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1.
Overexpression of PP2A‐C5 that encodes the catalytic subunit 5 of protein phosphatase 2A in Arabidopsis confers better root and shoot development under salt conditions
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Protein phosphatase 2A (PP2A) is an enzyme consisting of three subunits: a scaffolding A subunit, a regulatory B subunit and a catalytic C subunit. PP2As were shown to play diverse roles in eukaryotes. In this study, the function of the Arabidopsis PP2A‐C5 gene that encodes the catalytic subunit 5 of PP2A was studied using both loss‐of‐function and gain‐of‐function analyses. Loss‐of‐function mutant pp2a‐c5‐1 displayed more impaired growth during root and shoot development, whereas overexpression of PP2A‐C5 conferred better root and shoot growth under different salt treatments, indicating that PP2A‐C5 plays an important role in plant growth under salt conditions. Double knockout mutants of pp2a‐c5‐1 and salt overly sensitive (sos) mutants sos1‐1, sos2‐2 or sos3‐1 showed additive sensitivity to NaCl, indicating that PP2A‐C5 functions in a pathway different from the SOS signalling pathway. Using yeast two‐hybrid analysis, four vacuolar membrane chloride channel (CLC) proteins, AtCLCa, AtCLCb, AtCLCc and AtCLCg, were found to interact with PP2A‐C5. Moreover, overexpression of AtCLCc leads to increased salt tolerance and Cl? accumulation in transgenic Arabidopsis plants. These data indicate that PP2A‐C5‐mediated better growth under salt conditions might involve up‐regulation of CLC activities on vacuolar membranes and that PP2A‐C5 could be used for improving salt tolerance in crops. 相似文献
2.
Alexis De Angeli Oscar Moran Stefanie Wege Sophie Filleur Genevi��ve Ephritikhine S��bastien Thomine H��l��ne Barbier-Brygoo Franco Gambale 《The Journal of biological chemistry》2009,284(39):26526-26532
Nitrate, one of the major nitrogen sources for plants, is stored in the vacuole. Nitrate accumulation within the vacuole is primarily mediated by the NO3−/H+ exchanger AtCLCa, which belongs to the chloride channel (CLC) family. Crystallography analysis of hCLC5 suggested that the C-terminal domain, composed by two cystathionine β-synthetase motifs in all eukaryotic members of the CLC family is able to interact with ATP. However, interaction of nucleotides with a functional CLC protein has not been unambiguously demonstrated. Here we show that ATP reversibly inhibits AtCLCa by interacting with the C-terminal domain. Applying the patch clamp technique to isolated Arabidopsis thaliana vacuoles, we demonstrate that ATP reduces AtCLCa activity with a maximum inhibition of 60%. ATP inhibition of nitrate influx into the vacuole at cytosolic physiological nitrate concentrations suggests that ATP modulation is physiologically relevant. ADP and AMP do not decrease the AtCLCa transport activity; nonetheless, AMP (but not ADP) competes with ATP, preventing inhibition. A molecular model of the C terminus of AtCLCa was built by homology to hCLC5 C terminus. The model predicted the effects of mutations of the ATP binding site on the interaction energy between ATP and AtCLCa that were further confirmed by functional expression of site-directed mutated AtCLCa.Nitrate is among the major nitrogen sources for plants in aerobic soils. It is taken up by root cells through plasma membrane transporters of nitrate-nitrite transporter and peptide transporter families. Once in the cytoplasm it can enter the amino acid biosynthesis pathway (1) or be accumulated in the vacuolar lumen via tonoplast transporters (2).The vacuolar nitrate transporter of the model plant Arabidopsis thaliana, AtCLCa, has been shown to work as an anion/proton antiporter (3, 4), similarly to the bacterial CLCec-1 (5) and human hCLC-4 (6) as well as hCLC-5 (7). However, whereas bacterial and animal CLCs2 transport chloride ions, the AtCLCa antiporter is more selective for nitrate, and therefore, it is able to mediate the accumulation of nitrate into the plant vacuole.Little is known on the modulation of CLC-proteins by nucleotides. The effects of ATP on the ion channel hCLC-1 are a matter of debate (8). Indeed, some reports have shown that ATP inhibits hCLC-1 currents, probably interacting with the C terminus of the protein (9–11). Conversely, other reports indicate that ATP does not modify the properties of hCLC-1 current (12). This discrepancy has been attributed to the oxidation state of the channel, as ATP would be effective only in the presence of reducing agents (13).The C terminus domain of all eukaryotic CLC proteins has two cystathionine β-synthetase motifs (CBS (14, 15)), each one characterized by a βαββα topology (16, 17). A structural and biochemical study of the hCLC-5 C-terminal part demonstrates that this region binds nucleotides (14). However, the effect of ATP binding on the transport activity of hCLC-5 is still unknown.The presence of analogous CBS domains in the C terminus of the AtCLCa antiporter suggested the hypothesis that ATP binds to this plant transporter and modulates its transport activity. Hence, we undertook a functional analysis of the effect of adenosine nucleotides on AtCLCa and found that ATP inhibits the AtCLCa-mediated transport. Based on a homology model of the C terminus of the channel, we identified two residues that would be putatively involved in the protein-nucleotide interaction. 相似文献
3.
4.
Several members of the CLC family are secondary active anion/proton exchangers, and not passive chloride channels. Among the exchangers, the endosomal ClC-5 protein that is mutated in Dent''s disease shows an extreme outward rectification that precludes a precise determination of its transport stoichiometry from measurements of the reversal potential. We developed a novel imaging method to determine the absolute proton flux in Xenopus oocytes from the extracellular proton gradient. We determined a transport stoichiometry of 2 Cl−/1 H+. Nitrate uncoupled proton transport but mutating the highly conserved serine 168 to proline, as found in the plant NO3−/H+ antiporter atClCa, led to coupled NO3−/H+ exchange. Among several amino acids tested at position 168, S168P was unique in mediating highly coupled NO3−/H+ exchange. We further found that ClC-5 is strongly stimulated by intracellular protons in an allosteric manner with an apparent pK of ∼7.2. A 2:1 stoichiometry appears to be a general property of CLC anion/proton exchangers. Serine 168 has an important function in determining anionic specificity of the exchange mechanism. 相似文献
5.
Eun-Yeong Bergsdorf Anselm A. Zdebik Thomas J. Jentsch 《The Journal of biological chemistry》2009,284(17):11184-11193
Members of the CLC gene family either function as chloride channels or as
anion/proton exchangers. The plant AtClC-a uses the pH gradient across the
vacuolar membrane to accumulate the nutrient
in this organelle. When AtClC-a was
expressed in Xenopus oocytes, it mediated
exchange
and less efficiently mediated Cl–/H+ exchange.
Mutating the “gating glutamate” Glu-203 to alanine resulted in an
uncoupled anion conductance that was larger for Cl– than
. Replacing the “proton
glutamate” Glu-270 by alanine abolished currents. These could be
restored by the uncoupling E203A mutation. Whereas mammalian endosomal ClC-4
and ClC-5 mediate stoichiometrically coupled
2Cl–/H+ exchange, their
transport is largely uncoupled from
protons. By contrast, the AtClC-a-mediated
accumulation in plant vacuoles
requires tight
coupling. Comparison of AtClC-a and ClC-5 sequences identified a proline in
AtClC-a that is replaced by serine in all mammalian CLC isoforms. When this
proline was mutated to serine (P160S), Cl–/H+
exchange of AtClC-a proceeded as efficiently as
exchange, suggesting a role of this residue in
exchange. Indeed, when the corresponding serine of ClC-5 was replaced by
proline, this Cl–/H+ exchanger gained efficient
coupling. When inserted into the model Torpedo chloride channel
ClC-0, the equivalent mutation increased nitrate relative to chloride
conductance. Hence, proline in the CLC pore signature sequence is important
for
exchange and conductance both in
plants and mammals. Gating and proton glutamates play similar roles in
bacterial, plant, and mammalian CLC anion/proton exchangers.CLC proteins are found in all phyla from bacteria to humans and either
mediate electrogenic anion/proton exchange or function as chloride channels
(1). In mammals, the roles of
plasma membrane CLC Cl– channels include transepithelial
transport
(2–5)
and control of muscle excitability
(6), whereas vesicular CLC
exchangers may facilitate endocytosis
(7) and lysosomal function
(8–10)
by electrically shunting vesicular proton pump currents
(11). In the plant
Arabidopsis thaliana, there are seven CLC isoforms
(AtClC-a–AtClC-g)2
(12–15),
which may mostly reside in intracellular membranes. AtClC-a uses the pH
gradient across the vacuolar membrane to transport the nutrient nitrate into
that organelle (16). This
secondary active transport requires a tightly coupled
exchange. Astonishingly, however, mammalian ClC-4 and -5 and bacterial EcClC-1
(one of the two CLC isoforms in Escherichia coli) display tightly
coupled Cl–/H+ exchange, but anion flux is largely
uncoupled from H+ when
is transported
(17–21).
The lack of appropriate expression systems for plant CLC transporters
(12) has so far impeded
structure-function analysis that may shed light on the ability of AtClC-a to
perform efficient
exchange. This dearth of data contrasts with the extensive mutagenesis work
performed with CLC proteins from animals and bacteria.The crystal structure of bacterial CLC homologues
(22,
23) and the investigation of
mutants (17,
19–21,
24–29)
have yielded important insights into their structure and function. CLC
proteins form dimers with two largely independent permeation pathways
(22,
25,
30,
31). Each of the monomers
displays two anion binding sites
(22). A third binding site is
observed when a certain key glutamate residue, which is located halfway in the
permeation pathway of almost all CLC proteins, is mutated to alanine
(23). Mutating this gating
glutamate in CLC Cl– channels strongly affects or even
completely suppresses single pore gating
(23), whereas CLC exchangers
are transformed by such mutations into pure anion conductances that are not
coupled to proton transport
(17,
19,
20). Another key glutamate,
located at the cytoplasmic surface of the CLC monomer, seems to be a hallmark
of CLC anion/proton exchangers. Mutating this proton glutamate to
nontitratable amino acids uncouples anion transport from protons in the
bacterial EcClC-1 protein (27)
but seems to abolish transport altogether in mammalian ClC-4 and -5
(21). In those latter
proteins, anion transport could be restored by additionally introducing an
uncoupling mutation at the gating glutamate
(21).The functional complementation by AtClC-c and -d
(12,
32) of growth phenotypes of a
yeast strain deleted for the single yeast CLC Gef1
(33) suggested that these
plant CLC proteins function in anion transport but could not reveal details of
their biophysical properties. We report here the first functional expression
of a plant CLC in animal cells. Expression of wild-type (WT) and mutant
AtClC-a in Xenopus oocytes indicate a general role of gating and
proton glutamate residues in anion/proton coupling across different isoforms
and species. We identified a proline in the CLC signature sequence of AtClC-a
that plays a crucial role in
exchange. Mutating it to serine, the residue present in mammalian CLC proteins
at this position, rendered AtClC-a Cl–/H+ exchange
as efficient as
exchange. Conversely, changing the corresponding serine of ClC-5 to proline
converted it into an efficient
exchanger. When proline replaced the critical serine in Torpedo
ClC-0, the relative conductance of
this model Cl– channel was drastically increased, and
“fast” protopore gating was slowed. 相似文献
6.
In the yeast Saccharomyces cerevisiae, the molecular chaperone HSP26 has the remarkable ability to sense increases in temperature directly and can switch from
an inactive to a chaperone-active state. In this report, we analyzed the effect of expression of HSP26 in Arabidopsis thaliana plants and their response to high temperature stress. The hsp26 transgenic plants exhibited stronger growth than wild type plants at 45 °C for 16 h. The chlorophyll content and chlorophyll
fluorescence decreased much more in wild type than in transgenic plants. Moreover, the transgenic plants had higher proline
and soluble sugar contents, and lower relative electrical conductivity and malondialdehyde contents after high temperature
stress. Furthermore, we found that over-expression of HSP26 in Arabidopsis increased the amount of free proline, elevated the expression of proline biosynthetic pathway genes and therefore enhanced
Arabidopsis tolerance to heat stress. 相似文献
7.
De Angeli A Monachello D Ephritikhine G Frachisse JM Thomine S Gambale F Barbier-Brygoo H 《Philosophical transactions of the Royal Society of London. Series B, Biological sciences》2009,364(1514):195-201
Plants need nitrate for growth and store the major part of it in the central vacuole of cells from root and shoot tissues. Based on few studies on the two model plants Arabidopsis thaliana and rice, members of the large ChLoride Channel (CLC) family have been proposed to encode anion channels/transporters involved in nitrate homeostasis. Proteins from the Arabidopsis CLC family (AtClC, comprising seven members) are present in various membrane compartments including the vacuolar membrane (AtClCa), Golgi vesicles (AtClCd and AtClCf) or chloroplast membranes (AtClCe). Through a combination of electrophysiological and genetic approaches, AtClCa was shown to function as a 2NO3-/1H+ exchanger that is able to accumulate specifically nitrate into the vacuole, in agreement with the main phenotypic trait of knockout mutant plants that accumulate 50 per cent less nitrate than their wild-type counterparts. The set-up of a functional complementation assay relying on transient expression of AtClCa cDNA in the mutant background opens the way for studies on structure-function relationships of the AtClCa nitrate transporter. Such studies will reveal whether important structural determinants identified in bacterial or mammalian CLCs are also crucial for AtClCa transport activity and regulation. 相似文献
8.
9.
Bo Zhu Ai-Sheng Xiong Ri-He Peng Jing Xu Xiao-Fen Jin Xiu-Rong Meng Quan-Hong Yao 《Molecular biology reports》2010,37(2):961-966
Thermal hysteresis proteins (Thps) known as antifreeze proteins for their antifreeze activity, depress the freezing point
of water below the melting point in many polar marine fishes, terrestrial arthropods and plants. For the purpose of breeding
cold-resistant plants, we designed to introduce the Thp gene into the plants. The physiological and biochemical effect of
high-lever expression of the modified Choristoneura fumiferana
Thp (ThpI) in Arabidopsis thaliana plants was analyzed. Under low temperature stress, the ThpI transgenic plants exhibited stronger growth than wild-type plants. The elevated cold tolerance of the ThpI over-expressing plants was confirmed by the changes of electrolyte leakage activity, malonyldialdehyde and proline contents.
These results preliminarily showed that the Thp possibly be used to enhance the low temperature-tolerant ability of plants. 相似文献
10.
Inhibition of Arabidopsis growth by the allelopathic compound azetidine‐2‐carboxylate is due to the low amino acid specificity of cytosolic prolyl‐tRNA synthetase
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Jiyeon Lee Naveen Joshi Rita Pasini Renwick C. J. Dobson Jane Allison Thomas Leustek 《The Plant journal : for cell and molecular biology》2016,88(2):236-246
The toxicity of azetidine‐2‐carboxylic acid (A2C), a structural analogue of L‐proline, results from its incorporation into proteins due to misrecognition by prolyl‐tRNA synthetase (ProRS). The growth of Arabidopsis thaliana seedling roots is more sensitive to inhibition by A2C than is cotyledon growth. Arabidopsis contains two ProRS isozymes. AtProRS‐Org (At5g52520) is localized in chloroplasts/mitochondria, and AtProRS‐Cyt (At3g62120) is cytosolic. AtProRS‐Cyt mRNA is more highly expressed in roots than in cotyledons. Arabidopsis ProRS isoforms were expressed as His‐tagged recombinant proteins in Escherichia coli. Both enzymes were functionally active in ATP‐PPi exchange and aminoacylation assays, and showed similar Km for L‐proline. A major difference was observed in the substrate specificity of the two enzymes. AtProRS‐Cyt showed nearly identical substrate specificity for L‐proline and A2C, but for AtProRS‐Org the specificity constant was 77.6 times higher for L‐proline than A2C, suggesting that A2C‐sensitivity may result from lower amino acid specificity of AtProRS‐Cyt. Molecular modelling and simulation results indicate that this specificity difference between the AtProRS isoforms may result from altered modes of substrate binding. Similar kinetic results were obtained with the ProRSs from Zea mays, suggesting that the difference in substrate specificity is a conserved feature of ProRS isoforms from plants that do not accumulate A2C and are sensitive to A2C toxicity. The discovery of the mode of action of A2C toxicity could lead to development of biorational weed management strategies. 相似文献
11.
12.
13.
The Arabidopsis thaliana At2g01170 gene is annotated as a putative gamma amino butyric acid (GABA) permease based on its sequence similarity to a
yeast GABA transporting gene (UGA4). A cDNA of At2g01170 was expressed in yeast and analyzed for amino acid transport activity. Both direct measurement of amino
acid transport and yeast growth experiments demonstrated that the At2g01170 encoded-protein exhibits transport activity for
alanine, arginine, glutamate and lysine, but not for GABA or proline. Significantly, unlike other amino acid transporters
described in plants to date, At2g01170 displayed both export and import activity. Based on that observation, it was named
bidirectional amino acid transporter 1 (BAT1). Sequence comparisons show BAT1 is not a member of any previously defined amino acid transporter family. It does share,
however, several conserved protein domains found in a variety of prokaryotic and eukaryotic amino acid transporters, suggesting
membership in an ancient family of transporters. BAT1 is a single copy gene in the Arabidopsis genome, and its mRNA is ubiquitously expressed in all organs. A transposon—GUS gene-trap insert in the BAT1 gene displays GUS localization in the vascular tissues (Dundar in Ann Appl Biol, 2009) suggesting BAT1 may function in amino acid export from the phloem into sink tissues. 相似文献
14.
15.
Sun Ha Kim Hyun Sook Lee Won Yong Song Kwan Sam Choi Yoonkang Hur 《Journal of Plant Biology》2007,50(1):1-7
Metallothioneins (MTs) are low-molecular-weight, cysteine-rich proteins that bind to heavy metals. Type-1 MTs function under
various abiotic stresses, including exposure to the cadmium ion. We have now isolated theBrassica rapa type-1 metallothioneirt gene (BrMT1)using yeast systems, and have found that it confers resistance to Cd in otherwise Cd-sensitive yeast. Using a constitutive CaMV35S
promoter and an RbsS transit peptide, we successfully targeted BrMT1 to the chloroplastsof Arabidopsis. Overexpression in either the chloroplasts or the cytosol effectively detoxified cadmium and H2O2 stresses in transgenicArabidopsis. in particular, the chloropfast-targeted BrMTl was associated with a significant reduction in paraquat-induced chlorosis and
the accumulation of H2O2. This is the first report regarding the effects of type-1 MT1 targeted to chloroplasts. Our results suggest that this may
be applicable to the development of plants with enhanced tolerance against environmental stresses. 相似文献
16.
In wild-type Nicotiana plumbaginifolia Viv. and other higher plants, nitrate reductase (NR) is regulated at the post-translational level and is rapidly inactivated in response to, for example, a light-to-dark transition. This inactivation is caused by phosphorylation of a conserved regulatory serine residue, Ser 521 in tobacco, and interaction with divalent cations or polyamines, and 14-3-3 proteins. The physiological importance of the post-translational NR modulation is presently under investigation using a transgenic N. plumbaginifolia line. This line expresses a mutated tobacco NR where Ser 521 has been changed into aspartic acid (Asp) by site-directed mutagenesis, resulting in a permanently active NR enzyme [C. Lillo et al. (2003) Plant J 35:566–573]. When cut leaves or roots of this line (S521) were placed in darkness in a buffer containing 50 mM KNO3, nitrite was excreted from the tissue at rates of 0.08–0.2 mol (g FW)–1 h–1 for at least 5 h. For the control transgenic plant (C1), which had the regulatory serine of NR intact, nitrite excretion was low and halted completely after 1–3 h. Without nitrate in the buffer in which the tissue was immersed, nitrite excretion was also low for S521, although 20–40 mol (g FW)–1 nitrate was present inside the tissue. Apparently, stored nitrate was not readily available for reduction in darkness. Leaf tissue and root segments of S521 also emitted much more nitric oxide (NO) than the control. Importantly, NO emission from leaf tissue of S521 was higher in the dark than in the light, opposite to what was usually observed when post-translational NR modulation was operating.Abbreviations NR Nitrate reductase - NO Nitric oxide - Ser Serine - WT Wild type 相似文献
17.
18.
Referee: Dr. Peter Csermely, Department of Medical Chemistry, Semmeliweis Univ. School of Medicine, P.O. Box 260, H-1444 Budapest 8, Hungary Hsp100/Clp family of proteins is ubiquitously distributed in living systems. Detailed work carried out in bacterial and yeast cells has shown that regulatory members of the Clp family (mainly ClpA, ClpB, and ClpC), together with the catalytic subunit (mainly ClpP), comprise an ATP-dependent two-component proteolytic system. Members of the Hsp100/Clp protein family are not only involved in the regulation of energy-dependent protein hydrolysis but also function as molecular chaperones. However, the biochemical/physiological role(s) of the Hsp100/Clp protein family in higher plants has yet to be elucidated. Recently, this protein family has been implicated in plant stress responses: the hot1 mutant of Arabidopsis thaliana, which has mutation in hsp101 gene, and is defective in tolerance to high temperature (S.-W. Hong and E. Vierling, 2000, Proc Natl Acad Sci USA, 97 (8), 4392-4397) and the transgenic Arabidopsis thaliana plants overexpressing AtHsp101 gene exhibit high temperature tolerance (C. Quietsch et al., 2000, Plant Cell, 12, 479–492). Furthermore, the Hsp101 protein is involved in the translational regulation of cellular mRNAs and one such candidate has been identified as the photosynthetic electron transport gene Ferredoxin 1 mRNA (J. Ling et al., 2000, Plant Cell, 12, 1213–1227). We present what is known about the bacterial, yeast, and plant Hsp100/Clp proteins, discuss their possible relationship, and, more importantly, examine the cellular roles that this important family of proteins plays in plants. 相似文献
19.
Yeong-Tae Kim Jonghee Oh Kyung-Hwan Kim Jae-Youl Uhm Byoung-Moo Lee 《Molecular biology reports》2010,37(2):717-727
Elicitins, extracellular proteins from Phytophthora fungi, elicit a hypersensitivity response (HR), including systemic acquired resistance, in some plants. The elicitin capsicein
(~10 kDa) was purified by FPLC from culture filtrates of P. capsici. Purified native and recombinant capsicein induced a hypersensitive response in leaves of the non-host plants Nicotiana glutinosa and Brassica rapa subsp. pekinensis. To search for candidate capsicein-interacting proteins from N. glutinosa, a yeast two-hybrid assay was used. We identified a protein interactor that is homologous to a serine/threonine kinase of
the plant receptor-like kinase (RLK) group and designated it NgRLK1. The ORF of NgRLK1 encodes a polypeptide of 832 amino acids (93,490 Da). A conserved domain analysis revealed that NgRLK1 has structural features
typical of a plant RLK. NgRLK1 was autophosphorylated, with higher activity in the presence of Mn2+ than Mg2+. 相似文献
20.
CLC transport proteins in plants 总被引:2,自引:0,他引:2
Nitrate compartmentalization in intracellular organelles has been long recognized as critical for plant physiology but the molecular identity of the proteins involved remained unclear for a long time. In Arabidopsis thaliana, AtClC-a has been recently shown to be a antiporter critical for nitrate transport into the vacuoles. AtClC-a is a member of the CLC protein family, whose animal and bacterial members, comprising both channels and H+-coupled antiporters, have been previously implicated exclusively in Cl− transport. Despite the different over Cl− selectivity of AtClC-a compared to the other CLC antiporters, it has similar transport properties.Other CLC homologues have been cloned in Arabidopsis, tobacco, rice and soybean. 相似文献