It is the cache of ${baseHref}. It is a snapshot of the page. The current page could have changed in the meantime.
Tip: To quickly find your search term on this page, press Ctrl+F or ⌘-F (Mac) and use the find bar.

Genetics and Molecular Biology - Caffeine content of Ethiopian Coffea arabica beans

SciELO - Scientific Electronic Library Online

 
vol.23 issue1Wild cassava, Manihot spp.: Biology and potentialities for genetic improvementInteractions in the Agrobacterium-soybean system and capability of some Brazilian soybean cultivars to produce somatic embryos author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Article

Indicators

Related links

Share


Genetics and Molecular Biology

Print version ISSN 1415-4757

Genet. Mol. Biol. vol.23 n.1 São Paulo Mar. 2000

http://dx.doi.org/10.1590/S1415-47572000000100036 

SHORT COMMUNICATION

CAFFEINE CONTENT OF ETHIOPIAN COFFEA ARABICA BEANS

 

Maria Bernadete Silvarolla1, Paulo Mazzafera2 and Marinez Muraro Alves de Lima1
1 Centro de Café e Plantas Tropicais, Instituto Agronômico de Campinas, Caixa Postal 28, 13001-970 Campinas, SP, Brasil. Send correspondence to M.B.S.
2 Departamento de Fisiologia Vegetal, Instituto de Biologia, Universidade Estadual de Campinas (UNICAMP), Caixa Postal 6109, 13083-970 Campinas, SP, Brasil.

 

 

ABSTRACT

The coffee germplasm bank of the Instituto Agronômico de Campinas has many Coffea arabica accessions from Ethiopia, which is considered the primary center of genetic diversity in coffee plants. An evaluation of the caffeine content of beans from 99 progenies revealed intra- and inter-progeny variability. In 68 progenies from the Kaffa region we found caffeine values in the range 0.46-2.82% (mean 1.18%), and in 22 progenies from Illubabor region these values ranged from 0.42 to 2.90% (mean 1.10%). This variability could be exploited in a breeding program aimed at producing beans with low-caffeine content.

 

 

INTRODUCTION

Although coffee is a popular beverage mostly due to the alertness caused by caffeine, there is an increasing market for decaffeinated coffee (Mazzafera et al., 1997). Organic solvents or supercritical carbon dioxide is used to decaffeinate coffee, with the final product containing less than 0.5% caffeine (Mazzafera and Carvalho, 1991; Saldaña et al., 1998). Supercritical extraction produces coffee free from chemical residues, the presence of which limits coffee consumption (Mazzafera and Carvalho, 1991). Supercritical extraction also has the advantage of being selective for caffeine without changing the final product quality, although recent studies have shown that other substances, such as sugars, oil and phenolic compounds (Saldaña, M.D.A., Mohamed, R.S. and Mazzafera, P., unpublished data), are also extracted during the process (Peker et al., 1992; Saldaña, 1997).

The Arabica coffee bean cultivar "Laurina" has half the content (0.6%) of caffeine found in other Coffea arabica cultivars (1.2%) (Carvalho et al., 1965), and differs from the latter in its peculiar plant architecture and low productivity (Carvalho et al., 1991). Carvalho et al. (1965) showed that these characteristics are recessive (lrlr), with a strong pleiotropic effect.

Mazzafera et al. (1992) evaluated the caffeine content of more than 500 coffee trees of C. arabica under selection for productivity and pest and disease resistance and observed little variability in the caffeine content. Breeding programs involving interspecific crosses among C. arabica and low-caffeine content African species resulted in hybrids with a low-caffeine content but with poor vegetative characteristics (Mazzafera and Carvalho, 1992). Problems resulting from strong genetic barriers between C. arabica and other native diploid Coffea species from the Mascarene Islands and Madagascar have been reported (Charrier, 1978; Charrier and Berthaud, 1975; Rakotomalala et al., 1992).

The production of low-caffeine coffee bean varieties, using traditional plant breeding methods, is slow and arduous. However, considering the problems associated with the methods of caffeine extraction currently used, the breeding of such plants is still a desirable solution. In the present work, we analyzed Arabica germplasm, originally introduced from Ethiopia, considered to be the primary center of genetic diversity in coffee plants (Medina Filho et al., 1984). The most promising genotypes could be valuable in a breeding program aimed at producing beans with a low-caffeine content, and would help to expand the limited genetic variability of Brazilian coffee (Medina Filho et al., 1984).

 

MATERIAL AND METHODS

The Coffea arabica plants studied were originally collected from seven regions in Ethiopia during an FAO expedition in 1964-65 (FAO, 1968). The plants were grown in Turrialba, Costa Rica, and transferred in 1975 to the germplasm bank of the Experimental Center of the Instituto Agronômico de Campinas (IAC).

Seeds from 724 plants were analyzed, of which 68 were progenies from the Kaffa region, 22 from Illubabor, five from Gojjam and one each from Eritrea, Geisha, Harar and Shoa. The Brazilian cultivars "Catuaí Vermelho" and "Mundo Novo" (24 plants) were included for comparison. Coffee beans were obtained from at least 20 mature fruits of each plant, and their caffeine content determined by high-performance liquid chromatography (Mazzafera et al., 1997), following extraction.

 

RESULTS AND DISCUSSION

The mean caffeine content of 499 plants from the Kaffa region was 1.18% (Table I), although there was high intra- and inter-progeny variability. Mean caffeine contents as low as 0.46% and as high as 2.82% were found.

 

 

In the 166 plants from the Illubabor region, caffeine content ranged from 0.42 to 2.90% (Table II). The plants from Gojjam, Eritrea, Geisha, Harar and Shoa (Table III) did not show the extreme values seen in the other two regions, probably because of the small number of plants analyzed.

 

 

 

 

These results show that some Ethiopian plants have a caffeine content lower than those of the reference cultivars "Catuaí Vermelho" and "Mundo Novo". However, the low productivity of the Ethiopian germplasm (Carvalho, A., Fazuoli, L.C. and Guerreiro Filho, O., unpublished data) limits their use and would require a hybridization program to produce high-yield cultivars.

The identification of some Ethiopian genotypes with a low-caffeine content confirms previous reports on the genetic variability of these accessions for a number of traits. Carvalho et al. (1983) reported variability in fruit shape, size, weight and color, and Mazzafera et al. (1989) identified male-sterile plants. In an early study, Carvalho (1959) evaluated a group of Ethiopian plants introduced to Brazil in 1952 and 1953 and identified additional factors of economic interest, such as the recessive allele "semi-erecta", which is responsible for a change in the lateral branch intersection of the stems. Plants with coffee leaf rust resistance were also identified.

 

ACKNOWLEDGMENTS

The authors thank Denise Cristina da Silva for help with the caffeine analyses. Research partially supported by Fundação de Amparo à Pesquisa do Estado de São Paulo (Proc. No. 94/1775-3). P.M. and M.M.A.L. are recipients of CNPq fellowships. Publication supported by FAPESP.

 

 

RESUMO

O banco de germoplasma de café do Instituto Agronômico de Campinas contém grande número de introduções de Coffea arabica provenientes da Etiópia, considerada centro de diversidade genética desta espécie. A avaliação dos teores de cafeína nas sementes de 99 progênies revelou a presença de variabilidade entre e dentro das progênies, de acordo com a região de origem das introduções. Entre as 68 progênies da região de Kaffa encontraram-se valores de cafeína entre 0.46 e 2.82% (média 1.18%) e entre as 22 progênies de Illubabor obtiveram-se plantas cujos teores de cafeína variaram de 0.42 a 2.90% (média 1.10%). A variabilidade aqui relatada poderá ser explorada na produção de uma variedade de café com baixos teores de cafeína nas sementes.

 

 

REFERENCES

Carvalho, A. (1959). A genética de Coffea: XXIV - Mutantes de Coffea arabica procedentes da Etiópia. Bragantia 18: 353-371.         [ Links ]

Carvalho, A., Tango, J.S. and Monaco, L.C. (1965). Genetic control of caffeine in coffee. Nature 205: 314.         [ Links ]

Carvalho, A., Fazuoli, L.C., Levy, F.A., Guerreiro Filho, O. and Mazzafera, P. (1983). Observações sobre características dos frutos de introduções de Coffea arabica da Etiópia. In: 10o Congresso Brasileiro de Pesquisas Cafeeiras, 1983. Resumos, pp. 90-92.         [ Links ]

Carvalho, A., Medina Filho, H.P., Fazuoli, L.C., Guerreiro Filho, O. and Lima, M.M.A. (1991). Aspectos genéticos do cafeeiro. Rev. Bras. Genet. 14: 135-183.         [ Links ]

Charrier, A. (1978). La structure génétique des caféiers spontanés de la région Malgache (Mascarocoffea). Leur relations avec les caféiers d'origene africaine (Eucoffea). Mémoires ORSTOM, 87, ORSTOM, Paris.         [ Links ]

Charrier, A. and Berthaud, J. (1975). Variation de la teneur em caféine dans le genre Coffea. Café Cacao Thé 19: 251-264.         [ Links ]

Food and Agriculture Organization of the United Nations (1968). Coffee Mission to Ethiopia 1964-65. FAO, Rome.         [ Links ]

Mazzafera, P. and Carvalho, A. (1991). A Cafeína do Café. Documentos IAC, 25. Instituto Agronômico, Campinas.         [ Links ]

Mazzafera, P. and Carvalho, A. (1992). Breeding for low seed caffeine content of coffee (Coffea L.) by interspecific hybridization. Euphytica 59: 55-60.         [ Links ]

Mazzafera, P., Eskes, A.B., Parvais, J.P. and Carvalho, A. (1989). Stérilité mâle détectée chez Coffea arabica et C. canephora au Brésil. In: 13th International Scientific Colloquium on Coffee, 1989. Annals, pp. 466-473.         [ Links ]

Mazzafera, P., Carvalho, A., Fazuoli, L.C. and Medina Filho, H.P. (1992). Variabilidade do teor de cafeína em sementes de café. Turrialba 42: 231-237.         [ Links ]

Mazzafera, P., Silvarolla, M.B., Lima, M.M.A. and Medina Filho, H.P. (1997). Caffeine content of diploid coffee species. Ciên. Cult. 49: 216-218.         [ Links ]

Medina Filho, H.P., Carvalho, A., Sondahl, M.R., Fazuoli, L.C. and Costa, W.M. (1984). Coffee breeding and related evolutionary aspects. In: Plant Breeding Reviews (Janick, J., ed.). The Avi Publishing Co. Inc., Westport, Connecticut, pp. 157-193.         [ Links ]

Peker, H., Srinivasan, M.P., Smith, J.M. and McCoy, J.B. (1992). Caffeine extraction rates from coffee beans with supercritical carbon dioxide. Am. Inst. Chem. Eng. Symp. Ser. 38: 761-770.         [ Links ]

Rakotomalala, J.J.R., Cros, E., Clifford, M.N. and Charrier, A. (1992). Caffeine and theobromine in green beans from Mascarocoffea. Phytochemistry 31: 1271-1272.         [ Links ]

Saldaña, M.D.A. (1997). Extração de cafeína, trigonelina e ácido clorogênico dos grãos de café com CO2 supercrítico. Master's thesis, Faculdade de Engenharia Química, UNICAMP.         [ Links ]

Saldaña, M.D.A., Mazzafera, P. and Mohamed, R.S. (1998). Extração dos alcalóides cafeína e trigonelina dos grãos de café com CO2 supercrítico. Ciênc. Tecnol. Aliment. 17: 371-376.         [ Links ]

 

(Received November 9, 1998)