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M. Tsimilli-Michael, R.J. Strasser (2008)
In vivo assessment of stress impact on plants’ vitality: applications in detecting and evaluating the beneficial role of mycorrhization on host plantsin Mycorrhiza: State of the Art, Genetics and Molecular Biology, Eco-Function, Biotechnology, Eco-Physiology, Structure and Systematics, 3
S.A. Parker (1968)
Photoluminescence of Solutions
J. Flexas, J.M. Escalona, S. Evain, J. Gulías, I. Moya, C.B. Osmond, H. Medrano (2002)
Steadystate chlorophyll fluorescence (Fs) measurements as a tool to follow variations of net CO2 assimilation and stomatal conductance during water-stress in C3 plantsPhysiol. Plant., 114
H.M. Kalaji (2014)
347
L.O. Björn, G.C. Papageorgiou, R.E. Blankenship, A. Govindjee (2009)
viewpoint: why chlorophyll aPhotosynth. Res., 99
M. Tsimilli-Michael (2008)
679in Mycorrhiza: State of the Art, Genetics and Molecular Biology, Eco-Function, Biotechnology, Eco-Physiology, Structure and Systematics, 3
H. Kautsky, A. Hirsch (1931)
Neue Versuche zur KohlensäureassimilationNaturwissenschaften, 19
H.M. Kalaji, G. Schansker, R.J. Ladle, V. Goltsev, K. Bosa, S.I. Allakhverdiev, M. Brestic, F. Bussotti, A. Calatayud, P. Dabrowski, N.I. Elsheery, L. Ferroni, L. Guidi, S.W. Hogewoning, A. Jajoo (2014)
Frequently asked questions about in vivo chlorophyll fluorescence: practical issuesPhotosynth. Res., 122
R.J. Strasser, A. Srivastava, M. Tsimilli-Michael (2000)
Probing Photosynthesis: Mechanism, Regulation and Adaptation
M.H. Kalaji, S. Pietkiewicz (2004)
Some physiological indices to be exploited as a crucial tool in plant breedingPlant Breed. Seeds Sci., 49
K.V. Neverov, S. Santabarbara, A.A. Krasnovsky (2011)
Phosphorescence study of chlorophyll d photophysics. Determination of the energy and lifetime of the photo-excited triplet state. Evidence of singlet oxygen photosensitizationPhotosynth. Res., 108
M.H. Kalaji (2004)
19Plant Breed. Seeds Sci., 49
B.J. Strasser, R.J. Strasser (1995)
Measuring fast fluorescence transients to address environmental questions: the JIP testPhotosynthesis: from Light to Biosphere, 5
A. Stirbet, A. Govindjee (2012)
Chlorophyll a fluorescence induction: a personal perspective of the thermal phase,the J-I-P risePhotosynth. Res., 113
E. Skórska (2000)
Reakcja wybranych roslin uprawnych na promieniowanie UV-B
D. Lazar (1999)
Chlorophyll a fluorescence inductionBiochim. Biophys. Acta, 1412
M. Terazima, N. Hirota, S.E. Braslavsky, A. Mandelis, S.E. Bialkowski, G.J. Diebold, R.J.D. Miller, D. Fournier, R.A. Palmer, A. Tam (2004)
Quantitiesterminology, and symbols in photothermal and related spectroscopies, Pure Appl. Chem., 76
S.E. Braslavsky (2007)
Glossary of terms used in photochemistry 3rd edition3rd edition, Pure Appl. Chem., 79
M.H. Kalaji, P. Guo (2008)
Photochemistry Research Progress
R.J. Strasser, M. Tsimilli-Michael, A. Srivastava (2004)
Chlorophyll a Fluorescence: A Signature of Photosynthesis, Vol. 19: Advances in Photosynthesis and Respiration
J. Kuckenberg, I. Tartachnyk, G. Noga (2008)
Evaluation of fluorescence and remission techniques for monitoring changes in peel chlorophyll and internal fruit characteristics in sunlit and shaded sides of apple fruit during shelf-lifePostharvest Biol. Tec., 48
A. Murkowski (2002)
Oddzialywanie czynników stresowych na luminescencje chlorofilu w aparacie fotosyntetycznym roslin uprawnych
H. v d Jalink, R. Schoor, A. Frandas, J.G. Pijlen, R.J. Bino (1998)
Chlorophyll fluorescence of Brassica oleracea seeds as a non-destructive marker for seed maturity and seed performanceSeed Sci. Res., 8
H.W. Trissl, Y. Gao, K. Wulf (1993)
Theoretical fluorescence induction curves derived from coupled differential equations describing the primary photochemistry of photosystem II by an exciton/radical pair equilibriumBiophys. J., 64
G.H. Mohammed, W.D. Binder, S.L. Gillies (1995)
Chlorophyll fluorescence: a review of its practical forestry applications and instrumentationScand. J. Forest Res., 10
H.M. Kalaji (2014)
121Photosynth. Res., 122
G.H. Krause, E. Weis (1991)
Chlorophyll fluorescence and photosynthesis: the basicsAnnu Rev. Plant Physiol., 42
H. Kalaji, V. Goltsev, K. Bosa, S.I. Allakhverdiev, R. Strasser (2012)
Experimental in vivo measurements of light emission in plants: a perspective dedicated to David WalkerPhotosynth. Res., 114
H.M. Kalaji, A. Jajoo, A. Oukarroum, M. Brestic, M. Zivcak, I. Samborska, M.D. Cetner, V. Goltsev, R.J. Ladle, P. Dabrowski, P. Ahmad (2014)
Emerging Technologies and Management of Crop Stress Tolerance
G. Papageorgiou (1975)
Chlorophyll fluorescence: an intrinsic probe of photosynthesis, Bioenergetics of Photosynthesis
E. Tyystjarvi, I. Vass (2004)
Chlorophyll a Fluorescence: A Signature of Photosynthesis
H.K. Lichtenthaler, U. Rinderle (1988)
The role of chlorophyll fluorescence in the detection of stress conditions in plantsCRC Crit. Rev. Anal. Chem., 19
R. Strasser (1991)
Regulation of Chloroplast Biogenesis
Analysis of plant behavior under diverse environmental conditions would be impossible without the methods for adequate assessment of the processes occurring in plants. The photosynthetic apparatus and its reaction to stress factors provide a reliable source of information on plant condition. One of the most informative methods based on monitoring the plant biophysical characteristics consists in detection and analysis of chlorophyll a fluorescence. Fluorescence is mainly emitted by chlorophyll a from the antenna complexes of photosystem II (PSII). However, fluorescence depends not only on the processes in the pigment matrix or PSII reaction centers but also on the redox reactions at the PSII donor and acceptor sides and even in the entire electron transport chain. Presently, a large variety of fluorometers from various manufacturers are available. Although application of such fluorometers does not require specialized training, the correct interpretation of the results would need sufficient knowledge for converting the instrumental data into the information on the condition of analyzed plants. This review is intended for a wide range of specialists employing fluorescence techniques for monitoring the physiological plant condition. It describes in a comprehensible way the theoretical basis of light emission by chlorophyll molecules, the origin of variable fluorescence, as well as relations between the fluorescence parameters, the redox state of electron carriers, and the light reactions of photosynthesis. Approaches to processing and analyzing the fluorescence induction curves are considered in detail on the basis of energy flux theory in the photosynthetic apparatus developed by Prof. Reto J. Strasser and known as a “JIP-test.” The physical meaning and relation of each calculated parameter to certain photosynthetic characteristics are presented, and examples of using these parameters for the assessment of plant physiological condition are outlined.
Russian Journal of Plant Physiology – Springer Journals
Published: Oct 19, 2016
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