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Artículos de revistas sobre el tema "Physcomitrella paten"

Autor: Grafiati
Publicado: 11 de marzo de 2023

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1

Zhou, Xun, Guan Nan Guo, Le Qi Wang, Su Lan Bai, Chun Li Li, Rong Yu y Yan Hong Li. "Paenibacillus physcomitrellae sp. nov., isolated from the moss Physcomitrella patens". International Journal of Systematic and Evolutionary Microbiology 65, Pt_10 (1 de octubre de 2015): 3400–3406. http://dx.doi.org/10.1099/ijsem.0.000428.

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A Gram-stain-positive, facultatively anaerobic and rod-shaped bacterium, designated strain XBT, was isolated from Physcomitrella patens growing in Beijing, China. The isolate was identified as a member of the genus Paenibacillus based on phenotypic characteristics and phylogenetic inferences. The novel strain was spore-forming, motile, catalase-negative and weakly oxidase-positive. Optimal growth of strain XBT occurred at 28°C and pH 7.0–7.5. The major polar lipids contained diphosphatidylglycerol, phosphatidylglycerol, phosphatidylethanolamine and several unidentified components, including one phospholipid, two aminophospholipids, three glycolipids, one aminolipid and one lipid. The predominant isoprenoid quinone was MK-7. The diamino acid found in the cell-wall peptidoglycan was meso-diaminopimelic acid. The major fatty acid components (>5 %) were anteiso-C15 : 0 (51.2 %), anteiso-C17 : 0 (20.6 %), iso-C16 : 0 (8.3 %) and C16 : 0 (6.7 %). The G+C content of the genomic DNA was 53.3 mol%. Phylogenetic analysis, based on the 16S rRNA gene sequence, showed that strain XBT fell within the evolutionary distances encompassed by the genus Paenibacillus; its closest phylogenetic neighbour was Paenibacillus yonginensis DCY84T (96.6 %). Based on phenotypic, chemotaxonomic and phylogenetic properties, strain XBT is considered to represent a novel species of the genus Paenibacillus, for which the name Paenibacillus physcomitrellae sp. nov., is proposed. The type strain is XBT ( = CGMCC 1.15044T = DSM 29851T).
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2

Reski, Ralf y David J. Cove. "Physcomitrella patens". Current Biology 14, n.º 7 (abril de 2004): R261—R262. http://dx.doi.org/10.1016/j.cub.2004.03.016.

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3

Gorina, S. S. y Y. Y. Toporkova. "OXYLIPINS. DYNAMICS GENE EXPRESSION OF THE LIPOXYGENASE CASCADE OF MOSS PHYSCOMITRELLA PATENS DURING INFECTION". ÈKOBIOTEH 3, n.º 2 (2020): 157–65. http://dx.doi.org/10.31163/2618-964x-2020-3-2-157-165.

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4

Cove, David. "The Moss, Physcomitrella patens". Journal of Plant Growth Regulation 19, n.º 3 (1 de septiembre de 2000): 275–83. http://dx.doi.org/10.1007/s003440000031.

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5

Sha, Wei, Li Wu y Xiao Hong Song. "In Silicon Cloning and Bioinformatics Analysis of an Eukaryotic Initiation Factor 4E Gene from Grimmia pilifera". Applied Mechanics and Materials 138-139 (noviembre de 2011): 1132–38. http://dx.doi.org/10.4028/www.scientific.net/amm.138-139.1132.

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GH425 gene comes from the Grimmia pilifera drought stress of cDNA library.In this experiment,we have got the full sequence of GH425NO.1 by E-cloning which using GH425 as gene probe,in Physcomitrella patens DNA Datebase.Through using ORFfinder to find out the longest ORF and design primer for it,then, validated the Physcomitrella patens by PT-PCR,and we have obtained corresponding band and proved that the result of silicon cloning is correct and the fragment is contained in Grimmia pilifera P.Beauv.Now,we know the sequence encodes Eukaryotic initiation factor 4E by Blastx,and analysis it with Bioinformatics.
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6

Schaefer, D. "Gene targeting in Physcomitrella patens". Current Opinion in Plant Biology 4, n.º 2 (1 de abril de 2001): 143–50. http://dx.doi.org/10.1016/s1369-5266(00)00150-3.

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7

Cove, D. J., P. F. Perroud, A. J. Charron, S. F. McDaniel, A. Khandelwal y R. S. Quatrano. "Culturing the Moss Physcomitrella patens". Cold Spring Harbor Protocols 2009, n.º 2 (1 de febrero de 2009): pdb.prot5136. http://dx.doi.org/10.1101/pdb.prot5136.

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8

Bricker, Terry M., Adam J. Bell, Lan Tran, Laurie K. Frankel y Steven M. Theg. "Photoheterotrophic growth of Physcomitrella patens". Planta 239, n.º 3 (27 de noviembre de 2013): 605–13. http://dx.doi.org/10.1007/s00425-013-2000-3.

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9

Sarnighausen, Eric, Virginie Wurtz, Dimitri Heintz, Alain Van Dorsselaer y Ralf Reski. "Mapping of the Physcomitrella patens proteome". Phytochemistry 65, n.º 11 (junio de 2004): 1589–607. http://dx.doi.org/10.1016/j.phytochem.2004.04.028.

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10

Arazi, Tzahi. "MicroRNAs in the moss Physcomitrella patens". Plant Molecular Biology 80, n.º 1 (4 de marzo de 2011): 55–65. http://dx.doi.org/10.1007/s11103-011-9761-5.

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11

Zhou, Xun, Guan Nan Guo, Le Qi Wang, Su Lan Bai y Yan Hong Li. "Cnuibacter physcomitrellae gen. nov., sp. nov., a novel member of the family Microbacteriaceae isolated from the moss of Physcomitrella patens". International Journal of Systematic and Evolutionary Microbiology 66, n.º 2 (1 de febrero de 2016): 680–88. http://dx.doi.org/10.1099/ijsem.0.000775.

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12

Scholz, Julia, Florian Brodhun, Ellen Hornung, Cornelia Herrfurth, Michael Stumpe, Anna K. Beike, Bernd Faltin, Wolfgang Frank, Ralf Reski y Ivo Feussner. "Biosynthesis of allene oxides in Physcomitrella patens". BMC Plant Biology 12, n.º 1 (2012): 228. http://dx.doi.org/10.1186/1471-2229-12-228.

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13

Schaefer, Didier G. y Jean-Pierre Zrÿd. "The Moss Physcomitrella patens, Now and Then". Plant Physiology 127, n.º 4 (1 de diciembre de 2001): 1430–38. http://dx.doi.org/10.1104/pp.010786.

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14

Bezanilla, Magdalena, Aihong Pan y Ralph S. Quatrano. "RNA Interference in the Moss Physcomitrella patens". Plant Physiology 133, n.º 2 (octubre de 2003): 470–74. http://dx.doi.org/10.1104/pp.103.024901.

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15

QUATRANO, R., S. MCDANIEL, A. KHANDELWAL, P. PERROUD y D. COVE. "Physcomitrella patens: mosses enter the genomic age". Current Opinion in Plant Biology 10, n.º 2 (abril de 2007): 182–89. http://dx.doi.org/10.1016/j.pbi.2007.01.005.

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16

Peramuna, Anantha, Hansol Bae, Erling Koch Rasmussen, Bjørn Dueholm, Thomas Waibel, Joanna H. Critchley, Kerstin Brzezek, Michael Roberts y Henrik Toft Simonsen. "Evaluation of synthetic promoters in Physcomitrella patens". Biochemical and Biophysical Research Communications 500, n.º 2 (junio de 2018): 418–22. http://dx.doi.org/10.1016/j.bbrc.2018.04.092.

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17

Schaefer, D., J. P. Zryd, C. D. Knight y D. J. Cove. "Stable transformation of the moss Physcomitrella patens". Molecular and General Genetics MGG 226, n.º 3 (mayo de 1991): 418–24. http://dx.doi.org/10.1007/bf00260654.

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18

Prigge, M. J. y M. Bezanilla. "Evolutionary crossroads in developmental biology: Physcomitrella patens". Development 137, n.º 21 (12 de octubre de 2010): 3535–43. http://dx.doi.org/10.1242/dev.049023.

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19

Boyd, Philip J., Nigel H. Grimsley y David J. Cove. "Somatic mutagenesis of the moss, Physcomitrella patens". Molecular and General Genetics MGG 211, n.º 3 (marzo de 1988): 545–46. http://dx.doi.org/10.1007/bf00425715.

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20

Krumm, Andrea. "Entwicklung eines Produktionsorganismus — das Moos Physcomitrella patens". BIOspektrum 26, n.º 2 (marzo de 2020): 187–88. http://dx.doi.org/10.1007/s12268-020-1350-1.

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21

Reski, Ralf, Hansol Bae y Henrik Toft Simonsen. "Physcomitrella patens, a versatile synthetic biology chassis". Plant Cell Reports 37, n.º 10 (24 de mayo de 2018): 1409–17. http://dx.doi.org/10.1007/s00299-018-2293-6.

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22

Zhao, Mengkai, Qilong Li, Zhenhua Chen, Qiang Lv, Fang Bao, Xiaoqin Wang y Yikun He. "Regulatory Mechanism of ABA and ABI3 on Vegetative Development in the Moss Physcomitrella patens". International Journal of Molecular Sciences 19, n.º 9 (12 de septiembre de 2018): 2728. http://dx.doi.org/10.3390/ijms19092728.

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The moss Physcomitrella patens is a model system for studying plant developmental processes. ABSCISIC ACID INSENSITIVE3 (ABI3), a transcription factor of the ABA signaling pathway, plays an important role in plant growth and development in vascular plant. To understand the regulatory mechanism of ABA and PpABI3 on vegetative development in Physcomitrella patens, we applied physiological, cellular, and RNA-seq analyses in wild type (WT) plants and ∆abi3 mutants. During ABA treatment, the growth of gametophytes was inhibited to a lesser extent ∆abi3 plants compared with WT plants. Microscopic observation indicated that the differentiation of caulonemata from chloronemata was accelerated in ∆abi3 plants when compared with WT plants, with or without 10 μM of ABA treatment. Under normal conditions, auxin concentration in ∆abi3 plants was markedly higher than that in WT plants. The auxin induced later differentiation of caulonemata from chloronemata, and the phenotype of ∆abi3 plants was similar to that of WT plants treated with exogenous indole-3-acetic acid (IAA). RNA-seq analysis showed that the PpABI3-regulated genes overlapped with genes regulated by the ABA treatment, and about 78% of auxin-related genes regulated by the ABA treatment overlapped with those regulated by PpABI3. These results suggested that ABA affected vegetative development partly through PpABI3 regulation in P. patens; PpABI3 is a negative regulator of vegetative development in P. patens, and the vegetative development regulation by ABA and PpABI3 might occur by regulating the expression of auxin-related genes. PpABI3 might be associated with cross-talk between ABA and auxin in P. patens.
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23

Odahara, Masaki. "Factors Affecting Organelle Genome Stability in Physcomitrella patens". Plants 9, n.º 2 (23 de enero de 2020): 145. http://dx.doi.org/10.3390/plants9020145.

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Organelle genomes are essential for plants; however, the mechanisms underlying the maintenance of organelle genomes are incompletely understood. Using the basal land plant Physcomitrella patens as a model, nuclear-encoded homologs of bacterial-type homologous recombination repair (HRR) factors have been shown to play an important role in the maintenance of organelle genome stability by suppressing recombination between short dispersed repeats. In this review, I summarize the factors and pathways involved in the maintenance of genome stability, as well as the repeats that cause genomic instability in organelles in P. patens, and compare them with findings in other plant species. I also discuss the relationship between HRR factors and organelle genome structure from the evolutionary standpoint.
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24

Luo, Weifeng, Setsuko Komatsu, Tatsuya Abe, Hideyuki Matsuura y Kosaku Takahashi. "Comparative Proteomic Analysis of Wild-Type Physcomitrella Patens and an OPDA-Deficient Physcomitrella Patens Mutant with Disrupted PpAOS1 and PpAOS2 Genes after Wounding". International Journal of Molecular Sciences 21, n.º 4 (19 de febrero de 2020): 1417. http://dx.doi.org/10.3390/ijms21041417.

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Wounding is a serious environmental stress in plants. Oxylipins such as jasmonic acid play an important role in defense against wounding. Mechanisms to adapt to wounding have been investigated in vascular plants; however, those mechanisms in nonvascular plants remain elusive. To examine the response to wounding in Physcomitrella patens, a model moss, a proteomic analysis of wounded P. patens was conducted. Proteomic analysis showed that wounding increased the abundance of proteins related to protein synthesis, amino acid metabolism, protein folding, photosystem, glycolysis, and energy synthesis. 12-Oxo-phytodienoic acid (OPDA) was induced by wounding and inhibited growth. Therefore, OPDA is considered a signaling molecule in this plant. Proteomic analysis of a P. patens mutant in which the PpAOS1 and PpAOS2 genes, which are involved in OPDA biosynthesis, are disrupted showed accumulation of proteins involved in protein synthesis in response to wounding in a similar way to the wild-type plant. In contrast, the fold-changes of the proteins in the wild-type plant were significantly different from those in the aos mutant. This study suggests that PpAOS gene expression enhances photosynthesis and effective energy utilization in response to wounding in P. patens.
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25

Ćosić, Marija, Milorad M. Vujičić, Marko S. Sabovljević y Aneta D. Sabovljević. "Effects of ABA and NaCl on physiological responses in selected bryophyte species". Botany 98, n.º 11 (noviembre de 2020): 639–50. http://dx.doi.org/10.1139/cjb-2020-0041.

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The effects of NaCl and abscisic acid (ABA) on selected bryophyte species were studied. Two phylogenetically unrelated halophyte mosses, namely, Entosthodon hungaricus (Boros) Loeske and Hennediella heimii (Hedw.) R.H. Zander in addition to one model non-halophyte moss, Physcomitrella patens (Hedw.) Bruch & Schimp, were selected to compare the variability in certain biochemical and physiological parameters under salt-stress alone and salt-stress upon ABA pretreatment. The results showed different patterns of effects from ABA in all three of the studied species, as well as no common response to salt stress. In general, all of the tested species reacted to exogenous ABA, which definitely contributed to changes observed in morphological development under salt stress, and to the functioning of the salt-tolerance mechanisms. Physcomitrella patens proved to be a salt-tolerant species. Although it is not ecologically classified as a halophyte, these results highlighted that various stress-resistance pathways are supported by similar reactions to different stresses. Significant differences in stress tolerance were documented between the two bryo-halophytes tested by comparing biochemical and physiological parameters. Our findings suggest that different salt-stress-tolerance strategies characterize these two species, both enhanced by exogenous ABA.
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26

Wu, Guochun, Sha Li, Xiaochuan Li, Yunhong Liu, Shuangshuang Zhao, Baohui Liu, Huapeng Zhou y Honghui Lin. "A Functional Alternative Oxidase Modulates Plant Salt Tolerance in Physcomitrella patens". Plant and Cell Physiology 60, n.º 8 (23 de mayo de 2019): 1829–41. http://dx.doi.org/10.1093/pcp/pcz099.

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Abstract Alternative oxidase (AOX) has been reported to be involved in mitochondrial function and redox homeostasis, thus playing an essential role in plant growth as well as stress responses. However, its biological functions in nonseed plants have not been well characterized. Here, we report that AOX participates in plant salt tolerance regulation in moss Physcomitrella patens (P. patens). AOX is highly conserved and localizes to mitochondria in P. patens. We observed that PpAOX rescued the impaired cyanide (CN)-resistant alternative (Alt) respiratory pathway in Arabidopsis thaliana (Arabidopsis) aox1a mutant. PpAOX transcription and Alt respiration were induced upon salt stress in P. patens. Using homologous recombination, we generated PpAOX-overexpressing lines (PpAOX OX). PpAOX OX plants exhibited higher Alt respiration and lower total reactive oxygen species accumulation under salt stress condition. Strikingly, we observed that PpAOX OX plants displayed decreased salt tolerance. Overexpression of PpAOX disturbed redox homeostasis in chloroplasts. Meanwhile, chloroplast structure was adversely affected in PpAOX OX plants in contrast to wild-type (WT) P. patens. We found that photosynthetic activity in PpAOX OX plants was also lower compared with that in WT. Together, our work revealed that AOX participates in plant salt tolerance in P. patens and there is a functional link between mitochondria and chloroplast under challenging conditions.
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27

Ikram, Kashkooli, Peramuna, Krol, Bouwmeester y Simonsen. "Insights into Heterologous Biosynthesis of Arteannuin B and Artemisinin in Physcomitrella patens". Molecules 24, n.º 21 (23 de octubre de 2019): 3822. http://dx.doi.org/10.3390/molecules24213822.

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: Metabolic engineering is an integrated bioengineering approach, which has made considerable progress in producing terpenoids in plants and fermentable hosts. Here, the full biosynthetic pathway of artemisinin, originating from Artemisia annua, was integrated into the moss Physcomitrella patens. Different combinations of the five artemisinin biosynthesis genes were ectopically expressed in P. patens to study biosynthesis pathway activity, but also to ensure survival of successful transformants. Transformation of the first pathway gene, ADS, into P. patens resulted in the accumulation of the expected metabolite, amorpha-4,11-diene, and also accumulation of a second product, arteannuin B. This demonstrates the presence of endogenous promiscuous enzyme activity, possibly cytochrome P450s, in P. patens. Introduction of three pathway genes, ADS-CYP71AV1-ADH1 or ADS-DBR2-ALDH1 both led to the accumulation of artemisinin, hinting at the presence of one or more endogenous enzymes in P. patens that can complement the partial pathways to full pathway activity. Transgenic P. patens lines containing the different gene combinations produce artemisinin in varying amounts. The pathway gene expression in the transgenic moss lines correlates well with the chemical profile of pathway products. Moreover, expression of the pathway genes resulted in lipid body formation in all transgenic moss lines, suggesting that these may have a function in sequestration of heterologous metabolites. This work thus provides novel insights into the metabolic response of P. patens and its complementation potential for A. annua artemisinin pathway genes. Identification of the related endogenous P. patens genes could contribute to a further successful metabolic engineering of artemisinin biosynthesis, as well as bioengineering of other high-value terpenoids in P. patens.
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28

Schaefer, Didier G. y Jean-Pierre Zryd. "Efficient gene targeting in the moss Physcomitrella patens". Plant Journal 11, n.º 6 (junio de 1997): 1195–206. http://dx.doi.org/10.1046/j.1365-313x.1997.11061195.x.

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29

Miyazaki, Sho, Mariho Hara, Shinsaku Ito, Keisuke Tanaka, Tadao Asami, Ken-ichiro Hayashi, Hiroshi Kawaide y Masatoshi Nakajima. "An Ancestral Gibberellin in a Moss Physcomitrella patens". Molecular Plant 11, n.º 8 (agosto de 2018): 1097–100. http://dx.doi.org/10.1016/j.molp.2018.03.010.

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30

Mueller, Stefanie J., Sebastian N. W. Hoernstein y Ralf Reski. "The mitochondrial proteome of the moss Physcomitrella patens". Mitochondrion 33 (marzo de 2017): 38–44. http://dx.doi.org/10.1016/j.mito.2016.07.007.

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31

Martínez-Cortés, Teresa, Federico Pomar, Fuencisla Merino y Esther Novo-Uzal. "A proteomic approach to Physcomitrella patens rhizoid exudates". Journal of Plant Physiology 171, n.º 17 (noviembre de 2014): 1671–78. http://dx.doi.org/10.1016/j.jplph.2014.08.004.

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32

Liu, Yunhong, Qianyuan Gong, Jiaxian He, Xia Sun, Xiaochuan Li, Shuangshuang Zhao, Qingwei Meng, Honghui Lin y Huapeng Zhou. "PpAOX regulates ER stress tolerance in Physcomitrella patens". Journal of Plant Physiology 251 (agosto de 2020): 153218. http://dx.doi.org/10.1016/j.jplph.2020.153218.

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33

Smidkova, M., M. Hola y K. J. Angelis. "Efficient biolistic transformation of the moss Physcomitrella patens". Biologia plantarum 54, n.º 4 (1 de diciembre de 2010): 777–80. http://dx.doi.org/10.1007/s10535-010-0141-9.

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34

Fojtová, Miloslava, Eva Sýkorová, Lucie Najdekrová, Pavla Polanská, Dagmar Zachová, Radka Vagnerová, Karel J. Angelis y Jiří Fajkus. "Telomere dynamics in the lower plant Physcomitrella patens". Plant Molecular Biology 87, n.º 6 (21 de febrero de 2015): 591–601. http://dx.doi.org/10.1007/s11103-015-0299-9.

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35

ASHTON, NEIL W., CONNIE E. M. CHAMPAGNE, TRACEY WEILER y LAURENT K. VERKOCZY. "The bryophyte Physcomitrella patens replicates extrachromosomal transgenic elements". New Phytologist 146, n.º 3 (junio de 2000): 391–402. http://dx.doi.org/10.1046/j.1469-8137.2000.00671.x.

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36

Tran, M. L. y A. W. Roberts. "Cellulose synthase gene expression profiling of Physcomitrella patens". Plant Biology 18, n.º 3 (7 de diciembre de 2015): 362–68. http://dx.doi.org/10.1111/plb.12416.

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Agarwal, Tanushree, Gouranga Upadhyaya, Tanmoy Halder, Abhishek Mukherjee, Arun Lahiri Majumder y Sudipta Ray. "Different dehydrins perform separate functions in Physcomitrella patens". Planta 245, n.º 1 (16 de septiembre de 2016): 101–18. http://dx.doi.org/10.1007/s00425-016-2596-1.

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38

Banerjee, Aparajita, Jonathan A. Arnesen, Daniel Moser, Balindile B. Motsa, Sean R. Johnson y Bjoern Hamberger. "Engineering modular diterpene biosynthetic pathways in Physcomitrella patens". Planta 249, n.º 1 (23 de noviembre de 2018): 221–33. http://dx.doi.org/10.1007/s00425-018-3053-0.

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39

Schlink, Katja y Ralf Reski. "Preparing high-quality DNA from moss (Physcomitrella patens)". Plant Molecular Biology Reporter 20, n.º 4 (diciembre de 2002): 423. http://dx.doi.org/10.1007/bf02772133.

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40

von Schwartzenberg, K., W. Schultze y H. Kassner. "The moss Physcomitrella patens releases a tetracyclic diterpene". Plant Cell Reports 22, n.º 10 (12 de febrero de 2004): 780–86. http://dx.doi.org/10.1007/s00299-004-0754-6.

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41

Richter, Hanna, Reinhard Lieberei, Miroslav Strnad, Ondrej Novák, Jiri Gruz, Stefan A. Rensing y Klaus von Schwartzenberg. "Polyphenol oxidases in Physcomitrella: functional PPO1 knockout modulates cytokinin-dependent developmentin the moss Physcomitrella patens". Journal of Experimental Botany 63, n.º 14 (29 de agosto de 2012): 5121–35. http://dx.doi.org/10.1093/jxb/ers169.

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42

Mahmood, Niaz y Nahid Tamanna. "Analyses of Physcomitrella patens Ankyrin Repeat Proteins by Computational Approach". Molecular Biology International 2016 (27 de junio de 2016): 1–8. http://dx.doi.org/10.1155/2016/9156735.

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Ankyrin (ANK) repeat containing proteins are evolutionary conserved and have functions in crucial cellular processes like cell cycle regulation and signal transduction. In this study, through an entirely in silico approach using the first release of the moss genome annotation, we found that at least 54 ANK proteins are present in P. patens. Based on their differential domain composition, the identified ANK proteins were classified into nine subfamilies. Comparative analysis of the different subfamilies of ANK proteins revealed that P. patens contains almost all the known subgroups of ANK proteins found in the other angiosperm species except for the ones having the TPR domain. Phylogenetic analysis using full length protein sequences supported the subfamily classification where the members of the same subfamily almost always clustered together. Synonymous divergence (dS) and nonsynonymous divergence (dN) ratios showed positive selection for the ANK genes of P. patens which probably helped them to attain significant functional diversity during the course of evolution. Taken together, the data provided here can provide useful insights for future functional studies of the proteins from this superfamily as well as comparative studies of ANK proteins.
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43

Koselski, Mateusz, Piotr Wasko, Kamil Derylo, Marek Tchorzewski y Kazimierz Trebacz. "Glutamate-Induced Electrical and Calcium Signals in the Moss Physcomitrella patens". Plant and Cell Physiology 61, n.º 10 (18 de agosto de 2020): 1807–17. http://dx.doi.org/10.1093/pcp/pcaa109.

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Abstract The mode of transmission of signals between plant cells is an important aspect of plant physiology. The main role in the generation of long-distance signals is played by changes in the membrane potential and cytoplasm calcium concentration, but the relationship between these responses evoked by the same stimuli in the same plant remains unknown. As one of the first plants that colonized land, the moss Physcomitrella patens is a suitable model organism for studying the evolution of signaling pathways in plants. Here, by the application of glutamate as a stimulus, we demonstrated that electrical but not calcium signals can be true carriers of information in long-distance signaling in Physcomitrella. The generation of electrical signals in a form of propagating transient depolarization seems to be dependent on the opening of calcium channels since the responses were reduced or totally blocked by calcium channel inhibitors. While the microelectrode measurements demonstrated the transmission of electric signals between leaf cells and juvenile cells (protonema), the fluorescence imaging of cytoplasmic calcium changes indicated that calcium response occurs only locally—at the site of glutamate application, and only in protonema cells. This study indicates different involvement of glutamate-induced electrical and calcium signals in cell-to-cell communication in these evolutionarily old terrestrial plants.
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44

Peng, Xingji, Xingguang Deng, Xiaoya Tang, Tinghong Tan, Dawei Zhang, Baohui Liu y Honghui Lin. "Involvement of Lhcb6 and Lhcb5 in Photosynthesis Regulation in Physcomitrella patens Response to Abiotic Stress". International Journal of Molecular Sciences 20, n.º 15 (26 de julio de 2019): 3665. http://dx.doi.org/10.3390/ijms20153665.

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There are a number of highly conserved photosystem II light-harvesting antenna proteins in moss whose functions are unclear. Here, we investigated the involvement of chlorophyll-binding proteins, Lhcb6 and Lhcb5, in light-harvesting and photosynthesis regulation in Physcomitrella patens. Lhcb6 or Lhcb5 knock-out resulted in a disordered thylakoid arrangement, a decrease in the number of grana membranes, and an increase in the number of starch granule. The absence of Lhcb6 or Lhcb5 did not noticeably alter the electron transport rates. However, the non-photochemical quenching activity in the lhcb5 mutant was dramatically reduced when compared to wild-type or lhcb6 plants under abiotic stress. Lhcb5 plants were more sensitive to photo-inhibition, while lhcb6 plants showed little difference compared to the wild-type plants under high-light stress. Moreover, both mutants showed a growth malformation phenotype with reduced chlorophyll content in the gametophyte. These results suggested that Lhcb6 or Lhcb5 played a unique role in plant development, thylakoid organization, and photoprotection of PSII in Physcomitrella, especially when exposed to high light or osmotic environments.
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45

Fernandez‐Pozo, Noe, Fabian B. Haas, Rabea Meyberg, Kristian K. Ullrich, Manuel Hiss, Pierre‐François Perroud, Sebastian Hanke et al. "PEATmoss ( Physcomitrella Expression Atlas Tool): a unified gene expression atlas for the model plant Physcomitrella patens". Plant Journal 102, n.º 1 (11 de enero de 2020): 165–77. http://dx.doi.org/10.1111/tpj.14607.

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46

Sun, Ming-Ming, Lin-Hui Li, Hua Xie, Rong-Cai Ma y Yi-Kun He. "Differentially Expressed Genes under Cold Acclimation in Physcomitrella patens". BMB Reports 40, n.º 6 (30 de noviembre de 2007): 986–1001. http://dx.doi.org/10.5483/bmbrep.2007.40.6.986.

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47

Leech, Mark J., Wolfgang Kammerer, David J. Cove, Cathie Martin y Trevor L. Wang. "Expression ofmyb-related genes in the moss,Physcomitrella patens". Plant Journal 3, n.º 1 (enero de 1993): 51–61. http://dx.doi.org/10.1046/j.1365-313x.1993.t01-3-00999.x.

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48

Ludwig-Müller, Jutta, Sabine Jülke, Nicole M. Bierfreund, Eva L. Decker y Ralf Reski. "Moss (Physcomitrella patens ) GH3 proteins act in auxin homeostasis". New Phytologist 181, n.º 2 (21 de noviembre de 2008): 323–38. http://dx.doi.org/10.1111/j.1469-8137.2008.02677.x.

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49

Oda, Yoshihisa, Aiko Hirata, Toshio Sano, Tomomichi Fujita, Yuji Hiwatashi, Yoshikatsu Sato, Akeo Kadota, Mitsuyasu Hasebe y Seiichiro Hasezawa. "Microtubules Regulate Dynamic Organization of Vacuoles in Physcomitrella patens". Plant and Cell Physiology 50, n.º 4 (27 de febrero de 2009): 855–68. http://dx.doi.org/10.1093/pcp/pcp031.

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50

Zobell, O., G. Coupland y B. Reiss. "The Family of CONSTANS‐Like Genes in Physcomitrella patens". Plant Biology 7, n.º 3 (mayo de 2005): 266–75. http://dx.doi.org/10.1055/s-2005-865621.

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