Detection of photochemical processes in Antarctic lichen
Xanthoria elegans using chlorophyll fluorescence imaging.

D 2004

Detection of photochemical processes in Antarctic lichen Xanthoria elegans using chlorophyll fluorescence imaging.

BARTÁK, Miloš a Jan GLOSER

Základní údaje

Originální název

Detection of photochemical processes in Antarctic lichen Xanthoria elegans using chlorophyll fluorescence imaging.

Název česky

Detekce fotochemických procesů u antarktického lišejníku Xanthoria elegans s využitím zobrazovacích technik fluorescence chlorofylu.

Autoři

BARTÁK, Miloš (203 Česká republika, garant) a Jan GLOSER (203 Česká republika)

Vydání

Bratislava, Slovakia, Book of Abstracts. Xth Days of Plant Physiology. s. 61-61, 2004

Nakladatel

Faculty of Natural Sciences, Comenius University,

Další údaje

Jazyk

angličtina

Typ výsledku

Stať ve sborníku

Obor

10600 1.6 Biological sciences

Stát vydavatele

Slovensko

Utajení

není předmětem státního či obchodního tajemství

Kód RIV

RIV/00216224:14310/04:00021226

Organizační jednotka

Přírodovědecká fakulta

Klíčová slova anglicky

photosynthesis; dehydration; Antarctica; lichen; physiological activity

Štítky

Antarctica, dehydration, lichen, photosynthesis, physiological activity

Změněno: 26. 5. 2006 11:08, prof. Ing. Miloš Barták, CSc.

Anotace

ORIG CZ

V originále

Introduction: Within last two decades, chlorophyll fluorescence imaging has met increasing number of applications in photosynthesis research. Using the technique, heterogeneity of photochemical processes of photosynthesis might be visualized at various levels ranging from a single cell to a plant community. In lichens, the technique has been used several times in anatomic[1] and photosynthetic studies made under controlled laboratory conditions[2]. In the presented study, we used the technique in the field in order to quantify photosynthetic processes in an epilithic crustose lichen species (Xanthoria elegans) as dependent on daily courses of in situ temperature, water availability and resulting hydration/dehydration of lichen thallus. Material and Methods: Heterogeneity of several photosynthetic chlorophyll (Chl) fluorescence parameters was measured on thalli of X. elegans attached to stone surfaces. Study plot was located at permanently deglaciated coastal areas of Galindez Island (64 W, 65 S, maritime Antarctica) in the vicinity of Ukrainian antarctic station Vernadsky (former Faraday). In March 2004, potential yield of photochemical reactions in photosystem II (Fv/Fm) and quantum yield of photosystem II (FII) were measured using a portable fluorometer HFC-010 (Photon Systems Instruments, Czech Republic) equipped with a CCD camera and image analysis system. The set up allowed to record 512 x 512 pixel grey scale images of X. elegans thalli with maximum recording rate of 20 ms. To visualize time courses of Chl fluorescence parameters, the grey scale images were converted to false colour images. The images of Fv/Fm and FII distribution over a thallus were taken repeatedly during a daytime and analyzed in relation to daily courses of temperature and thallus hydration. Aditionally, photosynthetic gas exchange and water potential measurements of thalli were made using a portable IR gas analyzer EGM-3 (PP Sytems, United Kingdom) and water potential meter WP4-T (Decagon, USA). Results and discussion: Field measurements revealed that hydration status of thallus is main limiting factor of photosynthetic processes in X. elegans. Maximum daily values of Fv/Fm and FII were found after rainfall and/or snowfall episodes when thalli reached optimum hydration. With ongoing desiccation of thalli caused by above-zero thallus temperature and wind velocity, gradual decrease of Fv/Fm and FII was recorded. Dehydration-dependent reduction and loss of photosynthetic activity was related to thallus age and structure. Intrathalline differences of Fv/Fm and FII in drying thallus caused heterogeneity of photosynthetic processes within a single thallus. Critical water potential for primary photosynthetic processes was about -30 MPa. Chl fluorescence imaging and water potential measurements documented that X. elegans is capable to maintain some detectable photosynthetic activity even at extremely low water potential of its thallus. This gives the species an advantage to prolong positive carbon balance during periods with suboptimal hydration.

Česky

V prezentované studii jsme použili metodu chlorphyll fluorescence imaging v terénních podmínkách při měření fotosynteticých procesů epilitického lišejníku (Xanthoria elegans), a to v závislosti na denním chodu teploty, dostupnosti vody a stupni ovlhčení stélky.

Návaznosti

MSM 143100007, záměr

Název: Ekologie pobřežní antarktické vegetační oázy

Investor: Ministerstvo školství, mládeže a tělovýchovy ČR, Ekologie pobřežní antarktické vegetační oázy

Citovat

BARTÁK, Miloš a Jan GLOSER. Detection of photochemical processes in Antarctic lichen Xanthoria elegans using chlorophyll fluorescence imaging. In Book of Abstracts. Xth Days of Plant Physiology. Bratislava, Slovakia: Faculty of Natural Sciences, Comenius University,, 2004, s. 61.

@inproceedings{557815,
   author = {Barták, Miloš and Gloser, Jan},
   address = {Bratislava, Slovakia},
   booktitle = {Book of Abstracts. Xth Days of Plant Physiology.},
   keywords = {photosynthesis; dehydration; Antarctica; lichen; physiological activity},
   language = {eng},
   location = {Bratislava, Slovakia},
   pages = {61-61},
   publisher = {Faculty of Natural Sciences, Comenius University,},
   title = {Detection of photochemical processes in Antarctic lichen Xanthoria elegans using chlorophyll fluorescence imaging.},
   year = {2004}
}

TY  - JOUR
ID  - 557815
AU  - Barták, Miloš - Gloser, Jan
PY  - 2004
TI  - Detection of photochemical processes in Antarctic lichen Xanthoria elegans using chlorophyll fluorescence imaging.
PB  - Faculty of Natural Sciences, Comenius University,
CY  - Bratislava, Slovakia
KW  - photosynthesis
KW  - dehydration
KW  - Antarctica
KW  - lichen
KW  - physiological activity
N2  - Introduction: Within last two decades, chlorophyll fluorescence imaging has met increasing number of applications in photosynthesis research. Using the technique, heterogeneity of photochemical processes of photosynthesis might be visualized at various levels ranging from a single cell to a plant community. In lichens, the technique has been used several times in anatomic[1] and photosynthetic studies made under controlled laboratory conditions[2]. In the presented study, we used the technique in the field in order to quantify photosynthetic processes in an epilithic crustose lichen species (Xanthoria elegans) as dependent on daily courses of in situ temperature, water availability and resulting hydration/dehydration of lichen thallus. Material and Methods: Heterogeneity of several photosynthetic chlorophyll (Chl) fluorescence parameters was measured on thalli of X. elegans attached to stone surfaces. Study plot was located at permanently deglaciated coastal areas of Galindez Island (64 W, 65 S, maritime Antarctica) in the vicinity of Ukrainian antarctic station Vernadsky (former Faraday). In March 2004, potential yield of photochemical reactions in photosystem II (Fv/Fm) and quantum yield of photosystem II (FII) were measured using a portable fluorometer HFC-010 (Photon Systems Instruments, Czech Republic) equipped with a CCD camera and image analysis system. The set up allowed to record 512 x 512 pixel grey scale images of X. elegans thalli with maximum recording rate of 20 ms. To visualize time courses of Chl fluorescence parameters, the grey scale images were converted to false colour images. The images of Fv/Fm and FII distribution over a thallus were taken repeatedly during a daytime and analyzed in relation to daily courses of temperature and thallus hydration. Aditionally, photosynthetic gas exchange and water potential measurements of thalli were made using a portable IR gas analyzer EGM-3 (PP Sytems, United Kingdom) and water potential meter WP4-T (Decagon, USA). Results and discussion: Field measurements revealed that hydration status of thallus is main limiting factor of photosynthetic processes in X. elegans. Maximum daily values of Fv/Fm and FII were found after rainfall and/or snowfall episodes when thalli reached optimum hydration. With ongoing desiccation of thalli caused by above-zero thallus temperature and wind velocity, gradual decrease of Fv/Fm and FII was recorded. Dehydration-dependent reduction and loss of photosynthetic activity was related to thallus age and structure. Intrathalline differences of Fv/Fm and FII in drying thallus caused heterogeneity of photosynthetic processes within a single thallus. Critical water potential for primary photosynthetic processes was about -30 MPa. Chl fluorescence imaging and water potential measurements documented that X. elegans is capable to maintain some detectable photosynthetic activity even at extremely low water potential of its thallus. This gives the species an advantage to prolong positive carbon balance during periods with suboptimal hydration.
ER  -

BARTÁK, Miloš a Jan GLOSER. Detection of photochemical processes in Antarctic lichen $<$i$>$Xanthoria elegans$<$/i$>$ using chlorophyll fluorescence imaging. In \textit{Book of Abstracts. Xth Days of Plant Physiology.}. Bratislava, Slovakia: Faculty of Natural Sciences, Comenius University,, 2004, s.~61.

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