allowing the identification of plants that retain lower water content in their fruits. In the subsequent hulling stage, the dried cherry fruit is pulped, and the study of weight reduction at this stage allows inference about the relationship between husk and beans content. Through these two stages, the mass ratio between harvested coffee and processed beans can be estimated.

In the literature, few studies have dedicated themselves to studying this characteristic. Intrinsic outturn considers only the mass reduction that occurs during hulling, disregarding the drying of the fruits. GASPARI-PEZZOPANE et al. (2004GASPARI-PEZZOPANE, C. et al. Genetic variability of intrinsic outturn in Coffea germplasm. Bragantia, v.63, p.39-54, 2004. Available from: <Available from: https://doi.org/10.1590/S0006-87052004000100005 >. Accessed: Feb. 05, 2024. doi: 10.1590/S0006-87052004000100005.
https://doi.org/10.1590/S0006-8705200400... ) and VACARELLI et al. (2003) VACCARELLI, V. N. et al. Relationship between outturn, empty fruits, and mocha type seeds in various Arabusta hybrids. Bioscience Journal, v.19, n.3, 2003. Available from: <Available from: https://seer.ufu.br/index.php/ biosciencejournal/article/view/6482 >. Accessed: Oct. 29, 2023.
https://seer.ufu.br/index.php/ bioscienc... evaluated the intrinsic outturn of 79 and 138 genotypes, respectively, observing variations of 48% to 62% in the weight retained after pulping. When evaluating diversity between different species, GASPARI-PEZZOPANE et al. (2004) MONTAGNON, C. et al. Heritability of Coffea canephora yield estimated from several mating designs. Euphytica, v.133, p.209-218, 2003. Available from <Available from https://doi.org/10.1023/A:1025543805652 >. Accessed: Nov. 14, 2023. doi: 10.1023/A:1025543805652.
https://doi.org/10.1023/A:1025543805652... observed a higher outturn in C. canephora coffee plants compared to Coffea arabica.

Considering the hulling and drying stages, PARTELLI et al. (2021PARTELLI, F. L. et al. Proportion of ripe fruit weight and volume to green coffee: Differences in 43 genotypes of Coffea canephora. Agronomy Journal, v.113, n.2, p.1050-1057, 2021. Available from: <Available from: https://doi.org/10.1002/agj2.20617 >. Accessed: Nov. 04, 2023. doi: 10.1002/agj2.20617.
https://doi.org/10.1002/agj2.20617... ) observed a range from 21.7% to 31.2% in the evaluation of 43 genotypes in the Nova Venécia-ES environment, categorizing them into four distinct clusters. Also, in the context of the drying and pulping stages, LOURENÇO et al. (2022LOURENÇO, J. L. R. et al. Genotype × Environment Interaction in the Coffee Outturn Index of Amazonian Robusta Cultivars. Agronomy, v.12, n.11, 2022. Available from: <Available from: https://doi.org/10.3390/agronomy12112874 >. Accessed: Nov. 03, 2023. doi: 10.3390/agronomy12112874.
https://doi.org/10.3390/agronomy12112874... ) scrutinized the outturn index of Amazonian Robusta cultivars. These researchers recorded average values of mass after drying and hulling of 46.12% and 53.01%, respectively, with an average outturn index of 24.4%. This study considered estimates of genetic parameters and experimental precision.

In light of this situation, the objective of this study is to comprehensively characterize the outturn index evaluated over time for registered cultivars and clones marketed in the public domain. This investigation takes into account the nuanced effects of genotypes, measurements, and the genetic progress achieved through the cultivation of selected genotypes.

MATERIALS AND METHODS

In January 2019, a clonal competition trial was set up in the experimental field of the Empresa Brasileira de Pesquisa Agropecuária (Embrapa) at 8^o48’05.5’’ S and 63^o51´02.7’’ W at 88 m above sea level. The predominant climate in the region is tropical rainy with a dry winter, type “Am” (Köppen), with a mean temperature of 26.0 ^oC and mean annual rainfall of 2095 mm. September is the hottest month of the year (27.1 ^oC) and May is the coldest month (24.9 ^oC) (ALVARES et al., 2013ALVARES, C. A. et al. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, v.22, n.6, p.711-728, 2013. Available from: <Available from: https://www.schweizerbart.de/papers/metz/detail/22/82078/Koppen_s_climate_classification_map_for_Brazil?af=crossref >. Accessed: Nov. 01, 2023.
https://www.schweizerbart.de/papers/metz... ). Crop treatments were carried out according to ESPINDULA et al. (2022ESPINDULA, M. C. et al. The Amazonian Robusta coffee plants cultivated in Rondônia. 1.ed. Brasília: Embrapa, 2022. 144p. Available from: <Available from: https://www.embrapa.br/busca-de-publicacoes/-/publicacao/1152388/robustas-amazonicos-os-cafeeiros-cultivados-em-rondonia >. Accessed: Nov. 03, 2023.
https://www.embrapa.br/busca-de-publicac... ). During the period of flowering, bean formation, and maturation of the fruit, climate data were recorded in Ambient Weather WS2902 smart weather stations. The climate data and soil chemical properties are showed elsewhere (LOURENÇO et al., 2022LOURENÇO, J. L. R. et al. Genotype × Environment Interaction in the Coffee Outturn Index of Amazonian Robusta Cultivars. Agronomy, v.12, n.11, 2022. Available from: <Available from: https://doi.org/10.3390/agronomy12112874 >. Accessed: Nov. 03, 2023. doi: 10.3390/agronomy12112874.
https://doi.org/10.3390/agronomy12112874... ).

The experiment extended over 36 months to consider both genotype and year effects, also known as measurements. To evaluate the impact of genotypes and measurements, as well as the interaction between these factors, a fully randomized experimental design with six replications was employed. In this study, 67 genotypes were assessed (Table 1), including registered cultivars (10) and clones marketed in the public domain, widely cultivated in the Amazon region (57). These cultivars, bearing the ‘BRS’ prefix, are categorized into three distinct compatibility groups and exhibit diverse maturation cycles, including early, intermediate, and late maturation stages (ROCHA et al., 2021ROCHA, R. B. et al. Coffea canephora breeding: estimated and achieved gains from selection in the Western Amazon, Brazil. Ciência Rural, v.51, n.5, 2021. Available from: <Available from: https://doi.org/10.1590/0103-8478cr20200713 >. Accessed: Nov. 09, 2023. doi: 10.1590/0103-8478cr20200713.
https://doi.org/10.1590/0103-8478cr20200... ; TEIXEIRA et al., 2020TEIXEIRA, A. L. et al. Amazonian Robustas - new Coffea canephora coffee cultivars for the Western Brazilian Amazon. Crop Breeding and Applied Biotechnology, v.20, 2020. Available from: <Available from: doi.org/10.1590/1984-70332020v20n3c53 >. Accessed: Nov. 03, 2023. doi: 10.1590/1984-70332020v20n3c53.
doi.org/10.1590/1984-70332020v20n3c53... ).

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Table 1
Identification of 67 genotypes studied based on their cultivation status and origin: whether they are cultivars or commercially available in the public domain. Mass ratios between ripe cherry fruits and processed grains were assessed in two harvests over 36 months, taking into account the stages of drying and peeling. The study was conducted at the Embrapa Rondônia experimental field in Porto Velho, RO.

Considering the maturation cycle of each genotype, harvesting occurred when approximately 80% of the fruits reached the red-cherry stage. Unique samples of washed cherry coffee were collected for each clone and naturally sun-dried on elevated drying beds for 10 to 15 days until achieving a moisture content of around 12%. Moisture content was assessed using a Gehaka (G600) grain moisture meter. Subsequently, 250 g samples of dry cherry coffee underwent processing with a manual coffee pulping machine, followed by separation using a set of sieves. Outturn index estimates were computed based on the reduction in weight observed during drying and pulping, adjusted to 12% moisture. The estimates for the outturn index were derived using the subsequent expression:

$O u t t u r n i n d e x = (\frac{m_{d r y c h e r r y}}{m_{f r o m f i e l d}}) . (\frac{m_{b e a n s}}{m_{b e a n s} + m_{h u l l}}) . F_{m o i s t 12 %}$ (1)

where Outturn index was estimated by the relation between the mass of the dry cherry coffee (^m dry cherry) and the mass of the coffee from the field (^m from field ), together with the relation between the mass of the coffee beans (^m beans) and the mass of the dried fruits (^m beans + ^m hull), corrected to 12% moisture (^F moist12%).

The significance of the clone effects and the homogeneity of residual variances was verified before the combined analysis to quantify the GY interaction effect, according to the following model described by CRUZ et al. (2013CRUZ, C. D. Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, v.35, n.3, p.271-276, 2013. Available from: <Available from: https://doi.org/10.4025/actasciagron.v35i3.21251 >. Accessed: Oct. 27, 2023. doi: 10.4025/actasciagron.v35i3.21251.
https://doi.org/10.4025/actasciagron.v35... ).

$Y_{i j k} = m + G_{i} + Y_{j} + G Y_{i j} + e_{i j k}$ (2)

where Y _ijk refers to the observation of the i^th genotype in the j^th measurement, m is the experimental average, G _i is the effect of the i^th genotype, E _j is the effect of the j^th measurement, GY _ij is the effect of the interaction between the i^th genotype and the j^th measurement, and e_ijk is the experimental error.

From the estimates of the mean square expected values, repeatability was estimated as follows (CRUZ et al., 2021CRUZ, C. D. et al. Biometry in plant breeding. Crop Breeding and Applied Biotechnology, v.21, 2021. Available from: <Available from: https://www.scielo.br/j/cbab/a/9vf7YzzQynVdD77NrJHzvSs/?format=pdf >. Accessed: Nov. 08, 2023. doi: 10.1590/1984-70332021v21Sa188.
https://www.scielo.br/j/cbab/a/9vf7YzzQy... ):

$r = \frac{C \hat{O} V (Y_{i j} Y_{i j ´})}{\sqrt{\hat{V} (Y_{i j}) \hat{V} (Y_{i j ´})}} = \frac{σ_{p}^{2}}{σ_{p}^{2} + σ_{e t}^{2}}$ (3)

where: r is the repeatability coefficient; σ ² _p is the genotypic variance combined with the variance of permanent environmental effects; σ ² _et is the temporary environmental variance associated with experimental error.

Estimates of the experimental coefficient of variation and the genetic coefficient of variation were utilized to assess the precision of the experiments. The performance of the clones was evaluated through scatter plots and correlation estimates between the initial and subsequent measurements. Genotypes were then classified based on their performance using the Scott-Knott test, with a significance level of 5%.

Genotypic values served as the basis for quantifying the selection gain (SG) in the first and second measurements, as well as the average gain over time. Estimates of SG took into account the selection differential and the repeatability coefficient within all measurements. All statistical analyses were performed using the software GENES (CRUZ et al., 2013CRUZ, C. D. Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, v.35, n.3, p.271-276, 2013. Available from: <Available from: https://doi.org/10.4025/actasciagron.v35i3.21251 >. Accessed: Oct. 27, 2023. doi: 10.4025/actasciagron.v35i3.21251.
https://doi.org/10.4025/actasciagron.v35... ) and Selegen (RESENDE, 2016RESENDE, M. D. V. Software Selegen-REML/BLUP: a useful tool for plant breeding. Crop Breeding and Applied Biotechnology, v.16, n.4, p.330-339, 2016. Available from: <Available from: https://doi.org/10.1590/1984-70332016v16n4a49 >. Accessed: Oct. 15, 2023. doi: 10.1590/1984-70332016v16n4a49.
https://doi.org/10.1590/1984-70332016v16... ).

RESULTS

The stages of drying and peeling were individually analyzed in this study. Significant effects of genotypes, years, and the genotype x years interaction (GY) were observed for all processing traits (Table 2). The notable effect of the GY interaction indicates the presence of clones that exhibited changes in their performance between measurements. This interaction could lean towards a complex type, where changes in performance result in shifts in the ranking of clones, or a simpler type, where changes lead to minor shifts in clone rankings from one measurement to another.

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Table 2
Summary of the analysis of variance and genetic parameter estimates for drying, peeling, and outturn of mature fruits to processed grains for 10 cultivars and 57 clones cultivated in public domain, assessed in two measurements: 1^st (2021-2022) and 2^nd (2022-2023). Embrapa, Porto Velho - RO, Brazil.

The estimates of the coefficient of experimental variation (CVe) were 1.37 for drying, 2.06 for peeling, and 2.46 for the outturn (Table 2). These low estimates suggested high precision in evaluating these processing traits. Beyond precision was observed a predominant genotypic variance, with repeatability (r) estimates of 86.4, 92.05, and 92.83 for drying, peeling, and outurn, respectively (Table 2). This high repeatability suggested that drying was more influenced by environmental effects than peeling (Table 2). Estimates of the ratio between genetic and experimental coefficients of variation (CVg/CVe) greater than one indicate favorable conditions for achieving gains through plant selection.

To interpret clone performance over time, mass levels maintained after drying and peeling were assessed at each measurement (Figures 1 and 2). Despite significant effects of the GY interaction, we observed a positive and high-magnitude association between the two measurements (Figures 1 and 2). This aligns with the observed high repeatability estimates and a simple type of GY interaction, where changes in clone performance between measurements are less tied to shifts in clone rankings. The means of the first and second measurements showed no significant differences according to the Scott Knott test at a 5% probability level (Table 2).

Figure 1
Dispersion of retained mass after drying (A) and retained mass after peeling (B) for 10 cultivars and 57 clones cultivated in public domain in Western Amazon, assessed in two measurements: 1^st (2021-2022) and 2^nd (2022-2023), at the Embrapa experimental field located in Porto Velho - RO municipality.

Figure 2
Dispersion of the outturn index for 10 cultivars and 57 clones cultivated in public domain evaluated in two assessments: 1^st (2021-2022) and 2^nd (2022-2023) at the Embrapa experimental field located in Porto Velho - RO municipality.

Mass dispersion values suggested that the majority of the mass was lost during the drying stage, resulting in an average retention of 42.37% of the original mass (Figure 3). Smaller amplitude was observed in this stage (9.5%), compared to larger amplitudes in peeling (19.45%). In turn, the outturn showed an amplitude of 10.74%, quantifying the difference in processed bean production between the clone with the highest and lowest performance (LB30 and BG180). Contrasts among clones are interpreted as follows to derive selection gain estimates, mitigating the impact of environmental and measurement errors on the traits.

Figure 3
Dispersion of the retained mass after drying, peeling and the outturn index for 10 cultivars and 57 clones cultivated in public domain in Western Amazon, evaluated over two years (2021-2022; 2022-2023) at the Embrapa experimental field located in the municipality of Porto Velho - RO. The boxplot on the left illustrates the positions of the minimum, maximum, median values, and the 1^st and 3^rd quartiles.

Average performance of each genotype was interpreted using the Scott Knott mean grouping test, creating mutually exclusive groups ordered from the best-performing clone. Low estimates of experimental error resulted in grouping genotypes into 12 different average groups for the outturn index (Table 3). LB30 showed the highest outturn and grouped separately from other genotypes. BRS1216 and LB12 grouped in the second-best outturn group, followed by genotypes N7, LB10, LB20, BRS3220, AS5, LB88, GJ25, and SK80 in the third group of higher outurn (Table 3). Groups formed by genotypes WP6, GJ5, AS2, SK244, P60, N1, P42, followed by clones AS10, AS7, GJ20, and GJ30, BG180 correspond to lower-outturn genotypes observed in this study.

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Table 3
Performance in terms of drying (Stage 1), peeling (Stage 2), and outturn from ripe fruits to processed grains for 10 cultivars and 57 clones cultivated in public domain in Western Amazon, assessed over two years (2021-2022) (2022-2023) at the Embrapa experimental field located in the municipality of Porto Velho - RO.

LB30, LB88, LB12, BRS1216, GJ25 presented the highest masses after peeling, while GJ8, LB07, BRS3137, GB7, CA1 presented higher masses after drying. Clones with higher masses after peeling showed greater alignment with clones with higher outturn. Higher genotypic effects emphasize the importance of genotype effects in expressing husk levels. While the drying (1) and peeling (2) stages showed a weak association (r_1x2=0.03^NS), the correlation estimates between these stages and outturn (3) were significant and of high magnitude (r_1x3=0.60^**, r_2x3=0.78^**).

To estimate gains with selection, progress estimates with the cultivation of eight genotypes with the highest and lowest performance were considered (Table 4). The new average of clones selected for higher outturn (LB30, BRS1216, LB12, N7, LB10, LB20, BRS3220, AS5) was 25.51%, associated with a selection gain of 12.17% (Table 4). In turn, the cultivation of clones with lower outturn (BG180, GJ30, GJ20, AS7, AS10, P42, N1, and P60) is associated with an average of 19.15%, representing a reduction of 14.02% compared to the average of all evaluated clones.

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Table 4
Estimates of gain through selection for outturn from ripe fruits to processed grains, involving the selection of eight genotypes with the highest outturn and eight genotypes with the lowest outturn, characterized over two years (2021-2022) (2022-2023) at the Embrapa experimental field in the municipality of Porto Velho - RO.

The first quartile referring to the top 25% of clones showed an amplitude from 23.72 to 27.92. The second and third quartiles, covering 50% of the evaluated clones, ranged from 21.55 to 23.72. Finally, the lowest 25% of clones in terms of outturn are found in the range of 17.18 to 21.55. Based on the distribution of values, clones were classified according to their performance (Table 5).

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Table 5
Ranking of the outturn for 10 cultivars and 57 clones cultivated in public domain in Western Amazon, evaluated in two measurements: 1^st (2021-2022) and 2^nd (2022-2023), at the Embrapa experimental field located in the municipality of Porto Velho - RO.

DISCUSSION

Cultivated across the global tropical belt, encompassing many developing nations, C. canephora coffee farming has witnessed significant transformations in the past decade (FERRÃO et al., 2017FERRÃO, R. G. et al. Genetic improvement of Coffea canephora. In FERRÃO, R. G. et al. (Eds). Café conilon. Espirito Santo: Incaper, 2017. p.120-173. Available from: <Available from: https://biblioteca.incaper.es.gov.br/digital/bitstream/123456789/3514/1/book-conilon-coffee-3rd-edition-2019-Incaper.pdf >. Accessed: Nov. 12, 2023.
https://biblioteca.incaper.es.gov.br/dig... ). Enhancements in cultivation efficiency, stemming from improved management practices and plant breeding, have led to the consideration of several traits in plant selection. New cultivars are now expected to exhibit a range of favorable characteristics.

This study addressed an important yet underexplored facet of productivity. Cultivated for bean production, the dry husk of coffee fruits once discarded in the past, is a significant source of nutrients and organic matter that returns to the field in the best production systems. However, during fruit processing, it is desirable for fruits to possess lower husk content, resulting in a higher mass of beans post-drying and husking.

The findings underscore the dual influence of genetics and the environment on moisture, husk, and bean content. While genetic variability plays a crucial role in drying, husking exhibits greater genetic determination, reflecting the unique husk levels associated with each genotype. In examining the outturn expression across different environments, LOURENÇO et al. (2022LOURENÇO, J. L. R. et al. Genotype × Environment Interaction in the Coffee Outturn Index of Amazonian Robusta Cultivars. Agronomy, v.12, n.11, 2022. Available from: <Available from: https://doi.org/10.3390/agronomy12112874 >. Accessed: Nov. 03, 2023. doi: 10.3390/agronomy12112874.
https://doi.org/10.3390/agronomy12112874... ) observed that fruits from irrigated trials experienced a more pronounced mass reduction after drying due to higher water content.

Estimates of genetic parameters and experimental error contribute to a nuanced understanding of the genetic variability. Unlike previous literature, this study considers the evaluation of outturn over time. Measurements taken in the 2021-2022 and 2022-2023 harvests reveal that while some clones showed performance fluctuations from one year to another, this did not significantly alter the ranking of clones between harvests. The consistent ranking reflects predominantly genotypic effects, supporting the case for selecting superior clones.

Despite their intensive cultivation, the clones trade in public domain are unknown in many aspects. A 10% contrast, as observed between higher and lower-performing clones, translates to a 10% reduction in final productivity in a plantation, simply due to the different in the outturn index.

Among the top eight high outturn clones are two cultivars developed by Embrapa, BRS1216 and BRS3220, and six clones traded in public domain: LB30, LB12, LB10, LB20, N7, and AS5. Registered cultivars have undergone evaluations in diverse environments over several years and exhibit known behaviors (TEIXEIRA et al., 2020TEIXEIRA, A. L. et al. Amazonian Robustas - new Coffea canephora coffee cultivars for the Western Brazilian Amazon. Crop Breeding and Applied Biotechnology, v.20, 2020. Available from: <Available from: doi.org/10.1590/1984-70332020v20n3c53 >. Accessed: Nov. 03, 2023. doi: 10.1590/1984-70332020v20n3c53.
doi.org/10.1590/1984-70332020v20n3c53... ). For instance, BRS1216 is characterized by high productivity, rigid stems, intermediate maturation cycle, resistance to nematodes and rust, full-bodied flavor, and falls under compatibility group I. Conversely, BRS3220 features flexible stems, intermediate maturation cycle, nematode susceptibility, rust resistance, full-bodied flavor, and belongs to compatibility group III (ROCHA et al., 2021ROCHA, R. B. et al. Coffea canephora breeding: estimated and achieved gains from selection in the Western Amazon, Brazil. Ciência Rural, v.51, n.5, 2021. Available from: <Available from: https://doi.org/10.1590/0103-8478cr20200713 >. Accessed: Nov. 09, 2023. doi: 10.1590/0103-8478cr20200713.
https://doi.org/10.1590/0103-8478cr20200... ). LOURENÇO et al. (2022LOURENÇO, J. L. R. et al. Genotype × Environment Interaction in the Coffee Outturn Index of Amazonian Robusta Cultivars. Agronomy, v.12, n.11, 2022. Available from: <Available from: https://doi.org/10.3390/agronomy12112874 >. Accessed: Nov. 03, 2023. doi: 10.3390/agronomy12112874.
https://doi.org/10.3390/agronomy12112874... ) also noted the superior outturn of these cultivars across different environments.

The evaluation of control plants with known behavior enhances the interpretation of the studied clones’ performance. For the evaluated population, outturn values between 24% and 28% are considered high.

One of the first outturn assessments conducted by GASPARI-PEZZOPANE et al. (2004GASPARI-PEZZOPANE, C. et al. Genetic variability of intrinsic outturn in Coffea germplasm. Bragantia, v.63, p.39-54, 2004. Available from: <Available from: https://doi.org/10.1590/S0006-87052004000100005 >. Accessed: Feb. 05, 2024. doi: 10.1590/S0006-87052004000100005.
https://doi.org/10.1590/S0006-8705200400... ) studying accessions from the Germplasm Bank at the Agronomic Institute of Campinas, revealed that the Robusta botanical variety had slightly lower outturn than the Conilon botanical variety. PARTELLI et al. (2021PARTELLI, F. L. et al. Proportion of ripe fruit weight and volume to green coffee: Differences in 43 genotypes of Coffea canephora. Agronomy Journal, v.113, n.2, p.1050-1057, 2021. Available from: <Available from: https://doi.org/10.1002/agj2.20617 >. Accessed: Nov. 04, 2023. doi: 10.1002/agj2.20617.
https://doi.org/10.1002/agj2.20617... ), without discriminating between drying and husking stages, noted outturn values higher than those observed in this study, in a breeding population with a higher frequency of Conilon plants.

Among the lower outturn genotypes are clones traded in public domain: BG180, GJ30, GJ20, AS7, AS10, P42, N1, and P60. Cultivating these clones together results in reduced population performance. The primary distinction in this set lies in their lower bean mass after husking. These clones retained 40.12% of mass after drying compared to the average of 42.37%, and 47.76% of mass after husking compared to the average of 53.04%.

While mass reduction during drying is associated with water loss from husk, mucilage, and beans until reaching an ideal moisture content of 12%, mass reduction during husking is linked to the separation of husk and beans. Mass retained after husking proves more critical in determining the outturn and is less influenced by the environment, making it pivotal for selecting clones with a favorable set of characteristics.

Despite their intensive cultivation, clones traded in public domain remain unknown in many aspects, and characterizing them is vital for their optimal cultivation and the sustainability of coffee production. The results of this study contributed to a deeper understanding of the genetic variability of this important component influencing productivity and quality.

CONCLUSION

This study addressesed a crucial yet underexplored component of productivity. The results demonstrate that moisture, husk, and bean content levels are influenced by both plant genetics and the environment. While genetic variability is significant for both drying and husking, husking exhibits greater genetic determination due to the distinctive husk levels of each genotype. Minor shifts in the ranking of clones between measurements, along with high estimates of genetic parameters contribute to a better understanding of this variability. The selected high outturn clones-LB30, BRS1216, LB12, N7, LB10, LB20, BRS3220, AS5-showed an average outturn of 25.51%, representing a gain of 12.17%. In contrast, the clones of lower performance-BG180, GJ30, GJ20, AS7, AS10, P42, N1, P60-averaged 19.15%, indicating a reduction of 14.02%. Based on the distribution of outturn values, genotypes were classified according to their performance, providing valuable insights for the optimal use of cultivated clones.

ACKNOWLEDGMENTS

The authors thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for the scholarship granted, and the Secretaria Estadual de Desenvolvimento Econômico, government of the state of Rondônia and Consórcio Pesquisa Café for funding.

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CR-2024-0056.R1

Edited by

Editors: Alessandro Lucio (0000-0003-0761-4200)

Fábio Luiz Partelli (0000-0002-8830-0846)

Publication Dates

Publication in this collection
26 Aug 2024
Date of issue
2025

History

Received
05 Feb 2024
Accepted
27 May 2024
Reviewed
21 July 2024

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

[1] AKPERTEY, A. et al. Genetic variability for vigor and yield of robusta coffee (Coffea canephora) clones in Ghana. Heliyon, v.8, e10192, 2022. Available from: <Available from: https://doi.org/10.1016/j.heliyon.2022.e10192 >. Accessed: Nov. 03, 2023. doi: 10.1016/j.heliyon.2022.e10192.
» https://doi.org/10.1016/j.heliyon.2022.e10192.» https://doi.org/10.1016/j.heliyon.2022.e10192

[2] ALVARES, C. A. et al. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, v.22, n.6, p.711-728, 2013. Available from: <Available from: https://www.schweizerbart.de/papers/metz/detail/22/82078/Koppen_s_climate_classification_map_for_Brazil?af=crossref >. Accessed: Nov. 01, 2023.
» https://www.schweizerbart.de/papers/metz/detail/22/82078/Koppen_s_climate_classification_map_for_Brazil?af=crossref

[3] ALKIMIM, E. R. et al. Designing the best breeding strategy for Coffea canephora: Genetic evaluation of pure and hybrid individuals aiming to select for productivity and disease resistance traits. PLoS One, v.16, e0260997, 2021. Available from: <Available from: https://doi.org/10.1371/journal.pone.0260997 >. Accessed: Dec. 04, 2023. doi: 10.1371/journal.pone.0260997.
» https://doi.org/10.1371/journal.pone.0260997.» https://doi.org/10.1371/journal.pone.0260997

[4] BERTHAUD, J.; CHARRIER, A. Genetics resources of Coffea In: CLARKE, R.J.; MACRAE, R. Coffee: Agronomy. London: Elsevier Applied Science, 1988. p.1-41. Available from: <Available from: https://horizon.documentation.ird.fr/exl-doc/pleins_textes/pleins_textes_7/b_fdi_53-54/010020483.pdf >. Accessed: Oct. 30, 2023.
» https://horizon.documentation.ird.fr/exl-doc/pleins_textes/pleins_textes_7/b_fdi_53-54/010020483.pdf

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[19] PARTELLI, F. L. et al. Proportion of ripe fruit weight and volume to green coffee: Differences in 43 genotypes of Coffea canephora Agronomy Journal, v.113, n.2, p.1050-1057, 2021. Available from: <Available from: https://doi.org/10.1002/agj2.20617 >. Accessed: Nov. 04, 2023. doi: 10.1002/agj2.20617.
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n	Genotype	Cultivation status	Origin	n	Genotype	Cultivation status	Origin
1	BRS1216	Cultivar	Embrapa¹	35	LB10	Public Domain	Laerte Braun¹¹
2	BRS2299	Cultivar	Embrapa²	36	LB102	Public Domain	Laerte Braun¹¹
3	BRS2314	Cultivar	Embrapa³	37	LB110	Public Domain	Laerte Braun¹¹
4	BRS2336	Cultivar	Embrapa⁴	38	LB12	Public Domain	Laerte Braun¹¹
5	BRS2357	Cultivar	Embrapa⁵	39	LB15	Public Domain	Laerte Braun¹¹
6	BRS3137	Cultivar	Embrapa⁶	40	LB160	Public Domain	Laerte Braun¹¹
7	BRS3193	Cultivar	Embrapa⁷	41	LB20	Public Domain	Laerte Braun¹¹
8	BRS3210	Cultivar	Embrapa⁸	42	LB22	Public Domain	Laerte Braun¹¹
9	BRS3213	Cultivar	Embrapa⁹	43	LB30	Public Domain	Laerte Braun¹¹
10	BRS3220	Cultivar	Embrapa¹⁰	44	LB33	Public Domain	Laerte Braun¹¹
11	AR106	Public Domain	Aldnei Raasch¹¹	45	LB68	Public Domain	Laerte Braun¹¹
12	AS1	Public Domain	Ademar Schmidt¹¹	46	LB80	Public Domain	Laerte Braun¹¹
13	AS10	Public Domain	Ademar Schmidt¹¹	47	LB88	Public Domain	Laerte Braun¹¹
14	AS12	Public Domain	Ademar Schmidt¹¹	48	N1	Public Domain	Nivaldo Ferreira¹¹
15	AS2	Public Domain	Ademar Schmidt¹¹	49	N11	Public Domain	Nivaldo Ferreira¹¹
16	AS3	Public Domain	Ademar Schmidt¹¹	50	N12	Public Domain	Nivaldo Ferreira¹¹
17	AS5	Public Domain	Ademar Schmidt¹¹	51	N13	Public Domain	Nivaldo Ferreira¹¹
18	AS6	Public Domain	Ademar Schmidt¹¹	52	N16	Public Domain	Nivaldo Ferreira¹¹
19	AS7	Public Domain	Ademar Schmidt¹¹	53	N17	Public Domain	Nivaldo Ferreira¹¹
20	BG180	Public Domain	Ronildo Berger¹¹	54	N2	Public Domain	Nivaldo Ferreira¹¹
21	CA1	Public Domain	Carlos Silva¹¹	55	N32	Public Domain	Nivaldo Ferreira¹¹
22	GB1	Public Domain	Gilberto Boone¹¹	56	N7	Public Domain	Nivaldo Ferreira¹¹
23	GB4	Public Domain	Gilberto Boone¹¹	57	N8(G8)	Public Domain	Nivaldo Ferreira¹¹
24	GB7	Public Domain	Gilberto Boone¹¹	58	P42	Public Domain	Wanderly Bernabé¹¹
25	GJ1	Public Domain	Geraldo Jacomin¹¹	59	P50	Public Domain	Valdecir Piske¹¹
26	GJ20	Public Domain	Geraldo Jacomin¹¹	60	P60	Public Domain	Laerte Braun¹¹
27	GJ21	Public Domain	Geraldo Jacomin¹¹	61	R152	Public Domain	Ronaldo Guedes¹¹
28	GJ25	Public Domain	Geraldo Jacomin¹¹	62	R22	Public Domain	Ronaldo Vitoriano¹¹
29	GJ3	Public Domain	Geraldo Jacomin¹¹	63	SK244	Public Domain	Sergio Kalk¹¹
30	GJ30	Public Domain	Geraldo Jacomin¹¹	64	SK41	Public Domain	Sergio Kalk¹¹
31	GJ5	Public Domain	Geraldo Jacomin¹¹	65	SK80	Public Domain	Sergio Kalk¹¹
32	GJ8	Public Domain	Geraldo Jacomin¹¹	66	VP156	Public Domain	Valdecir Piske¹¹
33	L1	Public Domain	Alcides Rosa¹¹	67	WP6	Public Domain	Vanderley Peter¹¹
34	LB7	Public Domain	Laerte Braun¹¹

SV	DF	Drying	Peeling	Outturn
Genotypes (G)	66	7.35^**	12.58^**	13.94^**
Years (Y)	1	329.67^**	6.36^**	157.50^**
GY	66	11.97^**	5.34^**	5.17^**
Residual	268
Total	401
Mean		42.37	53.03	22.67
Mean 1^o year		43.07a	53.15a	22.90a
Mean 2^o year		42.01a	52.87a	22.20a
CVe		1.37	2.06	2.46
R		86.4	92.05	92.83
CVg		4.89	6.64	8.24
CVg/Cve		3.56	3.21	3.34

Genotypes	Stage1	Stage2	Outturn	Genotypes	Stage1	Stage2	Outturn
AR106	41.78i	50.88h	21.25h	LB10	45.72d	54.72e	25.03c
AS1	40.20k	52.50g	21.10h	LB102	42.38h	51.15h	21.70g
AS10	38.73m	50.45h	19.55j	LB110	40.68j	52.75g	21.45g
AS12	39.40l	55.38e	21.80g	LB12	43.68g	58.71c	25.60b
AS2	40.88j	50.53h	20.65i	LB15	41.80i	57.27d	23.97d
AS3	40.35k	55.42e	22.37f	LB160	44.32f	51.12h	22.67e
AS5	45.07e	54.63e	24.65c	LB20	44.75e	55.80e	24.98c
AS6	40.13k	54.08f	21.70g	LB22	41.85i	56.87d	23.82d
AS7	39.01l	49.88i	19.45j	LB30	44.85e	62.20a	27.92a
BG180	39.73k	43.28k	17.18l	LB33	42.00i	55.57e	23.30e
BRS1216	44.23f	58.70c	25.96b	LB68	42.50h	51.60g	21.93g
BRS2299	43.47g	54.25f	23.58d	LB80	43.38g	50.60h	21.97g
BRS2314	44.02g	49.20i	21.65g	LB88	40.73j	60.43b	24.62c
BRS2336	42.27h	52.75g	22.27f	N1	39.90k	51.43g	20.50i
BRS2357	41.38i	56.55d	23.42d	N11	45.02e	53.35f	24.02d
BRS3137	47.05b	49.82i	23.45d	N12	40.75j	53.13f	21.67g
BRS3193	43.93g	53.07f	23.33e	N13	41.78i	54.68e	22.83e
BRS3210	43.70g	52.55g	22.97e	N16	42.73h	53.03f	22.67e
BRS3213	40.10k	55.75e	22.37f	N17	42.73h	55.97e	23.93d
BRS3220	44.30f	55.75e	24.73c	N2	42.37h	50.33h	21.30h
CA1	46.48c	47.60j	22.13f	N32	45.58d	47.78j	21.78g
GB1	45.20e	51.13h	23.10e	N7	44.25f	56.97d	25.20c
GB4	42.15h	55.53e	23.43d	N8(G8)	40.98i	55.47e	22.73e
GB7	46.55c	50.92h	23.72d	P42	41.61i	48.53j	20.21i
GJ1	41.47i	53.00f	21.97g	P50	40.25k	57.38d	23.10e
GJ20	39.30l	46.65j	18.31k	P60	41.78i	49.08i	20.50i
GJ21	40.52j	52.08g	21.10h	R152	43.30g	53.55f	23.23e
GJ25	41.95i	58.63c	24.60c	R22	43.77g	52.62g	23.02e
GJ3	43.55g	54.37f	23.68d	SK244	43.00g	47.93j	20.63i
GJ30	40.86j	42.75k	17.46l	SK41	43.30g	55.88e	24.18d
GJ5	38.38m	53.98f	20.73i	SK80	44.50f	55.08e	24.52c
GJ8	47.88a	49.53i	23.72d	VP156	38.76m	56.67d	21.92g
L1	43.27g	51.83g	22.40f	WP6	41.27i	50.46h	20.80i
LB07	47.17b	50.23h	23.70d

----------------------------------------------Gain from the selection of the 8 clones with the highest outturn-------------------------------------------
Measure	Mo	Ms	SD	r	SG	SG%
1^o year	22.90	26.23	3.33	0.98	3.26	14.21
2^o year	22.20	25.02	2.57	0.97	2.50	11.28
Mean	22.55	25.51	2.96	0.93	2.74	12.17
Genotypes	1^oStage	2^oStage	Outturn
LB30	44.85	62.2	27.92
BRS1216	44.23	58.7	25.96
LB12	43.68	58.71	25.6
N7	44.25	56.97	25.2
LB10	45.72	54.72	25.03
LB20	44.75	55.8	24.98
BRS3220	44.3	55.75	24.73
AS5	45.07	54.63	24.65
----------------------------------------------Gain from the selection of the 8 clones with the lower outturn--------------------------------------------
Measure	Mo	Ms	SD	r	SG	SG%
1^o year	22.90	19.02	-3.87	0.98	-3.78	-16.51
2^o year	22.20	19.15	-2.94	0.97	-2.85	-12.87
Mean	22.55	19.15	-3.41	0.93	-3.16	-14.02
Genótipos	1^oStage	2^oStage	Outturn
BG180	39.73	43.28	17.18
GJ30	40.86	42.75	17.46
GJ20	39.3	46.65	18.31
AS7	39.01	49.88	19.45
AS10	38.73	50.45	19.55
P42	41.61	48.53	20.21
N1	39.9	51.43	20.5
P60	41.78	49.08	20.5

Class	Outturn	Genotypes
High	>26	LB30
	25 ├ 26	BRS1216, LB12, N7, LB10
	24 ├ 25	LB20, BRS3220, AS5, LB88, GJ25, SK80, SK41, N11
Medium	23 ├ 24	LB15, N17, LB22, GB7, GJ8, LB07, GJ3, BRS2299, BRS3137, GB4, BRS2357, BRS3193, LB33, R152, GB1, P50, R22
	22 ├ 23	BRS3210, N13, N8(G8), LB160, N16, L1, AS3, BRS3213, BRS2336, CA1
	21 ├ 22	GJ1, LB80, LB68, VP156, AS12, N32, AS6, LB102, N12, BRS2314, LB110, N2, AR106, AS1, GJ21
Low	20 ├ 21	WP6, GJ5, AS2, SK244, N1, P60, P42
Low	17 ├ 20	AS10, AS7, GJ20, GJ30, BG180

Brasil

Brasil

Unraveling the genetic diversity of coffee processing traits in Coffea canephora

Diversidade genética das características de processamento do café em Coffea canephora

ABSTRACT:

RESUMO:

INTRODUCTION

MATERIALS AND METHODS

RESULTS

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Edited by

Publication Dates

History