220 Percival: Use of Chlorophyll Fluorescence to Identify Oak Stress Koves Pechy, K., B. Biro, I. Voros, T. Takacs, E. Osztoics, and R.J. Strasser. 1998. Enhanced activity of microsymbiont-alfalfa system probed by the fast fluorescence rise OJIP, pp. 2765–2768. In Garab, P. (Ed.). Photosynthesis: Mechanisms and Effects: Proceedings of the International Congress on Photosynthesis, Budapest. Kluwer Academic Publishers, Dordrecht, The Netherlands. Kruger, G.H.J., M. Tsimilli-Michael, and R.J. Strasser 1997. Light stress provokes plastic and elastic modifications in structure and function of photosystem II in camellia leaves. Physiol. Plantarum 101:265–277. Lawlor, D.W. 2001. Photosynthesis (3rd ed.). Scientific Publishers Ltd., Oxford, UK. Lazar, D., and P. Ilik. 1997. High-temperature induced chlorophyll fluorescence changes in barley leaves. Comparison of critical temperatures determined from fluorescence induction and from fluorescence temperature curve. Plant Sci. 124:159–164. Lazar, D., P. Ilik, and J. Naus. 1997. An appearance of K- peak in fluorescence induction depends on the acclimation of barley leaves to higher temperatures. J. Lumin. 72:595–596. Lazar, D., P. Pospisil, and J. Naus. 1999. Decrease of fluorescence intensity after the K step in chlorophyll a fluorescence induction is suppressed by electron acceptors and donors to photosystem 2. Photosynthetica 37(2):255–265. Lu, C., and J. Zhang. 1998. Effects of water stress on photosynthesis, chlorophyll fluorescence and photo- inhibition in wheat plants. Aust. J. Plant Physiol. 25:883–892. Maki, D.S., and S.J. Colombo. 2001. Early detection of the effects of warm storage on conifer seedlings using physiological tests. For. Ecol. Manage. 154:237–249. Meinander, O., S. Somersalo, T. Holopainen, and R.J. Strasser. 1996. Scots pine after exposure to elevated ozone and carbon dioxide probed by reflectance spectra and chlorophyll a fluorescence transients. J. Plant Physiol. 148:229–236. Montague, T., R. Kjelgren, and L. Rupp. 1998. Surface energy balance affects gas exchange of three shrub species. J. Arboric. 24(5):254–262. Palta, J.P. 1992. Mechanisms for obtaining freezing stress resistance in herbaceous plants, pp. 219–250. In Plant Breeding in the 1990s: Proceedings of a Symposium held at North Carolina State University. Percival, G.C. 2004. Evaluation of physiological tests as predictors of young tree establishment and growth. J. Arboric. 30(2):80–92. Percival, G.C., and G.A. Fraser. 2002. The influence of powdery mildew infection on photosynthesis, chlorophyll fluorescence, leaf chlorophyll and carotenoid content of three woody species. Arboric. J. 26(4):333–347. Percival, G.C., and A. Henderson. 2003. An assessment of the freezing tolerance of urban trees using chlorophyll fluorescence. J. Hortic. Sci. Biotech. 78(2):254–260. Percival, G.C., G.A. Fraser, and G. Oxenham. 2003. Foliar salt tolerance of Acer genotypes using chlorophyll fluorescence. J. Arboric. 29(2):61–66. Popovic, R., D. Dewez, and P. Juneau. 2003. Applications of chlorophyll fluorescence in ecotoxicology: Heavy metals, herbicides, and air pollutants, pp. 151–184. In DeEll, J.R., and P.M.A. Toivonen (Eds.). Practical Applications of Chlorophyll Fluorescence in Plant Biology. Kluwer Academic Publishers, London, UK. Pospisil, P., J. Skotnica, and J. Naus. 1998. Low and high temperature dependence of minimum Fo and maximum Fm chlorophyll fluorescence in vivo. Biochim. Biophys. Acta 1363:95–99. Richardson, A.D., M. Aikens, G.P. Berlyn, and P. Marshall. 2004. Drought stress and paper birch (Betula papyrifera) seedlings: Effects of an organic biostimulant on plant health and stress tolerance, and detection of stress effects with instrument-based, non-invasive methods. J. Arboric. 30(1):52–60. Sestak, Z., and P. Stiffel. 1997. Leaf age related differences in chlorophyll fluorescence. Photosynthetica 33(3– 4):347–369. Srivastava, A.F., A. Jutter, and R.J. Strasser 1998. Action of the allelochemical fischerellin A on photosystem II. Biochem. Biophys. Acta 1364:326–336. Willits, D.H., and M.M. Peet. 2001. Using chlorophyll fluorescence to model leaf photosynthesis in greenhouse pepper and tomato. Acta Hortic. 507:311–315. Yamada, M., T. Hidaka, and H. Fukamachi. 1996. Heat tolerance in leaves of tropical fruit crops as measured by chlorophyll fluorescence. Scientia Hortic. 67:39–48. Yamane, Y., T. Shikanai, Y. Kashino, H. Koike, and K. Satoh. 2000. Reduction of QA in the dark: Another cause of fluorescence Fo increases by high temperatures in higher plants. Photosynthesis Res. 63:23–34. Acknowledgments. The author is grateful for funding from the TREE Fund (Hyland Johns grant). ©2005 International Society of Arboriculture
September 2005
| Title Name |
Pages |
Delete |
Url |
| Empty |
Ai generated response may be inaccurate.
Search Text Block
Page #page_num
#doc_title
Hi $receivername|$receiveremail,
$sendername|$senderemail wrote these comments for you:
$message
$sendername|$senderemail would like for you to view the following digital edition.
Please click on the page below to be directed to the digital edition:
$thumbnail$pagenum
$link$pagenum
Your form submission was a success.
Downloading PDF
Generating your PDF, please wait...
This process might take longer please wait
