Grapes are the main reason why the grapevine (Vitis vinifera L.) is cultivated. However, climate, soil conditions, vegetation and anthropogenic effects on the soil greatly affect grapevine production. The organoleptic properties of grape-derived products, such as wine, are influenced by these factors, which are becoming increasingly popular in Africa. Thus, grapevines, which are commonly grown in warm regions, are acclimatized in Africa using grapevine varieties that can adjust to tropical conditions. This study, which was carried out in 2019, aimed to promote grapevine cultivation in C?te d’Ivoire by examining the influence of pedoclimatic factors on the agro-physiological characteristics of grapevines. In C?te d’Ivoire, there were four distinct agro-ecological zones (North, South, Southeast and West) where three grapevine varieties, Bequignol, Muscat Rouge and Aleatico, were grown. Grapevine plants could grow robustly in morpho-physiological ways because the soils had sufficient fertility, as revealed by the analysis of experimental sites. Grapevine varieties have successfully adapted to different terroirs, with the exception of Muscat Rouge, which only displayed favorable morphological characteristics in the Man zone (West). Regardless of the grape variety, the regions with the best grapevine-growing conditions were Man (West), followed by Aboisso (Southeast). Consequently, grapevine development was less favorable in Korhogo (North) and Abidjan (South) zones. Thus, the cultivation of grapevine varieties in C?te d’Ivoire was greatly influenced by terroir.
References
[1]
Sultan, B., Roudier, P. and Traoré, S. (2015) Chapitre 10. Les impacts du changement climatique sur les rendements agricoles en Afrique de l’Ouest. In: Sultan, B., Lalou, R., Sanni, M.A., Oumarou, A. and Soumaré, M.A., Eds., Les sociétés rurales face aux changementsclimatiques et environnementauxen Afrique de l’Ouest, IRD Éditions, 209-225. https://doi.org/10.4000/books.irdeditions.9773
[2]
Affoh, R., Zheng, H., Dangui, K. and Dissani, B.M. (2022) The Impact of Climate Variability and Change on Food Security in Sub-Saharan Africa: Perspective from Panel Data Analysis. Sustainability, 14, Article 759. https://doi.org/10.3390/su14020759
[3]
USAID (2022) Conception d’activités agricoles efficaces sensibles à la nutrition, Guide du facilitateur. Feed the Future, JSI Research and Training Institute, Inc., 1-102.
[4]
Chabin, Y. and Rochard, J. (2023) Objectifs du Développement Durable (ODD) l’ONU et Responsabilité Sociale/Sociétale des Entreprises, au sein de la filière vitivinicole: Concepts et applications. BIO Web of Conferences, 56, Article ID: 03011. https://doi.org/10.1051/bioconf/20235603011
[5]
Rochard, J. (2023) Arido-viticulture dans le contexte de changement climatique: Concept, bases pratiques et exemples des vignobles de Lanzarote et Santorin. BIO Web of Conferences, 56, Article ID: 01001. https://doi.org/10.1051/bioconf/20235601001
[6]
Sophia, M. (2017) Fiche technique de la culture de la vigne au Maroc. https://www.agrimaroc.ma/fiche-technique-de-la-culture-de-la-vigne-au-maroc/
[7]
Garcia, D. (2021) Influence des conditions agroécologiques sur la qualité des raisins et la typicité des vins: Revue des études récentes. Journal de la viticulture et œnologietropicale, 5, 29-47
[8]
Vaudour, E. (2003) Les terroirs viticoles. Dunod.
[9]
Hall, A. and Jones, G.V. (2010) Climatic Variability and Change: Their Impact on Grapevine Phenology and Wine Composition. Global Change Biology, 16, 1151-1169
[10]
Yao, K.T., Gogbeu, D.G.L., Coulibaly, I., Kouadio, O.K.S. and Kouakou, T.H. (2022) Screening of Six Grapevine Varieties from France in Nursery for Their Resilience to the Pedoclimatic Conditions of Côte d’Ivoire. Journal of Agriculture and Research, 9, 1-16
[11]
De Liedekerke, D.P.L. and Collard, E. (2017) Entre Ancien et Nouveau Monde, quel avenir pour le vignoble Belge? Analyse stratégique d’un phénomène en pleine expansion. Master’s Thesis, Louvain School of Management, Université catholique de Louvain. http://hdl.handle.net/2078.1/thesis:10928
[12]
Soto, M., et al. (2019) Les défis de la viticulture en zone tropicale: Le cas de l’Afrique de l’Ouest. Cahiers Agricultures, 28, 113-121
[13]
Bodin, F. and Morlat, R. (2006) Characterization of Viticultural Terroirs Using a Simple Field Model Based on Soil Depth I. Validation of the Water Supply Regime, Phenology and Vine Vigour, in the Anjou Vineyard (France). Plant and Soil, 281, 37-54. https://doi.org/10.1007/s11104-005-3768-0
[14]
Gatti, M. (2012) Evaluation de l’effet du terroir sur la teneur en stilbènes du vin. Ph.D. Thesis, Université Nantes Angers le Mans.
[15]
Arrouays, D., Antoni, V., Bady, M., Bispo, A. and Brossard, M. (2012) Fertilité des sols conclusions du rapport sur l’état des sols de France. Innovations agronomiques, 21, 1-11.
[16]
Labreuche, J. and Déroulède, M. (2013) Deux méthodes pour observer la structure du sol. https://www.agro-transfert-rt.org/wp-content/uploads/2016/03/Article-PA-diagnostic-structure-sol.pdf
[17]
Mbonigaba, M.J., Nzeyimana, I., Bucagu, C. and Culot, M. (2009) Caractérisation physique, chimique et microbiologique de trois sols acides tropicaux du Rwanda sous jachères naturelles et contraintes à leur productivité. Biotechnology Agronomy Society and Environment, 13, 545-555.
[18]
Ministère de l’environnement, de la lutte contre les changements climatiques, de la faune et des parcs du Québec (2023) Détermination du pH: Méthode électrométrique. Méthode d’analyse MA. 100—pH 1.1 (révision 6). https://www.ceaeq.gouv.qc.ca/methodes/pdf/methode-analyse-100-ph.pdf
[19]
M’Sadak, Y., Ben, M. and Tayachi, L. (2012) Possibilité d’incorporation du méthacompost avicole dans la confection des substrats de culture à base de compost sylvicole en pépinière forestière. Nature Technologie, 6, 59-70.
[20]
Geiger, J.W., Davis, N.M., Blakemore, W.S. and Long, C.L. (1987) A Method for Determining Total Nitrogen Inkjeldahl Digestion Solution Using Acentrifugal Analyser. Journal of Analytical Methods in Chemistry, 9, 72-76. https://doi.org/10.1155/s1463924687000166
[21]
Thirion-Merle, V.V. (2016) Spectrométrie de fluorescence X. Des archives contemporaines, Université de Lyon, 1-7.
[22]
Harkat, H. (2014) Appréciation de la nutrition minérale de quelques vignobles de la région de Skikda par la démarche de l’enquête. Master’s Thesis, Université de Constantine.
[23]
Flisch, R., Neuweiler, R., Kuster, T. and Oberholer, H. (2017) Caractéristiques et analyses du sol. Recherche Agronomique Suisse, 8, 1-33.
[24]
Henson, I.E., Mahalakshmi, V., Bidinger, F.R. and Alagarswamy, G. (1981) Genotypic Variation in Pearl Millet (Pennisetum americanum (L.) Leeke), in the Ability to Accumulate Abscisic Acid in Response to Water Stress. Journal of Experimental Botany, 32, 899-910. https://doi.org/10.1093/jxb/32.5.899
[25]
Carbonneau, A., Metay, A., Torregrosa, L., Ojeda, H., Pellegrino, A., Deloire, A., et al. (2020) Traité de la vigne. In: Carbonneau, A., et al., Eds., Traité de la vigne, Dunod, 375-513. https://doi.org/10.3917/dunod.carbo.2020.01.0375
[26]
Gabriele Marcolino Gonçalves, M., Alves Caldeira Brant, L., Vieira da Mota, R., Peregrino, I., Rita de Souza, C., de Albuquerque Regina, M., et al. (2022) Soil and Climate Effects on Winter Wine Produced under the Tropical Environmental Conditions of Southeastern Brazil. OENO One, 56, 63-79. https://doi.org/10.20870/oeno-one.2022.56.2.4617
[27]
Duchaufour, P. (1997) Pédologie: Sol, végétation, environnement. Abrégés de Péd-ologie. 5ème Edition, Masson.
[28]
Quimeby, C. (2022) Etat de l’art des indicateurs d’évaluation des composantes de la fertilité des sols: Physique, chimique et biologique. https://it2.fr/app/uploads/2023/09/ENR_IT2_2022_-SOLORGA_Etat-de-lart-indicateurs-fertilite-sols.pdf
[29]
Archambeaud, M. and Thomas, F. (2016) Les sols agricoles. France Agricole.
[30]
Khelil, A. (2009) Nutrition et fertilisation arbres fruitiers et vigne. OPU.
[31]
Gabriela, B. (2014) Caractéristiques du sol et de la géologie des régions viticoles suisse. https://www.soil.ch
[32]
Arias, L.A., Berli, F., Fontana, A., Bottini, R. and Piccoli, P. (2022) Climate Change Effects on Grapevine Physiology and Biochemistry: Benefits and Challenges of High Altitude as an Adaptation Strategy. Frontiers in Plant Science, 13, Article 835425. https://doi.org/10.3389/fpls.2022.835425
[33]
Olivain, C. and Bessis, R. (1988) Fertilité des rameaux anticipés de vigne (Vitis vinifera L.): II.—Influence de la fertilité potentielle et de la vitesse de croissance. Agronomie, 8, 187-192. https://doi.org/10.1051/agro:19880303
[34]
Akanza, P., N’zue, B. and Anguete, K. (2002) Influence de la fumure minérale et de la litière de volaille sur la production du manioc (Manihot esculenta Crantz) en Côte d’Ivoire. AgronomieAfricaine, 14, 79-89.
[35]
Verdoodt, A. and van Ranst, E. (2003) Land Evaluation for Agricultural Production in the Tropics. A Large-Scale Land Suitability Classification for Rwanda. Ghent University. Laboratory of Soil Science, 1-175
[36]
Goëbau, N. (2017) Assimilation et effets d’apports foliaires de phosphore et de calcium sur l’équilibre minéral de parcelles de vignes du Languedoc-Roussillon. Master’s Thesis, SupAgro University.
[37]
Mpelasoka, B.S., Schachtman, D.P., Treeby, M.T. and Thomas, M.R. (2003) A Review of Potassium Nutrition in Grapevines with Special Emphasis on Berry Accumulation. Australian Journal of Grape and Wine Research, 9, 154-168. https://doi.org/10.1111/j.1755-0238.2003.tb00265.x
[38]
Nistor, E., Dobrei, A.G., Mattii, G.B. and Dobrei, A. (2022) Calcium and Potassium Accumulation during the Growing Season in Cabernet Sauvignon and Merlot Grape Varieties. Plants, 11, Article 1536. https://doi.org/10.3390/plants11121536
[39]
Villette, J., Cuéllar, T., Verdeil, J., Delrot, S. and Gaillard, I. (2020) Grapevine Potassium Nutrition and Fruit Quality in the Context of Climate Change. Frontiers in Plant Science, 11, Article 123. https://doi.org/10.3389/fpls.2020.00123
[40]
Kalavati P. and Modi, H.A. (2012) The Importance of Potassium in Plant Growth—A Review. Indian Journal of Plant Sciences, 1, 177-186
[41]
Podleśny, J. and Podleśna, A. (2011) Effect of Rainfall Amount and Distribution on Growth, Development and Yields of Determinate and Indeterminate Cultivars of blue Lupin. Polish Journal of Agronomy, 4, 16-22.
[42]
Faralli, M., Mallucci, S., Bignardi, A., Varner, M. and Bertamini, M. (2024) Four Decades in the Vineyard: The Impact of Climate Change on Grapevine Phenology and Wine Quality in Northern Italy. OENO One, 58, 1-21. https://doi.org/10.20870/oeno-one.2024.58.3.8083
[43]
Anastasiou, E., Templalexis, C., Lentzou, D., Biniari, K., Xanthopoulos, G. and Fountas, S. (2023) Do Soil and Climatic Parameters Affect Yield and Quality on Table Grapes? Smart Agricultural Technology, 3, Article ID: 100088. https://doi.org/10.1016/j.atech.2022.100088
[44]
INRA (2021) Catalogue des vignes cultivées en France. https://www.plantgrape.fr/fr
[45]
Egon, M. (2022) Humidité de l’air. https://glosario.wein.plus/humidite-de-l-air
[46]
Zhu, J.K. (2002) Salt and Drought Stress Signal Transduction in Plants. Annual Review of Plant Biology, 53, 247-273.
[47]
Bois, B. and Pérard, J. (2009) Climat et viticulture au Vietnam: Évaluation et perspectives. Climatologie, 6, 75-89. https://doi.org/10.4267/climatologie.525
[48]
Groeninger, R. (2016) Noms des cépages. http://www.lescepages.fr
[49]
Huglin, P. and Schneider, C. (1998) Biologie et écologie de la vigne. Tec and Doc.
[50]
White, R.E. (2003) Soils for Fine Wines, Edition. Oxford University Press.
[51]
Akinnuoye-Adelabu, D.B. and Modi, A.T. (2017) Planting Dates and Harvesting Stages Influence on Maize Yield under Rain-Fed Conditions. Journal of Agricultural Science, 9, 43-55. https://doi.org/10.5539/jas.v9n9p43
[52]
Bykova, O., Chuine, I. and Morin, X. (2019) Highlighting the Importance of Water Availability in Reproductive Processes to Understand Climate Change Impacts on Plant Biodiversity. Perspectives in Plant Ecology, Evolution and Systematics, 37, 20-25. https://doi.org/10.1016/j.ppees.2019.01.003
[53]
Caferri, R. and Bassi, R. (2022) Plants and Water in a Changing World: A Physiological and Ecological Perspective. RendicontiLincei. ScienzeFisiche e Naturali, 33, 479-487. https://doi.org/10.1007/s12210-022-01084-7
[54]
Dumont, E. (2015) L’impact du climat sur la viticulture. https://www.lesaireslevillage.fr/agriculturevalleeorb.pdf
[55]
Simonovici, M. (2019) Enquête Pratiques phytosanitaires en viticulture en 2016 Nombre de traitements et indicateurs de fréquence de traitement. https://agreste.agriculture.gouv.fr/agreste-web/download/publication/publie/Dos1902/Dossier2019-2.pdf
[56]
van Leeuwen, C. (2010) Terroir: The Effect of the Physical Environment on Vine Growth, Grape Ripening and Wine Sensory Attributes. In: Reynolds, A.G., Ed., Managing Wine Quality, Elsevier, 273-315. https://doi.org/10.1533/9781845699284.3.273
[57]
de Liedekerke, G. (2016) Étude du terroir et de la relation sol-plante sur la nutrition de la vigne et son impact sur la qualité potentielle des vins de la Région wallonne. Bioengineer, Université catholique de Louvain, Belgique.
[58]
Van Leeuwen, C. and Chery, P. (2001) Quelle méthode pour caractériser et étudier le terroir viticole: analyse de sol, cartographie pédologique ou étude écophysiologique? Journal International des Sciences de la Vigne et du Vin, 35, 13-20.
[59]
Rouvellac, E. (2013) Le terroir, essai d’une réflexion géographique à travers la viticulture. Ph.D. Thesis, Université de Limoges.
