Allocation of photoassimilates to biomass, resin and carbohydrates in Grindelia chiloensis as affected by light intensity.

ZAVALA, J.A.; RAVETTA, D.A.

FIELD CROPS RESEARCH

Año: 2001 vol. 69 p. 143 - 149

0378-4290

Grindelia chiloensis (Asteraceae) is a shrub native to Patagonia, Argentina, and can accumulate as much as 25% resin (on a dry weight basis) in leaves. The resin can be used in applications similar to those of pine resins. Reductions in available radiation are thought to decrease both the plant C:N ratio and resin production. The objective of this study was to assess the effect of light availability on the allocation of photoassimilates to biomass, resin (terpenes) and carbohydrates in G. chiloensis. To examine this, three radiation treatments were applied to ®eld grown plants: (i) 100% radiation (full-sun), (ii) 50% radiation and (iii) 25% photon ¯ux density radiation. Changes in available radiation resulted in signi®cant changes in above ground biomass accumulation, carbon based secondary metabolites (resin), non-structural carbohydrate (TNC) content, and relative growth rate (RGR). At low radiation levels, above ground biomass accumulation, RGR, resin, TNC content and CO2(Asteraceae) is a shrub native to Patagonia, Argentina, and can accumulate as much as 25% resin (on a dry weight basis) in leaves. The resin can be used in applications similar to those of pine resins. Reductions in available radiation are thought to decrease both the plant C:N ratio and resin production. The objective of this study was to assess the effect of light availability on the allocation of photoassimilates to biomass, resin (terpenes) and carbohydrates in G. chiloensis. To examine this, three radiation treatments were applied to ®eld grown plants: (i) 100% radiation (full-sun), (ii) 50% radiation and (iii) 25% photon ¯ux density radiation. Changes in available radiation resulted in signi®cant changes in above ground biomass accumulation, carbon based secondary metabolites (resin), non-structural carbohydrate (TNC) content, and relative growth rate (RGR). At low radiation levels, above ground biomass accumulation, RGR, resin, TNC content and CO2G. chiloensis. To examine this, three radiation treatments were applied to ®eld grown plants: (i) 100% radiation (full-sun), (ii) 50% radiation and (iii) 25% photon ¯ux density radiation. Changes in available radiation resulted in signi®cant changes in above ground biomass accumulation, carbon based secondary metabolites (resin), non-structural carbohydrate (TNC) content, and relative growth rate (RGR). At low radiation levels, above ground biomass accumulation, RGR, resin, TNC content and CO22 assimilation rate were highly reduced (from 150 to 80 g per plant, from 16 to 7%, and from 30.2 to 8.6 g per plant, for biomass, resin content, and resin production, respectively). The responses to low radiation found in G. chiloensis would limit productivity and the distribution of this species when grown under cultivation. # 2001 Elsevier Science B.V. All rights reserved.G. chiloensis would limit productivity and the distribution of this species when grown under cultivation. # 2001 Elsevier Science B.V. All rights reserved.# 2001 Elsevier Science B.V. All rights reserved.