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Conselho dos Exportadores de Café do Brasil (CECAFE). 2021. Exportação anual 2021. www.cecafe.com.br/dados-estatisticos/exportacoes-brasileiras/

Secretaria de Estado de Agricultura, Pecuária e Abastecimento (SEAPA). 2021. Indicadores do café de Minas Gerais, do Brasil e do Mundo, Junho de 2021. www.reformaagraria.mg.gov.br/images/documentos/perfil_caf%C3%A9_junho_2021[1].pdf

Marie L, Abdallah C, Campa C, Courtel P, Bordeaux M et al. 2020. G× E interactions on yield and quality in Coffea arabica: new F1 hybrids outperform American cultivars. Euphytica 216:78

Turreira-García N. 2022. Farmers’ perceptions and adoption of Coffea arabica F1 hybrids in Central America. World Development Sustainability 1:100007

Jezeer RE, Verweij PA, Boot RG, Junginger M, Santos MJ. 2019. Influence of livelihood assets, experienced shocks and perceived risks on smallholder coffee farming practices in Peru. Journal of Environmental Management 242:496−506

Carvalho A, Krug CA, Mendes JET, Antunes Filho H, de Morais H, et al. 1952. Melhoramento do cafeeiro: IV-café Mundo Novo. Bragantia 12:97−130

Carvalho CHS (ed). 2008. Cultivares de café: origem, características e recomendações. Brasília: Embrapa. 247 pp

Guerreiro-Filho O, Ramalho MAP, Andrade VT. 2018. Alcides Carvalho and the selection of Catuaí cultivar: interpreting the past and drawing lessons for the future. Crop Breeding and Applied Biotechnology 18:460−66

Instituto Agronômico de Campinas (IAC). 2021. Cultivares de café desenvolvidas pelo Instituto Agronômico (IAC) e registradas no Ministério da Agricultura, Pecuária e Abastecimento – MAPA (Registro Nacional de Cultivares – RNC). www.iac.sp.gov.br/areasdepesquisa/cafe/tabela_rnc_cultivares_cafe_iac.pdf

Tassone GAT, Nadaleti DHS, Carvalho GR, Pereira FAC, Andrade VT, et al. 2019. Simultaneous selection in coffee progenies of mundo novo by selection indices. Coffee Science 14:83−92

Rodrigues CI, Maia R, Miranda M, Ribeirinho M, Nogueira JMF, et al. 2009. Stable isotope analysis for green coffee bean: a possible method for geographic origin discrimination. Journal of Food Composition and Analysis 22:463−71

de Oliveira Fassio L, Pereira RGFA, Malta MR, Liska GR, Sousa MMM, et al. 2019. Sensory profile of arabica coffee accesses of the germplasm collection of Minas Gerais–Brazil. Coffee Science 14:382−93

Sobreira FM, de Oliveira ACB, Pereira AA, Martins AG, Sakiyama NS. 2016. Divergence among arabica coffee genotypes for sensory quality. Australian Journal of Crop Science 10:1442−48

Borém FM, Figueiredo LP, Ribeiro FC, Taveira JHS, Giomo GS et al. 2016. The relationship between organic acids, sucrose and the quality of specialty coffees. African Journal of Agricultural Research 11:709−717

Brazil Specialty Coffee Association (BSCA). 2022. http://brazilcoffeenation.com.br/variety/show/id/74

Leroy T, Ribeyre F, Bertrand B, Charmetant P, Dufour M, et al. 2006. Genetics of coffee quality. Brazilian Journal of Plant Physiology 18:229−42

Scholz MBS, Figueiredo VRG, Silva JVN, Kitzberger CSG. 2011. Características físico-químicas de grãos verdes e torrados de cultivares de café (Coffea arabica L.) do IAPAR. Coffee Science 6:245−55

Bertrand B, Boulanger R, Dussert S, Ribeyre F, Berthiot L, et al. 2012. Climatic factors directly impact the volatile organic compound fingerprint in green Arabica coffee bean as well as coffee beverage quality. Food Chemistry 135:2575−83

Malta MR, De Rezende Chagas SJ. 2009. Avaliação de compostos não-voláteis em diferentes cultivares de cafeeiro produzidas na região Sul de Minas Gerais. Acta Scientiarum Agronomy 31:57−61

Sunarharum WB, Williams DJ, Smyth HE. 2014. Complexity of coffee flavor: A compositional and sensory perspective. Food Research International 62:315−25

Tran HTM, Furtado A, Vargas CAC, Smyth H, Lee SL, et al. 2018. SNP in the Coffea arabica genome associated with coffee quality. Tree Genetics & Genomes 14:72

Heo J, Adhikari K, Choi KS, Lee J. 2020. Analysis of caffeine, chlorogenic acid, trigonelline, and volatile in crew coffee using high performance liquid chromatography and solid-phase microextraction - gas chromatography-mass spectrometry. Foods 9:1746

International Trade Centre (ITC). 2011. The Coffee Exporter's Guide. 3^rd Edition. Geneva: ITC. xvi, 247 pp

Cilas C, Bouharmont P, Boccara M, Eskes AB, Baradat PH. 1998. Prediction of genetic value for coffee production in Coffea arabica from a half-diallel with lines and hybrids. Euphytica 104:49−59

Steiger D, Nagai C, Moore P, Morden C, Osgood R, et al. 2002. AFLP analysis of genetic diversity within and among Coffea arabica cultivars. Theoretical and Applied Genetics 105:209−15

Tran TMH. 2005. Genetic variation in cultivated coffee (Coffea arabica L.) accessions in northern New South Wales. Thesis. Southern Cross University, Australia

Mishra MK, Tornincasa P, De Nardi B, Asquini, E, Dreos R, et al. 2011. Genome organization in coffee as revealed by EST PCRRFLP, SNPs and SSR analysis. Journal of Crop Science and Biotechnology 14:25

Berecha G. 2014. Genetic Diversity, Pollination Ecology and Organoleptic Characteristics of Coffea arabica L., in Ethiopian Moist Forests of Different Management Intensity. Dissertation. KU Leuven, Leuven, Belgium

Gichimu BM. 2016. Selection for Resistance to Coffee Berry Disease, High Yields and Good Quality within Coffea arabica L. Cultivar, Ruiru 11. Thesis. Jomo Kenyatta University of Agriculture and Technology, Kenya

Caetano AL, Barbosa FS. 2019. Probabilidade de ocorrência de chuvas extremas para região de Inconfidentes–MG. Revista Brasileira de Climatologia 25

Souza ACC, Silva ML. 2016. Geoprocessamento aplicado ao levantamento de solos no município de Inconfidentes-MG. Revista Brasileira de Geografia Física 9:200−14

Technical Standards Committee. 2015. SCAA Protocols, Cupping Specialty Coffee. Specialty Coffee Association of America. www.scaa.org/PDF/resources/cupping-protocols.pdf

Lingle TR. 1986. The coffee cupper's handbook: systematic guide to the sensory evaluation of coffee's flavor. Coffee Development Group, Washington

International Organization for Standardization (ISO). 1999. Green coffee – determination of loss mass at 105 ºC. ISO 6673: 2003

Vitorino MD, França AS, Oliveira L, Borges MLA. 2001. Metodologias de obtenção de extrato de café visando a dosagem de compostos não-voláteis. Revista Brasileira de Armazenamento 26:17−24

Dishe Z. 1962. General color reaction. In Carbohydrate Chemistry, eds. Whistler RL, Wolfrom ML. New York: Academic Press. pp 477−512

Association Of Official Analytical Chemistry (AOAC). 1990. Official methods of analysis of the Association of Official Analytical Chemists. 15^th Edition. Washington

Goldstein JL, Swain T. 1963. Changes in tannins in ripening fruits. Phytochemistry 2:371−83

Carvalho VD, Chagas SJR, Chalfoun SM, Botrel N, Juste Junior ESG. 1994. Relação entre a composição físico-química e química do grão beneficiado e a qualidade de bebida do café 1-Atividades de polifenoloxidase e peroxidase, índice de coloração de acidez. Pesquisa Agropecuária Brasileira 29:449−54

Loeffler TM, Tekrony DM, Egli DB. 1988. The bulk conductivity test as an indicator of soybean seed quality. Journal of Seed Technology 12:37−53

Prete CEC. 1992. Condutividade elétrica do exsudato de grãos de café (Coffea arabica L.) e sua relação com a qualidade da bebida. Doctoral Thesis. Escola Superior de Agricultura Luiz de Queiroz (ESALQ), Piracicaba, Brazil. https://doi.org/10.11606/T.11.1992.tde-20210104-163950

Healey A, Furtado A, Cooper T, Henry RJ. 2014. Protocol: a simple method for extracting next-generation sequencing quality genomic DNA from recalcitrant plant species. Plant Methods 10:21

Merot-L'Anthoene V, Tournebize R, Darracq O, Rattina V, Lepelley M, et al. 2019. Development and evaluation of a genome-wide Coffee 8.5K SNP array and its application for high-density genetic mapping and for investigating the origin of Coffea arabica L. Plant Biotechnology Journal 17:1418−30

Zhang D, Vega FE, Solano W, Su F, Infante F, et al. 2021. Selecting a core set of nuclear SNP markers for molecular characterization of Arabica coffee (Coffea arabica L.) genetic resources. Conservation Genetics Resources 13:329−35

Wang J, Lin M, Crenshaw A, Hutchinson A, Hicks B, et al. 2009. High-throughput single nucleotide polymorphism genotyping using nanofluidic Dynamic Arrays. BMC Genomics 10:561

Fluidigm. 2013. Fluidigm® SNP Genotyping User Guide. PN 68000098 Rev I1, South San Francisco, CA, Fluidigm Corporation.

Cruz CD. 2016. Genes Software-extended and integrated with the R, Matlab and Selegen. Acta Scientiarum Agronomy 38:547−52

Scott AJ, Knott M. 1974. A cluster analysis method for grouping means in the analysis of variance. Biometrics 30:507−12

Pritchard JK, Stephens M, Donnelly P. 2000. Inference of population structure using multilocus genotype data. Genetics 155:945−59

Evanno G, Regnaut S, Goudet J. 2005. Detecting the number of clusters of individuals using the software STRUCTURE: a simulation study. Molecular Ecology 14:2611−20

Puechmaille SJ. 2016. The program STRUCTURE does not reliably recover the correct population structure when sampling is uneven: subsampling and new estimators alleviate the problem. Molecular Ecology Resources 16:608−27

Li YL, Liu JX. 2018. SᴛʀᴜᴄᴛᴜʀᴇSᴇʟᴇᴄᴛᴏʀ: A web-based software to select and visualize the optimal number of clusters using multiple methods. Molecular Ecology Resources 18:176−77

Jakobsson M, Rosenberg NA. 2007. CLUMPP: a cluster matching and permutation program for dealing with label switching and multimodality in analysis of population structure. Bioinformatics 23:1801−6

Rosenberg NA, Burke T, Elo K, Feldman MW, Freidlin PJ, et al. 2001. Empirical evaluation of genetic clustering methods using multilocus genotypes from 20 chicken breeds. Genetics 159:699−713

Dieringer D, Schlötterer C. 2003. Mɪᴄʀᴏsᴀᴛᴇʟʟɪᴛᴇ ᴀɴᴀʟʏsᴇʀ (MSA): a platform independent analysis tool for large microsatellite data sets. Molecular Ecology Notes 3:167−69

Nadalete DHS. 2020. Banco ativo de germoplasma de Minas Gerais: Avaliação física, sensorial e aceitabilidade do consumidor. Thesis. Universidade Federal de Lavras, Brazil

Allred KF, Yackley KM, Vanamala J, Allred CD. 2009. Trigonelline is a novel phytoestrogen in coffee beans. The Journal of Nutrition 139:1833−38

Van Cuong T, Ling LH, Quan GK, Tiep TD, Nan X, et al. 2014. Effect of roasting conditions on several chemical constituents of Vietnam Robusta coffee. The Annals of the University Dunarea de Jos of Galati, Fascicle VI - Food Technology 38:43−56

De Maria CAB, Trugo LC, Neto FRA, Moreira RFA, Alviano CS. 1996. Composition of green coffee water-soluble fractions and identification of volatiles formed during roasting. Food Chemistry 55:203−7

Vaast P, Bertrand B, Perriot JJ, Guyot B, Génard M. 2006. Fruit thinning and shade improve bean characteristics and beverage quality of coffee (Coffea arabica L.) under optimal conditions. Journal of the Science of Food and Agriculture 86:197−204

Seninde DR, Chambers EIV. 2020. Coffee flavor: A review. Beverages 6:44

Borém FM. 2008. Pós-colheita do Café. Lavras, Brazil: Universidade Federal de Lavras

Girma B, Gure A, Wedajo F. 2020. Influence of Altitude on Caffeine, 5-caffeoylquinic acid, and nicotinic acid contents of arabica coffee varieties. Journal of Chemistry 2020:3904761

Ogutu C, Cherono S, Ntini C, Wang L, Han Y. 2022. Comprehensive analysis of quality characteristics in main commercial coffee varieties and wild Arabica in Kenya. Food Chemistry: X 14:100294

Joët T, Laffargue A, Salmona J, Doulbeau S, Descroix F, et al. 2009. Metabolic pathways in tropical dicotyledonous albuminous seeds: Coffea arabica as a case study. New Phytologist 182:146−62

Cheng B, Smyth HE, Furtado A, Henry RJ. 2020. Slower development of lower canopy beans produces better coffee. Journal of Experimental Botany 71:4201−14

Sant’Ana GC, Pereira LFP, Pot D, Ivamoto ST, Domingues DS, et al. 2018. Genome-wide association study reveals candidate genes influencing lipids and diterpenes contents in Coffea arabica L. Scientific Reports 8:465

Malta MR, Pereira RGFA, de Rezende Chagas SJ. 2005. Potassium leaching and eletric conductivity of grain coffee (Coffea arabica L.) exsudate: some factors that may affect these evaluations. Ciência e Agrotecnologia 29:1015−20

Saath R. 2010. Qualidade do café natural e despolpado em diferentes condições de secagem e tempos de armazenamento. Thesis. Universidade Estadual Paulista, Brazil

Mazzafera P, Gonçalves KV, Shimizu MM. 2002. Extraction and activity determination of polyphenoloxidase in coffee. Scientia Agrícola 59:695−700

Antunes Filho H, Carvalho A. 1954. Genética de Coffea: XIX-Mutação somática afetando a cor das folhas em café. Bragantia 13:XI−XII

Krug CA. 1949. Mutações em Coffea arabica L. Bragantia 9:1−10

Lashermes P, Combes MC, Robert J, Trouslot P, D'Hont A, et al. 1999. Molecular characterisation and origin of the Coffea arabica L. genome. Molecular and General Genetics MGG 261:259−66