A Mechanistic View of the Non‐ideal Osmotic and Motional Behavior of Intracellular Water

Cameron, Ivan L.; Kanal, Kalpana M.; Keener, C; Fullerton, Gary D.

doi:10.1006/cbir.1996.0123

Cited by 55 publications

(41 citation statements)

References 41 publications

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“…45 Cytoplasm is highly organized and it is permeated by a dense network of protein filaments, the cytoskeleton. High protein concentration, 46 fibrillary structures and membranous organelles hinder and constrain molecular diffusion. Viscosity of the cytoplasm as determined with electron spin resonance 47 or fluorescence recovery 48 techniques ranges from 2 to 5 cP.…”

Section: Water Diffusion In Vivomentioning

confidence: 99%

“…Prolongation of tumour T 1 and T 2 suggests a parallel gain of water which inevitably will increase water diffusivity. 46 A BT4C glioma line has been extensively used for testing of viral delivery methods for therapeutic genes in our Institute. 12,60,61 This gliosarcoma expands relatively rapidly without microscopic cysts, maintaining adequate perfusion until it occupies a large part of the hemispheric volume.…”

Section: Effects Of Cytotoxic Treatment On Water Diffusionmentioning

confidence: 99%

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Monitoring cytotoxic tumour treatment response by diffusion magnetic resonance imaging and proton spectroscopy

Kauppinen¹

2002

NMR in Biomedicine

110

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Exposure of tumours to anti-cancer drugs, gene or radiation therapy consistently leads to an increase in water diffusion in the cases expressing favourable treatment response. The diffusion change coincides cytotoxic cell eradication and precedes volume reduction in drug or gene therapy-treated experimental tumours. Interestingly, the recent studies from human brain tumour patients undergoing chemotherapy show similar behaviour of diffusion, suggesting important application for MRI in patient management. In this review observations from diffusion MRI and MRS in the tumours during cytotoxic treatment are summarized and the cellular mechanisms affecting molecular mobility are discussed in the light of tissue microenvironmental and microdynamic changes.

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Section: Water Diffusion In Vivomentioning

confidence: 99%

Section: Effects Of Cytotoxic Treatment On Water Diffusionmentioning

confidence: 99%

Monitoring cytotoxic tumour treatment response by diffusion magnetic resonance imaging and proton spectroscopy

Kauppinen¹

2002

NMR in Biomedicine

110

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“…The extent of OUR water in cells has been reported in five vertebrate cell types (Cameron et al 1997, Fullerton et al 2006b, Cameron and Fullerton 2014 and ranges from 1.1 to 2.2 g water per g dry mass. Data in a report by Maric et al (2001) When a known globular protein is dissolved in bulk water the colligative properties of the resulting bulk water solution changes its osmotic pressure, freezing point, boiling point and vapor pressure.…”

Section: Physical Measured Properties Of Bulk and Non-bulk Water Fracmentioning

confidence: 99%

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2014

WATER

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This report reviews evidence on the physical properties and size, in g water per g dry mass (g/g) of multiple non-bulk water of hydration fractions on proteins and in cells. A molecular stoichiometric hydration model (SHM) is presented that explains the four observed and measured monolayer water of hydration fractions on tendon collagen (Fullerton et al. 2006 a , Fullerton andCameron 2007). This SHM has been shown applicable to globular proteins and to cells (Cameron et al. 2011). The extent of nonbulk water has been found to increase during protein unfolding and decrease during protein aggregation (Fullerton et al. 2006). This review also presents evidence that multilayers of water, with non-bulk water properties, extend out from the surface of proteins and biomacromolecules in cells. These facts have been largely overlooked or ignored by most protein chemists and cell biologists. In the conclusion it is recalled that a major fraction of cell water has physical and physiological properties that differ from those of bulk water. Thus studies that do not take the physical properties and size of non-bulk water fractions into account must be judged incomplete. IntroductionThe presence and extent of multiple water of hydration fractions on proteins and in cells has been a subject of debate (Ball 2008, Pollack and Clegg 2008, Fullerton and Cameron 2007, Cameron and Fullerton 2008, Cameron, Lanctot and Fullerton 2011. The physical characteristics and size of multiple water of hydration fractions has been measured on tendon/collagen by water proton NMR spin-lattice relaxation at different levels of collagen hydration (Fullerton et al. 2006). Three distinct hydration compartments were identified and their size quantified. The sizes were defined by Abbreviations: g/g grams water per gram dry mass, SHM stoichiometric hydration model, SASA solvent accessible surface area, QENS quasi-elastic neutron scattering spectroscopy, NMR nuclear magnetic resonance, CD circular dichroism spectroscopy, VW vicinal water, EZ exclusion zone water, PML polarized multilayered water, OUR osmotically unresponsize water, TEM transmission electron microscopy.

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“…This common assumption, either expressed or just tacitly assumed, is that all water above that of this ''bound water'' value has the physical properties of liquid water in bulk. Evidence is mounting to refute this common assumption about the extent of water of hydration on proteins and in cells (Ling, 2001(Ling, , 2004Pollack, 2003;Cameron et al, 1997Cameron et al, , 2007Fullerton and Cameron, 2007).…”

Section: Introductionmentioning

confidence: 99%

Characterization of water of hydration fractions in rabbit skeletal muscle with age and time of post‐mortem by centrifugal dehydration force and rehydration methods

Cameron

Short

Fullerton

2008

Cell Biology International

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Centrifugal dehydration force (CDF) and rehydration isotherm (RHI) methods were used to measure and characterize hydration fractions in rabbit psoas skeletal muscle. The CDF method assessed fluid flow rate from rabbit muscle and hydration capacity of the fractions. Bulk and multiple non-bulk water fractions were identified. The non-bulk water was divisible into the following fractions: two outer non-bulk fractions, a main chain proteins backbone or double water bridge fraction, and a single water bridge fraction. The total non-bulk water amounts to about 85% of the total water in the muscle. The sizes of the water fractions (in g water/g dry mass) agree with a recently proposed molecular stoichiometric hydration model (SHM) applicable to all proteins in and out of cells (Fullerton GD, Cameron IL. Water compartments in cells. Methods Enzymol, 2007; Cameron IL, Fullerton GD. Interfacial water compartments on tendon/collagen and in cells. In: Pollack GH, Chin WC, editors. Phase transitions in cells. Dordrecht, The Netherlands: Springer, 2008). Age of the rabbit significantly slowed the flow rate of the outer non-bulk water fraction by about 50%. Also, muscle of the older rabbit (26 weeks vs. 12 weeks old) had less bulk water and less outer non-bulk water but the same amount of main chain backbone water compared to muscle of the younger rabbit. Increase in time post-mortem from 30min to 4h resulted in rigor mortis and a significantly slower flow rate of water from the outer non-bulk water fraction, which is attributed to muscle contraction, increased packing of contractile elements and increased obstructions to flow of fluid from the muscle fibers.

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A Mechanistic View of the Non‐ideal Osmotic and Motional Behavior of Intracellular Water

Cited by 55 publications

References 41 publications

Monitoring cytotoxic tumour treatment response by diffusion magnetic resonance imaging and proton spectroscopy

Monitoring cytotoxic tumour treatment response by diffusion magnetic resonance imaging and proton spectroscopy

Untitled

Characterization of water of hydration fractions in rabbit skeletal muscle with age and time of post‐mortem by centrifugal dehydration force and rehydration methods

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