NOTE: In accordance with Washington University's Open Access Resolution, all possible effort is made to make our publications freely available to the public. We are posting what we can at the Washington University Open Scholarship repository.
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2023
A. Flynn, K. Miller, J. M. Codjoe, M. R. King, and E. S. Haswell. The soluble N-termini of mechanosensitive ion channels MSL8, MSL9, and MSL10 are environmentally sensitive intrinsically disordered regions with distinct biophysical characteristics in vivo. Plant Direct, in press. bioRxiV.
M. Goodman, E. S. Haswell, V. Vasquez. (2023). The Usual and the Unusual Suspects: Mechanosensitive (MS) Proteins. Journal of General Physiology. 155:e202213248. PubMed.
J. Monaghan, S. Brady, E. S. Haswell, S. Roy, B. Schwessinger, and H. E. McFarlane. (2023). Running a research group in the next generation: Combining sustainable and reproducible research with values-driven leadership. Journal of Experimental Botany, 74:1-6. PubMed.
2022
J. M. Codjoe, R. Richardson, F. McLoughlin, R. Vierstra, E. S. Haswell (2022). Unbiased proteomic and forward genetic screens reveal that mechanosensitive ion channel MSL10 functions at ER-plasma membrane contact sites in Arabidopsis thaliana. eLIFE, 11:e80501. PubMed.
T. J. Kleist, I. W. Lin, S. Xu, G. Maksaev, E. S. Haswell, W. B Frommer, M. M Wudick. (2022). OzTracs: Optical Osmolality Reporters Engineered from Mechanosensitive Ion Channels. Biomolecules, 12:787. PubMed.
C. Procko, I. Radin, C. Hou, R. Richardson, E. S. Haswell, J. Chory. (2022). Dynamic calcium signals mediate the feeding response of the carnivorous sundew plant. PNAS, 119:e2206433119. PubMed.
K. Miller, W. Strychalski, M. Nickaeen, A. Carlsson and E. S. Haswell. (2022). In vitro experiments and kinetic models of Arabidopsis pollen hydration show that MSL8 is not a simple tension-gated osmoregulator. Current Biology, 32:2921-2934. PubMed.
S. Rice, E. Lazarus, C. Anderton, K. Birnbaum, J. Brophy, B. Cole, D. Dickel, D. Ehrhardt, N. Fahlgren, M. Frank, E. Haswell, S.Huang, S. Leiboff, M. Libault, M. Otegui, N. Provart, R. Uhrig, and S. Rhee. (2022). First Plant Cell Atlas Symposium Report. Plant Direct 8:e406. PubMed.
X. Peng., Y. Liu, W. He, E. D. Hoppe, L. Zhou, F. Xin, E. S. Haswell, B. G. Pickard, G. M. Genin and T. J. Lu. (2022). Acoustic radiation force on a long cylinder, and potential sound transduction by tomato trichomes. Biophysical Journal, 121:3917-3926. PubMed.
Y. Wang, J. Coomey, K. Miller, G. S. Jensen and E. S. Haswell. (2022). Interactions between a mechanosensitive ion channel and cell wall integrity signaling influence pollen germination in Arabidopsis thaliana. Journal of Experimental Botany. 73:1533-1545. PubMed.
D. Basu, J.M. Codjoe, K. M. Veley and E. S. Haswell. (2022). The Mechanosensitive Ion Channel MSL10 Modulates Susceptibility to Pseudomonas syringae in Arabidopsis thaliana. Mol Plant Micro Interact. 35:567-582. PubMed.
I. Radin and E. S. Haswell. (2022). Looking at Mechanobiology Through an Evolutionary Lens. Current Opinion in Plant Biology. 65:102112. Free Access. PubMed.
J. M. Codjoe, K. Miller and E. S. Haswell. (2022). Plant Cell Mechanobiology: Greater than the Sum of its Parts. Plant Cell. 34:129-145. PubMed.
I. Radin, R. Richardson and E. S. Haswell. (2022). Moss Piezo homologs have a conserved structure, are ubiquitously expressed, and do not affect general vacuole function. Plant Signaling and Behavior. 17:2015893. PubMed.
2021
J. Moe-Lange, N. M. Gappel, M. Machado, M. M. Wudick, C. S. A. Sies, S. N. Schott-Verdugo, M. Bonus, S. Mishra, T. Hartwig, M. Bezrutczyk, D. Basu, E. E. Farmer, H. Gohlke, A. Malkovskiy, E. S. Haswell, M. J. Lercher, D. W. Ehrhardt, W. B. Frommer & T. J. Kleist. (2021). Interdependence of a mechanosensitive anion channel and glutamate receptors in distal wound signaling. Science Advances 7: eabg4298. Open Access. PubMed.
I. Radin, R. Richardson, J. Coomey, E. Weiner, C. J. Bascom, T. Li, M. Bezanilla and E. S. Haswell. (2021). Plant PIEZO Homologs Modulate Vacuole Morphology During Tip Growth. Science 373: 586-590. PubMed. Free Access.
J. Friesner, A. Colon-Carmona, A. Schnoes, A. Stepanova, G. Mason, G. MacIntosh, H. Ullah, I. Baxter, J. Callis, K. Sierra-Cajas, K. Elliott, E. S. Haswell, M. E. Zavala, M. Wildermuth, M. Williams, M. Ayalew, N. Henkhaus, N. Prunet, P. Lemaux, R. Yadegari, R. Amasino, R. Hangarter, R. Innes, S. Brady, T. Long, T. Woodford-Thomas, V. May, Y. Sun, and Jose Dinneny. (2021). Broadening the impact of plant science through innovative, integrative and inclusive outreach. Plant Direct. 5:e 00316. Open Access. PubMed.
Bowdish D, Desai TA, DePace A, Haswell ES, Baltrus D, García AJ, Deans T, Lage K, Wittkopp P. (2021). Leadership. Cell Systems. 12(1):1-4. PubMed.
2020
N. Henkhaus, M. Bartlett, D. Gang, R. Grumet, I. Jordon-Thaden, A. Lorence, E. Lyons, S. Miller, S. Murray, A. Nelson, C. Specht, B. Tyler, T. Wentworth, D. Ackerly, D. Baltensperger, P. Benfey, James B., S. Chellamma, R. Crowder, M. Donoghue, J. P. Dundore-Arias, J, Fletcher, K. Gillespie, L. Guralnick, E. Haswell, M. Hunter, S. Kaeppler, S. Kepinski, F.-W. Li, S. Mackenzie, L. McDade, Y. Min, J. Nemhauser, B. Pearson, P. Petracek, K. Rogers, A. Sakai, D. Sickler, T. Spady, C. Taylor, L. Wayne, O. Wendroth, F. Zapata, and D. Stern. (2020). Plant science decadal vision 2020-2030: Reimagining the potential of plants for a healthy and sustainable future. Plant Direct. 4: e00252. Open Access.
A. Schlegel and E. S. Haswell. (2020). Charged pore-lining residues are required for normal channel kinetics in the eukaryotic mechanosensitive ion channel MSL1. Channels. 14, 310-32. PubMed.
D. Basu and E. S. Haswell. (2020). The Mechanosensitive ion channel MSL10 potentiates responses to cell swelling in Arabidopsis seedlings. Current Biology 30:2716-2728. SneakPeek. PubMed. Dispatch in Current Biology. Research Highlights in Nature Plants.
Z. Deng, G. Maksaev*, A. Schlegel*, J. Zhang, M. Rau, J. Fitzpatrick, E. S. Haswell and P. Yuan. Structural mechanism for gating of a eukaryotic mechanosensitive channel of small conductance. (2020). Nature Communications 11:3690.*equal contributions. PubMed.
D. Basu, J. M. Shoots and E. S. Haswell. (2020). Interactions between the N- and C-termini of mechanosensitive ion channel AtMSL10 are consistent with a three-step mechanism for activating its signaling function. Journal of Experimental Botany 71:4020-4032. Free Access. PubMed.
A. M. Schlegel and E. S. Haswell. (2020). Analyzing plant mechanosensitive ion channels expressed in giant E. coli spheroplasts by single channel patch-clamp electrophysiology. Methods in Cell Biology. 160:61-82. PubMed.
A. M. Schlegel and E. S. Haswell. (2020). Plant biomechanics: No pain, no gain for birch tree stems. Current Biology 30: R164-166. Free access. PubMed.
2019
J. S. Lee, M. E. Wilson, R. Richardson and E. S. Haswell. (2019). Genetic and physical interactions between mechanosensitive ion channel homologs MscS-Like (MSL)1, 2, and 3 reveal their role in intra-organellar communication. Plant Direct. 3:e00124. Open access.
E. S. Haswell. Q & A Liz Haswell (2019). Current Biology 29: R556-R557. Link.
2018
E. S. Haswell & Ram Dixit. (2018). Counting What Counts: The importance of quantitative approaches to studying plant cell biology. Current Opinion in Plant Biology. 46: 1-3. PubMed
N. Herrera, G. Maksaev, E. S. Haswell, D. C. Rees. (2018). Elucidating a role for the cytoplasmic domain in the Mycobacterium tuberculosis mechanosensitive channel of large conductance. Scientific Reports 8:14566. PubMed.
G. Maksaev, J. Shoots, S. Ohri and E. S. Haswell. (2018). Nonpolar residues in the presumptive pore-lining helix of mechanosensitive channel MSL10 influence channel behavior and confirm its non-conducting function. Plant Direct, 2:1–13. Open access.
2017
K. Fal, M. Liu, A. Duisembekova, E. S. Haswell and O. Hamant. (2017). Phyllotactic variance is regulated by the Paf1C protein VIP3. Development 144:4428-4436. PubMed.
D. S. Stone, E. S. Haswell and E. Sztul. Finding your inner modeler: an NSF-sponsored workshop to introduce cell biologists to modeling/computational approaches. Cellular Logistics 7:4 e1382669. Free e-pub. PubMed.
E. S. Haswell. (2017). The sustainable professor. eLIFE 6:e31083. Open access. PubMed.
D. Basu and E. S. Haswell. (2017). Plant mechanosensitive ion channels: An ocean of possibilities. Current Opinion in Plant Biology 40:43-48. PubMed
O. Hamant and E. S. Haswell. (2017). Life behind the Wall: Sensing Mechanical Cues in Plants. BMC Biology 15:59. Open access. PubMed.
E. S. Hamilton and E. S. Haswell. (2017). The Tension-sensitive Ion Transport Activity of MSL8 is Critical for its Function in Pollen Hydration and Germination. Plant Cell & Physiology 58: 1222-1237. Open access. PubMed.
G. Jensen, K. Fal, O. Hamant and E. S. Haswell. (2017). The RNA Polymerase-Associated Factor 1 (Paf1) Complex is Required for Touch Responses in Plants. Journal of Experimental Botany 68:499-511.
Open access. PubMed
2016
C. Lee, G. Maksaev, G. Jensen, M. Murcha, M. E. Wilson, M. Fricker, R. Hell, E. S. Haswell, H. A. Millar and L. Sweetlove. (2016). MSL1 is a Mechanosensitive Ion Channel that Dissipates Mitochondrial Membrane Potential and Maintains Redox Homeostasis in Mitochondria During Abiotic Stress. Plant Journal 88:809-825. PubMed
M. E. Wilson, M. Mixdorf, R. H. Berg and E. S. Haswell. (2016). Plastid Osmotic Shock Influences Dedifferentiation at the Plant Shoot Apex. Development 143: 3382-3393. PubMed
2015
D. R. Luesse, M. E. Wilson and E. S. Haswell. (2015). RNA-Sequencing Analysis of the msl2msl3, crl, and ggps1Mutants Indicates that Diverse Sources of Plastid Dysfunction Do Not Alter Leaf Morphology Through a Common Signaling Pathway. Frontiers in Plant Science 6:1148. PubMed
E. S. Hamilton, G. S. Jensen, G. Maksaev, Andrew Katims, Ashley Sherp and E. S. Haswell. (2015). Mechanosensitive Ion Channel MSL8 Regulates Osmotic Forces During Pollen Hydration and Germination. Science 350:438-441. PubMed FREE ACCESS to Abstract Reprint Full Text
S. M. Brady, M. Burow, W. Busch, O. Carlborg, K. J. Denby, J. Glazebrook, E. S. Hamilton, S. Harmer, E. S. Haswell, J. N. Maloof, D. Kliebenstein. (2015). Reassess the t-test: Interact With All Your Data Via ANOVA. Plant Cell 27:2088-94. PubMed
G. Maksaev and E. S. Haswell. (2015). Expression and Characterization of Mechanosensitive Ion Channels in Xenopus Oocytes. Plant Gravitropism: Methods and Protocols 1309:151-69. PubMed
E. S. Haswell and P. E. Verslues. (2015). The Ongoing Search for the Molecular Basis of Plant Osmosensing. Journal of General Physiology 145: 389-394. PubMed
E. S. Hamilton, A. M. Schlegel and E. S. Haswell. (2015). United in Diversity: Plant Mechanosensitive Channels. Annual Review of Plant Biology 66:113-137. PubMed
2014
K. M. Veley, G. Maksaev, S. M. Kloepper, E. M. Frick, E. January and E. S. Haswell. (2014). MSL10 has a Regulated Cell Death Signaling Activity that is Separable from its Mechanosensitive Ion Channel Activity. Plant Cell 26: 3115-31. PubMed
S. Bell, J. Blumstein, K. Brose, A. Carroll, J. Chang, J. Charles, E. Haswell, M. Michelitsch, J. Owens, C. K. Patil, R. Smith, J. Tupy, E. Walsh, T. Ware. (2014). Defining Success in Graduate School. Molecular Biology of the Cell 25:1942-1944. PubMed
M. E. Wilson, M. R. Basu, G. B. Bhaskara, P. E. Verslues, and E. S. Haswell. (2014). Plastid Osmotic Stress Activates Cellular Osmotic Stress Responses. Plant Physiology 165:119-128. PubMed
2013
M.E. Wilson, G. Maksaev, and E. S. Haswell. (2013). MscS-like Mechanosensitive Channels in Plants and Microbes. Biochemistry 5(34): 5708–5722. PubMed
G. E. Monschausen & E. S. Haswell. (2013). A Force of Nature: Molecular Mechanisms of Mechanoperception in Plants. J. Experimental Botany 64(15): 4663-80. PubMed
G. Maksaev & E. S. Haswell. (2013). Recent Characterizations of MscS and its Homologs Provide Insights into the Basis of Ion Selectivity. Channels 7(3): 215-220. PubMed
2012
G. Maksaev & E. S. Haswell. (2012). MscS-Like10 is a Stretch-Activated Ion Channel from Arabidopsis thaliana with a Preference for Anions. PNAS 109: 19015-19020. PubMed
G. S. Jensen & E. S. Haswell. (2012). Functional Analysis of Conserved Motifs in the Mechanosensitive Channel Homolog MscS-Like 2. PLoS ONE 7(6): e40336. PubMed
K. M. Veley & E. S. Haswell. (2012). Plastids and Pathogens: Mechanosensitive Channels and Survival in a Hypoosmotic World. Plant Signaling & Behavior 7: 668-71. PubMed
2011
K. M. Veley, S. Marshburn, C. E. Clure, and E. S. Haswell. (2012). Mechanosensitive Channels Protect Plastids from Hypoosmotic Shock during Normal Plant Growth. Current Biology 22: 408-413. PubMed
M. E. Wilson & E. S. Haswell. (2012). A Role for Mechanosensitive Channels in Chloroplast and Bacterial Fission. Plant Signaling & Behavior 7:157-160. PubMed
G. Maksaev & E. S. Haswell. (2011). Expression and Characterization of the Bacterial Mechanosensitive Channel MscS in Xenopus laevis Ooctyes. Journal of General Physiology 138:641-9. PubMed
E. S. Haswell, R. Phillips, & D. C. Rees. (2011). Mechanosensitive Channels: What Can They Do and How Do They Do It? Structure 19: 1356-1369. Pubmed
M. E. Wilson, G. S. Jensen, & E. S. Haswell. (2011). Two Mechanosensitive Channel Homologs Influence FtsZ Ring Placement in Arabidopsis. The Plant Cell 23:939-2949. PubMed
2003-2008
R. Peyronnet, E. S. Haswell, H. Barbier-Brygoo, & J-M. Frachisse. (2008). AtMSL9 and AtMSL10: Sensors of Plasma Membrane Tension in Arabidopsis Roots. Plant Signaling & Behavior 3:726-729. PubMed
E. S. Haswell*, R. Peyronnet*, H. Barbier-Brygoo, E. M. Meyerowitz, & J-M. Frachisse. (2008). Two MscS Homologues Provide Mechanosensitive Channel Activities in the Arabidopsis Root. Current Biology 18:730-734. *equal contribution. PubMed
E. S. Haswell. (2007). MscS-like Proteins in Plants. Current Topics in Membranes 58: 329-359. ScienceDirect
E. S. Haswell & E. M. Meyerowitz. (2006). MscS-like Proteins Control Plastid Size and Shape in Arabidopsis thaliana. Current Biology 16:1-11. PubMed
E. S. Haswell. (2003). Gravity Perception: How Plants Stand up for Themselves. Current Biology 13:R761-R763. PubMed
1998-2003
D. J. Steger, E. S. Haswell, A. L. Miller, S. R. Wente, and E. K. O’Shea. (2003). Regulation of Chromatin Remodeling by Inositol Polyphosphates. Science 5603: 114-116. PubMed
E. S. Haswell and E. K. O'Shea. (1999). An In Vitro System Recapitulates Chromatin Remodeling at the PHO5Promoter. Molecular and Cellular Biology 19: 2817-2827. PubMed
E. S. Haswell and E. K. O'Shea. (1998). Specificity of ATP-Dependent Chromatin Remodeling at the Yeast PHO5Promoter. Cold Spring Harbor Symposium on Quantitative Biology 63: 563-567. PubMed
