Seasonal changes in photosynthesis and water-use efficiency of savanna species and eucalypts in Venezuela

Herrera, Ana; Ballestrini, Caín; Urich, Rosa; Rengifo, Elizabeth; González, Armando

Abstract

Eucalypt plantations in Venezuela occupy 14% of land covered by savannas. Since water use by plantations in the savannas of Mapire (Venezuelan Llanos) was apparently similar to or lower than in the natural vegetation, evaluating how carbon fixation by plantations compares to the natural vegetation could help to elucidate whether plantations have higher water-use efficiency (WUE) than the savanna. We aimed to determine, using measurements of leaf gas exchange, the seasonal changes in photosynthetic rate (P N) and WUE of a seasonally dry savanna in Mapire, composed mainly of the grass Trachypogon vestitus and the tree Curatella americana, and trees of Eucalyptus urophylla growing in an experimental plantation. Daily integrated WUE (WUEint) was highest in C. americana and similar between T. vestitus and E. urophylla during both seasons. The Gross carbon fixation (GCF) at the leaf level in T. vestitus was similar to C. americana and lower than E. urophylla during the dry season, whereas during the rainy season it was nearly as high as in E. urophylla and both higher than C. americana. Gross carbon fixation (GCF) in T. vestitus was higher than in C. americana, but lower than in E. urophylla during the dry season, while it was much higher than the other two species during the rainy season. The contribution to savanna GCF of C. americana was small and constant throughout the seasons. The GCF in eucalypts was 15% higher than in the savanna during the dry season, but 45% lower during the rainy season, GCF averaging 85% of that in the savanna. Since water use by plantations is lower than in the savanna, they have a large potential for C sequestration without significantly altering ground water availability.

dry season; gross primary production; rainy season

Albrecht A, Kandji ST (2003) Carbon sequestration in tropical agroforestry systems. Agriculture, Ecosystems and Environment 99:15-27.
Baruch Z, Bilbao B (1999) Effects of fire and defoliation on the life history of native and invader C₄ grasses in a Neotropical savanna. Oecologia 119:510-520.
Cabral OMR, Gash JHC, Rocha HR, Marsden C, Ligo MAV, Freitas HC, Tatsch JD, Gomes E (2011) Fluxes of CO₂ above a plantation of Eucalyptus in southeast Brazil. Agricultural and Forest Meteorology 151:49-59.
Chen D, Zhang C, Wu J, Zhou L, Lin Y, Fu S (2011) Subtropical plantations are large carbon sinks: Evidence from two monoculture plantations in South China. Agriculture, Ecosystems and Environment 151:1214-1225.
Cook GD, Liedloff AC, Eager RW, Chen X, Williams RJ, O'Grady AP, Hutley LB (2005) The estimation of carbon budgets of frequently burnt tree stands in savannas of northern Australia, using allometric analysis and isotopic discrimination. Australian Journal of Botany 53:621-630.
Dezzeo N, Flores S, Zambrano-Martínez S, Rodgers L, Ochoa E (2008) Estructura y composición florística de bosques secos y sabanas en los llanos orientales del Orinoco, Venezuela. Interciencia 33:733-740.
Dye PJ, Olbrich BW (1993) Estimating transpiration from 6-year-old Eucalyptus grandis trees: development of a canopy conductance model and comparison with independent sap flux measurements. Plant, Cell and Environment 16:45-53.
Farquhar GD, Ehleringer JR, Hubick KT (1989) Carbon isotope discrimination and photosynthesis. Annual Review of Plant Physiology and Plant Molecular Biology 40:503-537.
Feistler AM, Habermann G (2012) Assessing the role of vertical leaves within the photosynthetic function of Styrax camporum under drought conditions. Photosynthetica 50: 613-622.
Goldstein G, Rada F, Rundel P, Azocar A, Orozco A (1989). Gas exchange and water relations of evergreen and deciduous tropical savanna trees. Annales des Sciences Forestières 46:448-453.
González R, Stock J, Jerez M, Carrero G, Plonczak M, Schutte F (2005) Análisis biológico y financiero de un ensayo de fertilización en plantaciones de Eucalyptus urophylla establecidas en suelos arenosos del oriente de Venezuela. Revista Forestal Venezolana 49:175-181.
Habermann G, Machado SR, Guimarães VF, Rodrigues JD (2008) Leaf heliotropism in Styrax camporum Pohl. from the Brazilian Cerrado - distinct gas exchange and leaf structure, but similar leaf temperature and water relations Brazilian Journal of Plant Physiology 20, 71-83.
Herrera A, Urich R, Rengifo E, Ballestrini C, González A, León W (2012) Transpiration in a eucalypt plantation and a savanna in Venezuela. Trees 26:1759-1769.
Jones HG (1983) Plants and Microclimate. Cambridge University Press, Cambridge, pp. 281-282.
Medina E, Mendoza A, Montes R (1978) Nutrient balance and organic matter production in the Trachypogon savannas of Venezuela. Tropical Agriculture 55:243-253.
Medina E, Francisco M (1994) Photosynthesis and water relations of savanna tree species differing in leaf phenology. Tree Physiology 14:1367-1381.
O'Grady AP, Chen X, Eamus D, Hutley LB (2000) Composition, structure, leaf area index and standing biomass of a eucalypt open forest near Darwin in the Northern Territory. Australian Journal of Botany 48:629-638.
Poorter H, Grace J (1997) The fate of acquired carbon in plants: chemical composition and construction costs. In: Bazzaz FA, Grace J (eds.) Plant Resource Allocation, pp 53-61. Academic Press, San Diego, California.
San José JJ, Montes RA, Fariñas MR (1998) Carbon stocks and fluxes in a temporal scaling from a savanna to a semi-deciduous forest. Forest Ecology and Management 105:251-262.
San José JJ, Montes RA (2001) Management effects on carbon stocks and fluxes across the Orinoco savannas. Forest Ecology and Management 150:293-311.
San José JJ, Montes RA, Rocha C (2003) Neotropical savanna converted to food cropping and cattle feeding systems: soil carbon and nitrogen changes over 30 years. Forest Ecology and Management 184:17-32.
San José JJ, Montes R, Grace J, Nikonova N, Osío A (2008) Land-use changes alter radiative energy and water vapor fluxes of a tall-grass Andropogon field and a savanna-woodland continuum in the Orinoco lowlands. Tree Physiology 28:425-435.
Schulze ED, Hall AE (1982) Stomatal responses, water loss and CO₂ assimilation rates of plants in contrasting environment. In: Lange OL, Nobel PS, Osmond CB, Ziegler H (Eds). Physiological Plant Ecology II, pp. 181-230. Springer-Verlag, New York.
Tezara W, Fernandez MD, Donoso C, Herrera A (1998) Seasonal changes in photosynthesis and stomatal conductance of five plant species from a semiarid ecosystem. Photosynthetica 35:399-410.
Turner NC, Schulze ED, Nicolle D, Schumacher J, Kuhlmann I (2008) Annual rainfall does not directly determine the carbon isotope ratio of leaves of Eucalyptus species. Physiologia Plantarum 132:440-445.
White DA, Turner NC, Galbraith JH (2000) Leaf water relations and stomatal behaviour of four allopatric Eucalyptus species planted in Mediterranean southwestern Australia. Tree Physiology 20:1157-1165.
Whitehead W, Beadle CL (2004) Physiological regulation of productivity and water use in Eucalyptus: a review. Forest Ecology and Management 193:113-140.

Publication Dates

Publication in this collection
15 Oct 2013
Date of issue
2013

History

Received
12 Apr 2013
Accepted
26 June 2013

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Albrecht A, Kandji ST (2003) Carbon sequestration in tropical agroforestry systems. Agriculture, Ecosystems and Environment 99:15-27.

[2] Baruch Z, Bilbao B (1999) Effects of fire and defoliation on the life history of native and invader C₄ grasses in a Neotropical savanna. Oecologia 119:510-520.

[3] Cabral OMR, Gash JHC, Rocha HR, Marsden C, Ligo MAV, Freitas HC, Tatsch JD, Gomes E (2011) Fluxes of CO₂ above a plantation of Eucalyptus in southeast Brazil. Agricultural and Forest Meteorology 151:49-59.

[4] Chen D, Zhang C, Wu J, Zhou L, Lin Y, Fu S (2011) Subtropical plantations are large carbon sinks: Evidence from two monoculture plantations in South China. Agriculture, Ecosystems and Environment 151:1214-1225.

[5] Cook GD, Liedloff AC, Eager RW, Chen X, Williams RJ, O'Grady AP, Hutley LB (2005) The estimation of carbon budgets of frequently burnt tree stands in savannas of northern Australia, using allometric analysis and isotopic discrimination. Australian Journal of Botany 53:621-630.

[6] Dezzeo N, Flores S, Zambrano-Martínez S, Rodgers L, Ochoa E (2008) Estructura y composición florística de bosques secos y sabanas en los llanos orientales del Orinoco, Venezuela. Interciencia 33:733-740.

[7] Dye PJ, Olbrich BW (1993) Estimating transpiration from 6-year-old Eucalyptus grandis trees: development of a canopy conductance model and comparison with independent sap flux measurements. Plant, Cell and Environment 16:45-53.

[8] Farquhar GD, Ehleringer JR, Hubick KT (1989) Carbon isotope discrimination and photosynthesis. Annual Review of Plant Physiology and Plant Molecular Biology 40:503-537.

[9] Feistler AM, Habermann G (2012) Assessing the role of vertical leaves within the photosynthetic function of Styrax camporum under drought conditions. Photosynthetica 50: 613-622.

[10] Goldstein G, Rada F, Rundel P, Azocar A, Orozco A (1989). Gas exchange and water relations of evergreen and deciduous tropical savanna trees. Annales des Sciences Forestières 46:448-453.

[11] González R, Stock J, Jerez M, Carrero G, Plonczak M, Schutte F (2005) Análisis biológico y financiero de un ensayo de fertilización en plantaciones de Eucalyptus urophylla establecidas en suelos arenosos del oriente de Venezuela. Revista Forestal Venezolana 49:175-181.

[12] Habermann G, Machado SR, Guimarães VF, Rodrigues JD (2008) Leaf heliotropism in Styrax camporum Pohl. from the Brazilian Cerrado - distinct gas exchange and leaf structure, but similar leaf temperature and water relations Brazilian Journal of Plant Physiology 20, 71-83.

[13] Herrera A, Urich R, Rengifo E, Ballestrini C, González A, León W (2012) Transpiration in a eucalypt plantation and a savanna in Venezuela. Trees 26:1759-1769.

[14] Jones HG (1983) Plants and Microclimate. Cambridge University Press, Cambridge, pp. 281-282.

[15] Medina E, Mendoza A, Montes R (1978) Nutrient balance and organic matter production in the Trachypogon savannas of Venezuela. Tropical Agriculture 55:243-253.

[16] Medina E, Francisco M (1994) Photosynthesis and water relations of savanna tree species differing in leaf phenology. Tree Physiology 14:1367-1381.

[17] O'Grady AP, Chen X, Eamus D, Hutley LB (2000) Composition, structure, leaf area index and standing biomass of a eucalypt open forest near Darwin in the Northern Territory. Australian Journal of Botany 48:629-638.

[18] Poorter H, Grace J (1997) The fate of acquired carbon in plants: chemical composition and construction costs. In: Bazzaz FA, Grace J (eds.) Plant Resource Allocation, pp 53-61. Academic Press, San Diego, California.

[19] San José JJ, Montes RA, Fariñas MR (1998) Carbon stocks and fluxes in a temporal scaling from a savanna to a semi-deciduous forest. Forest Ecology and Management 105:251-262.

[20] San José JJ, Montes RA (2001) Management effects on carbon stocks and fluxes across the Orinoco savannas. Forest Ecology and Management 150:293-311.

[21] San José JJ, Montes RA, Rocha C (2003) Neotropical savanna converted to food cropping and cattle feeding systems: soil carbon and nitrogen changes over 30 years. Forest Ecology and Management 184:17-32.

[22] San José JJ, Montes R, Grace J, Nikonova N, Osío A (2008) Land-use changes alter radiative energy and water vapor fluxes of a tall-grass Andropogon field and a savanna-woodland continuum in the Orinoco lowlands. Tree Physiology 28:425-435.

[23] Schulze ED, Hall AE (1982) Stomatal responses, water loss and CO₂ assimilation rates of plants in contrasting environment. In: Lange OL, Nobel PS, Osmond CB, Ziegler H (Eds). Physiological Plant Ecology II, pp. 181-230. Springer-Verlag, New York.

[24] Tezara W, Fernandez MD, Donoso C, Herrera A (1998) Seasonal changes in photosynthesis and stomatal conductance of five plant species from a semiarid ecosystem. Photosynthetica 35:399-410.

[25] Turner NC, Schulze ED, Nicolle D, Schumacher J, Kuhlmann I (2008) Annual rainfall does not directly determine the carbon isotope ratio of leaves of Eucalyptus species. Physiologia Plantarum 132:440-445.

[26] White DA, Turner NC, Galbraith JH (2000) Leaf water relations and stomatal behaviour of four allopatric Eucalyptus species planted in Mediterranean southwestern Australia. Tree Physiology 20:1157-1165.

[27] Whitehead W, Beadle CL (2004) Physiological regulation of productivity and water use in Eucalyptus: a review. Forest Ecology and Management 193:113-140.

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Seasonal changes in photosynthesis and water-use efficiency of savanna species and eucalypts in Venezuela

Abstract

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History