Anti-H+ATPase - Plasma membrane H+ATPase (rabbit antibody)

Cat# AS07260

Size : 50ug

Brand : Agrisera

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Product no: AS07 260

AS07 260 | Clonality: Polyclonal | Host: Rabbit | Reactivity: [global antibody] for di- and monocots, conifers, ferns, mosses, green algae | Cellular [compartment marker] for plasma membrane

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  • Product Info
  • Immunogen:

    KLH-conjugated synthetic peptide, derived from available di and monocot, fern, mosses and algal plasma membrane ATPase sequences including Arabidopsis thaliana ATPase 1 (UniProt: P20649, TAIR: At2g18960) and ATPase 2 (UniProt: P19456 , TAIR: At4g30190), 3 (UniProt: P20431, TAIR: At5g57350), 4 (UniProt: Q9SU58, TAIR: At3g47950), 6 (UniProt: Q9SH76, TAIR: At2g07560), 7 (UniProt: Q9LY32, TAIR: At3g60330), 8 (UniProt: Q9M2A0, TAIR: At3g42640), 9 (UniProt: Q42556, TAIR: At1g80660), 11 (UniProt: Q9LV11, TAIR: At5g62670) of Arabidopsis thaliana and hydrogen ATPase of Chlamydomonas reinhardtii (Q9FNS3)

    Host: Rabbit
    Clonality: Polyclonal
    Purity: Immunogen affinity purified serum in PBS pH 7.4.
    Format: Lyophilized
    Quantity: 50 µg
    Reconstitution: For reconstitution add 50 µl of sterile water
    Storage: Store lyophilized/reconstituted at -20°C; once reconstituted make aliquots to avoid repeated freeze-thaw cycles. Please remember to spin the tubes briefly prior to opening them to avoid any losses that might occur from material adhering to the cap or sides of the tube. Do not Store this antibody in 4°C.
    Tested applications: Immunofluorescence (IF), Immunolocalization (IL), Western blot (WB)
    Recommended dilution: 1 : 600-1 : 1000 (IF), 1 : 100 (IL), 1 : 1000-1 : 10 000 (WB)
    Expected | apparent MW:

    90-95 kDa (Arabidopsis thaliana, depending upon an isoform)

  • Reactivity
  • Confirmed reactivity: Actinidia chinensis, Aesculus hippocastanum, Arabidopsis thaliana, Camellia sinensis cv. Shu-chazao, Chara australis R.Br, Chlamydmonas reinhardtii, Cucumis sativus, Cucurbita moschata, Glycine max, Kandelia obovata, Hordeum vulgare, Lolium perenne, Lycopersicon esculentum, Malus x domestica Borkh. c.v. Fuji, Marchantia polymorpha, Medicago truncatula, Nicotiana benthamiana, Nicotiana tabacum, Noccaea caerulescens, Oryza sativa, Petunia hybrida, Phalenopsis Sogo Yukidian cultivar V3, Physcomitrium patens, Picea abies, Pisum sativum, Populus tremula, Pteris vittata (fern), Ricinus communis, Salicornia bigelovii, Spinacia oleracea, Solanum lycopersicum, Tagetes erecta, Tetraselmis chuii, Vicia faba, Zea mays
    Predicted reactivity: Amaranthus hypochondriacus,Avena sativa,Beta vulgaris, Cyanidioschyzon merolae, Dunaliella spp., Galdieria sulphuraria, Gossypium hirsutum, Hordeum vulgare, Ostreococcus spp., Pinus thunbergii, Physocomitrella patens, Mesembruanthemum crystallinum, Mortierella elongata, Nannochloropsis gaditana CCMP526, Ostreococcus tauri, Prosopis alba, Rosa chinensis Jacq., Saccharomyces cerevisiae, Solanum tuberosum, Sorghum bicolor, Spinacia oleracea, Triticum aestivum, Ulva prolifera, Ustilago maydis

    Species of your interest not listed? Contact us
    Not reactive in:

    Allium sp., Aspergillus niger, Citrus limon, Colobanthus apetala, Cuminium cyminum, Curcuma amada, Deschampsia antractica, Lupinus luteus, Morinda citrifolia, Trigonella foenum, Vicia faba

  • Application Examples
  • western blot using plant anti-H+ATPase antibodies

    20 µg of total protein from Arabidopsis thaliana (1), Hordeum vulgare (2), Zea mays (3), Nicotiana tabaccum plasma membrane fraction, 2.5 µg (4), extracted with Protein Extration Buffer, PEB (AS08 300, homogenate the tissue with 3 to 5 volumes of the homogenizing buffer), were denaturated for 10 min. in 70°C and separated on 4-12% NuPage (Invitrogen) LDS-PAGE and blotted 1h to PVDF. Blots were blocked immediately following transfer in blocking reagent in 20 mM Tris, 137 mM sodium chloride pH 7.6 with 0.1% (v/v) Tween-20 (TBS-T) for 1h at room temperature with agitation. Blots were incubated in the primary antibody at a dilution of 1: 5 000 for 1h at room temperature with agitation. The antibody solution was decanted and the blot was rinsed briefly twice, then washed once for 15 min and 3 times for 5 min in TBS-T at room temperature with agitation. Blots were incubated in secondary antibody (anti-rabbit IgG horse radish peroxidase conjugated, recommended secondary antibody AS09 602) diluted to 1:20 000 in 2% blocking solution for 1h at room temperature with agitation. The blots were washed as above and developed for 5 min with chemiluminescence detection reagent according the manufacturers instructions. Images of the blots were obtained using a CCD imager (FluorSMax, Bio-Rad) and Quantity One software (Bio-Rad). Exposure time was 2 min.

    Immunolocalization

    immunolocalization using anti-H+ATPase polyclonal antibodies

    Plasma membrane H+ATPase localization inArabidopsis thaliana roots.
    Arabidopsis thaliana, elongation zone, H+ATPase (green). Arabidopsis thaliana roots were fixed in para-formaldehyde for 30 minutes. Tissue cleaning has been performed before immunolocalization. Anti-rabbit H+ATPase | plasma membrane primary antibody diluted in 1: 300 and anti-rabbit IgG secondary antibody conjugated with Alexa 555. Co-staining with DAPI visualized nucleus (blue color). Scale bar – 100 µm.

    Courtesy Dr. Taras Pasternak, Freiburg University, Germany

    Application examples:

    Reactant: Kandelia obovata

    Application: Western Blotting

    Pudmed ID: 23977070

    Journal: PLoS One

    Figure Number: 4A,B

    Published Date: 2013-08-27

    First Author: Chen, J., Xiong, D. Y., et al.

    Impact Factor: 2.942

    Open Publication

    Western blot analysis of protein expression of plasma membrane (PM) H+-ATPase and Na+/H+ antiporter (NHE-1).Shown in (A) and (C) are the relative protein expression level of K. obovata seedlings grown under 400 mM NaCl and various concentrations of SNP for 15 days. Shown in (B) and (D) represent the relative protein expression level of K. obovata seedlings treated with the following Hoagland solution-based solutions for 15 days: Control (only Hoagland solution), NaCl (400 mM), SNP (100 µM), NaCl+SNP (400 mM NaCl+100 µM SNP), cPTIO+L-NNA (200 µM cPTIO+100 µM L-NNA), NaCl+cPTIO+L-NNA (400 mM NaCl+200 µM cPTIO+100 µM L-NNA). Three independent experiments were performed. The relative intensity of bands (column charts) was quantified by densitometric analysis with Quantity One software and expressed relative to the intensity of the control band defined as 1. For each parameter, bars with different letters indicate significant difference at P<0.05.


    Reactant: Arabidopsis thaliana (Thale cress)

    Application: Western Blotting

    Pudmed ID: 25915922

    Journal: PLoS One

    Figure Number: 6p

    Published Date: 2015-04-29

    First Author: Han, S. W., Alonso, J. M., et al.

    Impact Factor: 2.942

    Open Publication

    3xYpet-RBB1 is a cytoplasmic protein that associates with the tonoplast.(a-c) A 3xYpet-RBB1 fusion complements the bulb phenotype of rbb1-2. Four-day-old seedlings from rbb1-2 (a) or rbb1-2 3xYpet-RBB1 (b, c) were stained with Lysotracker Red (magenta, a, b) to label the vacuole. The signal from 3xYpet-RBB1 (c) for the complemented plant is shown. (d-f) 3xYpet-RBB1 does not co-localize with FM4-64. Images show the cotyledon of 7-d-old seedlings expressing 3xYpet-RBB1 (d) stained with 5 ?M FM4-64 (e) and the merged image (f). (g-i) 3xYpet-RBB1 and RFP-SYP22 do not co-localize. Cotyledons of 7-d-old seedlings expressing 3xYpet-RBB1 (g) and RFP-SYP22 (h) were imaged. Merged image (i) is shown. (j-l) 3xYpet-RBB1 and Lysotracker Red do not co-localize in rosette leaves. Seedlings from the 3xYpet-RBB1 line were stained with Lysotracker Red. Signal from 3xYpet-RBB1 (j), Lysotracker Red (k) and the merged image (l) are shown. Arrowheads indicate the localization of 3xYpet-RBB1 at the tip of elongating trans-vacuolar strands. (m-o) GFP molecules can also label the tips of transvacuolar strands. Seedlings from a 35::GFP marker line were stained with Lysotracker Red. The GFP signal (m), Lysotracker Red (n) and the merged image (o) are shown. Arrowheads indicate the tip of TVS. All scale bars = 20 ?m. (p) 3xYpet-RBB1 accumulates in the soluble (S100) and membrane pellet (P100) fractions from whole seedlings. Immunoblot of 3xYpet-RBB1 soluble (S100) and membrane (P100) fractions from Col-0 and 3xYpet-RBB1 transgenic plants using antibodies against GFP (?-GFP), cFBPase (?-cFBPase, control for soluble fraction), and Plasma Membrane H+ATPase (?-H+ATPase, control for membrane fraction).


    Reactant: Hordeum vulgare (Barley)

    Application: Western Blotting

    Pudmed ID: 26213372

    Journal: Sci Rep

    Figure Number: 6A

    Published Date: 2015-07-27

    First Author: Chen, J., Wang, W. H., et al.

    Impact Factor: 4.13

    Open Publication

    Western-blot analysis of root PM H+-ATPase(a) and vacuolar Na+/H+ antiporter (NHE1) (c) of barley seedlings treated with 150?mM NaCl and various NaHS concentrations (0, 50, 100, 200 and 500??M) for 48?h. CK: Hoagland solution only without adding NaHS and NaCl. Three independent experiments were conducted, and the immunoblotting results show similar trends of protein expression. The relative protein expression level is shown as the ratio of PM H+-ATPase to ?-actin (b) and NHE1 to ?-actin (d) analyzed with Quantity One software. Mean values?±?SE were calculated from independent experiments and columns labeled with different letters are significantly different at P?

    Reactant: Hordeum vulgare (Barley)

    Application: Western Blotting

    Pudmed ID: 26213372

    Journal: Sci Rep

    Figure Number: 7A

    Published Date: 2015-07-27

    First Author: Chen, J., Wang, W. H., et al.

    Impact Factor: 4.13

    Open Publication

    Western-blot analysis of root PM H+-ATPase(a) and vacuolar Na+/H+ antiporter (NHE1) (c) of barley seedlings treated with 150?mM NaCl (Na), 150?mM NaCl+100??M NaHS (Na+S), 150?mM NaCl+100??M NaHS+200??M cPTIO (Na+S+c), 150?mM NaCl+100??M SNP (Na+N), 150?mM NaCl+100??M SNP+200??M cPTIO (Na+N+c) for 48?h, respectively. CK: Hoagland solution only without adding NaHS and NaCl. Three independent experiments were conducted, and the immunoblotting results show similar trends of protein expression. The relative protein expression level is shown as the ratio of PM H+-ATPase to ?-actin (b) and NHE1 to ?-actin (d) analyzed with Quantity One software. Mean values?±?SE were calculated from independent experiments and columns labeled with different letters are significantly different at P?

    Reactant: Arabidopsis thaliana (Thale cress)

    Application: Western Blotting

    Pudmed ID: 27109828

    Journal: Nat Commun

    Figure Number: 6A

    Published Date: 2016-04-25

    First Author: Yang, B. J., Han, X. X., et al.

    Impact Factor: 13.783

    Open Publication

    Auxin stimulates PTRE1 accumulation at the plasma membrane.(a) Western blot analysis showed that auxin treatment results in relatively more PTRE1 at the plasma membrane, but decreased levels in nucleus and cytoplasm. Arabidopsis seedlings expressing PTRE1-GFP were treated with NAA (1??M, 60 or 120?min) and then surface-exposed membrane proteins were analysed using PTRE1 antibody or plasma membrane marker H+-ATPase. Nucleus and cytoplasm fractions were prepared from Col seedlings and analysed by western blot using antibody against PTRE1, nuclear marker H3 or cytoplasm marker UGPase. The relative quantities of the proteins were calculated by using image pro plus and indicated. (b) A proposed model for how PTRE1 and TIR1 coordinate auxin responses regulating proteasome activity and Aux/IAA protein degradation. Under normal condition (with basal auxin levels), 26S proteasome activity is maintained by appropriate distribution of PTRE1 at the plasma membrane and in intracellular compartments. In response to auxin, auxin rapidly stimulates the association of TIR1 and Aux/IAA proteins resulting in degradation of Aux/IAAs (1). Later, auxin suppresses PTRE1 to inhibit proteasome activity (possibly through stimulating the accumulation of PTRE1 at plasma membrane, resulting in decreased intracellular and nuclear localization) and hence suppresses Aux/IAA protein degradation (2) to coordinate regulation of auxin responses, reflecting a mechanism for fine control of Aux/IAA homeostasis and auxin signalling.

    Reactant: Oryza sativa (Asian rice)

    Application: Western Blotting

    Pudmed ID: 29479780

    Journal: Plant Biotechnol J

    Figure Number: 1C

    Published Date: 2018-10-01

    First Author: Deng, F., Yamaji, N., et al.

    Impact Factor: 8.66

    Open Publication

    Development of transgenic rice with reduced As accumulation in the grains using tissue?specific expression of OsABCC1, ??ECS and ScYCF1. (a) Analysis of the tissue?specific expression of the OsRCc3 promoter by immunostaining OsRCc3 promoter::GUS transgenic plants (RCc3p::GUS) using a GUS antibody. The internode section denoted by broken lines is magnified in the inset surrounded by yellow solid lines. Bar = 100 ?m. (b) Maps of vectors carrying RCc3p?A (RCc3 pro::OsABCC1?V5), RCc3p?AE (RCc3 pro::OsABCC1?V5, ZmUBI pro::??ECS) or RCc3p?AEY (RCc3 pro::OsABCC1?V5, ZmUBI pro::??ECS, RCc3 pro::ScYCF1). (c) Subcellular localization of OsABCC1?V5 in the roots of RCc3p?AEY plants using a sucrose density gradient analysis. Anti?V5, anti?OsABCC1, anti?V?ATPase (tonoplast marker), anti?H+?ATPase (plasma membrane marker) and Bip (ER marker) were used to assess protein abundance in the different compartments. The signal of OsABCC1?V5 corresponded to the signals of OsABCC1 and V?ATPase. (d) Arsenic accumulation in brown rice harvested from T3 transgenic plants transformed with RCc3p?A, RCc3p?AE, RCc3p?AEY, UBIp?A, UBIp?AE or UBIp?AEY. The As concentration was analysed in brown rice from plants grown in soil with a typical basal level of As. The values are means and standard errors (n = 5 plants). Different letters indicate significantly different means (Tukey's multiple comparison analysis, P ? 0.05).

    Reactant: Algae

    Application: Western Blotting

    Pudmed ID: 30157181

    Journal: PLoS One

    Figure Number: 2A

    Published Date: 2018-08-30

    First Author: Pertl-Obermeyer, H., Lackner, P., et al.

    Impact Factor: 2.942

    Open Publication

    Total membrane fractions of Chara internodal cells.(A) Proteins of membrane fractions (MF) were separated by SDS-PAGE (10%), stained with Coomassie Brilliant Blue (CBB) or blotted onto PVDF membranes for immunodetection of the plasma membrane H+ ATPase. 30 ?g protein per lane. Numbers on the left refer to molecular weight markers in kDa. Only the upper part of the PVDF membrane was used, the lower part was probed for immunodetection of low molecular weight proteins. (B) Immunodetection of selected organelle marker proteins for vacuoles (VHA-?, H+ PPase), ER (BiP2), plasma membrane and endosomal compartments (ARA6) or cytosol (tubulin, GRF 14-3-3). Proteins of the MFs were separated by preparative SDS-PAGE (12.75% or 10% for GRF and ARA6), plotted onto PVDF membranes cut into 3 mm strips and detected with the respective antibodies. 10 ?g protein per strip. Molecular weight markers are given in kDa. Arrow heads indicate the expected position of the respective protein.

    Reactant: Algae

    Application: Western Blotting

    Pudmed ID: 30157181

    Journal: PLoS One

    Figure Number: 5B

    Published Date: 2018-08-30

    First Author: Pertl-Obermeyer, H., Lackner, P., et al.

    Impact Factor: 2.942

    Open Publication

    Differences in charasome abundance and protein expression in alkaline and acidic regions of Chara cells.(A) Left image pair: FM1-43-labelled charasomes (green fluorescence) and chloroplasts (bright field image) at an acidic band. Right image pair: FM1-43-stained charasomes are absent from the alkaline band; the bright field images show the chloroplasts. An FM1-43-stained internodal cell was cut into acid and alkaline regions as described in Materials and Methods guided by pH banding pattern visualized by phenol red. Cell fragments were mounted in artificial fresh water and examined in the CLSM. Bar = 20 ?m (B) Proteins of membrane fractions (MF) and cytosolic fractions (CF) obtained from acidic (ac) and alkaline (alk) regions were separated by SDS-PAGE (10%) and stained with Comassie Brilliant Blue (CBB) or blotted onto PVDF membranes for immunodetection of the plasma membrane H+ ATPase using only the upper part of the membrane. 15 ?g protein was loaded per lane. Numbers on the left refer to molecular weight markers in kDa. (C) Immunodetection of selected higher and lower molecular weight proteins from the membrane fraction (MF) as indicated. 10 ?g protein was loaded per lane, 10% gel. PVDF membrane was cut into upper and lower halves at 50 kDa. Molecular weight markers given in kDa.

    Reactant: Vitis vinifera (Common grape vine)

    Application: Western Blotting

    Pudmed ID: 31156689

    Journal: Front Plant Sci

    Figure Number: 2E

    Published Date: 2019-06-04

    First Author: Kuang, L., Chen, S., et al.

    Impact Factor: 5.435

    Open Publication

    Grape berry flesh cell protoplast and vacuole preparations and quality check. (A) Isolated protoplasts. (B) Vacuole enrichment by Ficoll gradient centrifugation. (C) Crude vacuoles stained with Neutral Red. (D) Vacuoles in vacuole-enriched preparation stained with Neutral Red, solid arrow indicating vacuole, dashed arrow indicating tonoplast vesicle, inset indicating vacuoles with microdomains. (E) Relative quantity of P-ATPase between protoplast and vacuole isolations by western blotting analysis. (F) Relative quantity of V-ATPase between protoplast and vacuole isolations by western blotting analysis. Values were the average of three replicates ± SD.

    Reactant: Arabidopsis thaliana (Thale cress)

    Application: Western Blotting

    Pudmed ID: 32308664

    Journal: Front Plant Sci

    Figure Number: 2A

    Published Date: 2020-04-21

    First Author: Li, X., Sanagi, M., et al.

    Impact Factor: 5.435

    Open Publication

    Co-immunoprecipitation analysis of plasma membrane H+-ATPase and 14-3-3 proteins. WT and transgenic Arabidopsis plants expressing FLAG-14-3-3? were grown in control liquid medium containing 100 mM Glc/30 mM N, and 10-day-old seedlings were treated with the control (C) or the high C/low N-nutrient stress medium containing 200 mM Glc/0.3 mM N (S) for 30 min. Proteins were extracted and subjected to immunoprecipitation with anti-FLAG antibody beads, followed by immunoblotting with anti-plasma membrane H+-ATPase and anti-FLAG antibodies. Three independent experiments showed similar results.

  • Additional Information
  • Additional information:

    Cellular [compartment marker] for plasma membrane

    Additional information (application):

    Before SDS-PAGE, centrifuge your samples at room temperature at 10 000 rpm/1 min to remove any aggregates. 

    H+ATPase will be less abundant in mature roots and leafs and therefore detection may require use of very sensitive reagents. 

    This product can be sold containing ProClin if requested.

     

  • Background
  • Background:

    The Plasma Membrane H+ATPase is a family of proteins of ca. 100 kDa that are believed to be exclusive to the plasma membranes of plants and fungi. The protein is anchored within biological membrane which creates an electrochemical gradient used as an energy source and is essential for uptake of most metabolites and plant responses to environment, for example movement of leaves.

  • Product Citations
  • Selected references: Jiang et al.(2024). Dual function of overexpressing plasma membrane H+-ATPase in balancing carbon-water use. Science Advances Vol. 10, No. 45.
    Huang et al. (2024). Insight into Function and Subcellular Localization of a Type III-Secreted Effector in Pseudomonas syringae pv. tomato DC3000. American Journal of Plant Sciences > Vol.15 No.10, October 2024.
    Salazar et al. (2024). SOS1 tonoplast neo-localization and the RGG protein SALTY are important in the extreme salinity tolerance of Salicornia bigelovii. Nat Commun. 2024 May 20;15(1):4279.doi: 10.1038/s41467-024-48595-5.
    Mosesso et al. (2024). Arabidopsis CaLB1 undergoes phase separation with the ESCRT protein ALIX and modulates autophagosome maturation. Nat Commun. 2024 Jun 19;15(1):5188. doi: 10.1038/s41467-024-49485-6.
    Li et al. (2024). An NLR paralog Pit2 generated from tandem duplication of Pit1 fine-tunes Pit1 localization and function. Nat Commun. 2024 May 30;15(1):4610. doi: 10.1038/s41467-024-48943-5. 
    Kimura and Kanegae (2024).A phytochrome/phototropin chimeric photoreceptor promotes growth of fern gametophytes under limited light conditions. Exp Bot . 2024 Apr 15;75(8):2403-2416. 
    Cha et al. (2024). Arabidopsis COP1 guides stomatal response in guard cells through pH regulation. Commun Biol. 2024 Feb 5;7(1):150. doi: 10.1038/s42003-024-05847-w.  
    Nadiminti et al. (2023).Spatiotemporal Deposition of Cell Wall Polysaccharides in Oat Endosperm during Grain Development.Plant Physiol. 2023 Oct 20;194(1):168-189.doi: 10.1093/plphys/kiad566.
    Suanno et al. (2023) Small extracellular vesicles released from germinated kiwi pollen (pollensomes) present characteristics similar to mammalian exosomes and carry a plant homolog of ALIX, Front. Plant Sci., 25 January 2023, Sec. Plant Membrane Traffic and Transport, Volume 14 - 2023.
    Guo, Zhang , Wang, et al. (2023) Cold-induced calreticulin OsCRT3 conformational changes promote OsCIPK7 binding and temperature sensing in rice. EMBO J. 2023;42(1):e110518. doi:10.15252/embj.2021110518
    Vogel et al. (2022) Lipid-mediated activation of plasma membrane-localized deubiquitylating enzymes modulate endosomal trafficking. Nat Commun. 2022;13(1):6897. Published 2022 Nov 12. doi:10.1038/s41467-022-34637-3
    Akpinar, Cansev (2022) Physiological and molecular responses of roots differ from those of leaves in spinach plants subjected to short-term drought stress, South African Journal of Botany, Volume 151, Part A,2022,Pages 9-17, ISSN 0254-6299,https://doi.org/10.1016/j.sajb.2022.09.032.
    Baena et al. (2022) SNARE SYP132 mediates divergent traffic of plasma membrane H+-ATPase AHA1 and antimicrobial PR1 during bacterial pathogenesis. Plant Physiol. 2022 Jun 27;189(3):1639-1661. doi: 10.1093/plphys/kiac149. PMID: 35348763; PMCID: PMC9237740.
    Kostic et al. (2022),The Relative Sensitivity of Marigold vs. Tomato to Iron (Fe) Toxicity Is Associated with Root Traits: Root-to-Shoot Mass Ratio, Failure to Sequester Fe in Roots, and Levels of the Major Fe-Uptake Protein, IRT, Horticulturae 2022, 8(9), 803; https://doi.org/10.3390/horticulturae8090803
    Michalopoulou et al. (2022) The host exocyst complex is targeted by a conserved bacterial type-III effector that promotes virulence. Plant Cell. 2022 May 30:koac162. doi: 10.1093/plcell/koac162. Epub ahead of print. PMID: 35640532.
    Hofmann, Wienkoop & Luthje (2022) Hypoxia-Induced Aquaporins and Regulation of Redox Homeostasis by a Trans-Plasma Membrane Electron Transport System in Maize Roots. Antioxidants (Basel). 2022 Apr 25;11(5):836. doi: 10.3390/antiox11050836. PMID: 35624700; PMCID: PMC9137787.
    Huang et al (2021). Parasitic modulation of host development by ubiquitin-independent protein degradation. Cell. 2021 Sep 30;184(20):5201-5214.e12. doi: 10.1016/j.cell.2021.08.029. Epub 2021 Sep 17. PMID: 34536345; PMCID: PMC8525514.
    Lapshin et al. (2021) Sterol Extraction from Isolated Plant Plasma Membrane Vesicles Affects H+-ATPase Activity and H+-Transport. Biomolecules. 2021 Dec 16;11(12):1891. doi: 10.3390/biom11121891. PMID: 34944535; PMCID: PMC8699270.
    Choi et al. (2021) Augmented CO2 tolerance by expressing a single H+-pump enables microalgal valorization of industrial flue gas. Nat Commun. 2021 Oct 18;12(1):6049. doi: 10.1038/s41467-021-26325-5. PMID: 34663809; PMCID: PMC8523702.
    Cano-Ramirez et al. (2021) M. Plasma Membrane Fluidity: An Environment Thermal Detector in Plants. Cells. 2021 Oct 17;10(10):2778. doi: 10.3390/cells10102778. PMID: 34685758; PMCID: PMC8535034.
    Adamo et al. (2021). Nanoalgosomes: Introducing extracellular vesicles produced by microalgae. J Extracell Vesicles. 2021 Apr;10(6):e12081. doi: 10.1002/jev2.12081. Epub 2021 Apr 27. PMID: 33936568; PMCID: PMC8077145.
    Ekanayake et al. (2021) A. DYNAMIN-RELATED PROTEIN DRP1A functions with DRP2B in plant growth, flg22-immune responses, and endocytosis. Plant Physiol. 2021 Feb 3:kiab024. doi: 10.1093/plphys/kiab024. Epub ahead of print. PMID: 33564884.
    Wang et al. (2020). Plant NLR Immune Receptor Tm-22 Activation Requires NB-ARC Domain-Mediated Self-Association of CC Domain. PLoS Pathog. 2020 Apr 27;16(4):e1008475. doi: 10.1371/journal.ppat.1008475.
    Collins et al. (2020). EPSIN1 Modulates the Plasma Membrane Abundance of FLAGELLIN SENSING2 for Effective Immune Responses . Plant Physiol. 2020 Feb 24. pii: pp.01172.2019. doi: 10.1104/pp.19.01172
    Wang et al. (2020). The Arabidopsis exocyst subunits EXO70B1 and EXO70B2 regulate FLS2 homeostasis at the plasma membrane. New Phytol. 2020 Mar 2. doi: 10.1111/nph.16515.
    Kuang et al. (2019). Quantitative Proteome Analysis Reveals Changes in the Protein Landscape During Grape Berry Development With a Focus on Vacuolar Transport Proteins. Front Plant Sci. 2019 May 15;10:641. doi: 10.3389/fpls.2019.00641. eCollection 2019.
    Yuan et al. (2019). Phospholipidase Ddelta Negatively Regulates the Function of Resistance to Pseudomonas syringae pv. Maculicola 1 (RPM1). Front Plant Sci. 2019 Jan 18;9:1991. doi: 10.3389/fpls.2018.01991.
    Zhang et all. (2018). Root plasma membrane H+-ATPase is involved in low pH-inhibited nitrogen accumulation in tea plants (Camellia sinensis L.). Plant Growth Regul (2018) 86: 423.
    Roth et al. (2018). A rice Serine/Threonine receptor-like kinase regulates arbuscular mycorrhizal symbiosis at the peri-arbuscular membrane. Nat Commun. 2018 Nov 8;9(1):4677. doi: 10.1038/s41467-018-06865-z.
    Wang et al. (2018). Resistance protein Pit interacts with the GEF OsSPK1 to activate OsRac1 and trigger rice immunity. Proc Natl Acad Sci U S A. 2018 Nov 16. pii: 201813058. doi: 10.1073/pnas.1813058115.
    Pertl-Obermeyer et al. (2018). Dissecting the subcellular membrane proteome reveals enrichment of H+ (co-)transporters and vesicle trafficking proteins in acidic zones of Chara internodal cells. PLoS One. 2018 Aug 29;13(8):e0201480. doi: 10.1371/journal.pone.0201480.
    Zhang et al. (2018). Maintenance of mesophyll potassium and regulation of plasma membrane H+-ATPase are associated with physiological responses of tea plants to drought and subsequent rehydration. The Crop Journal July 2018. (Camellia sinensis)
    Seguel et al. (2018). PROHIBITIN 3 forms complexes with ISOCHORISMATE SYNTHASE 1 to regulate stress-induced salicylic acid biosynthesis in Arabidopsis. Plant Physiol. Jan 2018. DOI:10.1104/pp.17.00941
    Duan et al. (2017). A Lipid-Anchored NAC Transcription Factor Is Translocated into the Nucleus and Activates Glyoxalase I Expression during Drought Stress. Plant Cell. 2017 Jul;29(7):1748-1772. doi: 10.1105/tpc.17.00044. (Nicotiana benthamiana)
    Nagel et al. (2017). Arabidopsis SH3P2 is an ubiquitin-binding protein that functions together with ESCRT-I and the deubiquitylating enzyme AMSH3. Proc Natl Acad Sci U S A. 2017 Aug 7. pii: 201710866. doi: 10.1073/pnas.1710866114.
    Aloui et al. (2017). The plasma membrane proteome of Medicago truncatula roots as modified by arbuscular mycorrhizal symbiosis. Mycorrhiza. 2017 Jul 19. doi: 10.1007/s00572-017-0789-5.
    Lomin et al. (2017). Studies of cytokinin receptor–phosphotransmitter interaction provide evidences for the initiation of cytokinin signalling in the endoplasmic reticulum. Functional Plant Biology, CSIRO Publications. (Nicotiana benthamiana, western blot)
    Kovaleva et al. (2017). Regulation of Petunia Pollen Tube Growth by Phytohormones: Identification of Their Potential Targets. DOI:10.17265/2161-6256/2016.04.004. (immunolocalization)
    Liao et al. (2017). Arabidopsis E3 ubiquitin ligase PLANT U-BOX13 (PUB13) regulates chitin receptor LYSIN MOTIF RECEPTOR KINASE5 (LYK5) protein abundance. New Phytol. 2017 Feb 14. doi: 10.1111/nph.14472.
    Wang et al. (2016). Chloroplast-mediated regulation of CO2-concentrating mechanism by Ca2+-binding protein CAS in the green alga Chlamydomonas reinhardtii. Proc Natl Acad Sci U S A. 2016 Nov 1;113(44):12586-12591. doi: 10.1073/pnas.1606519113. Epub 2016 Oct 17. PMID: 27791081; PMCID: PMC5098658.
    LaMontagne et al. (2016). Isolation of Microsomal Membrane Proteins from Arabidopsis thaliana. Curr. Protoc. Plant Biol. 1:217-234. doi: 10.1002/cppb.20020.
    Heard et al. (2015). Identification of Regulatory and Cargo Proteins of Endosomal and Secretory Pathways in Arabidopsis thaliana by Proteomic Dissection. Mol Cell Proteomics. 2015 Jul;14(7):1796-813. doi: 10.1074/mcp.M115.050286. Epub 2015 Apr 21.
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PM016
 100ug