start-ver=1.4
cd-journal=joma
no-vol=
cd-vols=
no-issue=
article-no=
start-page=
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20251222
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Suppression of Na+ Uptake Via Apoplastic Flow by Chitosan in Rice
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Purpose: Chitosan enhances tolerance to salinity in rice. Apoplastic flow plays a crucial role in the accumulation of sodium (Na+) in rice under salinity. This study investigated the effects of exogenous chitosan on apoplastic flow and Na+ uptake in NaCl-treated rice seedlings. Methods: We employed an apoplastic tracer, trisodium salt of 8-hydroxy-1,3,6-pyrenetrisulphonic acid (PTS), in order to evaluate apoplastic flow in rice (Oryza sativa L., cv. Nipponbare) seedlings that were hydroponically grown in the solution containing NaCl (0 and 25 mM), and chitosan (0 mg L??1, 10 mg L??1, and 50 mg L??1). Results: Application of 25 mM NaCl significantly increased PTS uptake and Na+ content in shoots but did not affect K+ content, resulting in a lower K+/Na+ ratio although 25 mM NaCl did not affect the seedling growth. The application of chitosan suppressed Na+-enhanced PTS uptake and Na+ accumulation in shoots without affecting the K+ content, which led to a higher K+/Na+ ratio. Moreover, chitosan did not affect the reducing sugar content or electrical conductivity in the solution containing NaCl. Conclusions: These results suggest that application of chitosan suppressed Na+-enhanced apoplastic flow to reduce Na+ uptake in rice seedlings.
en-copyright=
kn-copyright=

en-aut-name=ZhaoMaoxiang
en-aut-sei=Zhao
en-aut-mei=Maoxiang
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=GalibMd. Asadulla Al
en-aut-sei=Galib
en-aut-mei=Md. Asadulla Al
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=NakamuraToshiyuki
en-aut-sei=Nakamura
en-aut-mei=Toshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=NakamuraYoshimasa
en-aut-sei=Nakamura
en-aut-mei=Yoshimasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=HiraiYoshihiko
en-aut-sei=Hirai
en-aut-mei=Yoshihiko
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=NakashimaYoshitaka
en-aut-sei=Nakashima
en-aut-mei=Yoshitaka
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

en-aut-name=MunemasaShintaro
en-aut-sei=Munemasa
en-aut-mei=Shintaro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=7
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=8
ORCID=

en-aut-name=MurataYoshiyuki
en-aut-sei=Murata
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=9
ORCID=

affil-num=1
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=2
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=3
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=6
en-affil=
kn-affil=

affil-num=7
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=8
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=9
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=
en-keyword=Rice ? Salinity
kn-keyword=Rice ? Salinity
en-keyword=Apoplastic flow
kn-keyword=Apoplastic flow
en-keyword=Trisodium-8-hydroxy-1,3,6-pyrenetrisulphonic acid
kn-keyword=Trisodium-8-hydroxy-1,3,6-pyrenetrisulphonic acid
en-keyword=Chitosan
kn-keyword=Chitosan
END

start-ver=1.4
cd-journal=joma
no-vol=14
cd-vols=
no-issue=17
article-no=
start-page=1305
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20250822
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Discovery and Functional Characterization of Novel Aquaporins in Tomato (Solanum lycopersicum): Implications for Ion Transport and Salinity Tolerance
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Aquaporins (AQPs) are membrane proteins that facilitate the transport of water and solutes. Among AQPs, plasma membrane intrinsic proteins (PIPs) play a critical role in maintaining water balance between the internal and external cell environments. This study focuses on the tomato due to its economic importance and cultivation under moderate salinity conditions in Japan. A swelling assay using X. laevis oocyte confirmed that all five examined tomato SlPIP2 isoforms showed water transport activity. Among them, two-electrode voltage clamp (TEVC) experiments showed that only SlPIP2;1, SlPIP2;4, and SlPIP2;8 transport Na+ and K+, with no transport activity for Cs+, Rb+, Li+, or Cl?. CaCl2 (1.8 mM) reduced ionic currents by approximately 45% compared to 30 ?M free-Ca2+. These isoforms function as very low-affinity Na+ and K+ transporters. Expression analysis showed that SlPIP2;4 and SlPIP2;8 had low, stable expression, while SlPIP2;1 was strongly upregulated in roots NaCl treatment (200 mM, 17days), suggesting distinct physiological roles for these ion-conducting AQPs (icAQPs). These data hypothesized that tomato icAQPs play a critical role in ion homeostasis, particularly under salinity stress. In conclusion, the first icAQPs have been identified in the dicotyledonous crop. These icAQPs are essential for plant resilience under salt stress.
en-copyright=
kn-copyright=

en-aut-name=PaulNewton Chandra
en-aut-sei=Paul
en-aut-mei=Newton Chandra
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=ImranShahin
en-aut-sei=Imran
en-aut-mei=Shahin
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=MitsumotoAnri
en-aut-sei=Mitsumoto
en-aut-mei=Anri
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=KatsuharaMaki
en-aut-sei=Katsuhara
en-aut-mei=Maki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

affil-num=1
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=4
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=Aquaporin (AQP)
kn-keyword=Aquaporin (AQP)
en-keyword=ion transport
kn-keyword=ion transport
en-keyword=plasma membrane intrinsic proteins (PIPs)
kn-keyword=plasma membrane intrinsic proteins (PIPs)
en-keyword=tomato
kn-keyword=tomato
en-keyword=oocytes
kn-keyword=oocytes
en-keyword=water transport
kn-keyword=water transport
END

start-ver=1.4
cd-journal=joma
no-vol=
cd-vols=
no-issue=
article-no=
start-page=
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20250603
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Amino Acid Substitutions in Loop C of Arabidopsis PIP2 Aquaporins Alters the Permeability of CO2
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=The transport of CO2 across biomembranes in plant cells is essential for efficient photosynthesis. Some aquaporins capable of CO2 transport, referred to as �eCOOporins�f, are postulated to play a crucial role in leaf CO2 diffusion. However, the structural basis of CO2 permeation through aquaporins remains largely unknown. Here, we show that amino acids in loop C are critical for the CO2 permeability of Arabidopsis thaliana PIP2 aquaporins. We found that swapping tyrosine and serine in loop C to histidine and phenylalanine, which differ between AtPIP2;1 and AtPIP2;3, altered CO2 permeability when examined in the Xenopus laevis oocyte heterologous expression system. AlphaFold2 modelling indicated that these substitution induced a conformational shift in the sidechain of arginine in the aromatic/arginine (ar/R) selectivity filter and in lysine at the extracellular mouth of the monomeric pore in PIP2 aquaporins. Our findings demonstrate that distal amino acid substitutions can trigger conformational changes of the ar/R filter in the monomeric pore, modulating CO2 permeability. Additionally, phylogenetic analysis suggested that aquaporins capable of dual water/CO2 permeability are ancestral to those that are water-selective and CO2-impermeable, and CO2-selective and water impermeable.
en-copyright=
kn-copyright=

en-aut-name=TaniaShaila Shermin
en-aut-sei=Tania
en-aut-mei=Shaila Shermin
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=UtsugiShigeko
en-aut-sei=Utsugi
en-aut-mei=Shigeko
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=TsuchiyaYoshiyuki
en-aut-sei=Tsuchiya
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=SasanoShizuka
en-aut-sei=Sasano
en-aut-mei=Shizuka
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=KatsuharaMaki
en-aut-sei=Katsuhara
en-aut-mei=Maki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

affil-num=1
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=4
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=6
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=Arabidopsis thaliana
kn-keyword=Arabidopsis thaliana
en-keyword=CO2 transport
kn-keyword=CO2 transport
en-keyword=monomeric pore
kn-keyword=monomeric pore
en-keyword=PIP2 aquaporin
kn-keyword=PIP2 aquaporin
en-keyword=Xenopus laevis
kn-keyword=Xenopus laevis
END

start-ver=1.4
cd-journal=joma
no-vol=177
cd-vols=
no-issue=4
article-no=
start-page=e70396
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=202507
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=CNGC2 Negatively Regulates Stomatal Closure and Is Not Required for flg22- and H2O2-Induced Guard Cell [Ca2+]cyt Elevation in Arabidopsis thaliana
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=In guard cells, cytosolic Ca2+ acts as a second messenger that mediates abscisic acid (ABA)- and pathogen-associated molecular pattern (PAMP)-induced stomatal closure. It was reported that Arabidopsis cyclic nucleotide-gated ion channel 2 (CNGC2) functions as hydrogen peroxide (H2O2)- and PAMP-activated Ca2+-permeable channels at the plasma membrane of mesophyll cells and mediates Ca2+-dependent PAMP-triggered immunity. In this study, we examined the role of CNGC2 in the regulation of stomatal movement because CNGC2 is also expressed in guard cells. We found that stomata of the CNGC2 disruption mutant cngc2-3 are constitutively closed even in the absence of ABA or the flagellar-derived PAMP, flg22. Consistently, leaf temperatures of the cngc2-3 mutant were higher than those of wild-type (WT) plants. The stomatal phenotype of the cngc2-3 mutant was restored by complementation with wild-type CNGC2 under the control of the guard cell preferential promoter, pGC1. Elevation of cytosolic free Ca2+ concentration in guard cells induced by flg22 and H2O2 remained intact in the cngc2-3 mutant. The introduction of the ost1-3 mutation into the cngc2-3 background did not alter the stomatal phenotype. However, the stomatal phenotype of the cngc2-3 mutant was successfully rescued in the double disruption mutant cngc2-3aba2-2. Taken together, these results suggest that CNGC2 negatively regulates stomatal closure response and does not function as flg22? and H2O2-activated Ca2+ channels in guard cells. Though CNGC2 is responsive for H2O2- and flg22-induced [Ca2+]cyt elevation in mesophyll cells, the involvement of CNGC2 in the response to H2O2 and flg22 in guard cells is questionable.
en-copyright=
kn-copyright=

en-aut-name=AkterRojina
en-aut-sei=Akter
en-aut-mei=Rojina
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=InoueYasuhiro
en-aut-sei=Inoue
en-aut-mei=Yasuhiro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=MasumotoSaori
en-aut-sei=Masumoto
en-aut-mei=Saori
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=MimataYoshiharu
en-aut-sei=Mimata
en-aut-mei=Yoshiharu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MatsuuraTakakazu
en-aut-sei=Matsuura
en-aut-mei=Takakazu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

en-aut-name=NakamuraToshiyuki
en-aut-sei=Nakamura
en-aut-mei=Toshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=7
ORCID=

en-aut-name=NakamuraYoshimasa
en-aut-sei=Nakamura
en-aut-mei=Yoshimasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=8
ORCID=

en-aut-name=MurataYoshiyuki
en-aut-sei=Murata
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=9
ORCID=

en-aut-name=MunemasaShintaro
en-aut-sei=Munemasa
en-aut-mei=Shintaro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=10
ORCID=

affil-num=1
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=2
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=3
en-affil=Faculty of Agriculture, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=6
en-affil=
kn-affil=

affil-num=7
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=8
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=9
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=10
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=
en-keyword=calcium signaling
kn-keyword=calcium signaling
en-keyword=CNGC
kn-keyword=CNGC
en-keyword=stomata
kn-keyword=stomata
END

start-ver=1.4
cd-journal=joma
no-vol=
cd-vols=
no-issue=
article-no=
start-page=
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2025
dt-pub=20250612
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Sulfur dioxide-induced guard cell death and stomatal closure are attenuated in nitrate/proton antiporter AtCLCa mutants
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Guard cells surrounding the stomata play a crucial role in regulating the entrance of hazardous gases such as SO2 into leaves. Stomatal closure could be a plant response to mitigate SO2 damage, although the mechanism for SO2-induced closure remains controversial. Proposed mediators for SO2-induced stomatal closure include phytohormones, reactive oxygen species, gasotransmitters, and cytosolic acidification. In this study, we investigated the mechanism of stomatal closure in Arabidopsis in response to SO2. Despite an increment in auxin and jasmonates after SO2 exposure, the addition of auxin did not cause stomatal closure and jasmonate-insensitive mutants exhibited SO2-induced stomatal closure suggesting auxin and jasmonates are not mediators leading to the closure. In addition, supplementation of scavenging reagents for reactive oxygen species and gasotransmitters did not inhibit SO2-induced closure. Instead, we found that cytosolic acidification is a credible mechanism for SO2-induced stomatal closure in Arabidopsis. CLCa mutants coding H+/nitrate antiporter, involved in cytosolic pH homeostasis, showed less sensitive stomatal phenotype against SO2. These results suggest that cytosolic pH homeostasis plays a tenable role in SO2 response in guard cells.
en-copyright=
kn-copyright=

en-aut-name=OoiLia
en-aut-sei=Ooi
en-aut-mei=Lia
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=MatsuuraTakakazu
en-aut-sei=Matsuura
en-aut-mei=Takakazu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

affil-num=1
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=airborne pollutants
kn-keyword=airborne pollutants
en-keyword=cytosolic acidification
kn-keyword=cytosolic acidification
en-keyword=stomatal closure
kn-keyword=stomatal closure
en-keyword=sulfur dioxide
kn-keyword=sulfur dioxide
END

start-ver=1.4
cd-journal=joma
no-vol=88
cd-vols=
no-issue=10
article-no=
start-page=1164
end-page=1171
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2024
dt-pub=20240716
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Cytosolic acidification and oxidation are the toxic mechanisms of SO2 in Arabidopsis guard cells
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=SO2/H2SO3 can damage plants. However, its toxic mechanism has still been controversial. Two models have been proposed, cytosolic acidification model and cellular oxidation model. Here, we assessed the toxic mechanism of H2SO3 in three cell types of Arabidopsis thaliana, mesophyll cells, guard cells (GCs), and petal cells. The sensitivity of GCs of Chloride channel a (CLCa)-knockout mutants to H2SO3 was significantly lower than those of wildtype plants. Expression of other CLC genes in mesophyll cells and petal cells were different from GCs. Treatment with antioxidant, disodium 4,5-dihydroxy-1,3-benzenedisulfonate (tiron), increased the median lethal concentration (LC50) of H2SO3 in GCs indicating the involvement of cellular oxidation, while the effect was negligible in mesophyll cells and petal cells. These results indicate that there are two toxic mechanisms of SO2 to Arabidopsis cells: cytosolic acidification and cellular oxidation, and the toxic mechanism may vary among cell types.
en-copyright=
kn-copyright=

en-aut-name=MozhganiMahdi
en-aut-sei=Mozhgani
en-aut-mei=Mahdi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=OoiLia
en-aut-sei=Ooi
en-aut-mei=Lia
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=EspagneChristelle
en-aut-sei=Espagne
en-aut-mei=Christelle
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=FilleurSophie
en-aut-sei=Filleur
en-aut-mei=Sophie
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MoriIzumi C
en-aut-sei=Mori
en-aut-mei=Izumi C
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

affil-num=1
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=Universit? Paris-Saclay, CEA, CNRS, Institute for Integrative Biology of the Cell (I2BC)
kn-affil=

affil-num=4
en-affil=Universit? Paris-Saclay, CEA, CNRS, Institute for Integrative Biology of the Cell (I2BC)
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=cytosolic acidification
kn-keyword=cytosolic acidification
en-keyword=Arabidopsis
kn-keyword=Arabidopsis
en-keyword=cellular oxidation
kn-keyword=cellular oxidation
en-keyword=chloride channel a
kn-keyword=chloride channel a
en-keyword=sulfur dioxide
kn-keyword=sulfur dioxide
END

start-ver=1.4
cd-journal=joma
no-vol=87
cd-vols=
no-issue=11
article-no=
start-page=1323
end-page=1331
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2023
dt-pub=20230808
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=The effect of exogenous dihydroxyacetone and methylglyoxal on growth, anthocyanin accumulation, and the glyoxalase system in Arabidopsis
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Dihydroxyacetone (DHA) occurs in wide-ranging organisms, including plants, and can undergo spontaneous conversion to methylglyoxal (MG). While the toxicity of MG to plants is well-known, the toxicity of DHA to plants remains to be elucidated. We investigated the effects of DHA and MG on Arabidopsis. Exogenous DHA at up to 10 mM did not affect the radicle emergence, the expansion of green cotyledons, the seedling growth, or the activity of glyoxalase II, while DHA at 10 mM inhibited the root elongation and increased the activity of glyoxalase I. Exogenous MG at 1.0 mM inhibited these physiological responses and increased both activities. Dihydroxyacetone at 10 mM increased the MG content in the roots. These results indicate that DHA is not so toxic as MG in Arabidopsis seeds and seedlings and suggest that the toxic effect of DHA at high concentrations is attributed to MG accumulation by the conversion to MG.
en-copyright=
kn-copyright=

en-aut-name=ZhaoMaoxiang
en-aut-sei=Zhao
en-aut-mei=Maoxiang
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=NakamuraToshiyuki
en-aut-sei=Nakamura
en-aut-mei=Toshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=NakamuraYoshimasa
en-aut-sei=Nakamura
en-aut-mei=Yoshimasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=MunemasaShintaro
en-aut-sei=Munemasa
en-aut-mei=Shintaro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MoriIzumi C
en-aut-sei=Mori
en-aut-mei=Izumi C
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=MurataYoshiyuki
en-aut-sei=Murata
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

affil-num=1
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=2
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=3
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=6
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=
en-keyword=dihydroxyacetone
kn-keyword=dihydroxyacetone
en-keyword=methylglyoxal
kn-keyword=methylglyoxal
en-keyword=growth
kn-keyword=growth
en-keyword=anthocyanin
kn-keyword=anthocyanin
en-keyword=glyoxalase system
kn-keyword=glyoxalase system
END

start-ver=1.4
cd-journal=joma
no-vol=71
cd-vols=
no-issue=16
article-no=
start-page=4778
end-page=4796
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2020
dt-pub=20200506
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Low temperature modulates natural peel degreening in lemon fruit independently of endogenous ethylene
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Peel degreening is an important aspect of fruit ripening in many citrus fruit, and previous studies have shown that it can be advanced by ethylene treatment or by low-temperature storage. However, the important regulators and pathways involved in natural peel degreening remain largely unknown. To determine how natural peel degreening is regulated in lemon fruit (Citrus limon), we studied transcriptome and physiochemical changes in the flavedo in response to ethylene treatment and low temperatures. Treatment with ethylene induced rapid peel degreening, which was strongly inhibited by the ethylene antagonist, 1-methylcyclopropene (1-MCP). Compared with 25 degrees C, moderately low storage temperatures of 5-20 degrees C also triggered peel degreening. Surprisingly, repeated 1-MCP treatments failed to inhibit the peel degreening induced by low temperature. Transcriptome analysis revealed that low temperature and ethylene independently regulated genes associated with chlorophyll degradation, carotenoid metabolism, photosystem proteins, phytohormone biosynthesis and signalling, and transcription factors. Peel degreening of fruit on trees occurred in association with drops in ambient temperature, and it coincided with the differential expression of low temperature-regulated genes. In contrast, genes that were uniquely regulated by ethylene showed no significant expression changes during on-tree peel degreening. Based on these findings, we hypothesize that low temperature plays a prominent role in regulating natural peel degreening independently of ethylene in citrus fruit.
en-copyright=
kn-copyright=

en-aut-name=MitaloOscar W.
en-aut-sei=Mitalo
en-aut-mei=Oscar W.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=OtsukiTakumi
en-aut-sei=Otsuki
en-aut-mei=Takumi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=OkadaRui
en-aut-sei=Okada
en-aut-mei=Rui
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=ObitsuSaeka
en-aut-sei=Obitsu
en-aut-mei=Saeka
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MasudaKanae
en-aut-sei=Masuda
en-aut-mei=Kanae
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=HojoYuko
en-aut-sei=Hojo
en-aut-mei=Yuko
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

en-aut-name=MatsuuraTakakazu
en-aut-sei=Matsuura
en-aut-mei=Takakazu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=7
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=8
ORCID=

en-aut-name=AbeDaigo
en-aut-sei=Abe
en-aut-mei=Daigo
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=9
ORCID=

en-aut-name=AsicheWilliam O.
en-aut-sei=Asiche
en-aut-mei=William O.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=10
ORCID=

en-aut-name=AkagiTakashi
en-aut-sei=Akagi
en-aut-mei=Takashi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=11
ORCID=

en-aut-name=KuboYasutaka
en-aut-sei=Kubo
en-aut-mei=Yasutaka
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=12
ORCID=

en-aut-name=UshijimaKoichiro
en-aut-sei=Ushijima
en-aut-mei=Koichiro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=13
ORCID=

affil-num=1
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=2
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=3
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=6
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=7
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=8
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=9
en-affil=National Agriculture and Food Research Organization, Shikoku Research Station
kn-affil=

affil-num=10
en-affil=Department of Research and Development, Del Monte Kenya Ltd
kn-affil=

affil-num=11
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=12
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=13
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=
en-keyword=1-methylcyclopropene
kn-keyword=1-methylcyclopropene
en-keyword=carotenoids
kn-keyword=carotenoids
en-keyword=chlorophyll
kn-keyword=chlorophyll
en-keyword=Citrus limon
kn-keyword=Citrus limon
en-keyword=ethylene
kn-keyword=ethylene
en-keyword=low temperature
kn-keyword=low temperature
en-keyword=peel degreening
kn-keyword=peel degreening
en-keyword=phytohormones
kn-keyword=phytohormones
en-keyword=transcriptome
kn-keyword=transcriptome
END

start-ver=1.4
cd-journal=joma
no-vol=247
cd-vols=
no-issue=
article-no=
start-page=125933
end-page=
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2020
dt-pub=20200116
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Application of the cellular oxidation biosensor to Toxicity Identification Evaluations for high-throughput toxicity assessment of river water
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Toxicity Identification Evaluation (TIE) is a useful method for the classification and identification of toxicants in a composite environment water sample. However, its extension to a larger sample size has been restrained owing to the limited throughput of toxicity bioassays. Here we reported the development of a high-throughput method of TIE Phase I. This newly developed method was assisted by the fluorescence-based cellular oxidation (CO) biosensor fabricated with roGFP2-expressing bacterial cells in 96-well microplate format. The assessment of four river water samples from Langat river basin by this new method demonstrated that the contaminant composition of the four samples can be classified into two distinct groups. The entire toxicity assay consisted of 2338 tests was completed within 12 h with a fluorescence microplate reader. Concurrently, the sample volume for each assay was reduced to 50 ƒÊL, which is 600 to 4700 times lesser to compare with conventional bioassays. These imply that the throughput of the CO biosensor-assisted TIE Phase I is now feasible for constructing a large-scale toxicity monitoring system, which would cover a whole watershed scale.
en-copyright=
kn-copyright=

en-aut-name=OoiLia
en-aut-sei=Ooi
en-aut-mei=Lia
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=OkazakiKeisuke
en-aut-sei=Okazaki
en-aut-mei=Keisuke
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=Arias-BarreiroCarlos R.
en-aut-sei=Arias-Barreiro
en-aut-mei=Carlos R.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=HengLee Yook
en-aut-sei=Heng
en-aut-mei=Lee Yook
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

affil-num=1
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=nstitute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=4
en-affil=Southeast Asia Disaster Prevention Research Initiative (SEADPRI-UKM), Institute for Environment and Development (LESTARI), The National University of Malaysia
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=High-throughput cytotoxicity biosensor
kn-keyword=High-throughput cytotoxicity biosensor
en-keyword=Toxicity identification evaluation
kn-keyword=Toxicity identification evaluation
en-keyword=River water pollution
kn-keyword=River water pollution
en-keyword=Ecotoxicity management
kn-keyword=Ecotoxicity management
en-keyword=Integrated watershed management
kn-keyword=Integrated watershed management
END

start-ver=1.4
cd-journal=joma
no-vol=42
cd-vols=
no-issue=2
article-no=
start-page=437
end-page=447
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2018
dt-pub=20180716
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=The mechanism of SO2 -induced stomatal closure differs from O3 and CO2 responses and is mediated by nonapoptotic cell death in guard cells.
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract= Plants closing stomata in the presence of harmful gases is believed to be a stress avoidance mechanism. SO2 , one of the major airborne pollutants, has long been reported to induce stomatal closure, yet the mechanism remains unknown. Little is known about the stomatal response to airborne pollutants besides O3 . SLOW ANION CHANNEL-ASSOCIATED 1 (SLAC1) and OPEN STOMATA 1 (OST1) were identified as genes mediating O3 -induced closure. SLAC1 and OST1 are also known to mediate stomatal closure in response to CO2 , together with RESPIRATORY BURST OXIDASE HOMOLOGs (RBOHs). The overlaying roles of these genes in response to O3 and CO2 suggested that plants share their molecular regulators for airborne stimuli. Here, we investigated and compared stomatal closure event induced by a wide concentration range of SO2 in Arabidopsis through molecular genetic approaches. O3 - and CO2 -insensitive stomata mutants did not show significant differences from the wild type in stomatal sensitivity, guard cell viability, and chlorophyll content revealing that SO2 -induced closure is not regulated by the same molecular mechanisms as for O3 and CO2 . Nonapoptotic cell death is shown as the reason for SO2 -induced closure, which proposed the closure as a physicochemical process resulted from SO2 distress, instead of a biological protection mechanism.
en-copyright=
kn-copyright=

en-aut-name=Ooi Lia
en-aut-sei=Ooi 
en-aut-mei=Lia
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=MatsuuraTakakazu
en-aut-sei=Matsuura
en-aut-mei=Takakazu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=MunemasaShintaro
en-aut-sei=Munemasa
en-aut-mei=Shintaro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=MurataYoshiyuki
en-aut-sei=Murata
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=KatsuharaMaki
en-aut-sei=Katsuhara
en-aut-mei=Maki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=HirayamaTakashi
en-aut-sei=Hirayama
en-aut-mei=Takashi
kn-aut-name=•½ŽRûéŽu
kn-aut-sei=•½ŽR
kn-aut-mei=ûéŽu
aut-affil-num=6
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=7
ORCID=

affil-num=1
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=2
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=3
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=6
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=7
en-affil= Institute of Plant Science and Resources, Okayama University
kn-affil=
en-keyword=airborne pollutants
kn-keyword=airborne pollutants
en-keyword=nonapoptotic cell death
kn-keyword=nonapoptotic cell death
en-keyword=stomatal closure
kn-keyword=stomatal closure
en-keyword=sulfur dioxide
kn-keyword=sulfur dioxide
END

start-ver=1.4
cd-journal=joma
no-vol=57
cd-vols=
no-issue=8
article-no=
start-page=1779
end-page=1990
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2016
dt-pub=20160801
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Involvement of OST1 Protein Kinase and PYR/PYL/RCAR Receptors in Methyl Jasmonate-Induced Stomatal Closure in Arabidopsis Guard Cells
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract= Methyl jasmonate (MeJA) induces stomatal closure. It has been shown that stomata of many ABA-insensitive mutants are also insensitive to MeJA, and a low amount of ABA is a prerequisite for the MeJA response. However, the molecular mechanisms of the interaction between ABA and MeJA signaling remain to be elucidated. Here we studied the interplay of signaling of the two hormones in guard cells using the quadruple ABA receptor mutant pyr1 pyl1 pyl2 pyl4 and ABA-activated protein kinase mutants ost1-2 and srk2e. In the quadruple mutant, MeJA-induced stomatal closure, H2O2 production, nitric oxide (NO) production, cytosolic alkalization and plasma membrane Ca(2+)-permeable current (ICa) activation were not impaired. At the same time, the inactivation of the inward-rectifying K(+) current was impaired. In contrast to the quadruple mutant, MeJA-induced stomatal closure, H2O2 production, NO production and cytosolic alkalization were impaired in ost1-2 and srk2e as well as in aba2-2, the ABA-deficient mutant. The activation of ICa was also impaired in srk2e. Collectively, these results indicated that OST1 was essential for MeJA-induced stomatal closure, while PYR1, PYL1, PYL2 and PYL4 ABA receptors were not sufficient factors. MeJA did not appear to activate OST1 kinase activity. This implies that OST1 mediates MeJA signaling through an undetectable level of activity or a non-enzymatic action. MeJA induced the expression of an ABA synthesis gene, NCED3, and increased ABA contents only modestly. Taken together with previous reports, this study suggests that MeJA signaling in guard cells is primed by ABA and is not brought about through the pathway mediated by PYR1, PYL1 PYL2 and PYL4.
en-copyright=
kn-copyright=

en-aut-name=YinYe
en-aut-sei=Yin
en-aut-mei=Ye
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=AdachiYuji
en-aut-sei=Adachi
en-aut-mei=Yuji
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=NakamuraYoshimasa
en-aut-sei=Nakamura
en-aut-mei=Yoshimasa
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=MunemasaShintaro
en-aut-sei=Munemasa
en-aut-mei=Shintaro
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=MurataYoshiyuki
en-aut-sei=Murata
en-aut-mei=Yoshiyuki
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

affil-num=1
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=2
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=3
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=4
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=

affil-num=5
en-affil=Institute of Plant Science and Resources, Okayama University
kn-affil=

affil-num=6
en-affil=Graduate School of Environmental and Life Science, Okayama University
kn-affil=
en-keyword=ABA
kn-keyword=ABA
en-keyword=ABA receptors
kn-keyword=ABA receptors
en-keyword=Arabidopsis thaliana
kn-keyword=Arabidopsis thaliana
en-keyword=Guard cells
kn-keyword=Guard cells
en-keyword=Methyl jasmonate
kn-keyword=Methyl jasmonate
en-keyword=OST1 protein kinase
kn-keyword=OST1 protein kinase
END

start-ver=1.4
cd-journal=joma
no-vol=120
cd-vols=
no-issue=
article-no=
start-page=299
end-page=304
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2015
dt-pub=201502
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=
kn-title=Toxicity of tetramethylammonium hydroxide to aquatic organisms and its synergistic action with potassium iodide
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=The aquatic ecotoxicity of chemicals involved in the manufacturing process of thin film transistor liquid crystal displays was assessed with a battery of four selected acute toxicity bioassays. We focused on tetramethylammonium hydroxide (TMAH, CAS No. 75-59-2), a widely utilized etchant. The toxicity of TMAH was low when tested in the 72 h-algal growth inhibition test (Pseudokirchneriellia subcapitata, EC50 = 360 mg L?1) and the Microtox? test (Vibrio fischeri, IC50 = 6.4 g L?1). In contrast, the 24 h-microcrustacean immobilization and the 96 h-fish mortality tests showed relatively higher toxicity (Daphnia magna, EC50 = 32 mg L?1 and Oryzias latipes, LC50 = 154 mg L?1). Isobologram and mixture toxicity index analyses revealed apparent synergism of the mixture of TMAH and potassium iodide when examined with the D. magna immobilization test. The synergistic action was unique to iodide over other halide salts i.e. fluoride, chloride and bromide. Quaternary ammonium ions with longer alkyl chains such as tetraethylammonium and tetrabutylammonium were more toxic than TMAH in the D. magna immobilization test.
en-copyright=
kn-copyright=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=1
ORCID=

en-aut-name=Arias-BarreiroCarlos R.
en-aut-sei=Arias-Barreiro
en-aut-mei=Carlos R.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=2
ORCID=

en-aut-name=KoutsaftisApostolos
en-aut-sei=Koutsaftis
en-aut-mei=Apostolos
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=3
ORCID=

en-aut-name=OgoAtsushi
en-aut-sei=Ogo
en-aut-mei=Atsushi
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=4
ORCID=

en-aut-name=KawanoTomonori
en-aut-sei=Kawano
en-aut-mei=Tomonori
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=5
ORCID=

en-aut-name=YoshizukaKazuharu
en-aut-sei=Yoshizuka
en-aut-mei=Kazuharu
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=6
ORCID=

en-aut-name=Inayat-HussainSalmaan H.
en-aut-sei=Inayat-Hussain
en-aut-mei=Salmaan H.
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=7
ORCID=

en-aut-name=AoyamaIsao
en-aut-sei=Aoyama
en-aut-mei=Isao
kn-aut-name=
kn-aut-sei=
kn-aut-mei=
aut-affil-num=8
ORCID=

affil-num=1
en-affil=
kn-affil=Institute of Plant Science and Resources, Okayama University

affil-num=2
en-affil=
kn-affil=Institute of Plant Science and Resources, Okayama University

affil-num=3
en-affil=
kn-affil=Institute of Plant Science and Resources, Okayama University

affil-num=4
en-affil=
kn-affil=Institute of Plant Science and Resources, Okayama University

affil-num=5
en-affil=
kn-affil=School of International Environmental Science, The University of Kitakyushu

affil-num=6
en-affil=
kn-affil=School of International Environmental Science, The University of Kitakyushu

affil-num=7
en-affil=
kn-affil=Faculty of Health Sciences, Univerisiti Kebangsaan Malaysia

affil-num=8
en-affil=
kn-affil=Institute of Plant Science and Resources, Okayama University
en-keyword=Tetramethylammonium hydroxide
kn-keyword=Tetramethylammonium hydroxide
en-keyword=Potassium iodide
kn-keyword=Potassium iodide
en-keyword=Aquatic toxicity
kn-keyword=Aquatic toxicity
en-keyword=Synergism
kn-keyword=Synergism
en-keyword=D. magna
kn-keyword=D. magna
en-keyword=Semiconductor wastewater
kn-keyword=Semiconductor wastewater
END

start-ver=1.4
cd-journal=joma
no-vol=31
cd-vols=
no-issue=
article-no=
start-page=21
end-page=25
dt-received=
dt-revised=
dt-accepted=
dt-pub-year=2009
dt-pub=200912
dt-online=
en-article=
kn-article=
en-subject=
kn-subject=
en-title=Cooling effect on buildings by the roof greening at Research Institute for Bioresources, Okayama University
kn-title=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š‚É‚¨‚¯‚鉮�ã—Ή»‚É‚æ‚錚•¨—â‹pŒø‰Ê
en-subtitle=
kn-subtitle=
en-abstract=
kn-abstract=Roof greening is known to be environmentally friendly technology. Recently developed new roof greening systems, such as the thin-layer/Excel soil? system and the wetland type greening system, were tested at the roof top of buildings of Research Institute for Bioresources, Okayama University. After a multi-year test, these new systems have been established during high-temperature and less-rainfall summer seasons in the south Okayama region. Data indicated that roof greening effectively reduced the temperature of the concrete surface (more than 10�‹C). The room temperature under the green roof was also reduced both in a stock room (up to 6�‹C) and in an office room (about 2�‹C). We also provided the estimation indicating that this roof greening is useful for the decrease in CO(2) emission through the reduction of the electric power for air-conditioning in the summer.
en-copyright=
kn-copyright=

en-aut-name=KatsuharaMaki
en-aut-sei=Katsuhara
en-aut-mei=Maki
kn-aut-name=ŠŽŒ´�^–Ø
kn-aut-sei=ŠŽŒ´
kn-aut-mei=�^–Ø
aut-affil-num=1
ORCID=

en-aut-name=TanakamaruShigemi
en-aut-sei=Tanakamaru
en-aut-mei=Shigemi
kn-aut-name=“c’†ŠÛ�d”ü
kn-aut-sei=“c’†ŠÛ
kn-aut-mei=�d”ü
aut-affil-num=2
ORCID=

en-aut-name=MoriIzumi C.
en-aut-sei=Mori
en-aut-mei=Izumi C.
kn-aut-name=�X�ò
kn-aut-sei=�X
kn-aut-mei=�ò
aut-affil-num=3
ORCID=

en-aut-name=TaniAkio
en-aut-sei=Tani
en-aut-mei=Akio
kn-aut-name=’J–¾�¶
kn-aut-sei=’J
kn-aut-mei=–¾�¶
aut-affil-num=4
ORCID=

en-aut-name=UtsugiShigeko
en-aut-sei=Utsugi
en-aut-mei=Shigeko
kn-aut-name=‰F“s–ؔɎq
kn-aut-sei=‰F“s–Ø
kn-aut-mei=”ÉŽq
aut-affil-num=5
ORCID=

en-aut-name=EnomotoTakashi
en-aut-sei=Enomoto
en-aut-mei=Takashi
kn-aut-name=‰|–{Œh
kn-aut-sei=‰|–{
kn-aut-mei=Œh
aut-affil-num=6
ORCID=

en-aut-name=MaitaniToshihiko
en-aut-sei=Maitani
en-aut-mei=Toshihiko
kn-aut-name=•Ä’J�r•F
kn-aut-sei=•Ä’J
kn-aut-mei=�r•F
aut-affil-num=7
ORCID=

affil-num=1
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=2
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=3
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=4
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=5
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=6
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š

affil-num=7
en-affil=
kn-affil=‰ªŽR‘åŠwŽ‘Œ¹�¶•¨‰ÈŠwŒ¤‹†�Š
en-keyword=Roof greening
kn-keyword=Roof greening
en-keyword=wetland type greening
kn-keyword=wetland type greening
en-keyword=thin-Iayer/ Excel soil? system
kn-keyword=thin-Iayer/ Excel soil? system
en-keyword=cooling effect
kn-keyword=cooling effect
END