We would like to acknowledge those individuals, organizations, publishers and societies, who have granted permission to reproduce material in this book. Acknowledgements are listed by chapter:
Chapter 3
Figures 3.4,
3.14,
3.15,
3.17,
3.19,
3.23,
3.25,
3.34,
3.36,
3.37 and
3.39, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 3.9B, courtesy of Graham Moore, The John Innes Centre, UK
Figure 3.10, courtesy of Helen Ougham and Sid Thomas, Aberystwyth University, UK
Figure 3.16, from Freeman,
Biological Science, 3rd edition, 2008, Pearson Education
Figure 3.20, courtesy of Neil Jones, Aberystwyth University, UK
Figure 3.35, from Napoli, C., Lemieux, C. and Jorgensen, R., 1990,
The Plant Cell 2, 279–289, The American Society of Plant Biologists
Figure 3.46, source: RCSB PDB,
www.pdb.org. Data originators Gabdoulkhakov, A.G., Savoshkina, Y., Krauspenhaar, R., Stoeva, S., Konareva, N., Kornilov, V., Kornev, A.N., Voelter, W., Nikonov, S.V., Betzel, C. and Mikhailov, A.M.
Tables 3.2,
3.3,
3.4 and
3.5, modified from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Chapter 4
Figures 4.2,
4.5,
4.10,
4.15A,
4.18,
4.24A & D%,
4.25,
4.26,
4.28,
4.36,
4.39 and 4.41, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 4.3, from
Plant Cell Biology on DVD—Information for Students and a Resource for Teachers, Gunning, B.E.S., 2009, Springer Verlag,
www.plantcellbiologyonDVD.com. Micrograph courtesy of Adrienne Hardham, Australian National University
Figure 4.17, from
Plant Cell Biology on DVD—Information for Students and a Resource for Teachers, Gunning, B.E.S., 2009, Springer Verlag,
www.plantcellbiologyonDVD.com. Micrograph A, courtesy of Karl Oparka; micrograph B, courtesy of Martin Steer
Figure 4.18B, courtesy of Peter Eastmond, University of Warwick, UK
Figure 4.21, from
Plant Cell Biology on DVD—Information for Students and a Resource for Teachers, Gunning, B.E.S., 2009, Springer Verlag,
www.plantcellbiologyonDVD.com. Micrograph B, courtesy of Ursula Meindl
Chapter 5
Figure 5.7B, from Bjørn, P. et al. 2007,
Nature 450, 1111–14, Nature Publishing Group
Figure 5.13B, courtesy of C. Toyoshima, University of Tokyo, Japan
Figures 5.18 and
5.19, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 5.23, from Maurel, C., 2007,
FEBS Letters 581 (12): 2227–36, Elsevier
Table 5.1, from Taiz, L. and Zeiger, E.
Plant Physiology, 3rd edition, 2002, Sinauer Associates Inc. Data from Higinbotham et al., 1967
Chapter 6
Figure 6.2A & B, courtesy of Shinjiro Yamaguchi, published in Mikihiro Ogawa, et al., 2003,
The Plant Cell 15: 1591–604, The American Society of Plant Biologists
Figures 6.3,
6.10,
6.12,
6.13,
6.13,
6.15,
6.19,
6.20,
6.30,
6.31 and
6.34 from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 6.11, courtesy of William Hurkman and Delilah Wood, University of California, Berkeley
Figure 6.16A, courtesy of Lacey Samuels, University of British Columbia, Canada
Figure 6.16B, courtesy of Paul Bethke, from Bethke et al., 2007,
Plant Physiology 143: 1173–88, The American Society of Plant Biologists
Figure 6.17, courtesy of T. Okita, Washington State University
Figure 6.21, courtesy of Gerhard Leubner, originally published in Müller et al., 2006,
Plant and Cell Physiology 47: 864–77, Oxford University Press
Figure 6.23, courtesy of Paul Bethke, from Bethke et al., 2007,
Plant Physiology 143: 1173–88, The American Society of Plant Biologists
Figure 6.24, courtesy of Custom Life Science Images, © David McIntyre
Figure 6.27, courtesy of Paul Bethke, from Bethke et al., 2007,
Plant Physiology 143: 1173–88, The American Society of Plant Biologists
Figure 6.29, courtesy of Bob Buchanan, University of California, Berkeley and J. Yin-Zhengzhou, National Engineering Research Centre for Wheat, Henan Agricultural University, China
Table 6.2, from Loren Cordain, ‘Cereal grains: humanity's double-edged sword’ in Simopoulos, A.P. (ed.),
Evolutionary Aspects of Nutrition and Health. Diet, Exercise, Genetics and Chronic Disease, 1999,
World Review of Nutrition and Diet 84: 19–73, Karger, Basel
Tables 6.3,
6.4,
6.7,
6.12,
6.14,
6.15 and
6.16, modified from Bewley and Black,
Seeds: Physiology of Development and Germination, 2nd edition, 1994, Plenum Press
Table 6.10, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Table 6.13, from Stevenson-Paulik et al., 2005,
Proceedings of the National Academy of Sciences 102: 12612–17, National Academy of Sciences
Chapter 8
Figures 8.7,
8.14,
8.16,
8.20,
8.23 and
8.35, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 8.12, from Lopez-Juez, E., Nagatani, A., Tomizawa, K.I., Deak, M., Kern, R., Kendrick, R.E. and Furuya, M., 1992, The cucumber long hypocotyl mutant lacks a light-stable PHYB-like phytochrome.
The Plant Cell 4: 241–51, The American Society of Plant Biologists
Figure 8.21, adapted from Franklin and Whitelam, 2005,
Annals of Botany 96 (2): 169–75, Oxford University Press
Figure 8.26, courtesy of Troy Paddock, National Renewable Energy Laboratory (NREL)
Figure 8.32, from Lagercrantz, U., 2009,
Journal of Experimental Botany 60: 2501–15, Oxford University Press
Table 8.2, after Franklin, K.A. and Quail, P.H., 2010,
Journal of Experimental Botany 61: 11–24, Oxford University Press
Table 8.3, after Banerjee, R. and Batschauer, A., 2005,
Planta 220: 498–502, Springer Verlag
Chapter 10
Figures 10.1,
10.3,
10.5,
10.7,
10.15,
10.20,
10.42,
10.45, 10.48 and 10.50 from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 10.4A, courtesy of Thomas G. Ranney, North Carolina State University
Figure 10.4B, courtesy of Vilem Reinohl, Mendel University, Brno, Czech Republic
Figure 10.8B & C, courtesy of J. Kleine-Vehn and J. Friml, Ghent University, Belgium
Figure 10.9, courtesy of Remko Offring, Leiden University, the Netherlands
Figure 10.13, courtesy of Yuji Kamiya, RIKEN, Japan and Nobutaka Takahashi, University of Tokyo, Japan
Figure 10.14B, courtesy of Peter Hedden, Rothamstead Research, UK
Figure 10.14C, courtesy of Tina Barsby, National Institute of Agricultural Botany (NIAB), UK
Figure 10.28, courtesy of Caren Chang, University of Maryland
Figure 10.34, courtesy of Zhi-yong Wang, Carnegie Institution at Stanford University
Figure 10.49, courtesy of Miguel Blazguez, originally published in Munoz et al., 2008, Development, 135: 2573, The Company of Biologists
Chapter 11
Figures 11.1,
11.2B,
11.12,
11.14,
11.16,
11.17,
11.19,
11.23,
11.24 and
11.25, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 11.2A, courtesy of Neil Jones, Aberystwyth University, UK
Figure 11.7, source:
Proceedings of the National Academy of Sciences of the United States of America, 2005, 102 (43): 15694–9,
www.pnas.org,
Figure 11.9C & D, from Churchman et al., 2006,
The Plant Cell 18: 3145–57, The American Society of Plant Biologists
Figure 11.18B, from Culligan, K., Tissier, A. and Britta, A., 2004, ATR regulates a G2-phase cell-cycle checkpoint in
Arabidopsis thaliana. The Plant Cell 16: 1091–104, The American Society of Plant Biologists
Figure 11.20E, from Laux et al., 1996,
Development 122: 87–96, The Company of Biologists
Figure 11.22A, courtesy of Cal Lemke, University of Oklahoma
Figure 11.29B, courtesy of S.P. Murphy and H.W. Bass, Florida State University
Figure 11.31, from Couteau et al., 1999,
The Plant Cell 11: 1623–34, The American Society of Plant Biologists
Figure 11.32, inset from Brooker,
Genetics: Analysis and Principles, 4th edition, 2011, McGraw-Hill
Chapter 12
Figure 12.1, images from Keiko Sakakibara, Tomoaki Nishiyama, Hironori Deguchi and Mitsuyasu Hasebe, 2008, Class 1 KNOX genes are not involved in shoot development in the moss
Physcomitrella patens but do function in sporophyte development.
Evolution and Development 10: 555–66, John Wiley & Sons
Figure 12.2, courtesy of John Bowman, University of California, Davis
Figures 12.9,
12.12,
12.25,
12.26 and
12.27, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 12.16, from De Smet, I., Lau, S., Mayer, U. and Jurgens, G., 2010, Embryogenesis—the humble beginnings of plant life.
The Plant Journal 61: 959–970, John Wiley & Sons
Figure 12.18, from Foard, D.E. and Haber, A.H., 1961, Anatomic studies of gamma-irradiated wheat growing without cell division.
American Journal of Botany 48: 438–46, The Botanical Society of America
Figure 12.34, from Tsiantis, M. and Hay, A., 2003, Comparative plant development: the time of the leaf?
Nature Reviews Genetics 4: 169–80, Nature Publishing Group
Figure 12.42, from Chatterjee, M., Sparvoli, S., Edmunds, C., Garosi, P., Findlay, K. and Martin, C., 1996, DAG, a gene required for chloroplast differentiation and palisade development in
Antirrhinum majus. EMBO Journal 15: 4194–420, Nature Publishing Group
Figure 12.44, from Byrne, M.E., 2005, Networks in leaf development.
Current Opinion in Plant Biology 8: 59–66, Elsevier
Figure 12.51, from Hedden, P., 2003, The genes of the Green Revolution.
Trends in Genetics 19: 5–9, Elsevier
Figure 12.53, source: Peter Hedden, Rothamstead Research, UK
Figure 12.55, from Fu et al., 2002,
The Plant Cell, The American Society of Plant Biologists
Chapter 13
Figure 13.2, courtesy of M. Faget, ETH, Zürich, Switzerland
Figures 13.7,
13.13,
13.14,
13.15,
13.16,
13.17,
13.19,
13.20,
13.21,
13.22,
13.26,
13.29,
13.30,
13.31,
13.32,
13.34,
13.35,
13.36,
13.37,
13.38,
13.40,
13.42,
13.43,
13.44,
13.45,
13.47 and
13.51, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 13.52, from Bilecen, K., Ozturk, U.H., Duru, A.D., Sutlu, T., Petoukhov, M.V., Svergun, D.I., Koch, M.H.J., Sezerman, U.O., Cakmak, I. and Sayers, Z., 2005,
Triticum durum metallothionein. Isolation of the gene and structural characterization of the protein using solution scattering and molecular modeling.
Journal of Biological Chemistry 280: 13701–11, The American Society for Biochemistry and Molecular Biology
Tables 13.2 and
13.7, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Table 13.8, from Ashley, M.K., Grant, M. and Grabov, A., 2006,
Journal of Experimental Botany 57: 425–36, Oxford University Press
Table 13.9, from Karley, A.J. and White, P.J., 2009,
Current Opinion in Plant Biology 12: 291–8, Elsevier
Chapter 14
Figure 14.4, courtesy of Jean-Pierre Metraux, University of Fribourg, Switzerland
Figures 14.5,
14.6,
14.7,
14.9,
14.10,
14.11,
14.12,
14.15,
14.16,
14.17,
14.18,
14.21,
14.22,
14.24 and
14.30, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 14.8A, from
Plant Cell Biology on DVD—Information for Students and a Resource for Teachers, Gunning, B.E.S., 2009, Springer Verlag,
www.plantcellbiologyonDVD.com. Micrograph courtesy of Robyn Overall, University of Sydney, Australia
Figure 14.13, from Crafts and Yamaguchi,
The Auroradiography of Plant Materials, Calif. Agr. Expt. Station Extension Serv. Manual 35, 1964
Figure 14.26B, courtesy of Lacey Samuels, University of British Columbia Canada, from Suh, M.C. et al., 2005,
Plant Physiology 139: 1649–165, The American Society of Plant Biologists
Figures 14.27A & B, courtesy of David Robinson, University of Heidelberg, Germany
Figure 14.27C, courtesy of Julian Schroeder, University of California, San Diego
Tables 14.2 and
14.3, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Table 14.4, data from Willmer,
Stomata, 1983, Prentice Hall
Table 14.5, modified from Nobel,
Biophysical Plant Physiology and Ecology, 1st edition, 1983, Freeman
Chapter 16
Figures 16.7,
16.9,
16.11,
16.12,
16.16,
16.27,
16.29,
16.30,
16.31,
16.32,
16.34A%,
16.34D%,
16.34E,
16.35,
16.36,
16.39 and
16.42, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 16.3, from Poethig, R.S., 2009, Small RNAs and developmental timing in plants.
Current Opinion in Genetics and Development 19: 374–8, Elsevier
Figure 16.4, from Tooke, F., Ordidge, M., Chiurugwi, T. and Battey, N., 2005, Mechanisms and function of flower and inflorescence reversion.
Journal of Experimental Botany 56: 2587–99, Oxford University Press
Figure 16.10, images of flowers from Krizek, B.A. and Fletcher, J.C., 2005, Molecular mechanisms of flower development: an armchair guide.
Nature Reviews in Genetics 6: 688–98, Nature Publishing Group
Figure 16.23, from Grotewold, E., 2006, The genetics and biochemistry of floral pigments.
Annual Review of Plant Biology 57: 761–80, Annual Reviews
Figure 16.33, from Favaro et al., 2003, MADS-box protein complexes control carpel and ovule development in
Arabidopsis. The Plant Cell 15: 2603–11, The American Society of Plant Biologists
Figure 16.34B & C, from Lolle, S.J. and Pruitt, R.E., 1999,
Trends in Plant Science 4: 14–20, Elsevier
Figure 16.44, from Hochholdinger, F. and Hoecker, N., 2007, Towards the molecular basis of heterosis.
Trends in Plant Science 12: 427–32, Elsevier
Figure 16.46, micrograph from Le et al., 2007,
Plant Physiology 144: 562–74, The American Society of Plant Biologists
Figure 16.47, micrographs from Sabelli, P.A. and Larkins, B.A., 2009,
Plant Physiology 149: 14–26, The American Society of Plant Biologists
Chapter 17
Figure 17.4, from Saska, M.M. and Kuzovkina, Y.A., 2010,
Annals of Applied Biology 156: 431–7, John Wiley & Sons
Figure 17.6, from Jacoby, G.C., Workman, K.W. and D'Arrigo, R.D., 1999,
Quaternary Science Reviews 18: 1365–71, Elsevier
Figure 17.9, modified and simplified from Kloosterman, B., Vorst, O., Hall, R.D., Visser, R.G.F. and Bachem, C.W., 2005, Tuber on a chip: differential gene expression during potato tuber development.
Plant Biotechnology Journal 3: 505–19, John Wiley & Sons
Figure 17.10, pea image courtesy of Neil Jones, Aberystwyth University, UK
Figure 17.16B, from Stupar, R.M., Beaubien, K.A., Jin, W., Song, J., Lee, M-K., Wu, C., Zhang, H-B, Han, B. and Jiang, J., 2006,
Genetics 172: 1263–75, DOI, The Genetics Society of America
Figure 17.17, from Cooke, J.E.K. and Weih, W., 2005, Nitrogen storage and seasonal nitrogen cycling in
Populus: bridging molecular physiology and ecophysiology.
New Phytologist 167: 19–30, John Wiley & Sons. Courtesy of John Greenwood, University of Guelph, Canada
Figure 17.18, courtesy of John Clifton-Brown, Aberystwyth University, UK
Figure 17.27, from Arora, R., Rowland, L.J. and Tanino, K., 2003,
HortScience 38: 911–21, The American Society for Horticultural Science
Figure 17.28, from Chaloupkova, K. and Smart, C.C., 1994,
Plant Physiology 105: 497–507, The American Society of Plant Biologists
Figure 17.31, courtesy of Athole Marshall, Aberystwyth University, UK
Chapter 18
Figures 18.1,
18.3C,
18.5,
18.6,
18.7,
18.8,
18.9,
18.15,
18.17,
18.18,
18.27,
18.28,
18.29,
18.31,
18.32 and
18.36, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2000, The American Society of Plant Biologists
Figure 18.3D, courtesy of David Robinson, University of Heidelberg, Germany
Figure 18.11B, courtesy of Adrian Dauphinee, Gunawardena Laboratory, Biology Department, Dalhousie University, Canada
Figure 18.13, from Shibuya, K., Yamada, T., Suzuki, T., Shimizu, K. and Ichimura, K., 2009, InPSR26, a putative membrane protein, regulates programmed cell death during petal senescence in Japanese morning glory.
Plant Physiology 149: 816–24, The American Society of Plant Biologists.
Figure 18.14, courtesy of Thomas Schoch, License: CC-BY-SA 3.0
Figure 18.22, from Miguel, A., Perez-Amador, M.A. et al., 2000, Identification of BFN1, a bifunctional nuclease induced during leaf and stem senescence in
Arabidopsis. Plant Physiology 122: 169–79, The American Society of Plant Biologists
Figure 18.23, from Zimmermann P., Heinlein, C., Orendi, G. and Zentgraf, U., 2006, Senescence-specific regulation of catalases in
Arabidopsis thaliana (L.) Heynh.
Plant, Cell and Environment 29: 1049–60, John Wiley & Sons
Figure 18.24, courtesy of Helen Ougham and Sid Thomas, Aberystwyth University, UK
Figure 18.25, adapted from Uauy, C., Distelfeld, A., Fahima, T., Blechl, A. and Dubcovsky, J., 2006, A NAC gene regulating senescence improves grain protein, zinc, and iron content in wheat.
Science 314: 1298–301, American Association for the Advancement of Science
Figure 18.26, from Bhalerao, R., Keskitalo, J., Sterky, J.F., Erlandsson R., Björkbacka, H., Birve, S.J., Karlsson, J., Gardeström, P., Gustafsson, P., Lundeberg, J. and Jansson, S., 2003,
Plant Physiology 131: 430–42, The American Society of Plant Biologists
Figure 18.28, images courtesy of Hilda Zavaleta-Mancera, Postgrado de Botánica, Colegio de Postgraduados en Ciencias Agricolas, Montecillo, Mexico
Figure 18.39, from Giovannoni, J.J., 2007, Fruit ripening mutants yield insights into ripening control.
Current Opinion in Plant Biology 10: 283–9, Elsevier
Figure 18.40, leaf images courtesy of Keskitalo, J., Bergquist, G., Gardeström, P. and Jansson S., 2005,
Plant Physiology 139: 1635–48, The American Society of Plant Biologists
Figure 18.45, from Lorrain, Lin et al. 2004. Vascular associated death1, a novel GRAM domain-containing protein, is a regulator of cell death and defense responses in vascular tissues.
The Plant Cell 16: 2217–32, The American Society of Plant Biologists
Table 18.1, from Buchanan-Wollaston, V., Earl, S., Harrison, E., Mathas, E., Navabpour, S., Page, T. and Pink, D., 2003,
Plant Biotechnology Journal 1: 3–22, John Wiley & Sons
Table 18.2, from Prasanna, V., Prabha, T.N. and Tharanathan, R.N., 2007,
Critical Reviews in Food Science and Nutrition 47: 1–19, Taylor & Francis
Table 18.3, from Buchanan, Gruissem and Jones,
Biochemistry and Molecular Biology of Plants, 2nd edition, not yet published, John Wiley & Sons
