Membrane-Lipid Therapy in Operation: The HSP Co-Inducer BGP-15 Activates Stress Signal Transduction Pathways by Remodeling Plasma Membrane Rafts

Aging and pathophysiological conditions are linked to membrane changes which modulate membrane-controlled molecular switches, causing dysregulated heat shock protein (HSP) expression. HSP co-inducer hydroxylamines such as BGP-15 provide advanced therapeutic candidates for many diseases since they preferentially affect stressed cells and are unlikely have major side effects. In the present study in vitro molecular dynamic simulation, experiments with lipid monolayers and in vivo ultrasensitive fluorescence microscopy showed that BGP-15 alters the organization of cholesterol-rich membrane domains. Imaging of nanoscopic long-lived platforms using the raft marker glycosylphosphatidylinositol-anchored monomeric green fluorescent protein diffusing in the live Chinese hamster ovary (CHO) cell plasma membrane demonstrated that BGP-15 prevents the transient structural disintegration of rafts induced by fever-type heat stress. Moreover, BGP-15 was able to remodel cholesterol-enriched lipid platforms reminiscent of those observed earlier following non-lethal heat priming or membrane stress, and were shown to be obligate for the generation and transmission of stress signals. BGP-15 activation of HSP expression in B16-F10 mouse melanoma cells involves the Rac1 signaling cascade in accordance with the previous observation that cholesterol affects the targeting of Rac1 to membranes. Finally, in a human embryonic kidney cell line we demonstrate that BGP-15 is able to inhibit the rapid heat shock factor 1 (HSF1) acetylation monitored during the early phase of heat stress, thereby promoting a prolonged duration of HSF1 binding to heat shock elements. Taken together, our results indicate that BGP-15 has the potential to become a new class of pharmaceuticals for use in ‘membrane-lipid therapy’ to combat many various protein-misfolding diseases associated with aging.

[1]  H. Berendsen,et al.  Molecular dynamics with coupling to an external bath , 1984 .

[2]  J. Stewart Optimization of parameters for semiempirical methods I. Method , 1989 .

[3]  T. Darden,et al.  A smooth particle mesh Ewald method , 1995 .

[4]  A. Klamt Conductor-like Screening Model for Real Solvents: A New Approach to the Quantitative Calculation of Solvation Phenomena , 1995 .

[5]  J. Slotte,et al.  Cyclodextrin-mediated removal of sterols from monolayers: effects of sterol structure and phospholipids on desorption rate. , 1996, Biochemistry.

[6]  G. Balogh,et al.  Bimoclomol: A nontoxic, hydroxylamine derivative with stress protein-inducing activity and cytoprotective effects , 1997, Nature Medicine.

[7]  B. Maresca,et al.  Does the membrane's physical state control the expression of heat shock and other genes? , 1998, Trends in biochemical sciences.

[8]  P. Literati-Nagy,et al.  BGP-15, a nicotinic amidoxime derivate protecting heart from ischemia reperfusion injury through modulation of poly(ADP-ribose) polymerase. , 2000, Biochemical pharmacology.

[9]  H. Mcconnell,et al.  Condensed complexes, rafts, and the chemical activity of cholesterol in membranes. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[10]  S. Han,et al.  Implication of a Small GTPase Rac1 in the Activation of c-Jun N-terminal Kinase and Heat Shock Factor in Response to Heat Shock* , 2001, The Journal of Biological Chemistry.

[11]  András Fiser,et al.  Bimoclomol, a heat shock protein co-inducer, acts by the prolonged activation of heat shock factor-1. , 2003, Biochemical and biophysical research communications.

[12]  Gert Vriend,et al.  Making optimal use of empirical energy functions: Force‐field parameterization in crystal space , 2004, Proteins.

[13]  K. Iwabuchi,et al.  Distribution and Transport of Cholesterol-rich Membrane Domains Monitored by a Membrane-impermeant Fluorescent Polyethylene Glycol-derivatized Cholesterol* , 2004, Journal of Biological Chemistry.

[14]  Geoffrey Burnstock,et al.  Treatment with arimoclomol, a coinducer of heat shock proteins, delays disease progression in ALS mice , 2004, Nature Medicine.

[15]  Richard G. W. Anderson,et al.  Integrins Regulate Rac Targeting by Internalization of Membrane Domains , 2004, Science.

[16]  P. Csermely,et al.  Heat shock proteins as emerging therapeutic targets , 2005, British journal of pharmacology.

[17]  John F. Nagle,et al.  Structure of Fully Hydrated Fluid Phase Lipid Bilayers with Monounsaturated Chains , 2006, The Journal of Membrane Biology.

[18]  D. Kültz,et al.  Molecular and evolutionary basis of the cellular stress response. , 2005, Annual review of physiology.

[19]  A. de Marco,et al.  Native folding of aggregation-prone recombinant proteins in Escherichia coli by osmolytes, plasmid- or benzyl alcohol–overexpressed molecular chaperones , 2005, Cell stress & chaperones.

[20]  M. Brameshuber,et al.  Thinning out clusters while conserving stoichiometry of labeling , 2005 .

[21]  G. Balogh,et al.  The hyperfluidization of mammalian cell membranes acts as a signal to initiate the heat shock protein response , 2005, The FEBS journal.

[22]  Péter Csermely,et al.  The efficiency of multi-target drugs: the network approach might help drug design. , 2004, Trends in pharmacological sciences.

[23]  P. Escribá,et al.  Membrane-lipid therapy: a new approach in molecular medicine. , 2006, Trends in molecular medicine.

[24]  I. Horváth,et al.  Can the stress protein response be controlled by 'membrane-lipid therapy'? , 2007, Trends in biochemical sciences.

[25]  R. Place,et al.  Cell number‐dependent regulation of Hsp70B′ expression: Evidence of an extracellular regulator , 2007, Journal of cellular physiology.

[26]  Eloïse Lancelot,et al.  Comparison of the interaction of dihydrocholesterol and cholesterol with sphingolipid or phospholipid Langmuir monolayers. , 2007, Colloids and surfaces. B, Biointerfaces.

[27]  Malin Akerfelt,et al.  Hyperfluidization-coupled membrane microdomain reorganization is linked to activation of the heat shock response in a murine melanoma cell line , 2007, Proceedings of the National Academy of Sciences.

[28]  R. Voellmy,et al.  Chaperone regulation of the heat shock protein response. , 2007, Advances in experimental medicine and biology.

[29]  I. Horváth,et al.  Membrane-associated stress proteins: more than simply chaperones. , 2008, Biochimica et biophysica acta.

[30]  L. Vigh,et al.  Membranes: a meeting point for lipids, proteins and therapies , 2008, Journal of cellular and molecular medicine.

[31]  Jason Chung,et al.  HSP72 protects against obesity-induced insulin resistance , 2008, Proceedings of the National Academy of Sciences.

[32]  J. Slotte,et al.  Glycosylation induces shifts in the lateral distribution of cholesterol from ordered towards less ordered domains. , 2008, Biochimica et biophysica acta.

[33]  Richard I. Morimoto,et al.  Stress-Inducible Regulation of Heat Shock Factor 1 by the Deacetylase SIRT1 , 2009, Science.

[34]  Martin C Fillmore,et al.  Small-molecule modulation of cellular chaperones to treat protein misfolding disorders. , 2009, Current opinion in drug discovery & development.

[35]  K. Monastyrskaya,et al.  The annexins: spatial and temporal coordination of signaling events during cellular stress , 2009, Cellular and Molecular Life Sciences.

[36]  R. Assoian,et al.  The Absence of Caveolin-1 Increases Proliferation and Anchorage- Independent Growth by a Rac-Dependent, Erk-Independent Mechanism , 2009, Molecular and Cellular Biology.

[37]  Thomas Stockner,et al.  Membrane-mediated effect on ion channels induced by the anesthetic drug ketamine. , 2010, Journal of the American Chemical Society.

[38]  Yue Zhang,et al.  Signal Transduction Pathways Leading to Heat Shock Transcription. , 2010, Signal transduction insights.

[39]  G. Balogh,et al.  Lipidomics reveals membrane lipid remodelling and release of potential lipid mediators during early stress responses in a murine melanoma cell line. , 2010, Biochimica et biophysica acta.

[40]  Endre Kiss,et al.  Imaging of Mobile Long-lived Nanoplatforms in the Live Cell Plasma Membrane* , 2010, The Journal of Biological Chemistry.

[41]  G. Nagy,et al.  BGP-15 inhibits caspase-independent programmed cell death in acetaminophen-induced liver injury. , 2010, Toxicology and applied pharmacology.

[42]  R. Morimoto,et al.  Heat shock factors: integrators of cell stress, development and lifespan , 2010, Nature Reviews Molecular Cell Biology.

[43]  Andrija Finka,et al.  Meta-analysis of heat- and chemically upregulated chaperone genes in plant and human cells , 2010, Cell Stress and Chaperones.

[44]  I. Vorobyov,et al.  On the role of anionic lipids in charged protein interactions with membranes. , 2011, Biochimica et biophysica acta.

[45]  G. Balogh,et al.  Heat Stress Causes Spatially-Distinct Membrane Re-Modelling in K562 Leukemia Cells , 2011, PloS one.

[46]  A Possible Mechanism of Cholesteryl Glucoside Formation Involved in Heat Shock Response in the Animal Cell Membrane , 2011 .

[47]  I. Vattulainen,et al.  Lipid simulations: a perspective on lipids in action. , 2011, Cold Spring Harbor perspectives in biology.

[48]  J. Miyoshi,et al.  Rac1 GTPase in rodent kidneys is essential for salt-sensitive hypertension via a mineralocorticoid receptor-dependent pathway. , 2011, The Journal of clinical investigation.

[49]  P. Haldimann,et al.  The Novel Hydroxylamine Derivative NG-094 Suppresses Polyglutamine Protein Toxicity in Caenorhabditis elegans* , 2011, The Journal of Biological Chemistry.

[50]  Deli Zhang,et al.  Effects of different small HSPB members on contractile dysfunction and structural changes in a Drosophila melanogaster model for Atrial Fibrillation. , 2011, Journal of molecular and cellular cardiology.