日本植物バイオテクノロジー学会 (@JspbOfficial)

投稿一覧(最新100件)

Recent advances in steroidal glycoalkaloid biosynthesis in the genus Solanum (Akiyama et al., 2023) https://t.co/vtS6Ngn0cJ #plant_biotechnology_jspb https://t.co/46jtHuA1J2
Peculiar properties of tuber starch in a potato mutant lacking the α-glucan water dikinase 1 gene GWD1 created by targeted mutagenesis using the CRISPR/dMac3-Cas9 system (Ohnuma et al., 2023) https://t.co/SagADH6ErB #plant_biotechnology_jspb https://t.co/OotGpmMvp7
Optimizing genome editing efficiency in wheat: Effects of heat treatments and different promoters for single guide RNA expression (Kishi-Kaboshi et al., 2023) https://t.co/s4VKnxHXY6 #plant_biotechnology_jspb https://t.co/TqM9UkyvkA
Integrated gene-free potato genome editing using transient transcription activator-like effector nucleases and regeneration-promoting gene expression by Agrobacterium infection (Umemoto et al., 2023) https://t.co/4tmdrj0rW5 #plant_biotechnology_jspb https://t.co/eYatp478LK
A multiple shoot induction system for peptide-mediated gene delivery into plastids in Arabidopsis thaliana, Nicotiana benthamiana, and Fragaria × ananassa (Odahara et al., 2023) https://t.co/X5q05nwyuV #plant_biotechnology_jspb https://t.co/LMMEUpf5nH
Site-directed mutagenesis of soybean PEAPOD genes using the CRISPR/Cas9 system alters tissue developmental transition (Sim et al., 2023) https://t.co/r46S6XoWC1 #plant_biotechnology_jspb https://t.co/Q1Cmopwp24
Efficiency of potato genome editing: Targeted mutation on the genes involved in starch biosynthesis using the CRISPR/dMac3-Cas9 system (Kusano et al., 2023) https://t.co/nUUmqfzOEB #plant_biotechnology_jspb https://t.co/uwQLVtSufc
Recent advances in the improvement of soybean seed traits by genome editing (Sim et al., 2023) https://t.co/zX6e0rWuIU #plant_biotechnology_jspb https://t.co/b6Ix6OV2xg
Transcriptome analysis of tomato plants following salicylic acid-induced immunity against Clavibacter michiganensis ssp. michiganensis (Yokotani et al., 2023) https://t.co/hFAYNLWv3N #plant_biotechnology_jspb https://t.co/91R0K4f44z
MYB3R-mediated and cell cycle-dependent transcriptional regulation of a tobacco ortholog of SCARECROW-LIKE28 in synchronized cultures of BY-2 cells (Mineta et al., 2023) https://t.co/tKOZG1W3ac #plant_biotechnology_jspb https://t.co/QRB5LLUmOS
Precise genetic engineering with piggyBac transposon in plants (Nishizawa-Yokoi & Toki, 2023) https://t.co/7MXxek79Kf #plant_biotechnology_jspb https://t.co/EQhR5CuwDD
Efficient double-flowered gentian plant production using the CRISPR/Cas9 system (Nishihara et al., 2023) https://t.co/ybyherXnmy #plant_biotechnology_jspb https://t.co/GZKOsrY8h0
Salt tolerance and regulation of Na+, K+, and proline contents in different wild turfgrasses under salt stress (Tada et al., 2023) https://t.co/EeD3d1yGaP #plant_biotechnology_jspb https://t.co/mgkPPZ3YRZ
ADP-glucose pyrophosphorylase genes are differentially regulated in sugar-dependent or -independent manners in tomato (Solanum lycopersicum L.) fruit (Yin et al., 2023) https://t.co/0aduxXsAJA #plant_biotechnology_jspb https://t.co/6xq5M34sPH
Genome editing and molecular analyses of an Arabidopsis transcription factor, LATE FLOWERING (Nakano et al., 2023) https://t.co/Ri3Q1TZuVw #plant_biotechnology_jspb https://t.co/cvyiitILer
Structural features of T-DNA that induce transcriptional gene silencing during agroinfiltration (Iida et al.,2023) https://t.co/SgnZpEEaK8 #plant_biotechnology_jspb https://t.co/oHmdGxXbQQ
Variety-dependent accumulation of glucomannan in the starchy endosperm and aleurone cell walls of rice grains and its possible genetic basis (Zamorski et al., 2023) https://t.co/3r8kK757Ia #plant_biotechnology_jspb https://t.co/soZtfkwrxs
Development of an efficient Agrobacterium-mediated transformation method and its application in tryptophan pathway modification in Catharanthus roseus (Kisaka et al.2023) https://t.co/7fjwKWLU2y #plant_biotechnology_jspb https://t.co/RcM4a5eDQA
The construction of an Agrobacterium-mediated transformation system of Gynostemma pentaphyllum using the phosphomannose-isomerase/mannose selection system (Tan et al., 2023) https://t.co/vc3wYD6WE5 #plant_biotechnology_jspb https://t.co/vQ3X4jp5vi
Excision of DNA fragments with the piggyBacsystem in Chrysanthemum morifolium (Kishi-Kaboshi et al., 2023) https://t.co/P5MAKpPLqR #plant_biotechnology_jspb https://t.co/OnDRPfs1U8
Development of an inducible excision system of a visual marker Ipomoea batatas Myb gene from the genome of transgenic cells (Sato et al., 2023) https://t.co/YPNBjjeDv7 #plant_biotechnology_jspb https://t.co/NYWbNX53O6
Comparative analysis of endophyte diversity of Dendrobium officinale lived on rock and tree (Li et al., 2023) https://t.co/Iil9xqnusr #plant_biotechnology_jspb https://t.co/lSJ9vq6Khe
Obtainment and confirmation of intergeneric hybrids between marguerite (Argyranthemum frutescens (L.) Sch.Bip.) and two Rhodanthemum species (Katsuoka et al., 2023 ) https://t.co/Jfy6BCL4Lz #plant_biotechnology_jspb https://t.co/vyTw5uHPoi
Optimal culture conditions of Piriformospora indica for volatile compound release to promote effective plant growth (Bayubaskara et al., 2023) https://t.co/F122gXWxOL #plant_biotechnology_jspb https://t.co/dte697VyBC
Expressing recombinant human lactoferrin with antibacterial activity in <i>Nicotiana benthamiana (Miura et al., 2023) https://t.co/3hy2Afhllg #plant_biotechnology_jspb https://t.co/54WZJwznNp
Modulation of wheat grain dormancy by introducing the recombinant abscisic acid-stimulated abscisic acid biosynthesis gene (Zheng et al., 2023) https://t.co/tN77YrcjDm #plant_biotechnology_jspb https://t.co/fN5KLoCCO2
Isopropylmalate synthase NtIPMS as a potential molecular marker for seed vigor in tobacco (Niu et al., 2023) https://t.co/cUvxQeZgA5 #plant_biotechnology_jspb https://t.co/R9OrQ1MR00
Molecular characterization of Satsuma mandarin (Citrus unshiu Marc.) VASCULAR PLANT ONE-ZINC FINGER2 (CuVOZ2) interacting with CuFT1 and CuFT3 (Hasan et al., 2023) https://t.co/PQvCD7uuVJ #plant_biotechnology_jspb https://t.co/rxRo8gD2bY
Complementation and protein localization analyses of R3 MYBs in an Arabidopsis caprice mutant (Wakamatsu et al., 2023) https://t.co/GT95fsfqP7 #plant_biotechnology_jspb https://t.co/JaQwtIdoFC
A simple method for creating transgenic pea hairy roots using a Japanese pea cultivar and a Japanese Rhizobium radiobacter strain (Uchida and Hirai, 2023) https://t.co/3mfaWK7k1R #plant_biotechnology_jspb https://t.co/9hUz6fXfOh
Upstream open reading frame-mediated upregulation of ANAC082 expression in response to nucleolar stress in Arabidopsis (Sasaki et al., 2023) https://t.co/c9VlCtbUCc #plant_biotechnology_jspb https://t.co/4X5Z8ohMiX
The mitochondrial and plastid genomes of Oryza sativa L. cv. Taichung 65 (Ichida et al., 2023) https://t.co/sxizA8uKCX #plant_biotechnology_jspb https://t.co/MU2QXSdMta
Histone chaperone NUCLEOSOME ASSEMBLY PROTEIN 1 proteins affect plant growth under nitrogen deficient conditions in Arabidopsis thaliana (Jie et al., 2023 ) https://t.co/sSIEBqVH6l #plant_biotechnology_jspb https://t.co/pWdK5vs9Zq
Phosphatidylinositol-phospholipase C4 suppresses the hypersensitive response of Nicotiana benthamiana (Fukui et al., 2023) https://t.co/FdqBwIbofF #plant_biotechnology_jspb https://t.co/9KrSOSBELn
A developed system to extract specific responses of increment length in rice shoots under gradient changes in nitrogen concentration regimes (Fukai et al., 2023) https://t.co/N356Zl7zgb #plant_biotechnology_jspb https://t.co/v7fREeRoaP
Downregulation of a cluster of genes encoding nitrate transporter 1/peptide transporter family proteins in tomato with a mutated JRE4 transcription factor (Shoji & Saito, 2023) https://t.co/Gujefr8v6d #plant_biotechnology_jspb https://t.co/kcALGWGHRc
Post-embryonic function of GLOBULAR EMBRYO 4 (GLE4)/OsMPK6 in rice development (Ishimoto et al., 2023) https://t.co/kcJTQa0B7I #plant_biotechnology_jspb https://t.co/eNhbnfdYql
Suppressed expression of ErbB3-binding protein 1 (EBP1) genes compromised the hypersensitive response cell death in Nicotiana benthamiana (Watanabe et al., 2023) https://t.co/D7KKE8XPeC #plant_biotechnology_jspb https://t.co/ugE6MdzQHx
A rapid method for detection of the root-knot nematode resistance gene, Mi-1.2, in tomato cultivars (Furumizu&Sawa, 2023) https://t.co/3yM90eutp1 #plant_biotechnology_jspb https://t.co/At7YkZdzhY
Transformation of Nicotiana paniculata L., a recalcitrant species, using a T-DNA construct carrying two WUSCHEL-related homeobox genes (Kyo et al., 2023) https://t.co/ldg2CsRkWQ #plant_biotechnology_jspb https://t.co/HI8JGIi9aS
The essential role of the quasi-long terminal repeat sequence for replication and gene expression of an endogenous pararetrovirus, petunia vein clearing virus (Kuriyama et al., 2022) https://t.co/Uvc1fnAlxL #plant_biotechnology_jspb https://t.co/rI1EqFvzLO
A RING membrane-anchor E3 ubiquitin ligase gene is co-expressed with steroidal glycoalkaloid biosynthesis genes in tomato (Shoji&Saito, 2022) https://t.co/wni2FyPKXB #plant_biotechnology_jspb https://t.co/I1KNN7P55l
Measurement of reactive oxygen species production by luminol-based assay in Nicotiana benthamiana, Arabidopsis thaliana and Brassica rapa ssp. rapa (Jantean et al., 2022) https://t.co/JW0XTTYgXp #plant_biotechnology_jspb https://t.co/RbnfLAPrQ2
Comprehensive identification of terpene synthase genes and organ-dependent accumulation of terpenoid volatiles in a traditional medicinal plant Angelica archangelica L. (Suenaga-Hiromori et al., 2022) https://t.co/mz4rhMtC71 #plant_biotechnology_jspb https://t.co/CMQBAFW6Jb
Characterization of γ-glutamyltransferase- and phytochelatin synthase-mediated catabolism of glutathione and glutathione S-conjugates in Arabidopsis thaliana (Inoue et al., 2022) https://t.co/bp3K7Bi8L8 #plant_biotechnology_jspb https://t.co/p5YVZLo8AF
Recombinant MBP-pσ1 expressed in soybean seeds delays onset and reduces developing disease in an animal model of multiple sclerosis (Robles et al., 2022) https://t.co/7XMaDzqCzU #plant_biotechnology_jspb https://t.co/Onyr2KxdxH
RNA-seq study reveals the signaling and carbohydrate metabolism regulators involved in dormancy release by warm stratification in Paris polyphylla var. yunnanensis (Yang et al., 2022) https://t.co/y2fD3cnPH2 #plant_biotechnology_jspb https://t.co/wWlKPzd2Dh
Selection of a histidine auxotrophic Marchantia polymorpha strain with an auxotrophic selective marker (Fukushima&Kodama, 2022) https://t.co/2bhVgPiiv2 #plant_biotechnology_jspb https://t.co/sn3iBdIWRh
The influences of fungal endophytes inoculation on the biochemical status of grape cells of different varieties in vitro (Pan et al., 2022) https://t.co/MUTaXMEPkB #plant_biotechnology_jspb https://t.co/JvWT7IyMv4
Transcriptional regulation of cell proliferation competence-associated Arabidopsis genes, CDKA;1, RID1 and SRD2, by phytohormones in tissue culture (Takayanagi et al., 2022) https://t.co/FUq3DtQfhf #plant_biotechnology_jspb https://t.co/fvTxkiY8IL
Oxicam-type nonsteroidal anti-inflammatory drugs enhance Agrobacterium-mediated transient transformation in plants (Choi et al., 2022) https://t.co/u0aCN93HgW #plant_biotechnology_jspb https://t.co/rahamY5Ed9
Early flowering phenotype of the Arabidopsis altered meristem program1 mutant is dependent on the FLOWERING LOCUS T-mediated pathway (Nobusawa et al., 2022) https://t.co/opQ5vkF9G7 #plant_biotechnology_jspb https://t.co/eRVBeUWLud
Comprehensive effects of heavy-ion beam irradiation on sweet potato (Ipomoea batatas [L.] Lam.) (Park et al., 2022) https://t.co/ta3qi7OR1g #plant_biotechnology_jspb https://t.co/113js33JUT
IRE1-mediated cytoplasmic splicing and regulated IRE1-dependent decay of mRNA in the liverwort Marchantia polymorpha (Takeda et al., 2022) https://t.co/u39yBnilLU #plant_biotechnology_jspb https://t.co/uJuj5qeSBf
High-level transient production of a protease-resistant mutant form of human basic fibroblast growth factor in Nicotiana benthamiana leaves (Macauyag et al., 2022) https://t.co/mStZLld443 #plant_biotechnology_jspb https://t.co/Z24UAi81Zo
Identification of a regiospecific S-oxygenase for the production of marasmin in traditional medicinal plant Tulbaghia violacea (Wang et al., 2022) https://t.co/rn3BDV5sRt #plant_biotechnology_jspb https://t.co/spG9uAWFe3
Establishment of an efficient transformation method of garden stock (Matthiola incana) using a callus formation chemical inducer (Tanahara et al., 2022) https://t.co/LW1u5cxcfr #plant_biotechnology_jspb https://t.co/j9YqRqHCWm
Transcriptome sequencing and DEG analysis in different developmental stages of floral buds induced by potassium chlorate in Dimocarpus longan (Huang et al., 2022) https://t.co/YUJwRogVg9 #plant_biotechnology_jspb https://t.co/uw1ROgjmlp
Establishment of a genetic transformation system for Codonopsis pilosula callus (Liu et al., 2022) https://t.co/3bxxp6OX0A #plant_biotechnology_jspb https://t.co/NoW4jb24F4
Production of benzylglucosinolate in genetically engineered carrot suspension cultures (Kurzbach et al., 2022) https://t.co/LhPHNm76ZB #plant_biotechnology_jspb https://t.co/2PYC2lju9E
High-transcriptional activation ability of bamboo SECONDARY WALL NAC transcription factors is derived from C-terminal domain (Sakamoto et al., 2022) https://t.co/kktEKk5ZHz #plant_biotechnology_jspb https://t.co/2Z4cBugizi
Role of GSL8 in low calcium tolerance in Arabidopsis thaliana (Shikanai et al., 2022) https://t.co/VujSkHuh3M #plant_biotechnology_jspb https://t.co/SCSMgY5czF
Tetraploidization promotes radial stem growth in poplars (Umeda-Hara et al., 2022) https://t.co/oqaJcXmBc0 #plant_biotechnology_jspb https://t.co/u0iH7z34Aw
Dear prospective authors of Plant Biotechnology "JSPB has to inform you about the hike of the page charge regarding the manuscripts received after November 1st, 2022.” https://t.co/nxptgx13TT #plant_biotechnology_jspb https://t.co/c0kFnRGCTK
Arabidopsis homeobox-leucine zipper transcription factor BRASSINOSTEROID-RELATED HOMEOBOX 3 regulates leaf greenness by suppressing BR signaling (Hasegawa et al., 2022) https://t.co/DQY4nsbiWk #plant_biotechnology_jspb https://t.co/KEWO47OdTb
Induction of dwarf and early flowering phenotypes in Tricyrtis sp. by ectopic expression of LEAFY from Arabidopsis thaliana (Sankhuan et al., 2022) https://t.co/sP9gZzBzN1 #plant_biotechnology_jspb https://t.co/EmNJyp38Bp
The simple and rapid quantification method for L-3,4-dihydroxyphenylalanine (L-DOPA) from plant sprout using liquid chromatography-mass spectrometry (Yumoto et al., 2022) https://t.co/U7wcWcCpjr #plant_biotechnology_jspb https://t.co/9z5EiTBqSK
Procedure for the efficient acquisition of progeny seeds from crossed potato plants grafted onto tomato (Takeuchi et al., 2022) https://t.co/E2ubOrowuT #plant_biotechnology_jspb https://t.co/IpismSvAcM
Arabidopsis zinc finger homeodomain transcription factor BRASSINOSTEROID-RELATED HOMEOBOX 2 acts as a positive regulator of brassinosteroid response (Hasegawa et al., 2022) https://t.co/4gEXUMhrFv #plant_biotechnology_jspb https://t.co/i4K7pHZ5cn
Temperature-controlled atmospheric-pressure plasma treatment induces protein uptake via clathrin-mediated endocytosis in tobacco cells (Yanagawa et al., 2022) https://t.co/82o7V1SQwM #plant_biotechnology_jspb https://t.co/17TZftzsAq
Conjugates of 3-phenyllactic acid and tryptophan enhance root-promoting activity without adverse effects in Vigna angularis (Maki et al., 2022) https://t.co/Orhx2clOiB #plant_biotechnology_jspb https://t.co/oxzdryM5Cc
In vitro selection of blackberry (Rubus fruticosus ‘Tupy’) plants resistant to Botrytis cinerea using gamma ray-irradiated shoot tips (Huerta-Olalde et a., 2022) https://t.co/JOscn6wn5M #plant_biotechnology_jspb https://t.co/5E8z5OiUfI
Heterologous expression of flowering locus T promotes flowering but does not affect diurnal movement in the legume Lotus japonicus (Harada et al., 2022) https://t.co/mP6r8bAwUr #plant_biotechnology_jspb https://t.co/An7ZXnw87D
VND-INTERACTING2 effectively inhibits transcriptional activities of VASCULAR-RELATED NAC-DOMAIN7 through a conserved sequence (Ailizati et al., 2022) https://t.co/A53vHuA9eO #plant_biotechnology_jspb https://t.co/EPpx4Qyn6j
Comparison of constitutive promoter activities and development of maize ubiquitin promoter- and Gateway-based binary vectors for rice (Tsuda et al., 2022) https://t.co/Awqb48EvlG #plant_biotechnology_jspb https://t.co/gGhVtAH3LW
THESEUS1 is involved in tunicamycin-induced root growth inhibition, ectopic lignin deposition, and cell wall damage-induced unfolded protein response (Nakamura et al., 2022) https://t.co/GzZjDSt2RA #plant_biotechnology_jspb https://t.co/nzAgE3IkG6
OsCERK2/OsRLK10, a homolog of OsCERK1, has a potential role for chitin-triggered immunity and arbuscular mycorrhizal symbiosis in rice (Miyata et al., 2022) https://t.co/RStrSGjzdM #plant_biotechnology_jspb https://t.co/Z5q5cz1kKI
3-Phenyllactic acid is converted to phenylacetic acid and induces auxin-responsive root growth in Arabidopsis plants (Maki) https://t.co/IgxodmaOM0 #plant_biotechnology_jspb https://t.co/gP0kfJZXBN
Introduction of a long synthetic repetitive DNA sequence into cultured tobacco cells (Ohzeki et al., 2022) https://t.co/46LlOHAtIN #plant_biotechnology_jspb https://t.co/F1UqWQ9Iqq
Intergeneric hybridization of marguerite (Argyranthemum frutescens (L.) Sch. Bip.) and Roman chamomile (Chamaemelum nobile (L.) All.) using ovule culture and confirmation of hybridity (Katsuoka et al., 2022) https://t.co/6SlHhvLyCJ #plant_biotechnology_jspb https://t.co/XRm7ZLXGov
Evaluation of pollen tube growth ability in Petunia species having different style lengths (Kato et al., 2022) https://t.co/Wqka9oZ74u #plant_biotechnology_jspb https://t.co/ezQFBeG9Wg
Dear prospective authors of Plant Biotechnology (JSPB has to inform you new page charge regarding the manuscripts received after November 1st, 2022) https://t.co/rzJx1VMQxk #plant_biotechnology_jspb https://t.co/vyOrl2n5XQ
Preface to the special issue “Stem cell reformation in plants” (Iwase & Umeda, 2022) https://t.co/KWGSeoY2Gq #plant_biotechnology_jspb https://t.co/HVJLNn52QO
Evolution of root nodule symbiosis: Focusing on the transcriptional regulation from the genomic point of view (Battenberg & Hayashi, 2022) https://t.co/cEr7Y95YEo #plant_biotechnology_jspb https://t.co/UCWagpLNLr
Brassinosteroids are required for efficient root tip regeneration in Arabidopsis (Takahashi & Umeda, 2022) https://t.co/aeTmlArzo0 #plant_biotechnology_jspb https://t.co/dSinRewNlt
A glycogen synthase kinase 3-like kinase MpGSK regulates cell differentiation in Marchantia polymorpha (Furuya et al., 2022) https://t.co/jNOFw5qnei #plant_biotechnology_jspb https://t.co/aUrmELmGZb
Competitive action between Brassinosteroid and tracheary element differentiation inhibitory factor in controlling xylem cell differentiation (Kondo 2022) https://t.co/r8JmbrOel6 #plant_biotechnology_jspb https://t.co/5hkdtEsVHm
4-Phenylbutyric acid promotes plant regeneration as an auxin by being converted to phenylacetic acid via an IBR3-independent pathway (Iwase et al., 2022) https://t.co/6UKyNWPWkZ #plant_biotechnology_jspb https://t.co/NmfQa8qNQW
Enhancement of shoot regeneration by treatment with inhibitors of auxin biosynthesis and transport during callus induction in tissue culture of Arabidopsis thaliana (Ohbayashi, Sakamoto et al., 2022) https://t.co/yihD4F1gjb #plant_biotechnology_jspb https://t.co/b1ufYu7f0S
Expression of the auxin biosynthetic genes YUCCA1 and YUCCA4 is dependent on the boundary regulators CUP-SHAPED COTYLEDON genes in the Arabidopsis thaliana embryo (Yamada et al., 2022) https://t.co/OAxoiUoqvc #plant_biotechnology_jspb https://t.co/5yeqRYtned
Pericycle cell division competence underlies various developmental programs (Zhang et al., 2022) https://t.co/8cK9kxIdjR #plant_biotechnology_jspb https://t.co/BXFr27E2Hd
Illuminating the molecular mechanisms underlying shoot apical meristem homeostasis in plants (Shimotohno 2022) https://t.co/YNlQaukuyq #plant_biotechnology_jspb https://t.co/7Uiww6RH38
Abscisic acid switches cell division modes of asymmetric cell division and symmetric cell division in stem cells of protonemal filaments in the moss Physcomitrium patens (Hiroguchi et al., 2022) https://t.co/JNzNuN1SPr #plant_biotechnology_jspb https://t.co/jMlkUxhkiJ
Migration of prospindle before the first asymmetric division in germinating spore of Marchantia polymorph (Sakai et al., 2022) https://t.co/kzbs2mKT4l #plant_biotechnology_jspb https://t.co/0u4WDqeazj
RT @Docbenitake: 私たちの論文がPlant Biotechnology誌の特集号に掲載されたので宣伝です! 4PBA(4-フェニル酪酸)がオーキシンとして働くことを再発見しました。シロイヌナズナの中で天然オーキシンとして知られているPAA(フェニル酢酸)に変換…
Analysis of N-glycan profile of Arabidopsis alg3 cell culture (Sariyatun et al., 2021) https://t.co/D9mXFbnClL #plant_biotechnology_jspb https://t.co/UcJtHdIwPN
Efficient Agrobacterium-mediated genetic transformation method using hypocotyl explants of radish (Raphanus sativus L.) (Muto et al., 2021) https://t.co/1lIiQsjfG9 #plant_biotechnology_jspb https://t.co/2cW3Vo0nQ8
Inactivation of plant and animal viruses by proanthocyanidins from Alpinia zerumbet extract (Narusaka et al., 2021) https://t.co/5JrvbGK6n1 #plant_biotechnology_jspb https://t.co/aoeEXjdaFB
Culture-based preservation of Marchantia polymorpha gemmalings and thalli without encapsulation, drying, or freezing (Takahashi & Kodama, 2021) https://t.co/y2vR0TlLfj #plant_biotechnology_jspb https://t.co/IxjdU1XsG1

お気に入り一覧(最新100件)

私たちの論文がPlant Biotechnology誌の特集号に掲載されたので宣伝です! 4PBA(4-フェニル酪酸)がオーキシンとして働くことを再発見しました。シロイヌナズナの中で天然オーキシンとして知られているPAA(フェニル酢酸)に変換されているようです。 https://t.co/RNZJ7CqPX3 https://t.co/8QZsTTHhTh

フォロー(383ユーザ)の投稿一覧(直近7日間)

フォロワー(442ユーザ)の投稿一覧(直近7日間)