Your search keyword '"Sakharam, Waghmare"' showing total 13 results

1. Engineering a K+ channel ‘sensory antenna’ enhances stomatal kinetics, water use efficiency and photosynthesis

Author

Wijitra Horaruang, Martina Klejchová, William Carroll, Fernanda A. L. Silva-Alvim, Sakharam Waghmare, Maria Papanatsiou, Anna Amtmann, Adrian Hills, Jonas Chaves Alvim, Michael R. Blatt, and Ben Zhang

Subjects

Plant Science

Published

2022

2. SNARE SYP132 mediates divergent traffic of plasma membrane H+-ATPase AHA1 and antimicrobial PR1 during bacterial pathogenesis

Author

Lingfeng Xia, Sakharam Waghmare, Guillermo Baena, and Rucha Anil Karnik

Subjects

Proton-Translocating ATPases, Anti-Infective Agents, Arabidopsis Proteins, Qa-SNARE Proteins, Physiology, Cell Membrane, Arabidopsis, Genetics, Pseudomonas syringae, Plant Science, SNARE Proteins, Plant Diseases

Abstract

The vesicle trafficking SYNTAXIN OF PLANTS132 (SYP132) drives hormone-regulated endocytic traffic to suppress the density and function of plasma membrane (PM) H+-ATPases. In response to bacterial pathogens, it also promotes secretory traffic of antimicrobial pathogenesis-related (PR) proteins. These seemingly opposite actions of SYP132 raise questions about the mechanistic connections between the two, likely independent, membrane trafficking pathways intersecting plant growth and immunity. To study SYP132 and associated trafficking of PM H+-ATPase 1 (AHA1) and PATHOGENESIS-RELATED PROTEIN1 (PR1) during pathogenesis, we used the virulent Pseudomonas syringae pv. tomato DC3000 (Pst DC3000) bacteria for infection of Arabidopsis (Arabidopsis thaliana) plants. SYP132 overexpression suppressed bacterial infection in plants through the stomatal route. However, bacterial infection was enhanced when bacteria were infiltrated into leaf tissue to bypass stomatal defenses. Tracking time-dependent changes in native AHA1 and SYP132 abundance, cellular distribution, and function, we discovered that bacterial pathogen infection triggers AHA1 and SYP132 internalization from the plasma membrane. AHA1 bound to SYP132 through its regulatory SNARE Habc domain, and these interactions affected PM H+-ATPase traffic. Remarkably, using the Arabidopsis aha1 mutant, we discovered that AHA1 is essential for moderating SYP132 abundance and associated secretion of PR1 at the plasma membrane for pathogen defense. Thus, we show that during pathogenesis SYP132 coordinates AHA1 with opposing effects on the traffic of AHA1 and PR1.

Published

2022

3. Engineering a K

Author

Wijitra, Horaruang, Martina, Klejchová, William, Carroll, Fernanda A L, Silva-Alvim, Sakharam, Waghmare, Maria, Papanatsiou, Anna, Amtmann, Adrian, Hills, Jonas Chaves, Alvim, Michael R, Blatt, and Ben, Zhang

Subjects

Kinetics, Arabidopsis Proteins, Plant Stomata, Arabidopsis, Water, Photosynthesis

Abstract

Stomata of plant leaves open to enable CO

Published

2021

4. SNAREs SYP121 and SYP122 Mediate the Secretion of Distinct Cargo Subsets

Author

Rucha Karnik, Sakharam Waghmare, Michael R. Blatt, Edita Lileikyte, Jennifer K. Goodman, and Alexandra M. E. Jones

Subjects

0106 biological sciences, 0301 basic medicine, Vesicle fusion, biology, Physiology, Mutant, Plant Science, biology.organism_classification, 01 natural sciences, Cell biology, Transport protein, Cell membrane, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Arabidopsis, Genetics, medicine, Syntaxin, Arabidopsis thaliana, Secretion, 010606 plant biology & botany

Abstract

SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins drive vesicle fusion and contribute to homoeostasis, pathogen defense, cell expansion, and growth in plants. In Arabidopsis (Arabidopsis thaliana), two homologous Qa-SNAREs, SYNTAXIN OF PLANTS121 (SYP121) and SYP122, facilitate the majority of secretory traffic to the plasma membrane, and the single mutants are indistinguishable from wild-type plants in the absence of stress, implying a redundancy in their functions. Nonetheless, several studies suggest differences among the secretory cargo of these SNAREs. To address this issue, we conducted an analysis of the proteins secreted by cultured wild-type, syp121, and syp122 mutant Arabidopsis seedlings. Here, we report that a number of cargo proteins were associated differentially with traffic mediated by SYP121 and SYP122. The data also indicated important overlaps between the SNAREs. Therefore, we conclude that the two Qa-SNAREs mediate distinct but complementary secretory pathways during vegetative plant growth.

Published

2018

5. Gating control and K+ uptake by the KAT1 K+ channel leaveraged through membrane anchoring of the trafficking protein SYP121

Author

Cécile Lefoulon, Sakharam Waghmare, Michael R. Blatt, and Rucha Karnik

Subjects

0106 biological sciences, 0301 basic medicine, Vesicle fusion, biology, Physiology, SNARE binding, Chemistry, Vesicle, Plant Science, Gating, biology.organism_classification, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Membrane, Arabidopsis, Biophysics, Ion transporter, Ion channel, 010606 plant biology & botany

Abstract

Vesicle traffic is tightly coordinated with ion transport for plant cell expansion through physical interactions between subsets of vesicle-trafficking (so-called SNARE) proteins and plasma membrane Kv channels, including the archetypal inward-rectifying K+ channel, KAT1 of Arabidopsis. Ion channels open and close rapidly over milliseconds, whereas vesicle fusion events require many seconds. Binding has been mapped to conserved motifs of both the Kv channels and the SNAREs, but knowledge of the temporal kinetics of their interactions, especially as it might relate to channel gating and its coordination with vesicle fusion remains unclear. Here, we report that the SNARE SYP121 promotes KAT1 gating through a persistent interaction that alters the stability of the channel, both in its open and closed states. We show, too, that SYP121 action on the channel open state requires SNARE anchoring in the plasma membrane. Our findings indicate that SNARE binding confers a conformational bias that encompasses the microscopic kinetics of channel gating, with leverage applied through the SNARE anchor in favour of the open channel.

Published

2018

6. K(+) Channel-SEC11 Binding Exchange Regulates SNARE Assembly for Secretory Traffic

Author

Cécile Lefoulon, Michael R. Blatt, Naomi Donald, Edita Liliekyte, Ben Zhang, and Sakharam Waghmare

Subjects

0106 biological sciences, Vesicle fusion, Potassium Channels, Physiology, Arabidopsis, Cell Cycle Proteins, Plant Science, 01 natural sciences, Exocytosis, Cations, Genetics, Receptor, Ion transporter, Research Articles, SNARE complex assembly, biology, SNARE binding, Chemistry, Arabidopsis Proteins, Qa-SNARE Proteins, Cell Membrane, biology.organism_classification, Transport protein, Protein Transport, Biophysics, SNARE Proteins, 010606 plant biology & botany

Abstract

Cell expansion requires that ion transport and secretory membrane traffic operate in concert. Evidence from Arabidopsis (Arabidopsis thaliana) indicates that such coordination is mediated by physical interactions between subsets of so-called SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins, which drive the final stages of vesicle fusion, and K(+) channels, which facilitate uptake of the cation to maintain cell turgor pressure as the cell expands. However, the sequence of SNARE binding with the K(+) channels and its interweaving within the events of SNARE complex assembly for exocytosis remains unclear. We have combined protein-protein interaction and electrophysiological analyses to resolve the binding interactions of the hetero-oligomeric associations. We find that the RYxxWE motif, located within the voltage sensor of the K(+) channels, is a nexus for multiple SNARE interactions. Of these, K(+) channel binding and its displacement of the regulatory protein SEC11 is critical to prime the Qa-SNARE SYP121. Our results indicate a stabilizing role for the Qbc-SNARE SNAP33 in the Qa-SNARE transition to SNARE complex assembly with the R-SNARE VAMP721. They also suggest that, on its own, the R-SNARE enters an anomalous binding mode with the channels, possibly as a fail-safe measure to ensure a correct binding sequence. Thus, we suggest that SYP121 binding to the K(+) channels serves the role of a primary trigger to initiate assembly of the secretory machinery for exocytosis.

Published

2019

7. VAMP721 Conformations Unmask an Extended Motif for K+ Channel Binding and Gating Control

Author

Michael R. Blatt, Sakharam Waghmare, Naomi Donald, Ben Zhang, and Rucha Karnik

Subjects

0106 biological sciences, 0301 basic medicine, Vesicle fusion, Physiology, Vesicle, Protein domain, Lipid bilayer fusion, Plant Science, Gating, Biology, 01 natural sciences, 03 medical and health sciences, Crystallography, 030104 developmental biology, Genetics, Biophysics, SNARE complex, R-SNARE Proteins, 010606 plant biology & botany, SNARE complex assembly

Abstract

Soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins play a major role in membrane fusion and contribute to cell expansion, signaling, and polar growth in plants. The SNARE SYP121 of Arabidopsis thaliana that facilitates vesicle fusion at the plasma membrane also binds with, and regulates, K+ channels already present at the plasma membrane to affect K+ uptake and K+-dependent growth. Here, we report that its cognate partner VAMP721, which assembles with SYP121 to drive membrane fusion, binds to the KAT1 K+ channel via two sites on the protein, only one of which contributes to channel-gating control. Binding to the VAMP721 SNARE domain suppressed channel gating. By contrast, interaction with the amino-terminal longin domain conferred specificity on VAMP721 binding without influencing gating. Channel binding was defined by a linear motif within the longin domain. The SNARE domain is thought to wrap around this structure when not assembled with SYP121 in the SNARE complex. Fluorescence lifetime analysis showed that mutations within this motif, which suppressed channel binding and its effects on gating, also altered the conformational displacement between the VAMP721 SNARE and longin domains. The presence of these two channel-binding sites on VAMP721, one also required for SNARE complex assembly, implies a well-defined sequence of events coordinating K+ uptake and the final stages of vesicle traffic. It suggests that binding begins with VAMP721, and subsequently with SYP121, thereby coordinating K+ channel gating during SNARE assembly and vesicle fusion. Thus, our findings also are consistent with the idea that the K+ channels are nucleation points for SNARE complex assembly.

Published

2016

8. Gating control and K

Author

Cécile, Lefoulon, Sakharam, Waghmare, Rucha, Karnik, and Michael R, Blatt

Subjects

voltage‐dependent/protein conformation/plant cell expansion, inward‐rectifier/single‐channel analysis/binding, Arabidopsis Proteins, Qa-SNARE Proteins, Arabidopsis, Potassium, Biological Transport, Original Article, Original Articles, Potassium Channels, Inwardly Rectifying, SNARE Proteins, Ion Channel Gating, Qa‐SNARE/K+ channel

Abstract

Vesicle traffic is tightly coordinated with ion transport for plant cell expansion through physical interactions between subsets of vesicle‐trafficking (so‐called SNARE) proteins and plasma membrane Kv channels, including the archetypal inward‐rectifying K+ channel, KAT1 of Arabidopsis. Ion channels open and close rapidly over milliseconds, whereas vesicle fusion events require many seconds. Binding has been mapped to conserved motifs of both the Kv channels and the SNAREs, but knowledge of the temporal kinetics of their interactions, especially as it might relate to channel gating and its coordination with vesicle fusion remains unclear. Here, we report that the SNARE SYP121 promotes KAT1 gating through a persistent interaction that alters the stability of the channel, both in its open and closed states. We show, too, that SYP121 action on the channel open state requires SNARE anchoring in the plasma membrane. Our findings indicate that SNARE binding confers a conformational bias that encompasses the microscopic kinetics of channel gating, with leverage applied through the SNARE anchor in favour of the open channel., Plant cells maintain turgor pressure against the cell wall. So vesicle traffic and solute uptake must be tightly coordinated during cell expansion. Secretory vesicle traffic and K+ channel activities are promoted by physical interactions between subsets of vesicle‐trafficking proteins and Kv channels at the plant plasma membrane, but the temporal relationship between these processes has remained unclear. Ion channels open and close rapidly over milliseconds, whereas vesicle fusion requires periods of many seconds. Here, we show that the SNARE binding effects long‐term changes in channel gating kinetics through conformations of the channel voltage sensor that depend, in part, on the leverage afforded by anchoring of the SNARE in the plasma membrane.

Published

2018

9. Binding of SEC11 Indicates Its Role in SNARE Recycling after Vesicle Fusion and Identifies Two Pathways for Vesicular Traffic to the Plasma Membrane

Author

Rucha Karnik, Christin Aderhold, Ben Zhang, Christopher Grefen, Michael R. Blatt, and Sakharam Waghmare

Subjects

Vesicle fusion, Molecular Sequence Data, Mutant, Arabidopsis, Cell Cycle Proteins, Plant Science, Biology, Membrane Fusion, Models, Biological, Plant Epidermis, Cytosol, Arabidopsis thaliana, Amino Acid Sequence, Inflorescence, Receptor, Research Articles, Cell Proliferation, Cell Size, Regulation of gene expression, Arabidopsis Proteins, Qa-SNARE Proteins, Secretory Vesicles, Cell Membrane, Genetic Complementation Test, Wild type, Biological Transport, Cell Biology, biology.organism_classification, Cell biology, N-terminus, Mutation, biological phenomena, cell phenomena, and immunity, Carrier Proteins, Peptides, Protein Binding

Abstract

SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins drive vesicle fusion in all eukaryotes and contribute to homeostasis, pathogen defense, cell expansion, and growth in plants. Two homologous SNAREs, SYP121 (=SYR1/PEN1) and SYP122, dominate secretory traffic to the Arabidopsis thaliana plasma membrane. Although these proteins overlap functionally, differences between SYP121 and SYP122 have surfaced, suggesting that they mark two discrete pathways for vesicular traffic. The SNAREs share primary cognate partners, which has made separating their respective control mechanisms difficult. Here, we show that the regulatory protein SEC11 (=KEULE) binds selectively with SYP121 to affect secretory traffic mediated by this SNARE. SEC11 rescued traffic block by dominant-negative (inhibitory) fragments of both SNAREs, but only in plants expressing the native SYP121. Traffic and its rescue were sensitive to mutations affecting SEC11 interaction with the N terminus of SYP121. Furthermore, the domain of SEC11 that bound the SYP121 N terminus was itself able to block secretory traffic in the wild type and syp122 but not in syp121 mutant Arabidopsis. Thus, SEC11 binds and selectively regulates secretory traffic mediated by SYP121 and is important for recycling of the SNARE and its cognate partners.

Published

2015

10. Commandeering channel voltage sensors for secretion, cell turgor, and volume control

Author

Ben Zhang, Sakharam Waghmare, Rucha Karnik, Cécile Lefoulon, Wendy González, Michael R. Blatt, and Emily R. Larson

Subjects

0106 biological sciences, 0301 basic medicine, Potassium Channels, Turgor pressure, voltage-dependent, Cellular homeostasis, Review, Plant Science, Biology, plant cell turgor, 01 natural sciences, 03 medical and health sciences, Sec1-Munc18 protein, volume control, Secretion, Plant Physiological Phenomena, Ion transporter, Ion channel, Plant Proteins, Water transport, Vesicle, Biological Transport, SNARE protein, Secretory Vesicle, Cell biology, secretion, 030104 developmental biology, K+ channels, SNARE Proteins, Protein Binding, 010606 plant biology & botany

Abstract

Control of cell volume and osmolarity is central to cellular homeostasis in all eukaryotes. It lies at the heart of the century-old problem of how plants regulate turgor, mineral and water transport. Plants use strongly electrogenic H+-ATPases, and the substantial membrane voltages they foster, to drive solute accumulation and generate turgor pressure for cell expansion. Vesicle traffic adds membrane surface and contributes to wall remodelling as the cell grows. Although a balance between vesicle traffic and ion transport is essential for cell turgor and volume control, the mechanisms coordinating these processes have remained obscure. Recent discoveries have now uncovered interactions between conserved subsets of soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins that drive the final steps in secretory vesicle traffic and ion channels that mediate in inorganic solute uptake. These findings establish the core of molecular links, previously unanticipated, that coordinate cellular homeostasis and cell expansion., Trends Vesicle trafficking (SNARE) proteins ‘commandeer’ the voltage sensor domains of Kv channels to confer a voltage dependence on secretory traffic for coordination with ion transport during cell expansion. Sec1/Munc18 (SM) protein-mediated regulation of secretion is selective among plasma membrane SNAREs. SM proteins and Kv channels bind the SNARE SYP121 at overlapping sites, implying a sequential interplay between these proteins to coordinate membrane traffic and transport.

Published

2017

11. A vesicle-trafficking protein commandeers Kv channel voltage sensors for voltage-dependent secretion

Author

Ben Zhang, Sakharam Waghmare, Christopher Grefen, Yizhou Wang, Adrian Hills, Cécile Lefoulon, Michael R. Blatt, Emily R. Larson, and Rucha Karnik

Subjects

Vesicle fusion, Membrane, biology, In vivo, Arabidopsis, Vesicle, Turgor pressure, Secretion, Plant Science, biology.organism_classification, Ion transporter, Cell biology

Abstract

Growth in plants depends on ion transport for osmotic solute uptake and secretory membrane trafficking to deliver material for wall remodelling and cell expansion. The coordination of these processes lies at the heart of the question, unresolved for more than a century, of how plants regulate cell volume and turgor. Here we report that the SNARE protein SYP121 (SYR1/PEN1), which mediates vesicle fusion at the Arabidopsis plasma membrane, binds the voltage sensor domains (VSDs) of K(+) channels to confer a voltage dependence on secretory traffic in parallel with K(+) uptake. VSD binding enhances secretion in vivo subject to voltage, and mutations affecting VSD conformation alter binding and secretion in parallel with channel gating, net K(+) concentration, osmotic content and growth. These results demonstrate a new and unexpected mechanism for secretory control, in which a subset of plant SNAREs commandeer K(+) channel VSDs to coordinate membrane trafficking with K(+) uptake for growth.

Published

2015

12. Analysis of crRNA Using Liquid Chromatography Electrospray Ionization Mass Spectrometry (LC ESI MS)

Author

Sakharam Waghmare, Mark J. Dickman, and Alison O. Nwokeoji

Subjects

Trans-activating crRNA, Chromatography, Protein mass spectrometry, Chemistry, RNase P, Electrospray ionization, Reversed-phase chromatography, Mass spectrometry, Sample preparation in mass spectrometry, Adduct

Abstract

Mass spectrometry is a powerful tool for characterizing RNA. Here we describe a method for the identification and characterisation of crRNA using liquid chromatography interfaced with electrospray ionization mass spectrometry (LC ESI MS). The direct purification of crRNA from the Cascade-crRNA complex was performed using denaturing ion pair reverse phase chromatography. Following purification of the crRNA, the intact mass was determined by LC ESI MS. Using this approach, a significant reduction in metal ion adduct formation of the crRNA was observed. In addition, RNase mapping of the crRNA was performed using RNase digestion in conjunction with liquid chromatography tandem MS analysis. Using the intact mass of the crRNA, in conjunction with RNase mapping experiments enabled the identification and characterisation of the crRNA, providing further insight into crRNA processing in a number of type I CRISPR-Cas systems.

Published

2015

13. RNA-guided complex from a bacterial immune system enhances target recognition through seed sequence interactions

Author

Blake, Wiedenheft, Esther, van Duijn, Jelle B, Bultema, Jelle, Bultema, Sakharam P, Waghmare, Sakharam, Waghmare, Kaihong, Zhou, Arjan, Barendregt, Wiebke, Westphal, Albert J R, Heck, Albert, Heck, Egbert J, Boekema, Egbert, Boekema, Mark J, Dickman, Mark, Dickman, Jennifer A, Doudna, Electron Microscopy, Groningen Biomolecular Sciences and Biotechnology, and Host-Microbe Interactions

Subjects

Models, Molecular, Macromolecular Substances, DEFENSE, Molecular Sequence Data, PROTEIN, Adaptive Immunity, Biology, THERMOPHILUS, surveillance system, chemistry.chemical_compound, Bacterial Proteins, DOMAIN, Endoribonucleases, Escherichia coli, CRISPR, Cmr, Gene, Trans-activating crRNA, Genetics, Multidisciplinary, Base Sequence, RNA, DNA, Biological Sciences, PROKARYOTES, Argonaute, RNA silencing, chemistry, Pseudomonas aeruginosa, Nucleic acid, CRISPR Loci, REPEATS, RNA interface, RESISTANCE

Abstract

Prokaryotes have evolved multiple versions of an RNA-guided adaptive immune system that targets foreign nucleic acids. In each case, transcripts derived from clustered regularly interspaced short palindromic repeats (CRISPRs) are thought to selectively target invading phage and plasmids in a sequence-specific process involving a variable cassette of CRISPR-associated ( cas ) genes. The CRISPR locus in Pseudomonas aeruginosa (PA14) includes four cas genes that are unique to and conserved in microorganisms harboring the Csy-type (CRISPR system yersinia) immune system. Here we show that the Csy proteins (Csy1–4) assemble into a 350 kDa ribonucleoprotein complex that facilitates target recognition by enhancing sequence-specific hybridization between the CRISPR RNA and complementary target sequences. Target recognition is enthalpically driven and localized to a “seed sequence” at the 5′ end of the CRISPR RNA spacer. Structural analysis of the complex by small-angle X-ray scattering and single particle electron microscopy reveals a crescent-shaped particle that bears striking resemblance to the architecture of a large CRISPR-associated complex from Escherichia coli , termed Cascade. Although similarity between these two complexes is not evident at the sequence level, their unequal subunit stoichiometry and quaternary architecture reveal conserved structural features that may be common among diverse CRISPR-mediated defense systems.

Published

2011