Phytochrome evolution: Phytochrome genes in ferns and mosses

Schneider‐Poetsch, Hansjörg A. W.; Marx, Stefan; Kolukisaoglu, H. Üner; Hanelt, Sabine; Braun, Birgit

doi:10.1111/j.1399-3054.1994.tb00425.x

Cited by 31 publications

(15 citation statements)

References 26 publications

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“…This region is conserved in all phytochromes previously isolated and therefore is a useful probe to screen for phytochrome genes and͞or cDNAs (26,27 Fig. 1 A and B).…”

Section: By Using Methods and Conditions Described In Materials Andmentioning

confidence: 99%

A phytochrome from the fern Adiantum with features of the putative photoreceptor NPH1

Nozue

Kanegae

Imaizumi

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

181

111

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In plant photomorphogenesis, it is well accepted that the perception of red͞far-red and blue light is mediated by distinct photoreceptor families, i.e., the phytochromes and blue-light photoreceptors, respectively. Here we describe the discovery of a photoreceptor gene from the fern Adiantum that encodes a protein with features of both phytochrome and NPH1, the putative blue-light receptor for secondpositive phototropism in seed plants. The fusion of a functional photosensory domain of phytochrome with a nearly full-length NPH1 homolog suggests that this polypeptide could mediate both red͞far-red and blue-light responses in Adiantum normally ascribed to distinct photoreceptors.Plants alter their growth and development in response to the light environment through a process known as photomorphogenesis. Several families of photoreceptors contribute to the whole-plant response to light from the UV-B to near-infrared region (1). Red͞far-red light is perceived by phytochrome, a biliprotein of approximately 120 kDa encoded by a multigene family both in seed plants and in cryptogams (2, 3). Blue-light perception is primarily mediated by cryptochromes (CRYs; refs. 4 and 5) and probably by the product of NPH1 locus (6). Based on the phenotypes of the nph1 (nonphototropic hypocotyl) mutant (7) and cry1cry2 double mutant (8), NPH1 has been implicated as the major photoreceptor responsible for blue light-dependent phototropic curvature in seed plants. Indeed, all of the strong nph1 mutant alleles are defective in both first-and second-positive curvature (6), whereas cry1cry2 double mutants are only impaired in first-positive phototropic curvature (8). Owing to the presence of putative flavin-binding sites on the NPH1 polypeptide (7) and epistasis analyses (9), NPH1 appears to be the primary photoreceptor mediating second-positive phototropism in plants.The influence of phytochrome and blue-light photoreceptors on each other's activity is well documented (10). Genetic analyses have clearly demonstrated an interaction between phytochrome and CRY1 signaling pathways (11). Moreover, a direct interaction between phytochrome and the CRY photoreceptors was recently documented (12). In seed plants, blue light-mediated phototropism has been shown to be affected by red-and far red-light treatments (13). Based on these and other studies, it appears likely that the signal-transduction pathways for red-and blue-light photoreceptor families share at least one common component (see ref. 14 for review).The co-action of phytochrome and blue-light photoreceptors has been examined at the cellular level in fern gametophytes, notably for the genus Adiantum (15, 16). In Adiantum, phytochrome-dependent spore germination is suppressed by blue-light irradiation (17). Phytochrome also prolongs blue light-induced cell-cycle progression in filamentous protonemal cells of Adiantum (18). By contrast, phytochrome and bluelight receptors act cooperatively to mediate phototropism of Adiantum protonemata (19) and to affect chloroplast photorelocation...

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“…This region is conserved in all phytochromes previously isolated and therefore is a useful probe to screen for phytochrome genes and͞or cDNAs (26,27 Fig. 1 A and B).…”

Section: By Using Methods and Conditions Described In Materials Andmentioning

confidence: 99%

A phytochrome from the fern Adiantum with features of the putative photoreceptor NPH1

Nozue

Kanegae

Imaizumi

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

181

111

View full text Add to dashboard Cite

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“…P. patens phytochrome (Schneider-Poetsch et al, 1994) and cryptochrome genes (Imaizumi et al, 1999) have been characterized. Besides the well-known effect of increasing photon flux and directional growth responses to light (phototropism), mosses and ferns display a photopolarotropic response; in this case, tip growth localization, orientation of the plane of cell division as well as organelle movement can be modulated by the orientation of the plane of the electrical vector of linearly polarized light (Jenkins and Cove, 1983;Kadota et al, 2000).…”

Section: Physcomitrella Environmental Physiology and Biochemistrymentioning

confidence: 99%

The Moss Physcomitrella patens, Now and Then

Schaefer

2001

Plant Physiology

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“…Their N-tennini are homologous with other phytochrotnes and share 89% of their amino acids; however, the C-terminus of PhyCer is unrelated to CpPHY2 and to all other phytochromes. Additional evidence of diversity in a single taxon comprises reports of multiple phytochromes in Psilotum (Schneider-Poetsch et al 1994), and Anemia (Maucher, Scheuerlein & Schraudolf 1992). However, this diversity may result from taxon-specific diversification; in Psilotum, it may reflect a highly duplicated genome.…”

Section: Phy Gene Diversity In Land Plantsmentioning

confidence: 99%

Phytochrome gene diversity

Mathews

Sharrock

1997

Plant Cell & Environment

265

214

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The structures and functions of the phytochrome apoprotein genes (the PHY genes), their diversity across the plant kingdom, and their evolution are central concerns in the study of red-light sensing in plants. We summarize here recent advances in two areas relating to these topics: (1) the characteristics of the PHY gene family in Arabidopsis thaliana, the higher plant species for which the most extensive information on these genes is available, and (2) the similarity relationships, phylogeny, and evolutionary implications of PHY gene sequences and partial sequences which have been described from various plants. Together, these two areas of study, one directed at understanding in detail the phytochromes present in a single species and the other directed at a much broader understanding of PHY gene relatedness and distribution, are producing an increasingly clear picture of the diversity and evolution of plant red-light photoreceptors. Moreover, they suggest that the complexity of the phytochrome family has increased as land plants have evolved novel morphologies.

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Phytochrome evolution: Phytochrome genes in ferns and mosses

Cited by 31 publications

References 26 publications

A phytochrome from the fern Adiantum with features of the putative photoreceptor NPH1

A phytochrome from the fern Adiantum with features of the putative photoreceptor NPH1

The Moss Physcomitrella patens, Now and Then

Phytochrome gene diversity

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