| scholarly article | Q13442814 |
| P2093 | author name string | Kenji Sakurai | |
| Akio Watanabe | |||
| Hidekazu Takahashi | |||
| Hiromori Akagi | |||
| Namiko Satoh-Nagasawa | |||
| Nobushige Nakazawa | |||
| Tomohiko Kawamoto | |||
| Tatsuhito Fujimura | |||
| Kouichi Tezuka | |||
| Aya Hiraizumi | |||
| Hidenori Miyadate | |||
| Ikuko Kodama | |||
| Kazunao Katou | |||
| Saki Adachi | |||
| P2860 | cites work | Arabidopsis HMA2, a divalent heavy metal-transporting P(IB)-type ATPase, is involved in cytoplasmic Zn2+ homeostasis | Q24560198 |
| TreeView: an application to display phylogenetic trees on personal computers | Q27861074 | ||
| A new vital stain for visualizing vacuolar membrane dynamics and endocytosis in yeast | Q28131611 | ||
| The plant P1B-type ATPase AtHMA4 transports Zn and Cd and plays a role in detoxification of transition metals supplied at elevated levels | Q28304248 | ||
| SOSUI: classification and secondary structure prediction system for membrane proteins | Q29616676 | ||
| Evaluation of methods for the prediction of membrane spanning regions | Q33953551 | ||
| A long way ahead: understanding and engineering plant metal accumulation. | Q34740963 | ||
| A new pathway for vacuolar cadmium sequestration in Saccharomyces cerevisiae: YCF1-catalyzed transport of bis(glutathionato)cadmium | Q35898807 | ||
| P(1B)-ATPases--an ancient family of transition metal pumps with diverse functions in plants | Q36254496 | ||
| Put the metal to the petal: metal uptake and transport throughout plants | Q36450071 | ||
| Root-to-shoot Cd translocation via the xylem is the major process determining shoot and grain cadmium accumulation in rice | Q37215769 | ||
| Chromosomal regions with quantitative trait loci controlling cadmium concentration in brown rice (Oryza sativa). | Q40382081 | ||
| ConPred II: a consensus prediction method for obtaining transmembrane topology models with high reliability. | Q41010655 | ||
| Evolution of metal hyperaccumulation required cis-regulatory changes and triplication of HMA4. | Q43024506 | ||
| Heavy metal transport by AtHMA4 involves the N-terminal degenerated metal binding domain and the C-terminal His11 stretch | Q45284398 | ||
| Genomic comparison of P-type ATPase ion pumps in Arabidopsis and rice | Q46285537 | ||
| P-type ATPase heavy metal transporters with roles in essential zinc homeostasis in Arabidopsis | Q47725053 | ||
| AtHMA3, a plant P1B-ATPase, functions as a Cd/Pb transporter in yeast. | Q47970483 | ||
| AtHMA3, a P1B-ATPase allowing Cd/Zn/Co/Pb vacuolar storage in Arabidopsis | Q48072179 | ||
| A major quantitative trait locus for cadmium tolerance in Arabidopsis halleri colocalizes with HMA4, a gene encoding a heavy metal ATPase | Q48080136 | ||
| The Arabidopsis metal tolerance protein AtMTP3 maintains metal homeostasis by mediating Zn exclusion from the shoot under Fe deficiency and Zn oversupply. | Q50729833 | ||
| A novel method for predicting transmembrane segments in proteins based on a statistical analysis of the SwissProt database: the PRED-TMR algorithm. | Q52212777 | ||
| Functional analysis of the heavy metal binding domains of the Zn/Cd-transporting ATPase, HMA2, in Arabidopsis thaliana. | Q54503367 | ||
| Structural diversity and evolution of the Rf-1 locus in the genus Oryza | Q80592730 | ||
| A single recessive gene controls cadmium translocation in the cadmium hyperaccumulating rice cultivar Cho-Ko-Koku | Q82356018 | ||
| HMA P-type ATPases are the major mechanism for root-to-shoot Cd translocation in Arabidopsis thaliana | Q82936292 | ||
| A major quantitative trait locus controlling cadmium translocation in rice (Oryza sativa) | Q83524850 | ||
| Phytoextraction by rice capable of accumulating Cd at high levels: reduction of Cd content of rice grain | Q84515586 | ||
| P433 | issue | 1 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | cadmium | Q1091 |
| vacuole | Q127702 | ||
| P304 | page(s) | 190-199 | |
| P577 | publication date | 2010-09-14 | |
| P1433 | published in | New Phytologist | Q13548580 |
| P1476 | title | OsHMA3, a P1B-type of ATPase affects root-to-shoot cadmium translocation in rice by mediating efflux into vacuoles | |
| OsHMA3, a P1B‐type of ATPase affects root‐to‐shoot cadmium translocation in rice by mediating efflux into vacuoles | |||
| P478 | volume | 189 |
| Q52562637 | A Node-Expressed Transporter OsCCX2 Is Involved in Grain Cadmium Accumulation of Rice. |
| Q42446564 | A kinetic analysis of cadmium accumulation in a Cd hyper-accumulator fern, Athyrium yokoscense and tobacco plants |
| Q59106450 | A loss-of-function allele ofOsHMA3associated with high cadmium accumulation in shoots and grain ofJaponicarice cultivars |
| Q44518830 | A member of the heavy metal P-type ATPase OsHMA5 is involved in xylem loading of copper in rice |
| Q46694359 | Abutilon indicum L.: a prospective weed for phytoremediation |
| Q92128219 | Advances in the Uptake and Transport Mechanisms and QTLs Mapping of Cadmium in Rice |
| Q64072047 | Aeration Increases Cadmium (Cd) Retention by Enhancing Iron Plaque Formation and Regulating Pectin Synthesis in the Roots of Rice (Oryza sativa) Seedlings |
| Q47784439 | Allelic Variation of NtNramp5 Associated with Cultivar Variation in Cadmium Accumulation in Tobacco |
| Q28655797 | Alteration of leaf shape, improved metal tolerance, and productivity of seed by overexpression of CsHMA3 in Camelina sativa |
| Q49693510 | Annotation and characterization of Cd-responsive metal transporter genes in rapeseed (Brassica napus). |
| Q64115121 | Association Study Reveals Genetic Loci Responsible for Arsenic, Cadmium and Lead Accumulation in Rice Grain in Contaminated Farmlands |
| Q90618279 | Association between sequence variants in cadmium-related genes and the cadmium accumulation trait in thermo-sensitive genic male sterile rice |
| Q47161727 | Biochemical and Genetical Responses of Phoenix dactylifera L. to Cadmium Stress. |
| Q50887875 | Biochemical and molecular changes in rice seedlings (Oryza sativa L.) to cope with chromium stress. |
| Q36074830 | Cadmium absorption and transportation pathways in plants |
| Q51095635 | Cadmium adsorption, chelation and compartmentalization limit root-to-shoot translocation of cadmium in rice (Oryza sativa L.). |
| Q38782422 | Cadmium stress in rice: toxic effects, tolerance mechanisms, and management: a critical review |
| Q37326651 | Cadmium transport and tolerance in rice: perspectives for reducing grain cadmium accumulation |
| Q34821249 | Cadmium uptake and partitioning in durum wheat during grain filling |
| Q64966627 | Can Selenium and Molybdenum Restrain Cadmium Toxicity to Pollen Grains in Brassica napus? |
| Q43906310 | Characterization of OsLCT1, a cadmium transporter from indica rice (Oryza sativa). |
| Q47114714 | Co-expression network analysis of the transcriptomes of rice roots exposed to various cadmium stresses reveals universal cadmium-responsive genes. |
| Q35225624 | Comparative mapping combined with homology-based cloning of the rice genome reveals candidate genes for grain zinc and iron concentration in maize |
| Q41318630 | Comparative transcriptome analysis reveals key cadmium transport-related genes in roots of two pak choi (Brassica rapa L. ssp. chinensis) cultivars |
| Q26738502 | Comparison on cellular mechanisms of iron and cadmium accumulation in rice: prospects for cultivating Fe-rich but Cd-free rice |
| Q93172799 | Comprehensive analysis of variation of cadmium accumulation in rice and detection of a new weak allele of OsHMA3 |
| Q50347439 | Contribution of NtZIP1-Like to the Regulation of Zn Homeostasis |
| Q37164335 | Detection of QTLs to reduce cadmium content in rice grains using LAC23/Koshihikari chromosome segment substitution lines. |
| Q90062579 | Distribution and Redistribution of 109Cd and 65Zn in the Heavy Metal Hyperaccumulator Solanum nigrum L.: Influence of Cadmium and Zinc Concentrations in the Root Medium |
| Q92955794 | Durum wheat genome highlights past domestication signatures and future improvement targets |
| Q64100180 | Ectopic expression of a bacterial mercury transporter MerC in root epidermis for efficient mercury accumulation in shoots of Arabidopsis plants |
| Q51737108 | Effective reduction of cadmium accumulation in rice grain by expressing OsHMA3 under the control of OsHMA2 promoter. |
| Q21129195 | Enriching rice with Zn and Fe while minimizing Cd risk |
| Q39490274 | Functional analyses of TaHMA2, a P(1B)-type ATPase in wheat. |
| Q37270771 | Genetic Diversity, Rather than Cultivar Type, Determines Relative Grain Cd Accumulation in Hybrid Rice. |
| Q58106562 | Genetic basis of rice ionomic variation revealed by Genome-wide association studies |
| Q55686793 | Genome-Wide Identification and Characterization of Four Gene Families Putatively Involved in Cadmium Uptake, Translocation and Sequestration in Mulberry. |
| Q64989391 | Genome-wide analysis reveals four key transcription factors associated with cadmium stress in creeping bentgrass (Agrostis stolonifera L.). |
| Q48164584 | Genome-wide association analysis and QTL mapping reveal the genetic control of cadmium accumulation in maize leaf. |
| Q38997189 | Genome-wide association mapping of cadmium accumulation in different organs of barley |
| Q34411883 | Genome-wide association studies identify heavy metal ATPase3 as the primary determinant of natural variation in leaf cadmium in Arabidopsis thaliana. |
| Q59790151 | Genome-wide association study and candidate gene analysis of rice cadmium accumulation in grain in a diverse rice collection |
| Q36024739 | Genome-wide characterization of soybean P 1B -ATPases gene family provides functional implications in cadmium responses |
| Q64913401 | Genomic Comparison of the P-ATPase Gene Family in Four Cotton Species and Their Expression Patterns in Gossypium hirsutum. |
| Q37726869 | Genotypic and Environmental Variations in Grain Cadmium and Arsenic Concentrations Among a Panel of High Yielding Rice Cultivars |
| Q50450279 | Growth and Cadmium Phytoextraction by Swiss Chard, Maize, Rice, Noccaea caerulescens, and Alyssum murale in Ph Adjusted Biosolids Amended Soils. |
| Q95841117 | Heavy Metal Stress-Associated Proteins in Rice and Arabidopsis: Genome-Wide Identification, Phylogenetics, Duplication, and Expression Profiles Analysis |
| Q46357286 | Heavy metal ATPase 3 (HMA3) confers cadmium hypertolerance on the cadmium/zinc hyperaccumulator Sedum plumbizincicola |
| Q64978566 | Homology modeling and in vivo functional characterization of the zinc permeation pathway in a heavy metal P-type ATPase. |
| Q34374491 | HvHMA2, a P(1B)-ATPase from barley, is highly conserved among cereals and functions in Zn and Cd transport |
| Q64063058 | Ideal Cereals With Lower Arsenic and Cadmium by Accurately Enhancing Vacuolar Sequestration Capacity |
| Q35074365 | Identification and comparative analysis of cadmium tolerance-associated miRNAs and their targets in two soybean genotypes |
| Q48575916 | Identification of mutations allowing Natural Resistance Associated Macrophage Proteins (NRAMP) to discriminate against cadmium |
| Q39158827 | Impairing both HMA4 homeologs is required for cadmium reduction in tobacco. |
| Q33361061 | Inhibition of root meristem growth by cadmium involves nitric oxide-mediated repression of auxin accumulation and signalling in Arabidopsis |
| Q36436828 | Ion-beam irradiation, gene identification, and marker-assisted breeding in the development of low-cadmium rice |
| Q36788935 | Kinetic Analysis of Zinc/Cadmium Reciprocal Competitions Suggests a Possible Zn-Insensitive Pathway for Root-to-Shoot Cadmium Translocation in Rice. |
| Q35641299 | Low-affinity cation transporter (OsLCT1) regulates cadmium transport into rice grains |
| Q37554572 | Metal transport protein 8 in Camellia sinensis confers superior manganese tolerance when expressed in yeast and Arabidopsis thaliana |
| Q53428376 | Modulation of Zn/Cd P(1B2)-ATPase activities in Arabidopsis impacts differently on Zn and Cd contents in shoots and seeds. |
| Q47982313 | Molecular and biochemical properties of two P1B2-ATPases, CsHMA3 and CsHMA4, from cucumber |
| Q30410061 | Mutations in rice (Oryza sativa) heavy metal ATPase 2 (OsHMA2) restrict the translocation of zinc and cadmium |
| Q97882569 | Novel quantitative trait loci for low grain cadmium concentration in common wheat (Triticum aestivum L.). |
| Q41949701 | Origin and evolution of metal P-type ATPases in Plantae (Archaeplastida). |
| Q59106280 | OsATX1 Interacts with Heavy Metal P1B-Type ATPases and Affects Copper Transport and Distribution |
| Q42181194 | Overexpression of OsHMA3 enhances Cd tolerance and expression of Zn transporter genes in rice |
| Q45906710 | Physiological and transcriptome response to cadmium in cosmos (Cosmos bipinnatus Cav.) seedlings. |
| Q50089364 | Phytochelatin synthase has contrasting effects on cadmium and arsenic accumulation in rice grains |
| Q33710864 | Protein Biochemistry and Expression Regulation of Cadmium/Zinc Pumping ATPases in the Hyperaccumulator Plants Arabidopsis halleri and Noccaea caerulescens. |
| Q97549154 | QTL mapping and candidate gene analysis of cadmium accumulation in polished rice by genome-wide association study |
| Q34084958 | Real-time imaging and analysis of differences in cadmium dynamics in rice cultivars (Oryza sativa) using positron-emitting 107Cd tracer |
| Q89682021 | Reducing Cadmium Accumulation in Plants: Structure-Function Relations and Tissue-Specific Operation of Transporters in the Spotlight |
| Q26740142 | Regulating Subcellular Metal Homeostasis: The Key to Crop Improvement |
| Q33931670 | Rice ABCG43 is Cd inducible and confers Cd tolerance on yeast. |
| Q37255342 | Rice DEP1, encoding a highly cysteine-rich G protein γ subunit, confers cadmium tolerance on yeast cells and plants |
| Q93067367 | Rice phytochelatin synthases OsPCS1 and OsPCS2 make different contributions to cadmium and arsenic tolerance |
| Q41881805 | Role of the iron transporter OsNRAMP1 in cadmium uptake and accumulation in rice. |
| Q35940314 | Role of the node in controlling traffic of cadmium, zinc, and manganese in rice |
| Q46281305 | Silicon reduces cadmium accumulation by suppressing expression of transporter genes involved in cadmium uptake and translocation in rice. |
| Q36967676 | Silicon-induced reversibility of cadmium toxicity in rice |
| Q35031432 | Spatial transcriptomes of iron-deficient and cadmium-stressed rice |
| Q92061164 | The ABC transporter ABCG36 is required for cadmium tolerance in rice |
| Q50497818 | The OsHMA2 transporter is involved in root-to-shoot translocation of Zn and Cd in rice. |
| Q35342734 | The OsNRAMP1 iron transporter is involved in Cd accumulation in rice |
| Q46705611 | The auxin transporter, OsAUX1, is involved in primary root and root hair elongation and in Cd stress responses in rice (Oryza sativa L.). |
| Q92260065 | The genome-wide impact of cadmium on microRNA and mRNA expression in contrasting Cd responsive wheat genotypes |
| Q49909004 | The rice "fruit-weight 2.2-like" gene family member OsFWL4 is involved in the translocation of cadmium from roots to shoots |
| Q26849638 | The role of heavy-metal ATPases, HMAs, in zinc and cadmium transport in rice |
| Q64057478 | The tonoplast-localized transporter OsHMA3 plays an important role in maintaining Zn homeostasis in rice |
| Q92162934 | Transcriptional plasticity buffers genetic variation in zinc homeostasis |
| Q93083346 | Transgenerational memory of gene expression changes induced by heavy metal stress in rice (Oryza sativa L.). |
| Q44316394 | Vacuolar membrane transporters OsVIT1 and OsVIT2 modulate iron translocation between flag leaves and seeds in rice |
| Q49358894 | Vacuolar transporters - Companions on a longtime journey |
| Q92327757 | Variation in the BrHMA3 coding region controls natural variation in cadmium accumulation in Brassica rapa vegetables |
| Q92690724 | Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies |
| Q55293330 | You Shall Not Pass: Root Vacuoles as a Symplastic Checkpoint for Metal Translocation to Shoots and Possible Application to Grain Nutritional Quality. |
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