Abstract
The growth of Tabernaemontana pachysiphon (Apocynaceae) plants and the alkaloid content of leaves were investigated in the greenhouse at three levels of nutrient supply under two contrasting water and light regimes. We determined height increment, above-ground biomass production, leaf size, specific leaf weight and the content of the alkaloids apparicine, A2, isovoacangine, tubotaiwine and tubotaiwine-N-oxide. The effects of major controlling factors such as light, water and nutrient supply could be directly correlated with growth and were largely independent of each other. In contrast, leaf-alkaloid contents were influenced by interdependencies among the main factors and individually affected in a synergistic or antagonistic manner which deviated from the effects on growth. The following general trends could be identified with respect to the quantitatively predominant alkaloids apparicine, tubotaiwine and isovoacangine. Increasing nutrient supply had a positive effect on both growth and alkaloid content. Drought increased alkaloid content, but retarded growth. High light intensity lowered alkaloid content but promoted growth. We investigated the relationship between primary production and the production of secondary metabolites with respect to relative and total alkaloid content as well as in relation to the leaves' nitrogen status. Our results showed that under conditions of low nutrient supply, higher proportions of leaf nitrogen were allocated to alkaloids than at moderate or high nutrient supply. Under conditions of drought and low light, all plants allocated almost equal proportions of leaf nitrogen to alkaloids, regardless of fertiliser. Total alkaloid content per plant, however, increased with fertilisation. With respect to the N-allocation strategy, we found no indication of a trade-off between primary production and the production of secondary metabolites in this species. Rather, our results are in accordance with the carbon nutrient balance hypothesis.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aerts RJ, Verpoorte R (1992) The Influence of tryptophan and tryptamine feeding and light on alkaloid biosynthesis in Chinchona seedlings. Planta Med 58: 150–152
Aerts RJ, Stoker A, Beishuizen M, Jaarsma I, Heuvel M van de, Meijden E van der, Verpoorte R (1992) Detrimental effects of Cinchona leaf alkaloids on larvae of the polyphagous insect Spodoptera exigua. J Chem Ecol 18: 1955–1964
Ahmed ZF, Fahmy IR (1949) The effect of environment on the growth and alkaloidal content of Hyoscyamus muticus L. J Am Pharm Ass Sci Ed 38: 484–487
Bryant JP, Chapin FS III, Reichhardt P, Clausen T (1985) Adaption to resource availability as a determinant of chemical defense strategies in woody plants. Recent Adv Phytochem 19: 219–237
Chapin FS III (1980) The mineral nutrition of wild plants. Annu Rev Ecol Syst 11: 233–260
Chapin FS III, Schulze E-D, Mooney HA (1990) The ecology and economics of storage in plants. Annu Rev Ecol Syst 21: 423–447
Dagnino D, Schripsema J, Peltenburg A, Verpoorte R (1991) Capillary gas chromatographic analysis of indole alkaloids: investigation of the indole alkaloids present in Tabernaemontana divaricata cell suspension culture. J Nat Prod (Lloydia) 54: 1558–1563
Feeny P (1976) Plant apparency and chemical defense. Recent Adv Phytochem 10: 1–40
Fetcher N, Strain BR, Oberbauer SF (1983) Effects of light regime on the growth, leaf morphology, and water relations of seedlings of two species of tropical trees. Oecologia 58: 314–319
Fraenkel GS (1959) The raison d'être of secondary plant substances. Science 129: 1466–1470
Frischknecht PM, Baumann TW (1985) Stress induced formation of purine alkaloids in plant tissue culture of Coffea arabica Phytochemistry 24: 2255–2257
Frischknecht PM, Battig M, Baumann TW (1987) Effect of drought and wounding stress on indole alkaloid formation in Catharanthus roseus. Phytochemistry 26: 707–710
Gershenzon J (1984) Changes in the levels of plant secondary metabolites under water and nutrient stress. In: Timmermann BN, Stelink C, Loewus FA (eds) Phytochemical adaptations to stress. Recent Adv in Phytochemistry, vol 18. Plenum, New York, pp 273–320
Godoy-Hernandez G, Loyola-Vargas VM (1991) Effect of fungal homogenate, enzyme inhibitors and osmotic stress on alkaloid content of Catharanthus roseus cell suspension cultures. Plant Cell Rep 10: 537–540
Gulmon SL, Chu CC (1981) The effects of light and nitrogen on photosynthesis, leaf characteristics and dry matter allocation in the chaparral shrub, Diplacus aurantiacus. Oecologia 49: 207–212
Herms DA, Mattson WJ (1992) The dilemma of plants: to grow or defend. Q Rev Biol 67: 283–335
Hirata K, Horiuchi M, Asada M, Anso T, Miyamoto K, Miura Y (1992) Stimulation of dimeric alkaloid production by near-ultraviolet light in multiple shoot cultures of Catharanthus roseus. J Ferm Bioeng 74: 222–225
Hirose T (1988) Modeling the relative growth rate as a function of plant nitrogen concentration. Physiol Plant 72: 185–189
Hladik A, Hladik CM (1977) Siǵnification écologique des teneurs en alcaloides des vegetaux de la forest dense: resultats des tests preliminaires effectues au Gabon. Terre Vie 31: 515–555
Höft M (1995) Aut-ecological studies of Tabernaemontana pachysiphon Stapf and Rauvolfia mombasiana Stapf (Apocynaceae) in the Shimba Hills (Kenya) with special reference to their alkaloid content. Bayreuther Forum Ökologie 17
Hsiao TC (1973) Plant responses to water stress. Annu Rev Plant Physiol 24: 519–570
Knobloch K-H, Bast G, Berlin J (1982) Medium- and light-induced formation of serpentine and anthocyanins in cell suspension cultures of Catharanthus roseus. Phytochemistry 21: 591–593
Körner C (1991) Some often overlooked plant characteristics as determinants of plant growth. A reconsideration. Funct Ecol 5: 162–173
Küppers M, Koch G, Mooney HA (1988) Compensating effects of growth to changes in dry matter allocation in response to variation in photosynthetic characteristics induced by photoperiod, light, and nitrogen. Aust J Plant Physiol 15: 287–298
Lindsey K, Yeoman MM (1983) The relationship between growth rate, differentiation and alkaloid accumulation in cell cultures. J Exp Bot 43: 1055–1065
Loyola-Vargas VM, Mendez-Zeel M, Monforte-Gonzales M, Miranda-Ham MD (1992) Serpentine accumulation during greening in normal and tumor tissues of Catharanthus roseus. J Plant Physiol 140: 213–217
McDonald AJS, Ericsson A, Lohammar T (1986) Dependence of starch storage on nutrient availability and photon flux density in small birch (Betula pendula Roth). Plant Cell Environm 9: 433–438
McKey D (1974) Adaptive patterns in alkaloid physiology. Am Nat 108: 305–320
Mihaliak CA, Lincoln DE (1989) Plant biomass partitioning and chemical defense:response to defoliation and nitrate limitation. Occologia 80: 122–126
Morgan JM (1984) Osmoregulation and water stress in higher plants. Annu Rev Plant Physiol 35: 299–319
Nowacki E, Jurzysta M, Forski P, Nowacka D, Waller GR (1976) Effect of nitrogen nutrition on alkaloid metabolism in plants. Biochem Physiol Pflanz 169: 231–240
Ohnmeiss TE, Baldwin IT (1994) The allometry of nitrogen allocation to growth and an inducible defense under nitrogen-limited growth. Ecology 75: 995–1002
Omino EA, Kokwaro JO (1993) Ethnobotany of Apocynaceae species in Kenya. J Ethnopharmacol 40: 167–180
Rhodes DF (1979) Evolution of plant chemical defense against herbivores In: Rosenthal GA, Janzen DJ (eds) Herbivores: their interaction with secondary plant metabolites. Academic Press, Orlando, pp 3–54
Rhodes DF, Gates RG (1976) Toward a general theory of plant antiherbivore chemistry. Recent Adv Phytochem 10: 168–213
Saenz L, Santamaria JM, Villanueva MA, Loyola-Vargas VM, Oropeza C (1993) Changes in the alkaloid content of plants of Catharanthus roseus L (Don) as a result of water stress and treatment with abscisic acid. J Plant Physiol 142: 244–247
Schripsema J (1991) Factors involved in the alkaloid production of Tabernaemontana divaricata plant cell suspension cultures. Thesis. Rijksuniversiteit Leiden
Schripsema J, Verpoorte R (1992) Search for factors related to the indole alkaloid production in cell suspension cultures of Tabernaemontana divaricata. Planta Med 58: 245–249
Schripsema J, Peltenburg-Looman A, Erkelens C, Verpoorte R (1991) Nitrogen metabolism in cultures of Tabernaemontana divaricata. Phytochemistry 30: 3951–3954
Schulze E-D, Chapin FS III (1987) Plant specialization to environments of different resource availability. Ecol Stud 61: 120–148
Sokolov VS (1959) The influence of certain environmental factors on the formation and accumulation of alkaloids in plants. Symp Soc Exp Biol 13: 230–273
Stöckigt J, Zenk H (1977) Isovincoside (Strictosidine): the key intermediate in the enzymatic formation of indole alkaloids. FEBS Lett 79: 233–236
Todd GW (1972) Water deficits and enzymatic activity In: Kozlowski TT (ed) Water deficits and plant growth, vol III. Academic Press, New York, London, pp 177–210
Van Beek TA, Verpoorte R, Baerheim Svendsen A, Leeuwenberg AJM, Bisset NG (1984) Tabernaemontana a review of its alkaloids, botany, pharmacology and ethnopharmacy. J Ethnopharmacol 10: 1–156
Van Dam NM, Van der Meijden E, Verpoorte R (1993) Induced responses in three alkaloid-containing species. Oecologia 95: 425–430
Van der Heijden R (1989) Indole alkaloids in cell and tissue cultures of Tabernaemontana species. Thesis, Rijksuniversiteit Leiden
Van der Heijden R, Verpoorte R (1989) Identification of Tabernaemontana indole alkaloids by mass spectrometry. In: Atta-ur-Rahman (ed) Studies in natural products chemistry, vol 5. Structure elucidation (part B). Elsevier, Amsterdam, Oxford, pp 69–145
Van der Heijden R, Lamping PJ, Out PP, Wijnsma R, Verpoorte R (1987) High-Performance Liquid Chromatographic determination of indole alkaloids in a suspension culture of Tabernaemontana divaricata. J Chromatogr 396: 287–295
Verpoorte R (1987) Isotation and separation methods for indole alkaloids. In: Phillipson JD, Zenk MH (eds) Indole and biogenetically related alkaloids. Academic Press, London, pp 91–112
Waring RH, McDonald AJS, Larsson S, Ericsson T, Wiren A, Arwidsson E, Ericsson A, Lohammar T (1985) Differences in chemical composition of plants grown at constant relative growth rate with stable mineral nutrition. Oecologia 66: 157–160
Waterman PG, Ross JAM, McKey DB (1984) Factors affecting levels of some phenolic compounds digestibility and nitrogen content of the mature leaves of Barteria fistulosa (Passifloraceae). J Chem Ecol 10: 387–401
Watt JM, Breyer-Brandwijk MG (1962) The medicinal and poisonous plants of Southern and Eastern Africa, 2nd edn. Livingstone, Edinburgh pp 62–112
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Höft, M., Verpoorte, R. & Beck, E. Growth and alkaloid contents in leaves of Tabernaemontana pachysiphon Stapf (Apocynaceae) as influenced by light intensity, water and nutrient supply. Oecologia 107, 160–169 (1996). https://doi.org/10.1007/BF00327899
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00327899