Photosynthesis-nitrogen relationships in pioneer plants of disturbed tropical montane forest sites

Title:

Photosynthesis-nitrogen relationships in pioneer plants of disturbed tropical montane forest sites

Creator:

Quilici, A. and Medina, E.

Identifier:

https://cdk.lib.cas.cz/client/handle/uuid:1c5a476f-3b73-44b2-9d8c-a78b8ab45597
uuid:1c5a476f-3b73-44b2-9d8c-a78b8ab45597
issn:0300-3604
doi:10.1023/A:1006974806455

Subject:

Crotalaria anagyroides, ecological succession, nitrogen use efficiency, respiration, saccharides, specific leaf area, stomatal conductance, Verbesina turbacensis, and water use efficiency

Type:

model:article and TEXT

Format:

bez média and svazek

Description:

Tropical forest disturbances lead to the establishment of secondary successional plant communities constituted by light demanding species with high relative growth rate that conduct to rapid canopy closure. Two main strategies for N nutrition are: (a) mineral N acquisition in the form of NH4 and NO3, and (b) symbiotic atmospheric N2 fixation. Given the high N requirement for maximization of leaf area and radiant energy absorption, we hypothesize that contrasting strategies of N nutrition in these environments are reflected in leaf photosynthetic characteristics. We compared the N-photosynthesis relationships and carbon balance parameters per unit leaf area as they vary with age in two species with contrasting N acquisition strategies: a N2-fixer Crotalaria anagyroides HBK (Papilionoideae), and a mineral-N user Verbesina turbacensis HBK (Asteraceae). N2 fixation capacity was associated to higher specific leaf area (SLA), higher photosynthetic capacity (Pmax) per unit leaf area and leaf mass, and higher N content per unit leaf mass. The N2-fixer species showed higher slope in the relationship Pmax-N per unit leaf mass and area when compared to the leaves of non-fixer species. Moreover, the intrinsic photosynthetic N use efficiency (Pmax/N) was higher in the N2 fixer than in leaves of the non-fixer species. Changes in N due to leaf age resulted in larger changes in CO2 flux density at the leaf level in the N2-fixer species. The higher photosynthetic capacity of the N2-fixer species was mechanistically related to higher stomatal conductance, internal CO2 concentration (ci) values closer to atmospheric CO2 concentration (ca), and lower intrinsic water use efficiency than the mineral N-user species. Despite their higher Pmax per unit leaf area, total non-structural saccharides concentration was lower in mature leaves of the N2-fixer plant as compared to the non-fixer counterpart. This might be caused by the presence of a larger root sink (symbionts) stimulating saccharides export and higher diurnal respiration rates. and A. Quilici, E. Medina.

Language:

Multiple languages

Rights:

http://creativecommons.org/licenses/by-nc-sa/4.0/
policy:public

Coverage:

525-534

Source:

Photosynthetica | 1998 Volume:35 | Number:4

Harvested from:

CDK

Metadata only:

false