Hostname: page-component-76fb5796d-25wd4 Total loading time: 0 Render date: 2024-04-27T13:57:10.815Z Has data issue: false hasContentIssue false
  • English
  • Français

Changes in the chemical composition of the fruits of Grewia coriacea Mast. during development and ripening.

Published online by Cambridge University Press:  07 December 2007

Attibayéba ,
Léon Ngantsoué ,
Fulbert Essamambo  and
Agnès Clarisse Nkourissa
Attibayéba
Affiliation:
Lab. Physiol. Prod. Vég. Fac. sci., Univ. Marien Ngouabi, BP 69, Brazzaville, Congo
Léon Ngantsoué
Affiliation:
Lab. Physiol. Prod. Vég. Fac. sci., Univ. Marien Ngouabi, BP 69, Brazzaville, Congo
Fulbert Essamambo
Affiliation:
Lab. Pathol. Vég., Fac. sci., Univ. Marien Ngouabi, BP 69, Brazzaville, Congo
Agnès Clarisse Nkourissa
Affiliation:
Lab. Physiol. Prod. Vég. Fac. sci., Univ. Marien Ngouabi, BP 69, Brazzaville, Congo
Get access

Abstract

Introduction. Grewia coriacea is a widespread plant species that occurs spontaneously in tropical forests of Central Africa. It is one of the most important commercial spontaneous fruit crops in the Republic of Congo (Brazzaville), where it is harvested, sold and consumed on a rather large scale. However, similar to many other spontaneous products of the tropical rain forest in Africa, G. coriacea remains poorly studied and its nutritional potential is unknown. Because the fruit of G. coriacea is an important food for indigenous people in a large portion of the Congo River Basin, we studied the evolution of some compounds of this fruit starting from its fruit setting until its maturation. Materials and methods. The contents of various pigments (chlorophyll a and b, and carotenoids), and concentrations of soluble sugars, ascorbic acid and soluble proteins of the fruit pulp of G. coriacea were analyzed in the laboratory and they were followed during maturation. Results and discussion. The curves of evolution of the studied parameters followed some anticipated trends: increasing, decreasing or relative stability. Increasing applied to the carotenoids (3,0 mg·g–1 at the beginning of the fruit development up to 8.2 mg·g–1 at the end of its maturation), soluble sugars (9,9 µg·g–1 up to 75,4 µg·g–1), ascorbic acid (25 mg·100 g–1 up to 230 mg·100 g–1) and soluble proteins (7 µg·g–1 up to 40 µg·g–1). In contrast, the two chlorophyll pigments (chlorophyll a and b) showed an overall decreasing trend. Finally, the concentration of soluble proteins remained rather constant in the later stages, despite an initial increase in the early stage of development. Conclusion. To our knowledge, these results are the first data published concerning the temporal changes in physico-chemical parameters of G. coriacea fruits in tropical Africa. The study shows that the studied fruits have high nutritional potentials, and that their ability to accumulate rather high levels of ascorbic acid could make them a potential source of vitamin C.

Keywords

CongoGrewia coriaceafruitsdevelopmental stagesmaturationchemical compositionchlorophyllscarotenoidssugarsascorbic acidproteinsCongoGrewia coriaceafruitsstade de développementmaturationcomposition chimiquechlorophyllecaroténoïdesucresacide ascorbiqueprotéine
Type
Research Article
Information
Fruits , Volume 62 , Issue 6 , November 2007 , pp. 369 - 375
Copyright
© CIRAD, EDP Sciences, 2007

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ngantsoué, L., Attibayéba, Essamambo F., Bolopo-Engagoye, Kaboulou V., Germination des graines et croissance des jeunes plants de Grewia coriacea Mast., Ann. Univ. Marien Ngouabi 6 (2005) 140–148.
Anon., Flore du Congo, du Rwanda et du Burundi : spermaphytes, Inst. Ntl. Études Agron. (INEAC), Bruxelles, Belgique, 1963.
Youmbi, E., Clair-Maczulajtys, D., Bory, G., Variation de la composition chimique des fruits de Dacryodes edulis (Don) Lam., Fruits 44 (1989) 149–154.
El Bulk, R.E., Babiker, E.F.E., El Tinay, A.H., Changes in chemical composition of guava fruits during development and ripening, Food Chem. 59 (1997) 395–399. CrossRef
De Assis, S.A., Lima, D.C., De Faria Oliveira, O.M.M., Activity of pectinmetylesterase, pectin content and vitamin C in acerola fruit at various stages of fruit development, Food Chem. 74 (2001) 133–137. CrossRef
Glew, R.H., Ayaz, F.A., Sanz, C., Vanderjagt, D.J., Huang, H.S., Chuang, L.T., Strnad, M., Effect of postharvest period on sugars, organic acids and fatty acids composition in commercially sold medlar (Mespilus germanica Dutch.) fruit, Eur. Food Res. Technol. 216 (2003) 390–394. CrossRef
Glew, R.H., Ayaz, F.A. Millson, M., Huang, H.S., Chuang, LT., Sanz, C., Golding, J.B., Changes in sugars, acids and fatty acids in naturally parthenocarpic date plum persimmon (Diospyros lotus L.) fruit during maturation and ripening, Eur. Food Res. Technol. 221 (2005) 113–118. CrossRef
Ordoñez, R.M., Vattuone, M.A., Isla, M.J., Changes in carbohydrate content and related enzyme activity during Cyphomandra betacea (Cav.) Sendtn. fruit maturation, Postharvest Biol. Technol. 35 (2005) 293–301. CrossRef
Attibayéba, , Paulet, P., Activités enzymatiques et floraison in vitro de fragments de racines de Cichorium intybus L. : effet d’un apport exogène de molécules organiques, Ann. Univ. Marien Ngouabi 5 (2004) 215–224.
Khales, A., Baaziz, M., Quantitative and qualitative aspects of peroxidases extracted from cladodes of Opuntia ficus indica, Scientia Hortic. 103 (2005) 209–218. CrossRef
Bradford, M.M., A rapid and sensitive method for the quantitation of protein-dye biding, Anal. Biochem. 72 (1976) 248–254. CrossRef
Fairbairn, N.J., A modified anthrone reagent, Chem. Int. 4 (1953) 86.
Arnon D.I., Copper enzymes in isolated chloroplasts, polyphenoloxidase in Beta vulgaris, Plant Physiol. 24 (1949) 1–15.
Arcila-Pulgarin, J., Burhr, L., Bleiholder, H., Hack, H., Meier, V., Wicke, H., Application of the extended BBCH scale for the description of the growth stages of coffee (Coffea spp.), Ann. Appl. Biol. 141 (2002) 19–27. CrossRef
Cautin, R., Agusti, M., Phenological growth stages of the cherimoya tree (Annona cherimola Mill.), Scientia Hortic. 105 (2005) 491–497. CrossRef
Garcia-Carbonell, S., Yague, B., Bleiholder, H., Hack, H., Meier, U., Agusti, M., Phenological growth stages of the persimmon tree (Diospyros kaki), Ann. Appl. Biol. 141 (2002) 73–76. CrossRef
Solovchenko, A.E., Chivkunova, O.B., Merzlyak, M.N., Gudkovsky, V.A., Relationships between chlorophyll and carotenoid pigments during on – and off – tree ripening of apple fruit as revealed non-destructively with reflectance spectroscopy, Postharvest Biol. Technol. 38 (2005) 9–17. CrossRef
Wang, Z.F., Ying, T.J., Bao, B.L., Huang, X.D., Characteristics of fruit ripening in tomato mutant Epi, J. Zhejiang, Univ. Sci. 6B (2005) 502–507.
Mowlah, G., Itoo, S., Guava sugar components and related enzymes stages of fruit development and ripening, J. Jap. Soc. Food Sci. Technol. 29 (1982) 472–476. CrossRef
Itoo, S., Aiba, M., Ishihata, K., Ascorbic acid content in acerola fruit from different production regions and degrees of maturity and stability during processing, J. Jap. Soc. Food Sci. Technol. 37 (1990) 726–729. CrossRef