Protein conformational changes affect the sodium triple-quantum MR signal.

The aim of this study was to investigate possible sodium triple-quantum (TQ) signal dependence on pH variation and protein unfolding which may happen in vivo. The model system, composed of bovine serum albumin (BSA), was investigated over a wide pH range of 0.70 to 13.05 and during urea-induced unfolding. In both experimental series, the sodium and BSA concentration were kept constant so that TQ signal changes solely arose from an environmental change. The experiments were performed using unique potential to detect weak TQ signals by implementing a TQ time proportional phase increment pulse sequence. At a pH of 0.70, in which case the effect of the negatively charged groups was minimized, the minimum TQ percentage relative to single-quantum of 1.34% ± 0.05% was found. An increase of the pH up to 13.05 resulted in an increase of the sodium TQ signal by 225%. Urea-induced unfolding of BSA, without changes in pH, led to a smaller increase in the sodium TQ signal of up to 40%. The state of BSA unfolding was verified by fluorescence microscopy. Results of both experiments were well fitted by sigmoid functions. Both TQ signal increases were in agreement with an increase of the availability of negatively charged groups. The results point to vital contributions of the biochemical environment to the TQ MR signals. The sodium TQ signal in vivo could be a valuable biomarker of cell viability, and therefore possible effects of pH and protein unfolding need to be considered for a proper interpretation of changes in sodium TQ signals.

[1]  L. Schad,et al.  Efficient 23Na triple‐quantum signal imaging on clinical scanners: Cartesian imaging of single and triple‐quantum 23Na (CRISTINA) , 2020, Magnetic resonance in medicine.

[2]  Lothar R Schad,et al.  X‐nuclei imaging: Current state, technical challenges, and future directions , 2020, Journal of magnetic resonance imaging : JMRI.

[3]  Deborah Burstein,et al.  Sodium MRI revisited , 2019, Magnetic resonance in medicine.

[4]  V. Schepkin Statistical tensor analysis of the MQ MR signals generated by weak quadrupole interactions. , 2019, Zeitschrift fur medizinische Physik.

[5]  L. Schad,et al.  23Na Triple‐quantum signal of in vitro human liver cells, liposomes, and nanoparticles: Cell viability assessment vs. separation of intra‐ and extracellular signal , 2019, Journal of magnetic resonance imaging : JMRI.

[6]  M. Chappell,et al.  Tumor pH and Protein Concentration Contribute to the Signal of Amide Proton Transfer Magnetic Resonance Imaging. , 2019, Cancer research.

[7]  N Jon Shah,et al.  Relaxometry and quantification in simultaneously acquired single and triple quantum filtered sodium MRI , 2018, Magnetic resonance in medicine.

[8]  Michael T. McMahon,et al.  pH Imaging Using Chemical Exchange Saturation Transfer (CEST) MRI , 2017 .

[9]  L. Schad,et al.  Tracking protein function with sodium multi quantum spectroscopy in a 3D-tissue culture based on microcavity arrays , 2017, Scientific Reports.

[10]  T. Budinger,et al.  Comparison of potassium and sodium binding in vivo and in agarose samples using TQTPPI pulse sequence. , 2017, Journal of magnetic resonance.

[11]  D. Barber,et al.  Cancer cell behaviors mediated by dysregulated pH dynamics at a glance , 2017, Journal of Cell Science.

[12]  Keith R. Thulborn,et al.  Quantitative sodium MR imaging: A review of its evolving role in medicine , 2016, NeuroImage.

[13]  R. Bartha,et al.  Topiramate induces acute intracellular acidification in glioblastoma , 2016, Journal of Neuro-Oncology.

[14]  Wolfgang Bogner,et al.  Quantitative Sodium MR Imaging at 7 T: Initial Results and Comparison with Diffusion-weighted Imaging in Patients with Breast Tumors. , 2016, Radiology.

[15]  D. Aksentijević,et al.  Multiple quantum filtered 23Na NMR in the Langendorff perfused mouse heart: Ratio of triple/double quantum filtered signals correlates with [Na]i , 2015, Journal of molecular and cellular cardiology.

[16]  L. Schad,et al.  A double-tuned 1H/23Na resonator allows 1H-guided 23Na-MRI in ischemic stroke patients in one session , 2015, International journal of stroke : official journal of the International Stroke Society.

[17]  Xin Li,et al.  Mapping human brain capillary water lifetime: high‐resolution metabolic neuroimaging , 2015, NMR in biomedicine.

[18]  Alexander Radbruch,et al.  MR imaging of protein folding in vitro employing Nuclear‐Overhauser‐mediated saturation transfer , 2013, NMR in biomedicine.

[19]  Daniel Brenner,et al.  Simultaneous single‐quantum and triple‐quantum‐filtered MRI of 23Na (SISTINA) , 2013, Magnetic resonance in medicine.

[20]  C. Geraldes,et al.  23Na multiple quantum filtered NMR characterisation of Na+ binding and dynamics in animal cells: a comparative study and effect of Na+/Li+ competition , 2013, European Biophysics Journal.

[21]  L. Schad,et al.  Reduction of B(0) inhomogeneity effects in triple-quantum-filtered sodium imaging. , 2010, Journal of magnetic resonance.

[22]  C. Mukhopadhyay,et al.  Urea-mediated protein denaturation: a consensus view. , 2009, The journal of physical chemistry. B.

[23]  C. Pace,et al.  A summary of the measured pK values of the ionizable groups in folded proteins , 2008, Protein science : a publication of the Protein Society.

[24]  F E Boada,et al.  Serial triple quantum sodium MRI during non‐human primate focal brain ischemia , 2007, Magnetic resonance in medicine.

[25]  T. Chenevert,et al.  Proton and sodium MRI assessment of emerging tumor chemotherapeutic resistance , 2006, NMR in biomedicine.

[26]  C. Meyer,et al.  Sodium and proton diffusion MRI as biomarkers for early therapeutic response in subcutaneous tumors. , 2006, Magnetic resonance imaging.

[27]  F. Boada,et al.  Triple-quantum-filtered imaging of sodium in presence of B(0) inhomogeneities. , 2005, Journal of magnetic resonance.

[28]  P. Kuchel,et al.  Determination of Na+ binding parameters by relaxation analysis of selected 23Na NMR coherences: RNA, BSA and SDS , 2005, Magnetic resonance in chemistry : MRC.

[29]  Alnawaz Rehemtulla,et al.  Sodium magnetic resonance imaging of chemotherapeutic response in a rat glioma , 2005, Magnetic resonance in medicine.

[30]  Denise Davis,et al.  Triple quantum filtered sodium MRI of primary brain tumors , 2004, 2004 2nd IEEE International Symposium on Biomedical Imaging: Nano to Macro (IEEE Cat No. 04EX821).

[31]  Paul A Bottomley,et al.  Tissue sodium concentration in human brain tumors as measured with 23Na MR imaging. , 2003, Radiology.

[32]  Ruth Nussinov,et al.  Close‐Range Electrostatic Interactions in Proteins , 2002, Chembiochem : a European journal of chemical biology.

[33]  R. Kauppinen,et al.  Proton exchange as a relaxation mechanism for T1 in the rotating frame in native and immobilized protein solutions. , 2001, Biochemical and biophysical research communications.

[34]  P. Winter,et al.  Triple-quantum-filtered (23)Na NMR spectroscopy of subcutaneously implanted 9l gliosarcoma in the rat in the presence of TmDOTP(5-1). , 2001, Journal of magnetic resonance.

[35]  F. Boada,et al.  Three‐dimensional triple‐quantum–filtered 23Na imaging of in vivo human brain , 1999, Magnetic resonance in medicine.

[36]  T. Budinger,et al.  Multi-dose crystalloid cardioplegia preserves intracellular sodium homeostasis in myocardium. , 1999, Journal of molecular and cellular cardiology.

[37]  A. Sherry,et al.  Multiple quantum filtered 23Na NMR spectroscopy of the isolated, perfused rat liver , 1999, Magnetic resonance in medicine.

[38]  N. Bansal,et al.  Three‐dimensional triple‐quantum‐filtered 23Na imaging of the dog head in vivo , 1998, Journal of magnetic resonance imaging : JMRI.

[39]  S C Amartur,et al.  Sodium TQF NMR and intracellular sodium in isolated crystalloid perfused rat heart , 1998, Magnetic resonance in medicine.

[40]  G. Navon,et al.  Quantification of the contribution of extracellular sodium to 23Na multiple-quantum-filtered NMR spectra of suspensions of human red blood cells. , 1998, Journal of magnetic resonance.

[41]  A. Sherry,et al.  Evaluation of triple quantum‐filtered 23Na NMR spectroscopy in the in situ rat liver , 1997, Magnetic resonance in medicine.

[42]  K. Katsuta,et al.  Isothermal gelation of proteins. 1. Urea-induced gelation of whey proteins and their gelling mechanism , 1997 .

[43]  J. Katz,et al.  Evaluation of multiple-quantum-filtered 23Na NMR in monitoring intracellular Na content in the isolated perfused rat heart in the absence of a chemical-shift reagent. , 1997, Journal of magnetic resonance.

[44]  T. Budinger,et al.  Effects of specific sodium/hydrogen exchange inhibitor during cardioplegic arrest. , 1997, The Annals of thoracic surgery.

[45]  T. Budinger,et al.  Sodium alterations in isolated rat heart during cardioplegic arrest. , 1996, Journal of applied physiology.

[46]  D. Burkhoff,et al.  Evaluation of triple‐quantum‐filtered 23Na NMR in monitoring of intracellular na content in the perfused rat heart: Comparison of intra‐ and extracellular transverse relaxation and spectral amplitudes , 1996, Magnetic resonance in medicine.

[47]  N. Bansal,et al.  Three‐dimensional triple quantum‐filtered 23na imaging of rabbit kidney with weighted signal averaging , 1995, Journal of magnetic resonance imaging : JMRI.

[48]  L. Jelicks,et al.  On the extracellular contribution to multiple quantum filtered 23Na NMR of perfused rat heart , 1993, Magnetic resonance in medicine.

[49]  W. Rooney,et al.  A comprehensive approach to the analysis and interpretation of the resonances of spins 3/2 from living systems , 1991, NMR in biomedicine.

[50]  W. Rooney,et al.  The molecular environment of intracellular sodium: 23Na NMR relaxation , 1991, NMR in biomedicine.

[51]  J. V. D. Maarel Relaxation of spin quantum number S=3/2 under multiple‐pulse quadrupolar echoes , 1991 .

[52]  W. Pulsinelli,et al.  Dynamics of interstitial and intracellular pH in evolving brain infarct. , 1991, The American journal of physiology.

[53]  R. Hendrick,et al.  Evaluation of the double-quantum filter for the measurement of intracellular sodium concentration. , 1990, The Journal of biological chemistry.

[54]  C. Chung,et al.  Optimum detection of biexponential relaxation using multiple-quantum filtration techniques , 1990 .

[55]  A. Fersht,et al.  Mapping the transition state and pathway of protein folding by protein engineering , 1989, Nature.

[56]  L. Jelicks,et al.  Double-quantum NMR of sodium ions in cells and tissues. Paramagnetic quenching of extracellular coherence☆ , 1989 .

[57]  G. Bodenhausen,et al.  Relaxation-induced violations of coherence transfer selection rules in nuclear magnetic resonance , 1987 .

[58]  M. Diksic,et al.  Correlation of local cerebral blood flow, glucose utilization, and tissue pH following a middle cerebral artery occlusion in the rat. , 1985, Stroke.

[59]  A. Hakim,et al.  Autoradiographic Determination of Brain pH Following Middle Cerebral Artery Occlusion in the Rat , 1984, Stroke.

[60]  Jorge J. Moré,et al.  Computing a Trust Region Step , 1983 .

[61]  I. Cameron,et al.  Intracellular concentration of sodium and other elements as related to mitogenesis and oncogenesis in vivo. , 1980, Cancer research.

[62]  J. Koenig,et al.  Raman studies of bovine serum albumin , 1976, Biopolymers.

[63]  R. B. Moon,et al.  Determination of intracellular pH by 31P magnetic resonance. , 1973, The Journal of biological chemistry.

[64]  N. Ui CONFORMATIONAL STUDIES ON PROTEINS BY ISOELECTRIC FOCUSING * , 1973, Annals of the New York Academy of Sciences.

[65]  H. Pfister,et al.  Membranpotential und Ionenbindung in Proteinlösungen , 1964 .

[66]  H. Saroff The binding of ions to the muscle proteins; a theory for K+ and Na+ binding based on a hydrogen-bonded and chelated model. , 1957, Archives of biochemistry and biophysics.

[67]  C. W. Carr Studies on the binding of small ions in protein solutions with the use of membrane electrodes. IV. The binding of calcium ions in solutions of various proteins. , 1953, Archives of biochemistry and biophysics.

[68]  L. Uzman Organic Anion Binding by Denatured Bovine Serum Albumin , 1953, Nature.

[69]  Matthias Müller,et al.  Löffler/Petrides Biochemie und Pathobiochemie , 2014 .

[70]  J. V. D. Maarel Thermal relaxation and coherence dynamics of spin 3/2. II. Strong radio-frequency field , 2003 .

[71]  J. V. D. Maarel Thermal relaxation and coherence dynamics of spin 3/2. I. Static and fluctuating quadrupolar interactions in the multipole basis , 2003 .

[72]  Kevin L. Shaw,et al.  Linear extrapolation method of analyzing solvent denaturation curves , 2000, Proteins.

[73]  G. Navon,et al.  A23Na Multiple-Quantum-Filtered NMR Study of the Effect of the Cytoskeleton Conformation on the Anisotropic Motion of Sodium Ions in Red Blood Cells , 1996 .

[74]  C. Pace Determination and analysis of urea and guanidine hydrochloride denaturation curves. , 1986, Methods in enzymology.

[75]  D. Skoog Fundamentals of analytical chemistry , 1963 .

[76]  C. W. Carr Studies on the binding of small ions in protein solutions with the use of membrane electrodes. VI. The binding of sodium and potassium ions in solutions of various proteins. , 1956, Archives of biochemistry and biophysics.