Abutalybov, V. F., and Zholkevich, V. N.. 1979. ‘Isolation of actomyosin-like protein from sunflower roots.’ Doklady Akademii Nauk SSSR, 244: 1275–1277.Google Scholar

Abutalybov, V. F., and Zholkevich, V. N.. 1981. ‘Effect of Ca²⁺, Mg²⁺, Na⁺ on the activity of actomyosine-like ATPase isolated from sunflower roots.’ Phyziologia Rastenii, 28: 442.Google Scholar

Abutalybov, V. F., Shushanashvili, V. I., and Zholkevich, V. N.. 1980. ‘Isolation of actin-like protein from sunflower roots.’ Doklady Akademii Nauk SSSR, 252: 1023–1024.Google Scholar

Adler, C. L., Lock, J. A., and Fleet, R. W.. 2008. ‘Rainbows in the grass. II. Arbitrary diagonal incidence.’ Applied Optics, 47 (34): 214–219.Google Scholar

Aegthe, C. 1951. ‘Uber die physiologische herkunft des pflanzennektars.’ Berichte der Schweizerischen Botanischen Gesellschaft, 61: 240–277.Google Scholar

Ahmad, M., Hirz, M., Pichler, H., and Schwab, H.. 2014. ‘Protein expression in Pichia pastoris: recent achievements and perspectives for heterologous protein production.’ Applied Microbiology and Biotechnology, 98 (12): 5301–5317.CrossRefGoogle ScholarPubMed

Aki, T., Shigyo, M., Nakano, R., Yoneyama, T., and Yanagisawa, S.. 2008. ‘Nano scale proteomics revealed the presence of regulatory proteins including three FT-like proteins in phloem and xylem saps from rice.’ Plant & Cell Physiology, 49 (5): 767–790.CrossRefGoogle ScholarPubMed

Albacete, A., Martinez-Andujar, C., Ghanem, M. E., et al. 2009. ‘Rootstock-mediated changes in xylem ionic and hormonal status are correlated with delayed leaf senescence, and increased leaf area and crop productivity in salinized tomato.’ Plant, Cell & Environment, 32 (7): 928–938.CrossRefGoogle ScholarPubMed

Aldea, M., Hamilton, J. G., Resti, J. P., Zangerl, A. R., Berenbaum, M. R., and Elucia, E. H. D.. 2005. ‘Indirect effects of insect herbivory on leaf gas exchange in soybean.’ Plant, Cell & Environment, 28 (3): 402–411.CrossRefGoogle Scholar

Aloni, R. 2001. ‘Foliar and axial aspects of vascular differentiation: hypotheses and evidence.’ Journal of Plant Growth Regulation, 20 (1): 22–34.Google Scholar

Aloni, R. 2010. ‘The induction of vascular tissue by auxin.’ In Plant Hormones: Biosynthesis, Signal Transduction, Action, edited by Davies, P. J.. Dordrecht: Kluwer Academic Publishers, pp. 485–506.CrossRefGoogle Scholar

Aloni, R., Langhans, M., Aloni, E., Dreieicher, E., and Ullrich, C. I.. 2005. ‘Root-synthesized cytokinin in Arabidopsis is distributed in the shoot by the transpiration stream.’ Journal of Experimental Botany, 56 (416): 1535–1544.Google Scholar

Aloni, R., Schwalm, K., Langhans, M., and Ullrich, C. I.. 2003. ‘Gradual shifts in sites of free-auxin production during leaf-primordium development and their role in vascular differentiation and leaf morphogenesis in Arabidopsis.’ Planta, 216 (5): 841–853.CrossRefGoogle ScholarPubMed

Amasino, R. 2005. ‘1955: Kinetin arrives. The 50th anniversary of a new plant hormone.’ Plant Physiology, 138 (3): 1177–1184.Google Scholar

Ameziane, R., Bernhard, K., and Lightfoot, D. A.. 2000. ‘Expression of the bacterial gdhA gene encoding a NADPH glutamate dehydrogenase in tobacco affects plant growth and development.’ Plant and Soil, 221 (1): 47–57.CrossRefGoogle Scholar

Anonymous. 2004. ‘Gummy stem blight of greenhouse cucumber.’ Crop Protection Factsheet, September. Canada: Ministry of Agriculture and Lands, British Columbia.Google Scholar

Anonymous. 2009. ‘Guttation water of no relevance for agricultural practice as a route of exposure to pesticide residues.’ Bayer Crop Science, Press release, February 16, Monheim, available at www.bayercropscience.com.Google Scholar

Arango, M., Gevaudant, F., Oufattole, M., and Boutry, M.. 2003. ‘The plasma membrane proton pump ATPase: the significance of gene subfamilies.’ Planta, 216 (3): 355–365.CrossRefGoogle ScholarPubMed

Arens, K. 1934. ‘Die kutikulare exkretion des laublattes.’ Jahrbücher für Wissenschaftliche Botanik, 80: 248–300.Google Scholar

Arisz, W. H., Helder, R. J., and Nie, R. V.. 1951. ‘Analysis of the exudation process in tomato plants.’ Journal of Experimental Botany, 2 (3): 257–297.CrossRefGoogle Scholar

Arnold, A. 1952. ‘Uber den funktionsmechanismus der endodermiszellen der wurzeln.’ Protoplasma, 41 (2): 180–211.CrossRefGoogle Scholar

Azad, A. K., Sawa, Y., Ishikawa, T., and Shibata, H.. 2009. ‘Heterologous expression of tulip petal plasma membrane aquaporins in Pichia pastoris for water channel analysis.’ Applied and Environmental Microbiology, 75 (9): 2792–2797.CrossRefGoogle ScholarPubMed

Azarkan, M., Wintjens, R., Looze, Y., and Baeyens-Volant, D.. 2004. ‘Detection of three wound-induced proteins in papaya latex.’ Phytochemistry, 65 (5): 525–534.CrossRefGoogle ScholarPubMed

Baba, I. 1957. ‘Studies on the nutrition of the rice plant with special reference to nitrogen and silica: IV. On silica in the exudation and guttation sap.’ Japanese Journal of Crop Science, 25 (3): 139–140.CrossRefGoogle Scholar

Bai, X., Zhu, J., Zhang, P., Wang, Y., Yang, L., and Zhang, L.. 2007. ‘Na+ and water uptake in relation to radial reflection coefficient of root in arrow leaf saltbush under salt stress.’ Journal of Integrative Plant Biology, 49 (9): 1334–1340.CrossRefGoogle Scholar

Bailey, D. W. 2004. ‘Management strategies for optimal grazing distribution and use of arid rangelands.’ Journal of Animal Science 82 (E-Suppl): E147–E153.Google ScholarPubMed

Bain, S. M. 1902. ‘The action of copper on leaves with special reference to the injurious effects of fungicides on peach foliage; a physiological investigation.’ Tennessee Agricultural Experiment Station Bulletin, 15: 19–108.Google Scholar

Bald, J. G. 1952. ‘Stomatal droplets and the penetration of leaves by plant pathogens.’ American Journal of Botany, 39 (2): 97–99.CrossRefGoogle Scholar

Baluska, F. 2010. ‘Recent surprising similarities between plant cells and neurons.’ Plant Signaling & Behavior, 5 (2): 87–89.Google Scholar

Baluska, F. 2015. Long-distance Systemic Signaling and Communication in Plants. Berlin: Springer.Google Scholar

Baluska, F., and Mancuso, S.. 2009. Signaling in Plants. Berlin: Springer.Google Scholar

Baluska, F., and Volkmann, D.. 2008. ‘Plant myosins: do they have roles in gravi- and mechanosensing?’ In The Plant Cytoskeleton: A Key Tool for Agro-biotechnology, edited by Blume, Y. B., Baird, V., Yemets, A. I., and Breviario, D.. Berlin: Springer, pp. 161–172.Google Scholar

Baluska, F., Šamaj, J., Wojtaszek, P., Volkmann, D., and Menzel, D.. 2003. ‘Cytoskeleton–plasma membrane–cell wall continuum in plants. Emerging links revisited.’ Plant Physiology, 133 (2): 483–491.CrossRefGoogle ScholarPubMed

Baluska, F., Volkmann, D., and Mancuso, S.. 2006. Communication in Plants: Neuronal Aspects of Plant Life. Berlin: Springer.CrossRefGoogle Scholar

Baranetzky, J. 1877. ‘Untersuchungen uber die Periodicitat des Blutens der Krautartigen Pf lanzen und deren Ursachen.’ Naturf. Ges. Abhandl. Halle, 13: 1–63.Google Scholar

Barbour, M., and Farquhar, G. D.. 2000. ‘Relative humidity- and ABA-induced variation in carbon and oxygen isotope ratios of cotton leaves.’ Plant, Cell & Environment, 23 (5): 473–485.CrossRefGoogle Scholar

Barrs, H. D. 1966. ‘Root pressure and leaf water potential.’ Science, 152 (3726): 1266–1268.CrossRefGoogle ScholarPubMed

Barzana, G., Aroca, R., Paz, J. A., Chaumont, F., et al. 2012. ‘Arbuscular mycorrhizal symbiosis increases relative apoplastic water flow in roots of the host plant under both well-watered and drought stress conditions.’ Annals of Botany, 109: 1009–1017.CrossRefGoogle ScholarPubMed

Barzana, G., Aroca, R., Paz, J. A. S., et al. 2012. ‘Arbuscular mycorrhizal symbiosis increases relative apoplastic water flow in roots of the host plant under both well-watered and drought stress conditions.’ Annals of Botany, 109 (5): 1009–1017.CrossRefGoogle ScholarPubMed

Bertrand, A., Robitaille, G., and Boutin, R.. 1995. ‘Growth and ABA responses of maple seedlings to aluminum.’ Tree Physiology, 15 (12): 775–782.CrossRefGoogle Scholar

Beveridge, C. A. 2000. ‘Long distance signalling and a mutational analysis of branching in pea.’ Plant Growth Regulation 32 (2/3): 193–203.CrossRefGoogle Scholar

Bienert, G. P., Bienert, M. D., Jahn, T. P., Boutry, M., and Chaumon, F.. 2011. ‘Solanaceae XIPs are plasma membrane aquaporins that facilitate the transport of many uncharged substrates.’ The Plant Journal, 66 (2): 306–317.Google Scholar

Biles, C. L., and Abeles, F. B.. 1991. ‘Xylem sap proteins.’ Plant Physiology, 96 (2): 597–601.CrossRefGoogle ScholarPubMed

Birch, A. N. E., Arpaia, S., Lovei, G. L., et al. 2004. ‘Selection procedure to study ecological impact of GM plants: a case study of Bt-maize in Kenya.’ 8th International Symposium on the Biosafety of Genetically Modified Organisms, Montpellier, France, pp. 31–32.Google Scholar

Biswas, K., Yoshioka, K., Asanuma, K., et al. 2013. ‘Essential role of class II phosphatidylinositol-3-kinase-c2 in sphingosine 1-phosphate receptor-1-mediated signaling and migration in endothelial cells.’ The Journal of Biological Chemistry, 288 (4): 2325–2339.CrossRefGoogle Scholar

Blum, A. 2005. ‘Drought resistance, water-use efficiency, and yield potential: are they compatible, dissonant, or mutually exclusive?’ Australian Journal of Agricultural Research, 56 (11): 1159–1168.CrossRefGoogle Scholar

Bobik, K., Duby, G., Nizet, Y., et al. 2010. ‘Two widely expressed plasma membrane H+-ATPase isoforms of Nicotiana tabacum are differentially regulated by phosphorylation of their penultimate threonine.’ The Plant Journal, 62 (2): 291–301.CrossRefGoogle ScholarPubMed

Bohm, J. 1893. ‘Capillaritat and saftsteigen.’ Berichte der Deutschen Botanischen Gesellschaft, 11 (3): 203–212.Google Scholar

Bolle, C. 2004. ‘The role of GRAS proteins in plant signal transduction and development.’ Planta, 218 (5): 683–692.CrossRefGoogle ScholarPubMed

Borisjuk, N. V., Sitailo, L., Adler, K., et al. 1998. ‘Calreticulin expression in plant cells: developmental regulation, tissue specificity and intracellular distribution.’ Planta, 206 (4): 504–514.CrossRefGoogle ScholarPubMed

Borisjuk, N. V., Borisjuk, L. G., Logendra, S., Petersen, F., Gleba, Y., and Raskin, I.. 1999. ‘Production of recombinant proteins in plant root exudates.’ Nature Biotechnology, 17 (5): 466–469.CrossRefGoogle ScholarPubMed

Borisova, T. A, Lazareva, N. P., and Zholkevich, V. N.. 1986. ‘On different cell membrane permeability of root systems to water solutes.’ Studia Biophysica, 111: 173–176.Google Scholar

Bose, J. C. 1923. The Physiology of the Ascent of Sap. London: Longmans Green & Company.Google Scholar

Bose, J. C. 1927. Plant Autographs and their Revelations. London: Longmans Green & Company.CrossRefGoogle Scholar

Boyer, J. S. 1985. ‘Water transport.’ Annual Review of Plant Physiology, 36: 473–516.CrossRefGoogle Scholar

Brandl, M. T., and Amundson, R.. 2008. ‘Leaf age as a risk factor in contamination of lettuce with Escherichia coli O157:H7 and Salmonella enterica.’ Applied and Environmental Microbiology, 74 (8): 2298–2306.CrossRefGoogle ScholarPubMed

Brauer, D., Tu, S., Hsu, A., and Patterson, D.. 1993. ‘Evidence for an indirect coupling mechanism for the nitrate-sensitive proton pump from corn root tonoplast membranes.’ Physiologia Plantarum, 89 (3): 588–591.CrossRefGoogle Scholar

Bray, E. A. 2002. ‘Abscisic acid regulation of gene expression during water-deficit stress in the era of the Arabidopsis genome.’ Plant, Cell & Environment, 25 (2): 153–161.CrossRefGoogle ScholarPubMed

Brencic, A., and Winans, S. C.. 2005. ‘Detection of and response to signals involved in host-microbe interactions by plant-associated bacteria.’ Microbiology and Molecular Biology Reviews, 69 (1): 155–194.CrossRefGoogle ScholarPubMed

Brew, M. N. R., Myer, O., Hersom, M. J., et al. 2011. ‘Water intake and factors affecting water intake of growing beef cattle.’ Livestock Science 140 (1/2/3): 297–300.CrossRefGoogle Scholar

Britto, D. T., and Kronzucker, H. J.. 2006. ‘Futile cycling at the plasma membrane: a hallmark of low-affinity nutrient transport.’ Trends in Plant Science, 11 (11): 529–534.Google Scholar

Brodersen, C. R., and McElrone, A. J.. 2013. ‘Maintenance of xylem network transport capacity: a review of embolism repair in vascular plants.’ Frontiers in Plant Science, 4: 198.CrossRefGoogle ScholarPubMed

Brodribb, T. J., and Holbrook, N. M.. 2006. ‘Declining hydraulic efficiency as transpiring leaves desiccate: two types of response.’ Plant, Cell & Environment, 29 (12): 2205–2215.CrossRefGoogle ScholarPubMed

Brodribb, T. J., Holbrook, N. M., and Hill, R. S.. 2005. ‘Seedling growth in conifers and angiosperms: impacts of contrasting xylem structure.’ Australian Journal of Botany 53: 749–755.Google Scholar

Brotherson, J. D., and Feild, T. S.. 1987. ‘Tamarix: impacts of a successful weed.’ Rangelands, 9 (3): 110–112.Google Scholar

Brouillet, L., Bertrand, C., Cuerrier, A., and Barabé, D.. 1987. ‘Les hydathodes des genres Begonia et Hillebrandia (Begoniaceae).’ Canadian Journal of Botany, 65 (1): 34–52.CrossRefGoogle Scholar

Brown, A. H., Chapman, D. K., Heathcote, D. G., and Johnsson, A.. 1993. ‘A proposal to determine properties of the gravitropic response of plants in the absence of a complicating g-force (gthres).’ Final Report NASA Grant NAG 2-574. Philadelphia: Gravitational Plant Physiology Laboratory, University City Science Center, pp. 1–38.Google Scholar

Brown, G. D., and Lynch, J. J.. 1972. ‘Some aspects of the water balance of sheep at pasture when deprived of drinking water.’ Australian Journal of Agricultural Research, 23: 669–684.CrossRefGoogle Scholar

Broyer, T. C. 1951. ‘Exudation studies on the water relations of plants.’ American Journal of Botany, 38 (3): 157–162.CrossRefGoogle Scholar

Broyer, T. C., and Hoagland, D. R.. 1943. ‘Metabolic activities of roots and their bearing on the relation of upward movement of salts and water in plants.’ American Journal of Botany, 30 (4): 261–273.CrossRefGoogle Scholar

Buch-Pedersen, M. J., and Palmgren, M. G.. 2003. ‘Mechanism of proton transport by plant plasma membrane proton ATPases.’ Journal of Plant Research, 116 (6): 507–515.Google Scholar

Bugbee, B., and Koerner, G.. 2002. ‘Yield comparisons and unique characteristics of the dwarf wheat cultivar ‘USU-Apogee’ research: super dwarf cultivar studies: ‘Apogee’ wheat’, available at http://www.usu.edu/cpl/research_dwarf_wheat.htm [Verified on 20 November 2011].Google Scholar

Burdock, G. A. 2009. Fenaroli’s Handbook of Flavor Ingredients (6th ed.). California: CRC Press.Google Scholar

Burgerstein, A. 1887. ‘Materialien zu einer monographie betreffend die erscheinungen der transpiration der Pflanzen.’ Verhandlungen der Zoologisch-Botanischen Gesellschaft in Wien, 37: 691–782.Google Scholar

Burgerstein, A. 1920. Die transpiration der pflanzen (Vol. 2). Jena: Gustav Fischer.Google Scholar

Burgess, S. S. O., and Dawson, T. E.. 2004. ‘The contribution of fog to the water relations of Sequoia sempervirens (D. Don): foliar uptake and prevention of dehydration.’ Plant, Cell & Environment, 27 (8): 1023–1034.Google Scholar

Burkle, L., Cedzich, A., Dopke, C., et al. 2003. ‘Transport of cytokinins mediated by purine transporters of the PUP family expressed in phloem, hydathodes, and pollen of Arabidopsis.’ The Plant Journal, 34 (1): 13–26.CrossRefGoogle ScholarPubMed

Burow, G. B., Franks, C. D., and Xin, Z.. 2008. ‘Genetic and physiological analysis of an irradiated bloomless mutant (epicuticular wax mutant) of sorghum.’ Crop Science, 48: 41–48.CrossRefGoogle Scholar

Burow, G. B., Franks, C. D., Acosta-Martinez, V., and Xin, Z.. 2009. ‘Molecular mapping and characterization of BLMC, a locus for profuse wax (bloom) and enhanced cuticular features of Sorghum (Sorghum bicolor (L.) Moench.).’ Theoretical and Applied Genetics, 118: 423-431.CrossRefGoogle ScholarPubMed

Burow, G. B., Franks, C. D., and Xin, Z.. 2008. ‘Genetic and physiological analysis of an irradiated bloomless mutant (epicuticular wax mutant) of sorghum.’ Crop Science, 48 (1): 41–48.Google Scholar

Busch, D. E., and Smith, S. D.. 1993. ‘Effects of fire on water and salinity relationships of riparian woody taxa.’ Oecologia, 94 (2): 186–194.CrossRefGoogle Scholar

Canny, M. J. 1995. ‘A new theory for the ascent of sap—cohesion supported by tissue pressure.’ Annals of Botany, 75 (4): 343–357.CrossRefGoogle Scholar

Canny, M. J. 1997. ‘Vessel contents during transpiration—embolisms and refilling.’ American Journal of Botany, 84 (9): 1223–1230.Google Scholar

Canny, M. J. 1998. ‘Applications of the compensating pressure theory of water transport.’ American Journal of Botany, 85 (7): 897–909.CrossRefGoogle ScholarPubMed

Canny, M. J. 2001. ‘Contributions to the debate on water transport.’ American Journal of Botany, 88 (1): 43–46.CrossRefGoogle Scholar

Canny, M. J. 1990. ‘What becomes of the transpiration stream?’ New Phytologist, 114: 341–368.CrossRefGoogle ScholarPubMed

Cantrill, L. C., Overall, R. L., and Goodwin, P. B.. 1999. ‘Cell-to-cell communication via plant endomembranes.’ Cell Biology International, 23 (10): 653–661.CrossRefGoogle ScholarPubMed

Cao, K. F., Yang, S. J., Zhang, Y. J., and Brodribb, T. J.. 2012. ‘The maximum height of grasses is determined by roots.’ Ecology Letters, 15 (7): 666–672.CrossRefGoogle ScholarPubMed

Carlton, W. M., Braun, E. J., and Gleason, M. L.. 1998. ‘Ingress of Clavibacter michiganensis subsp. michiganensis into tomato leaves through hydathodes.’ Phytopathology, 88 (6): 525–529.CrossRefGoogle ScholarPubMed

Chaves, M. M., and Oliveira, M. M.. 2004. ‘Mechanisms underlying plant resilience to water deficits: prospects for water-saving agriculture.’ Journal of Experimental Botany, 55 (407): 2365–2384.CrossRefGoogle ScholarPubMed

Chen, C., and Chen, Y.. 2005. ‘Study on laminar hydathodes of Ficus formosana (Moraceae). I. Morphology and ultrastructure.’ Botanical Bulletin of Academia Sinica, 46: 205–215.Google Scholar

Chen, C., and Chen, Y. 2006. ‘Study on laminar hydathodes of Ficus formosana (Moraceae). II. Morphogenesis of hydathodes.’ Botanical Studies, 47: 279–292.Google Scholar

Chen, C., and Chen, Y. 2007. ‘Study on laminar hydathodes of Ficus formosana (Moraceae). III. Salt injury of guttation on hydathodes.’ Botanical Studies, 48 (2): 215–226.Google Scholar

Cherian, S., and Oliveira, M. M.. 2005. ‘Transgenic plants in phytoremediation: recent advances and new possibilities.’ Journal of the American Chemical Society, 39 (24): 9377–9390.Google ScholarPubMed

Choat, B., Jansen, S., Brodribb, T. J., et al. 2012. ‘Global convergence in the vulnerability of forests to drought.’ Nature, 491: 752–755.CrossRefGoogle ScholarPubMed

Chupp, C. 1925. Manual of Vegetable Garden Diseases. New York, NY: MacMillan Company.Google Scholar

Cochard, H., Venisse, J., Barigah, T., et al. 2007. ‘Putative role of aquaporins in variable hydraulic conductance of leaves in response to light.’ Plant Physiology, 143 (1): 122–133.Google Scholar

Comstock, J. P. 2002. ‘Hydraulic and chemical signaling in the control of stomatal conductance and transpiration.’ Journal of Experimental Botany, 53 (367): 195–200.Google Scholar

Conrad, U., and Fiedler, U.. 1998. ‘Compartment-specific accumulation of recombinant immunoglobulins in plant cells: an essential tool for antibody production of physiological functions and pathogen activity.’ Plant Molecular Biology 38 (1/2): 101–109.CrossRefGoogle ScholarPubMed

Crafts, A. S., and Broyer, T. C.. 1938. ‘Migration of salts and water into xylem of the roots of higher plants.’ American Journal of Botany, 25 (7): 529–535.Google Scholar

Crawford, K. M., and Zambryski, P. C.. 1999. ‘Plasmodesmata signaling: many roles, sophisticated statutes.’ Current Opinion in Plant Biology, 2 (5): 382–387.CrossRefGoogle ScholarPubMed

Curtis, J. D., and Lersten, N. R.. 1974. ‘Morphology, seasonal variation, and function of resin glands on buds and leaves of Populus deltoids (Salicaceae).’ American Journal of Botany, 61 (8): 835–845.Google Scholar

Curtis, L. C. 1943. ‘Deleterious effects of guttated fluids on foliage.’ American Journal of Botany, 30 (10): 778–781.Google Scholar

Curtis, L. C. 1944a. ‘The exudation of glutamine from lawn grass.’ Plant Physiology, 19 (1): 1–5.CrossRefGoogle ScholarPubMed

Curtis, L. C. 1944b. ‘The inf luence of guttation fluid on pesticides.’ Phytopathology, 34: 196–205.Google Scholar

D’Aoust, M., Couture, M. M. J., Charland, N., et al. 2010. ‘The production of hemagglutinin-based virus-like particles in plants: a rapid, efficient and safe response to pandemic inf luenza.’ Plant Biotechnology Journal, 8 (5): 607–619.Google Scholar

Dalbro, S. 1955. ‘Leaching of apple foliage by rain.’ 14th International Horticultural Congress Scheveningen, Holland.Google Scholar

Dane, F., and Shaw, J. J.. 1993. ‘Growth of bioluminescent Xanthomonas-campestris pv. campestris in susceptible and resistant host plants.’ Molecular Plant-Microbe Interactions, 6 (6): 786–789.Google Scholar

Daniel, T. W. 1949. ‘Coniferous root exudate.’ Plant Physiology, 24: 327–330.CrossRefGoogle ScholarPubMed

Daniell, H., Khan, M. S., and Allison, L.. 2002. ‘Milestones in chloroplast genetic engineering: an environmentally friendly era in biotechnology.’ Trends in Plant Science, 7 (2): 84–91.Google Scholar

Daviere, J., and Achard, P.. 2013. ‘Gibberellin signaling in plants.’ Development, 140: 1147–51.Google Scholar

Davis, T. A. 1961. ‘High root pressure in palms.’ Nature, 192: 227–228.CrossRefGoogle Scholar

Dawson, T. E. 1998. ‘Fog in the California redwood forest: ecosystem inputs and use by plants.’ Oecologia, 117 (4): 476–484.Google Scholar

de Candolle, A. P. 1825. Prodromus Systematis Naturalis, Regni Vegetabilis. Parisii: Sumptibus Sociorum Treuttel et Würt, p. 483.Google Scholar

de Muynck, B., Navarre, C., and Boutry, M.. 2010. ‘Production of antibodies in plants: status after twenty years.’ Plant Biotechnology Journal, 8 (5): 529–563.Google Scholar

de Saussure, N. 1804. Recherches Chimique Sur La Vegetation. Paris: Vue Nyon, pp. 264–265.Google Scholar

Dieffenbach, H., Kramer, D., and Luettge, U.. 1980a. ‘Release of guttation fluid from passive hydathodes of intact barley plants. I. Structural and cytological aspects.’ Annals of Botany, 45 (4): 397–401.CrossRefGoogle Scholar

Dieffenbach, H., Luettge, U., and Pitman, M. G.. 1980b. ‘Release of guttation fluid from passive hydathodes of intact barley plants. II. The effects ofabscisic acid and cytokinins.’ Annals of Botany, 45 (6): 703–712.CrossRefGoogle Scholar

Ding, X. S., Boydston, C. M., and Nelson, R. S.. 2001. ‘Presence of Brome Mosaic virus in barley guttation fluid and its association with localized cell death response.’ Phytopathology, 91 (5): 440–448.CrossRefGoogle ScholarPubMed

DiTomaso, J. M. 1998. ‘Impact, biology and ecology of salt cedar (Tamarix spp.) in the southwestern United States.’ Weed Technology, 12 (2): 236–336.Google Scholar

Dixon, H. H. 1914. Transpiration and the Ascent of Sap. London: MacMillan & Company.Google Scholar

Dixon, H. H., and Dixon, G. J.. 1931. ‘The exudation of water from the leaf tips of Colocasia antiquorum.’ The Scientific Proceedings of the Royal Dublin Society, 20: 7–10.Google Scholar

Dixon, H. H., and Joly, J.. 1895. ‘On the ascent of sap.’ Philosophical Transcations of the Royal Society B (Biological Sciences), 186: 536–576.Google Scholar

Dodd, I. C., Ngo, C., Turnbull, C. G., and Beveridge, C. A.. 2004. ‘Effects of nitrogen supply on xylem cytokinin delivery, transpiration and leaf expansion of pea genotypes differing in xylem-cytokinin concentration.’ Functional Plant Biology, 31 (9): 903–911.Google Scholar

Dodd, I. C. 2013. ‘Abscisic acid and stomatal closure: a hydraulic conductance conundrum.’ New Phytologist, 197 (1): 6–8.CrossRefGoogle ScholarPubMed

Dodd, J. D., and O’Sullivan, K. T.. 2012. Form and Function in Plants. London: Literary Licensing, LLC.Google Scholar

Drake, P. M. W., Barbi, T., Sexton, A., et al. 2009. ‘Development of rhizosecretion as a production system for recombinant proteins from hydroponic cultivated tobacco.’ FASEB Journal, 23 (10): 3581–3589.CrossRefGoogle ScholarPubMed

Drake, P. M. W., Chargelegue, D. M., Vine, N. D., van Dolleweerd, C. J., Obregon, P., and Ma, J. K. C.. 2003. ‘Rhizosecretion of a monoclonal antibody protein complex from transgenic tobacco roots.’ Plant Molecular Biology, 52 (1): 233–241.CrossRefGoogle ScholarPubMed

Drennan, P., Goldsworthy, D., and Buswell, A.. 2009. ‘Marginal and laminar hydathode-like structures in the leaves of the desiccation-tolerant angiosperm Myrothamnus flabellifolius Welw.’ Flora- Morphology, Distribution, Functional Ecology of Plants, 204 (3): 210–219.CrossRefGoogle Scholar

Duby, G., and Boutry, M.. 2009. ‘The plant plasma membrane proton pump ATPase: a highly regulated P-type ATPase with multiple physiological roles.’ Pflügers ArchivEuropean Journal of Physiology, 457 (3): 645–655.Google Scholar

Duby, G., Poreba, W., Piotrowiak, D., et al. 2009. ‘Activation of plant plasma membrane H+-ATPase by 14-3-3 proteins is negatively controlled by two phosphorylation sites within the H+-ATPase C-terminal region.’ Journal of Biological Chemistry, 284 (7): 4213–4221.Google Scholar

Duchartre, P. 1859. ‘Recherches physiologiques, anatomiques, et organogeniques sur la colocase des anciens, Colocasia antiquorum.’ Schottish Annales des Sciences Naturelles Botanique, 12: 232–279.Google Scholar

Duncan, K. W., Schemnitz, S. D., Suzuki, M., Homesley, Z., and Cardenas, M.. 1993. ‘Evaluation of saltcedar control- Pecos River, New Mexico.’ General Technical Report RM-226, USDA Forest Service Rocky Mountain Forest and Range Experiment Station, Fort Collins, Colorado.Google Scholar

Dustmamatov, A. G., and Zholkevich, V. N.. 2008. ‘Effects of HgCl2 on principal parameters of exudation from maize detached root systems.’ Russian Journal of Plant Physiology, 55 (6): 814–820.Google Scholar

Dustmamatov, A. G., Zholkevich, V. N., and Kuznetsov, V. V.. 2004. ‘Water pumping activity of the root system in the process of cross-adaptation of sunflower plants to hyperthermia and water deficiency.’ Russian Journal of Plant Physiology, 51 (6): 822–826.CrossRefGoogle Scholar

Eaton, F. M. 1941. ‘Water uptake and root growth as influenced by inequalities in the concentration of the substrate.’ Plant Physiology, 16 (3): 545–564.Google Scholar

Eaton, F. M. 1943. ‘The osmotic and vitalistic interpretations of exudation.’ American Journal of Botany, 30 (9): 663–674.CrossRefGoogle Scholar

Elias, T. S., and Gelband, H.. 1977. ‘Morphology, anatomy, and relationship of extraf loral nectarines and hydathodes in two species of Impatiens (Balsaminaceae).’ Botanical Gazette, 138: 206–212.CrossRefGoogle Scholar

Emberger, G. 2008. Available at www.messiah.edu/Oakes/fungi_on_wood/poroid fungi/species pages/Polyporus squamosus [Verified on 2 July 2010].Google Scholar

Endo, R. M. 1967. ‘The role of guttation fluid in fungal disease development.’ California Turfgrass Culture, 17: 12–13.Google Scholar

Engel, H. 1939. ‘Das Verholten des Blatter bei Benetzung mit Wasser.’ Jahrbücher für Wissenschaftliche Botanik, 88: 816–861.Google Scholar

Engel, H., and Friederichsen, U. I.. 1951. ‘Das licht als ursache periodischer guttationsschwankungen etiolierter haferkeimlinge.’ Planta, 39: 309–337.CrossRefGoogle Scholar

Engel, H., and Friederichsen, U. I.. 1952. ‘Weitere untersuchungen über periodische guttation etiolierter haferkeimlinge.’ Planta, 40: 529–549.Google Scholar

Engel, H., and Friederichsen, U. I.. 1954. ‘Periodische Guttation bei Zea mays.’ Planta, 44 (5): 459–471.Google Scholar

Enns, L. C., Canny, M. J., and McCully, M. E.. 2000. ‘An investigation of the role of solutes in the xylem sap and in the xylem parenchyma as a source of root pressure.’ Protoplasma 211 (3/4): 183–197.Google Scholar

Epel, B. L. 1994. ‘Plasmodesmata: composition, structure and trafficking.’ Plant Molecular Biology, 26: 1343–1356.Google Scholar

Esau, K. 2006. Anatomy of Seed Plants. Hoboken, New Jersey: John Wiley and Sons.Google Scholar

Eshel, M., and Beeckman, T.. 2013. Plant Roots: The Hidden Half (4th ed.). California: CRC Press.Google Scholar

Ewers, F. W., Cochard, H., and Tyree, M. T.. 1997. ‘A survey of root pressures in vines of a tropical lowland forest.’ Oecologia, 110: 191–196.CrossRefGoogle ScholarPubMed

Fahn, A. 1979. Secretory Tissues in Plants. London: Academic Press.Google Scholar

Fahn, A. 1988. ‘Secretory tissues in vascular plants.’ New Phytologist, 108: 229–257.Google Scholar

Fahn, A. 2000. ‘Structure and function of secretory cells.’ In: Hallahan, DL, Gray, JC, and Callow, JA (eds), Advances in Botanical Research Incorporating Advances in Plant Pathology (Vol. 31: plant trichomes). London: Academic Press, pp. 37–75.Google Scholar

Feild, T. S., and Arens, N. C.. 2007. ‘The ecophysiology of early angiosperms.’ Plant, Cell & Environment, 30 (3): 291–309.CrossRefGoogle ScholarPubMed

Feild, T. S., and Brodribb, T. J.. 2013. ‘Hydraulic tuning of vein cell microstructure in the evolution of angiosperm venation networks.’ New Phytologist, 199 (3): 720–726.Google Scholar

Feild, T. S., Arens, N. C., and Dawson, T. E.. 2003. ‘The ancestral ecology of angiosperms: emerging perspectives from extant basal lineages.’ International Journal of Plant Science 164 (S3): 129–142.Google Scholar

Feild, T. S., Sage, T. L., Czerniak, C., and Iles, W. J. D.. 2005. ‘Hydathodal leaf teeth of Chloranthus japonicus (Chloranthaceae) prevent guttation-induced flooding of the mesophyll.’ Plant, Cell & Environment, 28 (9): 1179–1190.Google Scholar

Fick, A. 1855. ‘Ueber Diffusion.’ Annalen der Physik, 170 (1): 59–86.CrossRefGoogle Scholar

Fischer, R., and Emans, N.. 2000. ‘Molecular farming of pharmaceutical proteins.’ Transgenic Research, 9: 279–299.Google Scholar

Fischer, R., and Schillberg, S.. 2004. Molecular Farming: Plant-made Pharmaceuticals and Technical Proteins. New York, NY: John Wiley & Sons.CrossRefGoogle Scholar

Fischer, R., Stoger, E., Schillberg, S., Christou, P., and Twyman, R. M.. 2004. ‘Plant-based production of biopharmaceuticals.’ Current Opinion in Plant Biology, 7: 152–158.Google Scholar

Fischer, R., Twyman, R. M., Hellwig, S., Drossard, J., and Schillberg, S.. 2007. ‘Facing the future with pharmaceuticals from plants.’ In: Xu, Z, Li, J, Xue, Y, and Yang, W (eds), Biotechnology and Sustainable Agriculture 2006 and Beyond. New York, NY: Springer, pp. 13–32.Google Scholar

Fischer, S., Charara, N., Gerber, A., et al. 2012. ‘Transient recombinant protein expression in a human amniocyte cell line: the CAP-T® cell system.’ Biotechnology and Bioengineering, 109 (9): 2250–2261.Google Scholar

Fisher, J. B., Angeles, G., Ewers, F. W., and Lopez-Portillo, J.. 1997. ‘Survey of root pressure in tropical vines and woody species.’ International Journal of Plant Sciences, 158: 44–50.CrossRefGoogle Scholar

Fisher, J. B., Angeles A., G., Ewers, F. W., and J. López-Portillo. 1997. ‘Survey of root pressure in tropical vines and woody species.’ International Journal of Plant Sciences, 158 (1): 44–50.Google Scholar

Fletcher, A. T., and Mader, J. C.. 2007. ‘Hormone profiling by LC-QToF-MS/MS in dormant Macadamia integrifolia: correlations with abnormal vertical growth.’ Journal of Plant Growth Regulation, 26: 351–361.CrossRefGoogle Scholar

Flood, M. G. 1919. ‘Exudation of water by Colocasia antiqualum.’ The Scientific Proceedings of the Royal Dublin Society, 15: 502.Google Scholar

Flowers, T. J. 2004. ‘Improving crop salt tolerance.’ Journal of Experimental Botany, 55 (396): 307–319.CrossRefGoogle ScholarPubMed

French, C. J., and Elder, M.. 1999. ‘Virus particles in guttate and xylem of infected cucumber (Cucumis sativus L.).’ Annals of Applied Biology, 134 (1): 81–87.Google Scholar

French, C. J., Elder, M., and Skelton, F.. 1993. ‘Recovering and identifying infectious plant viruses in guttation fluid.’ Hort Science, 28 (7): 746–747.Google Scholar

Frey-Wyssling, A. 1941. ‘Die guttation als aligemeine erscheinung.’ Berichte der Schweizerischen Botanischen Gesellschaft, 51: 321–325.Google Scholar

Fujii, Y., and Tanaka, N.. 1957. ‘Intensity of guttation in rice seedlings in relation to earliness or lateness of the variety.’ Japanese Journal of Crop Science, 25 (3): 131–132.Google Scholar

Fukui, H., Fukui, R., and Alvarez, A. M.. 1996. ‘Role of indigenous leaf-inhabiting bacteria in suppression of anthurium blight.’ Phytopathology 86: S36–S36.Google Scholar

Fukui, H., Fukui, R., and Alvarez, A. M.. 1999. ‘Suppression of bacterial blight by a bacterial community isolated from the guttation fluids of anthuriums.’ Applied and Environmental Microbiology, 65 (3): 1020–1028.Google Scholar

Galan, J. E., and Wolf-Watz, H.. 2006. ‘Protein delivery into eukaryotic cells by type III secretion machines.’ Nature, 444 (7119): 567–573.Google Scholar

Gang, D. R., Wang, J., Dudareva, N., et al. 2001. ‘An investigation of the storage and biosynthesis of phenylpropenes in sweet basil.’ Plant Physiology, 125 (2): 539–555.Google Scholar

Gareis, M., and Gareis, E.. 2007. ‘Guttation droplets of Penicillium nordicum and Penicillium verrucosum contain high concentrations of the mycotoxins ochratoxin A and B.’ Mycopathologia, 163 (4): 207–214.CrossRefGoogle ScholarPubMed

Gaumann, E. 1938. ‘Uber die experimentelle auslosung der guttation.’ Berichte der Deutschen Botanischen Gesellschaft, 56: 396–405.Google Scholar

Gaume, A., Komarnytsky, S., Borisjuk, N. V., and Raskin, I.. 2003. ‘Rhizosecretion of recombinant proteins from plant hairy roots.’ Plant Cell Reports, 21 (12): 1188–1193.Google Scholar

Gaxiola, R. A., Palmgren, M. G., and Schumacher, K.. 2007. ‘Plant proton pumps.’ FEBS Letters, 581 (12): 2204–2214.CrossRefGoogle ScholarPubMed

Gay, P. A., and Tuzun, S.. 2000. ‘Involvement of a novel peroxidase isozyme and lignification in hydathodes in resistance to black rot disease in cabbage.’ Canadian Journal of Botany, 78 (9): 1144–1149.Google Scholar

Georgiou, C. D., Patsoukis, N., Papapostolou, I., and Zervoudakis, G.. 2006. ‘Sclerotial metamorphosis in filamentous fungi is induced by oxidative stress.’ Integrative & Comparative Biology, 46 (6): 691–712.CrossRefGoogle ScholarPubMed

Gessner, F. 1941. ‘Untersuchungen über die beziehung zwischen wurzeldruck und atmung.’ Berichte der Deutschen Botanischen Gesellschaft, 59: 169–173.Google Scholar

Ghosh, M., and Singh, S. P.. 2005. ‘A review on phytoremediation of heavy metals and utilization of its byproducts.’ Applied Ecology and Environmental Research, 3: 1–18.CrossRefGoogle Scholar

Giddings, G., Allison, G., Brooks, D., and Carter, A.. 2000. ‘Transgenic plants as factories for biopharmaceuticals.’ Nature Biotechnology, 18 (11): 1151–1155.CrossRefGoogle ScholarPubMed

Ginsburg, H., and Ginzburg, B. Z.. 1970. ‘Radial water and solute flows in roots of Zea mays L. I. water flows.’ Journal of Experimental Botany, 21: 580–592.CrossRefGoogle Scholar

Ginsburg, H., and Ginzburg, B. Z.. 1971. ‘Evidence for active water transport in a corn root preparations.’ Journal of Membrane Biology, 4 (1): 29–41.CrossRefGoogle Scholar

Glas, J. J., Schimmel, B. C. J., Alba, J. M., R. Escobar-Bravo, Schuurink, R. C., and Kant, M. R.. 2012. ‘Plant glandular trichomes as targets for breeding or engineering of resistance to herbivores.’ International Journal of Molecular Sciences, 13 (12): 17077–17103.CrossRefGoogle Scholar

Goatley, J. L., and Lewis, R. W.. 1966. ‘Composition of guttation fluid from rye, wheat, and barley seedlings.’ Plant Physiology, 41 (3): 373–375.CrossRefGoogle ScholarPubMed

Godlewski, E. 1884. ‘Zur theorie de wasserbewegrang in den pflanzen.’ Jahrbücher für Wissenschaftliche Botanik, 15: 569–630.Google Scholar

Gophna, U., Ron, E. Z., and Graur, D.. 2003. ‘Bacterial type III secretion systems are ancient and evolved by multiple horizontal-transfer events.’ Gene, 312: 151–163.CrossRefGoogle ScholarPubMed

Gordon-Kamm, W. J., and Steponkus, P. L.. 1984. ‘The behaviour of the plasma membrane following osmotic contraction of isolated protoplasts: implications in freezing injury.’ Protoplasma, 123 (2): 83–94.CrossRefGoogle Scholar

Gottschalk, U. 2006. ‘Downstream processing in biomanufacturing: removing economic and technical bottlenecks.’ Bioforum Europe, 10: 28–31.Google Scholar

Gottschalk, U. 2011. ‘Overview of downstream processing in the biomanufacturing industry.’ In Comprehensive Biotechnology (2nd ed.), edited by Moo-Young, M., Butler, M., Webb, C., et al. Oxford: Elsevier/Pergamon, pp. 669–682.CrossRefGoogle Scholar

Govier, R. N., Brown, G. J. S., and Pate, J. S.. 1968. ‘Hemiparasitic nutrition in angiosperms II. Root haustoria and leaf glands of Odontites verna (Bell.) Dum. and their relevance to the abstraction of solutes from the host.’ New Phytologist, 67 (4): 963–972.Google Scholar

Greenhill, Alec Walter, and Albert Charles Chibnall. 1934. ‘The exudation of glutamine from perennial rye-grass.’ Biochemical Journal, 28 (4): 1422–1427.Google Scholar

Grodzinskii, A. M. 2016. Allelopathy in the Life of Plants and Their Communities. Jodhpur, India: Scientific Publishers.Google Scholar

Grossenbacher, K. A. 1938. ‘Diurnal fluctuation in root pressure.’ Plant Physiology, 13 (4): 669–676.Google Scholar

Grossenbacher, K. A.. 1939. ‘Autonomic cycle of rate of exudation of plants.’ American Journal of Botany, 26 (2): 107–109.CrossRefGoogle Scholar

Grovel, O., Pouchus, Y. F., and Verbist, J. F.. 2003. ‘Accumulation of gliotoxin, a cytotoxic mycotoxin from Aspergillus fumigatus, in blue mussel (Mytilus edulis).’ Toxicon, 42 (3): 297–300.Google Scholar

Grunwald, I., Rupprecht, I., Schuster, G., and Kloppstech, K.. 2003. ‘Identification of guttation fluid proteins: the presence of pathogenesis-related proteins in non-infected barley plants.’ Physiologia Plantarum, 119 (2): 192–202.CrossRefGoogle Scholar

Guiry, M. D., and Guiry, G. M.. 2008. ‘Vaucheria: Algae Base.’ National University of Ireland, Galway: World-wide Electronic Publication. Accessed through World Register of Marine Species at: http://www.marinespecies.org/aphia.php?p=taxdetails&id=144303 on December 30, 2019.Google Scholar

Haberlandt, G. 1914. Physiological Plant Anatomy (English translation by Drummond M.). London: Macmillan & Company.Google Scholar

Haberlandt, G. 1924. Physiologische Pflanzenanatomie. Leipzig: Wilhelm Engelmann.Google Scholar

Hakkinen, S. T., Raven, N., Henquet, M., et al. 2014. ‘Molecular farming in tobacco hairy roots by triggering the secretion of a pharmaceutical antibody.’ Biotechnology and Bioengineering, 111 (2): 336–346.CrossRefGoogle ScholarPubMed

Hales, S. 1727. Vegetable Staticks, (or An Account of Some Statical Experiments on the Sap in Vegetables). London: Reprinted by Scientific Book Guild.Google Scholar

Harris, R. I. 1999. ‘Guttation- the basis of an assay for evaluating formulation behaviour in vivo.’ Pesticide Science, 55 (5): 582–583.Google Scholar

Hassan, S, Keshavarz-Moore, E., Ma, J., and Thomas, C.. 2014. ‘Breakage of transgenic tobacco roots for monoclonal antibody release in an ultra-scale down shearing device.’ Biotechnology and Bioengineering, 111 (1): 196–201.Google Scholar

Hayashi, T., Harada, A., Sakai, T., and Takagi, S.. 2006. ‘Ca2+ transient induced by extracellular changes in osmotic pressure in Arabidopsis leaves: differential involvement of cell wall-plasma membrane adhesion.’ Plant, Cell & Environment, 29 (4): 661–672.Google Scholar

Hehle, V. K., Paul, M. J., Drake, P. M., Ma, J. K. C., and van Dolleweerd, C. J.. 2011. ‘Antibody degradation in tobacco plants: a predominantly apoplastic process.’ BMC Biotechnology, 128: 11.Google Scholar

Heimann, M. 1950. ‘Einfluß periodischer beleuchtung auf die guttationsrhythmik.’ Planta, 38 (2): 157–195.Google Scholar

Heimann, M. 1952. ‘Die abhangigkeit des blutungsverlaufs von beleuchtung und blattzahl.’ Planta, 40: 377–390.Google Scholar

Heinen, R. B., Ye, Q., and Chaumont, F.. 2009. ‘Role of aquaporins in leaf physiology.’ Journal of Experimental Botany, 60: 2971–2985.CrossRefGoogle ScholarPubMed

Hellwig, S., Drossard, J., Twyman, R. M., and Fischer, R.. 2004. ‘Plant cell cultures for the production of recombinant proteins.’ Nature Biotechnology, 22 (11): 1415–1422.Google Scholar

Heringa, J. W. 1971. ‘Guttation and dewdrops as contribution to some physiological disorders.’ Landbouwkd Tijdschr, 83: 7.Google Scholar

Hetherington, A. M., and Woodward, F. I.. 2003. ‘The role of stomata in sensing and driving environmental change.’ Nature, 424: 901–908.Google Scholar

Heyl, J. G. 1933. ‘Der einflue von aubenlaktoren auf das bluten der pflanzen.’ Planta, 20: 294–353.CrossRefGoogle Scholar

Hiatt, A., Cafferkey, R., and Bowdish, K.. 1989. ‘Production of antibodies in transgenic plants.’ Nature, 342 (6245): 76–78.CrossRefGoogle ScholarPubMed

Hoagland, D. R. 1944. The Inorganic Nutrition of Plants. Massachusetts: Chronica Botanica Company.Google Scholar

Hoagland, D. R., and Broyer, T. C.. 1936. ‘General nature of the process of salt accumulation by roots with description of experimental methods.’ Plant Physiology, 11 (3): 471–507.Google Scholar

Hoagland, D. R., and Broyer, T. C.. 1942. ‘Accumulation of salt and permeability in plant cells.’ The Journal of General Physiology, 25 (6): 865–880.Google Scholar

Hoffmann, E. J., and Castle, S. J.. 2012. ‘Imidacloprid in melon guttation fluid: a potential mode of exposure for pest and beneficial organisms.’ Journal of Economic Entomology, 105 (1): 67–71.Google Scholar

Hofmeister, W. 1862. ‘Uber Spannung, Ausflussmenge und Ausflussgeschwindigkeit von Saften lebender Pflanzen.’ Flora, 45: 97-108.Google Scholar

Hohn, K. 1951. ‘Beziehungen zwischen blutung und guttation bei zen mays.’ Planta, 39: 65–74.Google Scholar

Holbrook, N. Michele, and Zwieniecki, M. A.. 1999. ‘Embolism repair and xylem tension: do we need a miracle?’ Plant Physiology, 120 (1): 7–10.Google Scholar

Holbrook, N. M., Ahrens, E. T., Burns, M. J., and Zwieniecki, M. A.. 2001. ‘In vivo observation of cavitation and embolism repair using magnetic resonance imaging (MRI).’ Plant Physiology, 126 (1): 27–31.Google Scholar

Holland, M. A. 1997. ‘Occam’s razor applied to hormonology (are cytokinins produced by plants?).’ Plant Physiology, 115 (3): 865–868.Google Scholar

Hone, K., and Vollenweider, G.. 1960. ‘Beziehungen zwischen transpiration, guttation und wachstum bei Avena sativa.’ Beitragezur Biologieder Pflanzen, 35: 41–53.Google Scholar

Hose, E., Steudle, E., and Hartung, W.. 2000. ‘Abscisic acid and hydraulic conductivity of maize roots: a study using cell- and root-pressure probes.’ Planta, 211 (6): 874–882.Google Scholar

House, C. R. 1974. Water Transport in Cells and Tissues. London: Edward Arnold.Google Scholar

House, C. R., and Findlay, N.. 1966. ‘Water transport in isolated maize roots.’ Journal of Experimental Botany, 17 (2): 344–354.Google Scholar

Huber, B. 1956. Die Saftstrome Der Pflanzen. Berlin: Springer.Google Scholar

Hughes, R. N., and Brimblecombe, P. 1994. ‘Dew and guttation: formation and environmental significance.’ Agricultural and Forest Meteorology 67 (3/4): 173–190.Google Scholar

Hugouvieux, V., Barber, C. E., and Daniels, M. J.. 1998. ‘Entry of Xanthomonas campestris pv. campestris into hydathodes of Arabidopsis thaliana leaves: a system for studying early infection events in bacterial pathogenesis.’ Molecular Plant-Microbe Interactions, 11 (6): 537–543.Google Scholar

Hutwimmer, S., Wang, H., Strasser, H., and Burgstaller, W.. 2010. ‘Formation of exudate droplets by Metarhizium anisopliae and the presence of destruxins.’ Mycologia, 102 (1): 1–10.Google Scholar

Ingham, G. 1950. ‘The mineral content of air and rain and its importance to agriculture.’ Journal of Agricultural Science 40 (1/2): 55–61.Google Scholar

Isayenkov, S., Isner, J. C., and Maathuis, F. J. M.. 2010. ‘Vacuolar ion channels: roles in plant nutrition and signalling.’ FEBS Letters, 584 (10): 1982–1988.Google Scholar

Itai, C., and Vaadia, Y.. 1965. ‘Kinetin-like activity in root exudate of water-stressed sunflower plants.’ Physiologia Plantarum, 18 (4): 941–944.Google Scholar

Itai, C., Richmond, A., and Vaadia, Y.. 1968. ‘The role of cytokinins during water and salinity stress.’ Israel Journal of Plant Sciences, 17: 187–195.Google Scholar

Ivanoff, S. S. 1938. ‘Onion blight.’ Texas Agricultural Experiment Station, Fifty-first Annual Report, pp. 260–261.Google Scholar

Ivanoff, S. S. 1941. ‘Chemical deposits on foliage of citrus and other plants and their possible relation to chlorosis and yield.’ Texas Agricultural Experiment Station, Fifty-fourth Annual Report, pp. 181–182.Google Scholar

Ivanoff, S. S. 1944. ‘Guttation-salt injury on leaves of cantaloupe, pepper and onion.’ Phytopathology, 34 (4): 436–437.Google Scholar

Ivanoff, S. S. 1960. ‘Types of injuries on cantaloupe leaves associated with guttation.’ Phytopathology, 50: 640.Google Scholar

Ivanoff, S. S. 1961. ‘Injuries on cantaloupe leaves associated with laminal guttation away from marginal hydathodes.’ Phytopathology, 51: 584–585.Google Scholar

Ivanoff, S. S. 1963. ‘Guttation injuries of plants.’ Botanical Review, 29 (2): 202–229.Google Scholar

Jackson, R. W. 2009. Plant Pathogenic Bacteria: Genomics and Molecular Biology. Norwich: Horizon Scientific Press.Google Scholar

Jaffe, M. J., Leopold, A. C., and Staples, R. A.. 2002. ‘Thigmo responses in plants and fungi.’ American Journal of Botany, 89 (3): 375–382.Google Scholar

Jaradat, T. T., and Allen, R. D.. 1999. ‘Isolation of a novel cDNA encoding an auxin-induced basic helix–loop–helix transcription factor (Accession no. AF 165924) from cotton (Gossypium hirsutum L.).’ Plant Physiology, 121: 685–686.Google Scholar

Jasinski, M., Ducos, E., Martinoia, E., and Boutry, M.. 2003. ‘The ATP-binding cassette transporters: structure, function, and gene family comparison between rice and Arabidopsis.’ Plant Physiology, 131 (3): 1169–1177.Google Scholar

Jennings, D. H. 1991. ‘The role of droplets in helping to maintain a constant growth rate of aerial hyphae.’ Mycological Research, 95 (7): 883–884.Google Scholar

Jin, J., Panicker, D., Wang, Q., et al. 2014. ‘Next generation sequencing unravels the biosynthetic ability of Spearmint (Mentha spicata) peltate glandular trichomes through comparative transcriptomics.’ BMC Plant Biology, 14: 283–292.Google Scholar

Johnson, J. 1936. ‘Relation of root pressure to plant disease.’ Science, 84 (2171): 135–136.Google Scholar

Johnson, L. P. V. 1945. ‘Physiological studies on sap flow in the sugar maple (Acer saccharum Marsh.).’ Canadian Journal of Research, 23 (6): 192–197.Google Scholar

Joshi, Y. C., Qadar, A., and Rana, R. S.. 1979. ‘Differential sodium and potassium accumulation related to sodicity tolerance in wheat.’ Indian Journal of Plant Physiology, 22 (3): 226–230.Google Scholar

Kaldenhoff, R., Kai, L., and Uehlein, N.. 2014. ‘Aquaporins and membrane diffusion of CO2 in living organisms.’ Biochimicaet Biophysica Acta, 1840 (5): 1592–1595.Google Scholar

Kaldenhoff, R., Ribas-Carbo, M., Sans, J. F., Lovisolo, C., Heckwolf, M., and Uehlein, N.. 2008. ‘Aquaporins and plant water balance.’ Plant, Cell & Environment, 31 (5): 658–666.Google Scholar

Karg, S. R., and Kallio, P. T.. 2009. ‘The production of biopharmaceuticals in plant systems.’ Biotechnology Advances, 27 (6): 879–894.Google Scholar

Katou, K., Taura, T., and Furumoto, M.. 1987. ‘A model for water transport in the stele of plants roots.’ Protoplasma 140 (2/3): 123–132.Google Scholar

Katsuhara, M., Hanba, Y. T., Shiratake, K., and Maeshima, M.. 2008. ‘Expanding roles of plant aquaporins in plasma membranes and cell organelles.’ Functional Plant Biology, 35 (1): 1–14.Google Scholar

Kaufmann, I., Schulze-Till, T., Schneider, H. U., Zimmermann, U., Jakob, P., and Wegner, L. H.. 2009. ‘Functional repair of embolized vessels in maize roots after temporal drought stress, as demonstrated by magnetic resonance imaging.’ New Phytologist, 184 (1): 245–256.Google Scholar

Kaufmann, M. R., and Eckard, A. N.. 1971. ‘Evaluation of water stress control with polyethylene glycols by analysis of guttation.’ Plant Physiology, 47 (4): 453–456.Google Scholar

Kerstetter, R. E., Zepp, R. G., and Carreira, L. H.. 1998. ‘Peroxidases in grass dew derived from guttation: possible role in polymerization of soil organic matter.’ Biogeochemistry, 42 (3): 311–323.Google Scholar

Kieber, J. J., and Eric Schaller, G.. 2010. ‘The perception of cytokinin: a story of 50 years in the making.’ Plant Physiology, 154 (2): 487–492.CrossRefGoogle Scholar

Kim, H. J., and Triplett, B. A.. 2001. ‘Cotton fiber growth in plants and in vitro: models for plant cell elongation and cell wall biogenesis.’ Plant Physiology, 127 (4): 1361–1366.Google Scholar

Kim, K., Kwon, S., Lee, H., Hur, Y., Bang, J., and Kwak, S.. 2003. ‘A novel oxidative stress-inducible peroxidase promoter from sweet potato: molecular cloning and characterization in transgenic tobacco plants and cultured cells.’ Plant Molecular Biology, 51 (6): 831–838.Google Scholar

Kim, Y. X., and Steudle, E.. 2009. ‘Gating of aqùaporins by light and reactive oxygen species in leaf parenchyma cells of the midrib of Zea mays.’ Journal of Experimental Botany, 60 (2): 547–556.CrossRefGoogle ScholarPubMed

Kiran, R. 2014. Role of Guttation Fluid in the Spread of Bacterial Blight of Rice. Germany: LAMBERT Academic Publishing.Google Scholar

Kirchhoff, J., Raven, N., Boes, A., et al. 2012. ‘Monoclonal tobacco cell lines with enhanced recombinant protein yields can be generated from heterogeneous cell suspension cultures by flow sorting.’ Plant Biotechnology Journal, 10 (8): 936–944.Google Scholar

Klein, R. 1913. ‘Uber machweis und vorkommen von nitraten und nitriten en pflanzen.’ Beihefte zum Botanischen Centralblatt, 19: 409–452.Google Scholar

Klepper, B., and Kaufmann, M. R.. 1966. ‘Removal of salt from xylem sap by leaves and stems of guttating plants.’ Plant Physiology, 41 (10): 1743–1747.CrossRefGoogle ScholarPubMed

Knipfer, T., Das, D., and Steudle, E.. 2007. ‘During the measurements of root hydraulics with pressure probe, the contribution of unstirred layers is minimized in the pressure relaxation mode: comparison with pressure clamp and high pressure flow meter.’ Plant, Cell and Environment, 30: 845–860.Google Scholar

Knipling, E. B. 1967. ‘Measurement of leaf water potential by the dye method.’ Ecology, 48 (6): 1038–1041.Google Scholar

Koegel-Knaber, I. 2002. ‘The macromolecular organic composition of plants and microbial residues as inputs to soil organic matters.’ Soil Biology & Biochemistry, 34 (2): 139–162.Google Scholar

Koiwai, H., Nakaminami, K., Seo, M., Mitsuhashi, W., Toyomasu, T., and Koshiba, T.. 2004. ‘Tissue-specific localization of an abscisic acid biosynthetic enzyme, AAO3, in Arabidopsis.’ Plant Physiology, 134 (4): 1697–1707.Google Scholar

Komarnytsky, S., and Borisjuk, N. V.. 2012. ‘Plant-derived antibodies for academic, industrial, and therapeutic applications.’ In: Pathak, Y, and Benita, S (eds), Antibody-mediated Drug Delivery Systems: Concepts, Technology, and Applications (1st ed.). New York, NY: John Wiley & Sons.Google Scholar

Komarnytsky, S., Borisjuk, N. V., Borisjuk, L. G., Alam, M. Z., and Raskin, I.. 2000. ‘Production of recombinant proteins in tobacco guttation fluid.’ Plant Physiology, 124 (3): 927–934.Google Scholar

Komarnytsky, S., Borisjuk, N. V., Yakoby, N., Garvey, A., and Raskin, I.. 2006. ‘Co-secretion of protease inhibitor stabilizes antibodies produced by plant roots.’ Plant Physiology, 141 (4): 1185–1193.Google Scholar

Komarnytsky, S., Gaume, A., Garvey, A., Borisjuk, N. V., and Raskin, I.. 2004. ‘A quick and efficient system for antibiotic-free expression of heterologous genes in tobacco roots.’ Plant Cell Reports, 22 (10): 765–773.Google Scholar

Komis, G., Apostolakos, P., and Galatis, B.. 2002. ‘Hyperosmotic stress-induced actin filament reorganisaton in leaf cells of Chlorophyton comosum.’ Journal of Experimental Botany, 53 (375): 1699–1710.Google Scholar

Korolev, A. V., and Zholkevich, V. N.. 1990. ‘The effect of metabolic regulators on root pumping activity.’ Doklady Akademii Nauk SSSR, 310: 507–511.Google Scholar

Kostman, T. A., Tarlyn, N. M., Loewus, F. A., and Franceschi, V. R.. 2001. ‘Biosynthesis of L-Ascorbic acid and conversion of carbons 1 and 2 of L-ascorbic acid to oxalic acid occurs within individual calcium oxalate crystal idioblasts.’ Plant Physiology, 125 (2): 634–640.Google Scholar

Koulman, A., Lane, G. A., Christensen, M. J., Fraser, K., and Tapper, B. A.. 2007. ‘Peramine and other fungal alkaloids are exuded in the guttation fluid of endophyte-infected grasses.’ Phytochemistry, 68 (3): 355–360.Google Scholar

Kramer, P. J. 1939. ‘The forces concerned in the intake of water by transpiring plants.’ American Journal of Botany, 26 (10): 784–791.Google Scholar

Kramer, P. J. 1945. ‘Absorption of water by plants.’ Botanical Review, 11 (6): 310–355.Google Scholar

Kramer, P. J. 1949. Plant and Soil Water Relationships. New York, NY: McGraw-Hill.Google Scholar

Kramer, P. J., and Boyer, J. S.. 1995. Water Relations of Plants and Soils. California: Academic Press.Google Scholar

Kramer, P. J., and Currier, H. B.. 1950. ‘Water relations of plant cells and tissues.’ Annual Review of Plant Physiology, 1: 265–284.Google Scholar

Krasil’nikov, N. A. 1961. ‘Interaction between soil microorganisms and plants.’ In Soil Microorganisms and Higher Plants. Moscow: Academy of Sciences of the USSR (Russian version), 1958. Published in English for The National Science Foundation, Washington, D.C. and The Department of Agriculture, USA by the Israel Program for Scientific Translations in 1961.Google Scholar

Krasnoff, S. B., Keresztes, I., Gillilan, R. E., et al. 2007. ‘Serinocyclins A and B, cyclic heptapeptides from Metarhizium anisopliae.’ Journal of Natural Products, 70 (12): 1919–1924.CrossRefGoogle Scholar

Kundt, W. 1998. ‘The heart of plants.’ Current Science, 75: 98–102.Google Scholar

Kundt, W., and Gruber, E.. 2006. ‘The water circuit of the plants. Do plants have hearts?’ Quantitative Biology, 0603019: 1–19.Google Scholar

Kwak, J. M., Kim, S. A., Hong, S. W., and Nam, H. G.. 1997. ‘Evaluation of 515 expressed sequence tags obtained from guard cells of Brassica campestris.’ Planta, 202 (1): 9–17.Google Scholar

Lagarde, D., Basset, M., Lepetit, M., et al. 1996. ‘Tissue-specific expression of Arabidopsis AKT1 gene is consistent with a role in K+ nutrition.’ The Plant Journal, 9 (2): 195–203.Google Scholar

Lal, R. 2001. ‘Soil degradation by erosion.’ Land Degradation & Development, 12 (6): 519–539.Google Scholar

Lange, B. M., Mahmoud, S. S., Wildung, M. R., et al. 2011. ‘Improving peppermint essential oil yield and composition by metabolic engineering.’ Proceedings of the National Academy of Sciences of the United States of America, 108 (41): 16944–16949.Google Scholar

Lauger, P. 1985. ‘Kinetics of ion channels and ion pumps.’ In: Pullman, A, Vasilescu, V, and Packer, L (eds), Water and Ions in Biological System. Bucharest: Union of Societies for Medical Sciences, pp. 451–462.Google Scholar

Lausberg, T. 1935. ‘Quantitative untersuchungen uber die kuticulare excretion des laublettes.’ Jahrbucher fur Wissenschaftliche Botanik, 81: 769–806.Google Scholar

Lazareva, N. P., Borisova, T. A., and Zholkevich, V. N.. 1986. ‘Auto-oscillatary nature of pumping activity of Zea mays L. root system.’ Doklady Akademii Nauk SSSR, 289: 761–764.Google Scholar

Leakey, A. B. D., Scholes, J. D., and Press, M. C.. 2005. ‘Physiological and ecological significance of sunflecks for dipterocarp seedlings.’ Journal of Experimental Botany, 56 (411): 469–482.Google Scholar

LeClerc, J. A., and Breazeale, J. F.. 1909. Plant food removed from growing plants by rain or dew. U.S. Department of Agriculture Yearbook, pp. 389–402.Google Scholar

Lee, J. J., Woodward, A. W., and Chen, Z. J.. 2007. ‘Gene expression changes and early events in cotton fibre development.’ Annals of Botany, 100 (7): 1391–1401.Google Scholar

Lee, R. E. 2008. Phycology (4th ed.). Cambridge: Cambridge University Press.Google Scholar

Lehto, T., and Zwiazek, J. J.. 2011. ‘Ectomycorrhizas and water relations of trees: a review.’ Mycorrhiza, 21 (2): 71–90.Google Scholar

Lemenih, M., and Kassa, H.. 2011. Opportunities and Challenges for Sustainable Production and Marketing of Gums and Resins in Ethiopia. Bogor, Indonesia: Center for International Forestry Research.Google Scholar

LeNoble, M. E., Spollen, W. G., and Sharp, R. E.. 2004. ‘Maintenance of shoot growth by endogenous ABA: genetic assessment of the involvement of ethylene suppression.’ Journal of Experimental Botany, 55 (395): 237–245.Google Scholar

Lepeschkin, W. W. 1923. ‘Uber active und passive wasserdrusen und wasserspalten.’ Berichte der Deutschen Botanischen Gesellschaft, 41 (7): 298–300.Google Scholar

Lersten, N. R., and Curtis, J. D.. 1982. ‘Hydathodes in Physocarpus (Rosaceae: Spiraeoideae).’ Canadian Journal of Botany, 60 (6): 850–855.Google Scholar

Lersten, N. R., and Curtis, J. D.. 1985. ‘Distribution and anatomy of hydathodes in Asteraceae.’ Botanical Gazette, 146 (1): 106–114.Google Scholar

Lersten, N. R., and Curtis, J. D.. 1991. ‘Laminar hydathodes in Urticaceae: survey of tribes and anatomical observation on Pilea pumila and Urtica dioica.’ Plant Systematics and Evolution 176 (3/4): 179–203.Google Scholar

Lersten, N. R., and Curtis, J. D.. 1986. ‘Tubular cavities in white snakerrot, Eupatorium rugosum (Asteraceae).’ American Journal of Botany, 73 (7): 1016–1021.Google Scholar

Lersten, N. R., and Horner, H. T.. 2011. ‘Unique calcium oxalate “duplex” and “concretion” idioblasts in leaves of tribe Naucleeae (Rubiaceae).’ Amercian Journal of Botany, 94: 1–11.Google Scholar

Lersten, N. R., and Peterson, W. H.. 1974. ‘Anatomy of hydathodes and pigment disks in leaves of Ficusdiversifolia (Moraceae).’ Botanical Journal of Linnaean Society, 68 (2): 109–113.Google Scholar

Letham, D. S. 1994. ‘Cytokinins as phytohormones: sites of biosynthesis, translocation, and function of translocated cytokinin.’ In Cytokinins: Chemistry, Activity and Function, edited by Mok, D. W. S., and Mok, M. C.. Boca Raton, Florida: CRC Press, pp. 57–80.Google Scholar

Levin, D. A. 1973. ‘The role of trichomes in plant defence.’ Quarterly Review of Biology, 48 (1): 3–15.Google Scholar

Levitt, J. 1956. ‘The physical nature of transpiration pulls.’ Plant Physiology, 31: 248–250.Google Scholar

Lewis, R. W. 1962. ‘Guttation fluid: effects on growth of Claviceps purpurea in vitro.’ Science, 138 (3541): 690–691.Google Scholar

Ling, N. X. Y., and Leung, D. W. M.. 2010. ‘Inf luence of sugars and light on rhizosecretion of -glucosidase and acid phosphatase during micropropagation of potato.’ Plant Cell, Tissue and Organ Culture 103 (2): 279-283.Google Scholar

Liu, Q., Parsons, A. J., Xue, H., et al. 2011. ‘Competition between foliar Neotyphodium lolii endophytes and mycorrhizal Glomus spp. fungi in Lolium perenne depends on resource supply and host carbohydrate content.’ Functional Ecology, 25 (4): 910–920.Google Scholar

Lock, J. A., Adler, C. L., and Fleet, R. W.. 2008. ‘Rainbows in the grass. I. External-ref lection rainbows from pendant droplets.’ Applied Optics, 47 (34): 203–213.Google Scholar

Logvenkov, S. A. 1993a. ‘On the guttation mechanism in plants.’ Biophysics, 38 (5): 865–869.Google Scholar

Logvenkov, S. A. 1993b. ‘The guttation mechanism in plants.’ Biophysics, 38: 889–894.Google Scholar

Lohani, A., Verma, A., Joshi, H., Yadav, N., and Karki, N.. 2014. ‘Nanotechnology-based cosmeceuticals.’ ISRN Dermatology, 2014: 1–14.Google Scholar

Long, W. C., Sweet, D. V., and Turkey, H. B.. 1956. ‘Loss of nutrients from plant foliage by leaching as indicated by radioisotopes.’ Science, 123 (3206): 1039–1040.Google Scholar

Loo, D. F., Zeuthen, T., Chandy, G., and Wright, E. M.. 1996. ‘Cotransport of water by the Na+/glucose cotransporter.’ Proceedings of the National Academy of Sciences of the United States of America, 93 (23): 13367–13370.Google Scholar

Lucas, W. J. 1995. ‘Plasmodesmata: intercellular channels for macromolecular transport in plants.’ Current Opinion in Cell Biology, 7 (5): 673–680.Google Scholar

Lundegardh, H. 1944. ‘Bleeding and sap movement.’ Arkiv for Botanik 31 A: 1–56.Google Scholar

Lundegardh, H. 1950. ‘The translocation of salts and water through wheat roots.’ Physiologia Plantarum, 3 (2): 103–151.Google Scholar

Luo, W., and Goudriaan, J.. 2000. ‘Dew formation on rice under varying durations of nocturnal radiative loss.’ Agricultural and Forest Meteorology, 104 (4): 303–313.Google Scholar

Lyalin, O. O., Ktitorova, I. N., Barmicheva, E. M., and Achmedov, N. I.. 1986. ‘Intercellular connections in submerged trichomes of Salvinia.’ Soviet Plant Physiology, 33: 432–446.Google Scholar

Ma, H., Yanofsky, M. F., and Huang, H.. 1991. ‘Isolation and sequence analysis of TGA1 cDNAs encoding a tomato G-protein alpha subunit.’ Gene, 107 (2): 189–195.Google Scholar

Ma, H., Yanofsky, M. F., and Meyerowitz, E. M.. 1990. ‘Molecular cloning and characterization of GPA1, a G protein subunit gene from Arabidopsis thaliana.’ Proceedings of the National Academy of Sciences of the United States of America, 87 (10): 3821–3825.Google Scholar

Ma, J. K. C., Drake, P. M. W., and Christou, P.. 2003. ‘The production of recombinant pharmaceutical proteins in plants.’ Nature Reviews Genetics, 4 (10): 794–805.Google Scholar

Ma, J. K. C., Barros, E., Bock, R., et al. 2005. ‘Molecular farming for new drugs and vaccines- current perspectives on the production of pharmaceuticals in transgenic plants.’ EMBO Reports, 6 (7): 593–599.Google Scholar

Maeda, E., and Maeda, K.. 1987. ‘Ultrastructural studies of leaf hydathodes. I. Wheat (Triticum aestivum) leaf tips.’ Japanese Journal of Crop Sciences, 56 (4): 641–651.Google Scholar

Maeda, E., and Maeda, K.. 1988. ‘Ultrastructural studies of leaf hydathodes. II. Rice (Oryza sativa) leaf tips.’ Japanese Journal of Crop Sciences, 57 (4): 733–742.Google Scholar

Magwa, M. L. 1995. Investigation into the Enzymes of the Guttation Fluid of Plants. South Africa: University of Fort Hare.Google Scholar

Magwa, M. L., Lindner, W. A., and Brand, J. M.. 1993. ‘Guttation fluid peroxidases from Helianthus annuus.’ Phytochemistry, 32: 251–253.Google Scholar

Mahdieh, M., Mostajeran, A., Horie, T., and Katsuhara, M.. 2008. ‘Drought stress alters water relations and expression of PIP-type aquaporin genes inNicotiana tabacum plants.’ Plant & Cell Physiology, 49 (5): 801–813.Google Scholar

Mahmoud, S. S., and Croteau, R. B.. 2001. ‘Metabolic engineering of essential oil yield and composition in mint by altering expression of deoxyxylulose phosphate reductoisomerase and menthofuran synthase.’ Proceeding of the National Academy of Sciences of the United States of America, 98 (15): 8915–8920.Google Scholar

Mann, C. E. T. 1924. ‘The physiology of the nutrition of fruit trees.’ I. Annual Report of Long Ashton Agricultural and Horticultural Research Station, pp. 30–45.Google Scholar

Mann, C. E. T., and Wallace, T.. 1925. ‘The effect of leaching with cold water on the foliage of apple.’ Journal of Pomology and Horticultural Science, 4 (3): 146–161.Google Scholar

Marloth, R. 1887. ‘Zur bedeutung der salz abscheidenden drusen der tama racineen.’ Berichte der Deutschen Botanischen Gesellschaft, 5: 319–324.Google Scholar

Marschner, H. 1995. Mineral Nutrition of Higher Plants. London: Academic Press.Google Scholar

Martin, C. E., and von Willert, D. J.. 2000. ‘Leaf epidermal hydathodes and the ecophysiological consequences of foliar water uptake in species of Crassula from the Namib Desert in Southern Africa.’ Plant Biology, 2 (2): 229–242.Google Scholar

Matsumoto, T., Lian, H., Su, W., et al. 2009. ‘Role of theaquaporin PIP1 subfamily in the chilling tolerance of rice.’ Plant and Cell Physiology, 50 (2): 216–229.Google Scholar

Mattsson, M., Herrmann, B., David, M. B., et al. 2009. ‘Temporal variability in bioassays of the stomatal ammonia compensation point in relation to plant and soil nitrogen parameters in intensively managed grassland.’ Biogeosciences, 6 (2): 171–179.Google Scholar

Maurel, C, Verdoucq, L., Luu, D. T., and Santoni, V.. 2008. ‘Plant aquaporins: membrane channels with multiple integrated functions.’ Annual Review of Plant Biology, 59: 595–624.Google Scholar

Mauseth, J. D. 1988. Plant Anatomy. Menlo Park, CA: The Benjamin/Cummings Publication Company.Google Scholar

McCulloh, K. A., Meinzer, F. C., Sperry, J. S., et al. 2011. ‘Comparative hydraulic architecture of tropical tree species representing a range of successional status and wood density.’ Oecologia, 167 (1): 27–37.Google Scholar

McDowell, N., Pockman, W. T., Allen, C. D., et al. 2008. ‘Mechanisms of plant survival and mortality during drought. Why do some plants survive while others succumb to drought?’ New Phytologist, 178 (4): 719–739.Google Scholar

Mcintyre, G. I. 1994. ‘The role of transpiration in phototropism of the Avena coleoptile: evidence of stomatal control of the phototropic response.’ Australian Journal of Plant Physiology, 21 (3): 359–375.Google Scholar

McKenzie, M. J., Mett, V., Reynolds, P. H. S., Jameson, P. E.. 1998. ‘Controlled cytokinin production in transgenic tobacco using a copper-inducible promoter.’ Plant Physiology, 116 (3): 969–977.Google Scholar

McNear, D. H., Jr., Peltier, E., Everhart, J., et al. 2005. ‘Application of quantitative fluorescence and absorption-edge computed microtomography to image metal compartmentalization in Alyssum murale.’ Environmental Science & Technology, 39 (7): 2210–2218.Google Scholar

Meagher, R. B., and Heaton, A. C.. 2005. ‘Strategies for the engineered phytoremediation of toxic element pollution: mercury and arsenic.’ Journal of Industrial Microbiology and Biotechnology 32 (11/12): 502–513.Google Scholar

Meidner, H. 1977. ‘Sap exudation via the epidermis of leaves.’ Journal of Experimental Botany, 28 (6): 1408–1416.Google Scholar

Melotto, M., Underwood, W., Koczan, J., Nomura, K., and He, S. Y.. 2006. ‘Plant stomata function in innate immunity against bacterial invasion.’ Cell, 126 (5): 969–980.Google Scholar

Merlot, S., Leonhardt, N., Fenzi, F., et al. 2007. ‘Constitutive activation of a plasma membrane H(+)-ATPase prevents abscisic acid-mediated stomatal closure.’ EMBO Journal, 26 (13): 3216–3226.Google Scholar

Meyer, R. C., Yuan, J. T., Afzal, J., et al. 2006. ‘Identification of Gsr1: a locus inferred to regulate gene expression in response to exogenous glutamine.’ Euphytica, 151 (3): 291–302.Google Scholar

Michaud, L. G. 1854. Biographie Universelle Ancienne Et Moderne (1843)- Tome 1. Paris: A. Thoisnier Desplaces.Google Scholar

Miele, L. 1997. ‘Plants as bioreactors for biopharmaceuticals: regulatory considerations.’ Trends in Biotechnology, 15 (2): 45–50.Google Scholar

Mihucz, V. G., Tatar, E., Virag, I., Cseh, E., Fodor, F., and Zaray, G.. 2005. ‘Arsenic speciation in xylem sap of cucumber (Cucumis sativus L.).’ Analytical & Bioanalytical Chemistry, 383 (3): 461–466.Google Scholar

Milburn, J. A. 1979. Water Flow in Plants. London: Longman.Google Scholar

Miret, J. A., and Munne-Bosch, S.. 2014. ‘Plant amino acid-derived vitamins: biosynthesis and function.’ Amino Acids, 46 (4): 809–824.CrossRefGoogle ScholarPubMed

Miyawaki, K., Tarkowski, P., Matsumoto-Kitano, M., et al. 2006. ‘Roles of Arabidopsis ATP/ADP isopentenyltransferases and tRNA isopentenyltransferases in cytokinin biosynthesis.’ Proceedings of the National Academy of Sciences of the United States of America, 103 (44): 16598–16603.Google Scholar

Mizuno, N., Takahashi, A., Wagatsuma, T., Mizuno, T., and Obata, H.. 2002. ‘Chemical composition of guttation fluid and leaves of Petasites japonicus var giganteus and Polygonum cuspidatum growing on ultramafic soil.’ Soil Science & Plant Nutrition, 48 (3): 451–453.Google Scholar

Mizuno, N., Nosaka, S., Mizuno, T., Horie, K., and Obata, H.. 2003. ‘Distribution of Ni and Zn in the leaves to Thlaspi japonicum growing on ultramafic soil.’ Soil Science & Plant Nutrition, 49 (1): 93–97.Google Scholar

Molisch, H. 1916. ‘Beitrage zur mikrochemie der pflanze. Nr. 2: uber orangefarbige hydathoden bei Ficus javanica.’ Berichte der Deutschen Botanischen Gesellschaft, 34: 66–69.Google Scholar

Monshausen, G. B., and Haswell, E. S.. 2013. ‘A force of nature: molecular mechanisms of mechanoperception in plants.’ Journal of Experimental Botany, 64 (15): 4663–4680.Google Scholar

Morris, S. E., Turnbull, C. G. N., Murfet, I. C., and Beveridge, C. A.. 2001. ‘Mutational analysis of branching in pea. Evidence that Rms1 and Rms5 regulate the same novel signal.’ Plant Physiology, 126 (3): 1205–1213.Google Scholar

Morse, W. J. 1920. ‘Some observations upon the effect of borax in fertilizers.’ Maine Agricultural Experiment Station Research Bulletin 288. Orono: Maine Agricultural Experiment Station.Google Scholar

Morth, J. P., Pedersen, B. P., Buch-Pedersen, M. J., et al. 2011. ‘A structural overview of the plasma membrane Na+, K+-ATPase and H+ -ATPase ion pumps.’ Nature Reviews of Molecular Cell Biology, 12: 60–70.Google Scholar

Mortlock, C. 1952. ‘The structure and development of the hydathodes of Ranunculus fluitans Lam.’ New Phytologist, 51 (2): 129–138.Google Scholar

Mozhaeva, L. V., and Bulycheva, E. M.. 1971. ‘Properties of a contractile protein isolated from pumpkin roots.’ Izvestija Timirjazevskoj Sel ’skochozjajstvennoj Akademii, 2: 3–9.Google Scholar

Mozhaeva, L. V., and Pil’shchikova, N. V.. 1972. ‘On the nature of pumping water process by plant roots.’ Izvestija Timirjazevskoj Sel ’skochozjajstvennoj Akademii, 3: 3–15.Google Scholar

Mozhaeva, L. V., and Pil’shchikova, N. V.. 1978. ‘Relationship between root pressure constituents and root water pumping rate.’ Doklady Akademii Nauk SSSR, 239: 1005–1008.Google Scholar

Mozhaeva, L. V., Pil’shchikova, N. V., and Kuzina, V. I.. 1979. ‘Study on the nature of the motive force of plant exudation with the use of chemical effects.’ Izvestija Timirjazevskoj Sel ’skochozjajstvennoj Akademii, 9: 3–9.Google Scholar

Muller, D., and Leyser, O.. 2011. ‘Auxin, cytokinin and the control of shoot branching.’ Annals of Botany, 107 (7): 1203–1212.Google Scholar

Munch, E. 1930. Die Stoftbewegungen in Der Pflanze. Jena: Fischer.Google Scholar

Mungur, R., Glass, A. D. M., Goodenow, D. B., and Lightfoot, D. A.. 2005. ‘Metabolite fingerprinting in transgenic Nicotiana tabacum altered by the Escherichia coli glutamate dehydrogenase gene.’ Journal of Biomedicine and Biotechnology, 2005 (2): 198–214.Google Scholar

Munnecke, D. E., and Chandler, P. A.. 1957. ‘A leaf spot of Philodendron related to stomatal exudation and to temperature.’ Phytopathology, 47 (5): 299–303.Google Scholar

Munns, R., and Tester, M.. 2008. ‘Mechanisms of salinity tolerance.’ Annual Review of Plant Biology, 59: 651–681.Google Scholar

Munns, R., Passioura, J. B., Guo, J., Chazen, O., and Cramer, G. R.. 2000. ‘Water relations and leaf expansion: importance of time scale.’ Journal of Experimental Botany, 51 (350): 1495–1504.Google Scholar

Nagai, M., Ohnishi, M., Uehara, T., et al. 2013. ‘Ion gradients in xylem exudate and guttation fluid related to tissue ion levels along primary leaves of barley.’ Plant, Cell & Environment, 36 (10): 1826–1837.Google Scholar

Nambaru, E., and Marion-Poll, A.. 2005. ‘Abscisic acid biosyntheisis and catabolism.’ Annual Review of Plant Biology, 56: 165–185.Google Scholar

Nardini, A. L., Gullo, M. A., and Salleo, S.. 2011. ‘Refilling embolized xylem conduits:is it a matter of phloem unloading?’ Plant Science 180: 604–611.Google Scholar

Necmi, P. 2005. ‘Investigation of monthly variation in some plant-nutrient contents of guttation fluid samples taken from dieffenbachia plants.’ Journal of Plant Nutrition, 28 (8): 1375–1382.Google Scholar

Niittyla, T., Fuglsang, A. T., Palmgren, M. G., Frommer, W. B., and Schulze, W. X.. 2007. ‘Temporal analysis of sucrose-induced phosphorylation changes in plasma membrane proteins of Arabidopsis.’ Molecular & Cellular Proteomics, 6 (10): 1711–1726.Google Scholar

Ninkovic, V., and Baluska, F.. 2010. Plant Communication from Ecological Perspective. Berlin: Springer.Google Scholar

Nishizawa, N., and Mori, S.. 1977. ‘Invagination of plasmalemma: its role in the absorption of macromolecules in rice roots.’ Plant & Cell Physiology, 18: 767–782.Google Scholar

Nishizawa, N., and Mori, S.. 1978. ‘Endocytosis (heterophagy) in plant cells: involvement of ER and ER-derived vesicles.’ Plant & Cell Physiology, 19 (5): 717–730.Google Scholar

Nobbe, F., and Siegert, T.. 1864. Beitrage zur Pflanzencultur in wassrigen Nahrstoff losungen. Land Ever-State Journal 6: 19–45.Google Scholar