Long-term responses of the green-algal lichen Parmelia caperata to natural CO 2 enrichment

Balaguer, Luís; Manrique, Esteban; Ríos, Asunción de los; Ascaso, Carmen; Palmqvist, Kristin; Fordham, M. C.; Barnes, J. D.

doi:10.1007/s004420050773

Cited by 19 publications

(12 citation statements)

References 35 publications

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“…However, in two recent studies, the amount of Rubisco could be quantified on a relative scale for a range of lichens with the use of gel electrophoresis (Palmqvist et al, 1998 ;Balaguer et al, 1999). It was found that P max across species was well correlated with both their Rubisco and Chl a concentrations.…”

Section: Light and Nitrogen Relationsmentioning

confidence: 99%

Tansley Review No. 117

Palmqvist

2000

New Phytologist

221

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Lichens are nutritionally specialized fungi (the mycobiont component) that derive carbon and in some cases nitrogen from algal or cyanobacterial photobionts. The mycobiont and photobiont live together in an integrated thallus, but they lack specific tissue for the transport of metabolites and resources between them. Carbon is acquired through photosynthesis in the photobiont, which is active when the lichen is wet and exposed to light. Lichen photosynthesis is limited primarily by water, light and nitrogen, but can also be constrained by slow diffusion of CO # within the wet thallus. The assimilated carbon is exported from photobiont to mycobiont, which also predominates in terms of biomass, and apparently regulates the size of the photobiont population. It has therefore generally been assumed that most of the carbon is used for growth and maintenance of the fungal hyphae. However, the extent of photobiont respiration in relation to mycobiont respiration has seldom been quantified ; neither do we know the pool sizes of various carbon sinks within lichens. Owing to this lack of fundamental data we do not know whether, or how, carbohydrate resources are regulated to maintain an optimal balance between energy input and expenditures in these symbiotic organisms. This review summarizes data on growth, carbon gain and carbon expenditures in lichens, with particular emphasis on factors determining the photosynthetic capacity of their photobionts. An attempt is made to introduce an economic analysis of lichen growth processes, a view that has often been adopted in studies of higher plants. Areas in which more data are needed for the construction of a model on ' lichen resource allocation patterns ' are discussed.

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Section: Light and Nitrogen Relationsmentioning

confidence: 99%

Tansley Review No. 117

Palmqvist

2000

New Phytologist

221

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“…1999). This work has focused primarily on multicellular plants, although a few studies of photosynthetic algae found in lichen exposed to CO 2 ‐enriched air from CO 2 springs have been published (Balaguer & Barnes 1999; Balaguer et al. 1999).…”

Section: Introductionmentioning

confidence: 99%

Evolution of natural algal populations at elevated CO₂

Collins¹,

Bell

2005

Ecology Letters

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Over the next century, it is expected that the concentration of CO(2) in the atmosphere will roughly double (Watson et al., 2001, Climate Change 2001: the Scientific Basis, Intergovernmental Panel on Climate Change, Geneva). Microbial populations, which have large population sizes and short generation times, may respond to CO(2) enrichment through genetic change. Here we describe microalgae isolated from the soil of natural CO(2) springs and compare these strains with lines of Chlamydomonas that were selected at elevated CO(2) in the laboratory. Both the laboratory and natural populations failed to evolve specific adaptations to elevated CO(2), and contain populations that grow poorly at ambient levels of CO(2). Laboratory and CO(2) spring populations also include lines whose growth rates are insensitive to CO(2). This demonstrates that, although laboratory selection experiments use simplified environments, the evolutionary responses that are seen following long-term CO(2) enrichment correspond to those found in natural populations that have experienced similar conditions.

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“…Many lichens appear to be saturated at lower CO 2 levels than L. muralis. Examples include Flavoparmelia caperata (400 ppm; Balaguer et al 1999), Sticta latifrons, Pseudocyphellaria billardierii, Peltigera dolichorhiza and Sphaerophorus ramulosum (450 ppm; Green & Snelgar 1981). These species might be expected to show little or F.…”

Section: Discussionmentioning

confidence: 99%

“…Some special situations have been investigated where mosses and lichens experience shorter or longer periods of naturally extremely elevated ambient CO 2 . Balaguer et al (1999) studied acclimation of a lichen to elevated CO 2 in the vicinity of a natural CO 2 spring. Tarnawski et al (1992) report an enormous increase in CO 2 concentration within and near to the phylloplane of cushion and turf forms of the antarctic moss Grimmia antarctici and this was confirmed by Green et al (2000) for another antarctic moss, Bryum subrotundifolium.…”

Section: Introductionmentioning

confidence: 99%

Diel and seasonal courses of ambient carbon dioxide concentration and their effect on productivity of the epilithic lichen Lecanora muralis in a temperate, suburban habitat

Lange

Green

2008

The Lichenologist

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Ambient CO 2 concentration (together with CO 2 exchange and microclimate) was recorded every 30 min for 15 months for Lecanora muralis growing in the Botanical Garden Wü rzburg (Germany, northern Bavaria), a habitat on the outskirts of the city. Annual mean CO 2 was around 17 ppm higher than the global average reported for the time of measurement (361 ppm; 1995/96), and daily values ranged from 317 to 490 ppm. Diel courses of CO 2 could be classified into three different types. Type A, when CO 2 levels rose overnight and then fell strongly to below global levels during the day, which predominated in the summer (about 75% of days); Type B, irregular diel courses occurred during all seasons with often very rapid changes apparently due to advective CO 2 transport; Type C, CO 2 concentration was typically almost stable at generally between c. 330 and 430 ppm which predominated in the winter (63% of days).Under controlled conditions, CO 2 saturation of net photosynthesis (NP) of L. muralis at optimal hydration and light occurred at around 1000 ppm. NP was also affected by low CO 2 at limiting light and thallus water contents. Based upon these data, we estimated the improvement of NP of L. muralis due to transient increase of ambient CO 2 (as compared with the global average) for one selected combination of environmental factors (nocturnal dew or frost). This combination is an important source of water for the lichen, resulting in 40% of its annual production and, especially in these situations, photosynthesis was increased by high ambient CO 2 in the early morning under prevailing Type A conditions. After dew activation, light compensation point of NP occurred at an average concentration of 413 ppm and diel maxima of NP at 402 ppm. This allows a rough estimate that the transiently elevated CO 2 increased the photosynthetic gain of the lichen after dew of 7%, or an improvement to its annual carbon balance of about 3%. Conditions, especially interrelationships between lichen hydration, light and CO 2 are so complex that we are not yet able to extend our estimates to other environmental situations of photosynthetic activity of L. muralis.

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Long-term responses of the green-algal lichen Parmelia caperata to natural CO 2 enrichment

Cited by 19 publications

References 35 publications

Tansley Review No. 117

Tansley Review No. 117

Evolution of natural algal populations at elevated CO₂

Diel and seasonal courses of ambient carbon dioxide concentration and their effect on productivity of the epilithic lichen Lecanora muralis in a temperate, suburban habitat

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Long-term responses of the green-algal lichen Parmelia caperata to natural CO 2 enrichment

Cited by 19 publications

References 35 publications

Tansley Review No. 117

Tansley Review No. 117

Evolution of natural algal populations at elevated CO2

Diel and seasonal courses of ambient carbon dioxide concentration and their effect on productivity of the epilithic lichen Lecanora muralis in a temperate, suburban habitat

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Evolution of natural algal populations at elevated CO₂