TY - JOUR
T1 - The effect of phosphorus availability on the carbon economy of contrasting common bean (phaseolus vulgaris l.) genotypes
AU - Nielsen, Kai L.
AU - Eshel, Amram
AU - Lynch, Jonathan P.
N1 - Funding Information:
The authors thank Dr Douglas Beck, CIAT, for helpful discussions and for providing the seeds for this experiment. This research was supported by USDA/NRI grants 94371000311 and 99-351007596 to JPL, and BARD grant 294997R to AE, Kathleen Brown and JPL.
PY - 2001
Y1 - 2001
N2 - A common response to low phosphorus availability is increased relative biomass allocation to roots. The resulting increase in root:shoot ratio presumably enhances phosphorus acquisition, but may also reduce growth rates by diverting carbon to the production of heterotrophic rather than photosynthetic tissues. To assess the importance of increased carbon allocation to roots for the adaptation of plants to low P availability, carbon budgets were constructed for four common bean genotypes with contrasting adaptation to low phosphorus availability in the field ('phosphorus efficiency'). Solid-phase-buffered silica sand provided low (1 μM), medium (10 μM), and high (30 μM) phosphorus availability. Compared to the high phosphorus treatment, plant growth was reduced by 20% by medium phosphorus availability and by more than 90% by low phosphorus availability. Low phosphorus plants utilized a significantly larger fraction of their daytime net carbon assimilation on root respiration (c. 40%) compared to medium and high phosphorus plants (c. 20%). No significant difference was found among genotypes in this respect. Genotypes also had similar rates of P absorption per unit root weight and plant growth per unit of P absorbed. However, P-efficient genotypes allocated a larger fraction of their biomass to root growth, especially under low P conditions. Efficient genotypes had lower rates of root respiration than inefficient genotypes, which enabled them to maintain greater root biomass allocation than inefficient genotypes without increasing overall root carbon costs.
AB - A common response to low phosphorus availability is increased relative biomass allocation to roots. The resulting increase in root:shoot ratio presumably enhances phosphorus acquisition, but may also reduce growth rates by diverting carbon to the production of heterotrophic rather than photosynthetic tissues. To assess the importance of increased carbon allocation to roots for the adaptation of plants to low P availability, carbon budgets were constructed for four common bean genotypes with contrasting adaptation to low phosphorus availability in the field ('phosphorus efficiency'). Solid-phase-buffered silica sand provided low (1 μM), medium (10 μM), and high (30 μM) phosphorus availability. Compared to the high phosphorus treatment, plant growth was reduced by 20% by medium phosphorus availability and by more than 90% by low phosphorus availability. Low phosphorus plants utilized a significantly larger fraction of their daytime net carbon assimilation on root respiration (c. 40%) compared to medium and high phosphorus plants (c. 20%). No significant difference was found among genotypes in this respect. Genotypes also had similar rates of P absorption per unit root weight and plant growth per unit of P absorbed. However, P-efficient genotypes allocated a larger fraction of their biomass to root growth, especially under low P conditions. Efficient genotypes had lower rates of root respiration than inefficient genotypes, which enabled them to maintain greater root biomass allocation than inefficient genotypes without increasing overall root carbon costs.
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U2 - 10.1093/jxb/52.355.329
DO - 10.1093/jxb/52.355.329
M3 - Article
C2 - 11283178
AN - SCOPUS:0035063601
SN - 0022-0957
VL - 52
SP - 329
EP - 339
JO - Journal of experimental botany
JF - Journal of experimental botany
IS - 355
ER -