Handbook of Plant and Crop Physiology

(Steven Felgate) #1

  1. LW Tam, DL Kirk. Identification of cell-type-specific genes of Volvox carteriand characterization of their ex-
    pression during the asexual life cycle. Dev Biol 145:51–66, 1991.

  2. G Choi, M Przybylska, D Straus. Three abundant germ line–specific transcripts in Volvox carteriencode pho-
    tosynthetic proteins. Curr Genet 30:347–355, 1996.

  3. DL Kirk. Volvox: Molecular-Genetic Origins of Multicellularity and Cellular Differentiation. Cambridge: Cam-
    bridge University Press, 1999, p 321.

  4. P Puente, N Wei, XW Deng. Combinatorial interplay of promoter elements constitutes the minimal determinants
    for light and developmental control of gene expression in Arabidopsis. EMBO J 15:3732–3743, 1996.

  5. DJ Cove, NW Ashton. In: AF Dyer, JG Duckett, eds. The Experimental Biology of Bryophytes. London: Aca-
    demic Press, 1984, pp 177–202.

  6. BS Gorton, RE Eakin. Development of the gametophyte in the moss Tortella caespitosa. Bot Gaz 119:31–38,
    1957.

  7. PJ Boyd, NH Grimsley, DJ Cove. Somatic mutagenesis of the moss, Physcomitrella patens. Mol Gen Genet
    211:545–546, 1988.

  8. NH Grimsley, NW Ashton, DJ Cove. The production of somatic hybrids by protoplast fusion in the moss,
    Physcomitrella patens. Mol Gen Genet 154:97–100, 1977.

  9. DJ Cove, CD Knight, T Lamparter. Mosses as model systems. Trends Plant Sci 2:99–105, 1997.

  10. M Lal. The culture of bryophytes including apogamy, apospory, parthenogenesis and protoplasts. In: AF Dyer,
    JG Duckett, eds. The Experimental Biology of Bryophytes. London: Academic Press, 1984, pp 97–116.

  11. B Knoop. Development of bryophytes. In: AF Dyer, JG Duckett, eds. The Experimental Biology of Bryophytes.
    London: Academic Press, 1984, pp 143–176.

  12. KS Schumaker, MA Dietrich. Programmed changes in form during moss development. Plant Cell 9:1099–1107,
    1997.

  13. CD Knight, A Sehgal, K Atwal, J Wallace, DJ Cove, D Coates, RS Quatrano, S Bahadur, P Stockely, AC Cum-
    ing. Molecular responses to abscisic acid and stress are conserved between mosses and cereals. Plant Cell
    7:499–506, 1995.

  14. J Machuka, S Bashiardes, E Ruben, K Spooner, A Cuming, C Knight, D Cove. Sequence analysis of expressed
    sequence tags from an ABA-treated cDNA library identifies stress response genes in the moss Physcomitrella
    patens. Plant Cell Physiol 40:378–387, 1999.

  15. DJ Cove, CD Knight. The moss Physcomitrella patens, a model system with potential for the study of plant re-
    production. Plant Cell 5:1483–1488, 1993.

  16. M Bopp, HJ Jacob. Cytokinin effect on branching and bud formation in Funaria. Planta 169:462–464, 1986.

  17. K Reutter, R Atzorn, B Hadeler, T Schmulling, R Reski. Expression of the bacterial ipt gene in Physcomitrella
    rescues mutations in budding and in plastid division. Planta 206:196–203, 1998.

  18. DR Featherstone, DJ Cove, NW Ashton. Genetic analysis by somatic hybridization of cytokinin overproducing
    developmental mutants of the moss, Physcomitrella patens. Mol Gen Genet 222:217–224, 1990.

  19. DJ Cove, RS Quatrano, E Hartmann. The alignment of the axis of asymmetry in regenerating protoplasts of the
    moss,Ceratodon purpureus, is determined independently of axis polarity. Development 122:371–379, 1996.

  20. E Hartmann, GI Jenkins. Photomorphogenesis of mosses and liverworts. In: AF Dyer, JG Duckett, eds. The Ex-
    perimental Biology of Bryophytes. London: Academic Press, 1984, pp 203–228.

  21. DJ Cove, A Schild, NW Ashton, E Hartmann. Genetic and physiological studies of the effect of light on the de-
    velopment of the moss Physcomitrella patens. Photochem Photobiol 27:249–254, 1978.

  22. DJ Cove, CD Knight. Gravitropism and phototropism in the moss Physcomitrella patens. In: H Thomas, D Gri-
    erson, eds. Developmental Mutants in Higher Plants. Cambridge: Cambridge University Press, 1987, pp
    181–197.

  23. T Lamparter, H Esch, D Cove, J Hughes, E Hartmann. Aphototropic mutants of the moss Ceratodon purpureus
    with spectrally normal and with spectrally dysfunctional phytochrome. Plant Cell Environ 19:560–568, 1996.

  24. H Esch, E Hartmann, D Cove, M Wada, T Lamparter. Phytochrome-controlled phototropism of the moss Cer-
    atodon purpureus: physiology of the wild type and class 2 ptr-mutants. Planta 209:290–298, 1999.

  25. GI Jenkins, GRM Courtice, DJ Cove. Gravitropic responses of wild-type and mutant strains of the moss
    Physcomitrella patens. Plant Cell Environ 9:637–644, 1986.

  26. CD Knight, DJ Cove. The polarity of gravitropism in the moss Physcomitrella patensis reversed during mito-
    sis and after growth on a clinostat. Plant Cell Environ 14:995–1001, 1991.

  27. FD Sack. Gravitropism in protonemata of the moss Ceratodon. Mem Torrey Bot Club 25:36–44, 1993.

  28. OA Kuznetsov, J Schwuchow, FD Sack. Curvature induced by amyloplast magnetophoresis in protonemata of
    the moss Ceratodon purpureus. Plant Physiol 119:645–650, 1999.

  29. T Lamparter, J Hughes, E Hartmann. Blue light– and genetically-reversed gravitropic response in protonemata
    of the moss Ceratodon purpureus. Planta 206:95–102, 1999.

  30. R Reski. Molecular genetics of Physcomitrella. Planta 208:301–309, 1999.

  31. R Reski, M Faust, XH Wang, M Wehe, WO Abel. Genome analysis of the moss Physcomitrella patens. Mol
    Gen Genet 244:352–359, 1994.

  32. R Reski, S Reynolds, M Wehe, T Kleber-Janke, S Kruse. Moss (Physcomitrella patens) ESTs include several
    sequences which are novel for plants. Bot Acta 111:145–151, 1998.


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