The Importance of Cell Water

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The Importance of Cell Water

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ISIS Press Release 13/10/04

 

New Age of water

 

The Importance of Cell Water

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Prof. Martin Chaplin presents a new theory on the structure

of water in the cell that switches between low-density and

high-density clusters References for this article are posted

on ISIS members' website

http://www.i-sis.org.uk/full/TIOCWFull.php.

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Although we understand much of what goes on inside cells at

a molecular level, we don't know how all the molecules can

work together as a whole. Much useful biochemistry has been

discovered using dilute preparations from homogenised dead

cells, but living cells are very different, and contain more

concentrated solutes and more organised proteins. Indeed,

test tube experiments may mislead us, and it should come as

no surprise to find that living cells possess

characteristics that are very much more than the sum of

their parts.

 

The study of the live cell is fraught with difficulty, as

most procedures change it from its native state. The key to

understanding the cell comes from acknowledging the one

constituent that has often been ignored: water. The

significance of water for the cell becomes clear when we

seek to solve big puzzles, such as 'How are potassium ions

able to maintain a high concentration inside cells whereas

sodium ions are found mainly outside?' and 'How do cells

remain functional even when large holes are made in their

surface membranes?'

 

There are at least four views as to how the water inside the

cell affects its function:

 

1. The water mostly acts as an uncomplicated environment for

the cellular processes, which are determined by the

structure of the macromolecules only. Although this view

seems the one most promoted in current textbooks by default,

it is rapidly losing favour due to its inability to explain

natural processes.

 

2. The water forms polarised multi-layers over extended protein

surfaces, as proposed for many years by Gilbert Ling [1].

There is much experimental support for the foundations of

this theory but little experimental support for the required

structural changes in the proteins or the involvement of

extended protein surfaces, as proposed.

 

3. The water is involved in intracellular changes between 'sol'

and 'gel' states as more recently promoted by Gerald Pollack

[2]. This is an interesting and useful idea but without a

clear molecular mechanism.

 

4. The water actively changes the density of its hydrogen

bonded structuring to enable diverse intracellular

processes, in a manner compatible with the basic ideas of

both Gilbert Ling and Gerald Pollack.

 

The theory that I shall describe in this article (which I

presented at the Gordon Research Conference on Interfacial

Water and Cell Biology in June 2004) belongs to the fourth,

new category. I propose that changes in the density and

clustering of intracellular water are modulated by the

mobility of key proteins, which in turn are controlled by

the energy status and ionic content of the cell.

 

The nature of water

 

Water possesses many properties that seem strange, or

anomalous [3]. Some of these, such as its high melting and

boiling points can be simply explained as due to water's

hydrogen bonded clustering. Over the last 10 years, a broad

range of evidence has accumulated concerning a two-state

structuring within liquid water, which can explain many of

the remaining anomalies [4, 5]. This theory involves the

presence in liquid water, of clusters with a lower density

comparable with that of ice. The water molecules in such

clusters flicker between partners as their hydrogen bonds

are constantly making and breaking. Over a long time scale,

they appear as favoured arrangements. These low-density

water clusters do not consist of ice-like crystals, due to

their lack of long-range order, but they do contain water

molecules linked by hydrogen bonds in an expanded, 4-

coordinated tetrahedral arrangement. At the smallest scale,

the water may be thought of as an equilibrium between two

water tetramers (see Fig. 1): structure A, held closely by

non-bonded interactions, forming a more dense structure, and

structure B, with molecules held further away and linked by

hydrogen bonds to form a less dense structure There is

little difference in energy between the structures A and B,

so the equilibrium is easily affected by the presence of

solutes and surfaces. An increase in temperature or pressure

will shift the equilibrium to the left.

 

Figure 1. Equilibrium between two water tetramers.

 

Although the natural structuring in water at ordinary

temperatures tends towards the 'collapsed' structure A, the

low density structure B can grow to form larger non-

crystalline clusters based on dodecahedral (12-sided) water

cluster cores, similar to those found in the crystalline

'clathrate hydrates'; as for example, the extensive

icosahedral (H2O)280 aggregate built up from tetrahedrally

hydrogen-bonded water molecules surrounding a dodecahedron

made up of 20 water molecules, the basic clathrate cage

(Fig. 2).

 

Figure 2. Extensive icosahedral (H2O)280 structure of water

built up from tetrahedrally hydrogen-bonded water molecules.

 

Intracellular water contains lower density water with more

potassium ions

 

The differences in intracellular and extracellular

environments of cells is primarily due to the extensive

surface area and high intracellular concentration of solutes

that promote the low-density clustering of water and

restricted diffusion inside cells. The extensive surface of

cellular membranes (e.g., each liver cell contain ~100 000

mm2 membrane surface area) favours the formation of low-

density water inside cells, as the membrane lipids contain

hydrophilic head groups that encourage this organization of

the associated interfacial water. Other surfaces attract the

water, so stretching the hydrogen-bonded water contained by

the confined spaces within the cells.

 

The difference in ionic concentrations is particularly

evident in sodium (Na+; intracellular, 10 mM; extracellular,

150 mM) and potassium (K+; intracellular, 159 mM;

extracellular, 4 mM). Na+ ions create more broken hydrogen

bonding and prefer a high aqueous density, whereas K+ ions

prefer a low-density aqueous environment, as proven by

Philippa Wiggins [6]. The differences in intracellular and

extracellular distributions of potassium and sodium are due

to differences in the affinity of these ions for water. The

interactions between water and Na+ are stronger than those

between water molecules, which are in turn stronger than

those between water and K+ ions, all due to the differences

in surface charge density of the ions - that of the smaller

Na+ ion being nearly twice that of K+ ions. Ca2+, with an

intracellular concentration 0.1 mM and an extracellular

concentration of 2.5 mM, has a surface charge density more

than twice that of Na+, and has even stronger destructive

effects on low-density hydrogen-bonding than Na+ ions.

 

Other studies confirm the preference of K+ ions for low-

density water over Na+ ions. The ions partition according to

their preferred aqueous environment; in particular, the K+

ions are preferred within the intracellular environment and

naturally accumulate inside the cells at the expense of Na+

ions. This process occurs simply as a result of the water

structuring without the help of putative ion-pumps in the

cell membrane.

 

Besides, membrane ion-pumps cannot produce these large

differences in ionic composition, simply because the (ATP)

energy required far exceeds the energy available to the

cell. Also, many studies, as for example, the extensive

series carried out by Gilbert Ling, have shown that cells do

not need an intact membrane or active energy (ATP)

production to maintain the ionic concentration gradients.

 

The effect of intracellular protein on water structuring

 

The degree to which the density of cell water is lowered is

determined by the solutes and the state of motion of

protein. Water has conflicting effects in the mixed

environments around proteins due to the variety of amino

acids making up their surfaces. Weak interactions between

the protein and surface water molecules allow greater

protein flexibility. Strong interactions endow the protein

with greater stability and solubility. There is generally an

ordered structure in the layer of water molecules

immediately surrounding the protein, with both hydrophobic

clathrate-like and hydrogen bonded water molecules each

helping the other to optimize water's hydrogen bonding

network. Protein carboxylate groups are generally surrounded

by strongly hydrogen-bonded water whereas the water

surrounding the basic groups arginine, histidine and lysine

tends towards a more-open clathrate structuring. The

formation of partial clathrate cages over hydrophobic areas

maximizes non-bonded interactions between the water and the

protein without loss of hydrogen bonds between the water

molecules whereas carboxylate groups usually only fit a

collapsed water structure (see below) creating a reactive

fluid zone.

 

The rotation of the proteins will cause changes in the water

structuring outside this closest hydration shell. At the

breaking surface, hydrogen bonds are ruptured, creating a

zone of higher density water. Protein rotation thus creates

a surrounding high-density water zone with many broken

hydrogen bonds.

 

The importance of protein carboxylate groups

 

Protein has two acidic amino acids, aspartate and glutamate,

with carboxylate (-CO2-) side chains. Normally, aqueous

hydrogen bonding to these carboxylate oxygen atoms both

attracts water molecules causing a localised high density

water clustering and reduces the acidity of the carboxylic

acids. Otherwise, when the surrounding water molecules

prefer to hydrogen bond to themselves as with the formation

of a clathrate cage, the acidity of the carboxylate groups

is increased. It is found that Na+ ions prefer binding to

the weaker carboxylic acids whereas K+ ions prefer the

stronger acids [1].

 

Na+ and K+ ions also behave differently when close to the

carboxylate groups; K+ ions have a preference for forming

ion pairs, where there is direct contact between the K+ and

carboxylate ions, whereas Na+ ions form solvent separated

pairings where water molecules lie between the Na+ and

carboxylate ions, forming strengthened hydrogen bonds to the

carboxylate groups [7]. This is due to the Na+ ions holding

on to their water more strongly. The K+ ions prefer to be

within a clathrate water cage and this preference both

reinforces its direct ion pairing to the carboxylate group

and discourages aqueous hydrogen bonding to the associated

carboxylate groups.

 

The direct association of K+ ions with the aspartate and

glutamate groups in proteins is the central theme of Ling's

fixed charge hypothesis where evidence for the molecular

mechanism for the association includes (1) the low

intracellular electrical conductance, (2) the strongly

reduced mobility of intracellular K+ ions, (3) the one to

one stoichiometric absorption of K+ ions to the carboxylate

groups and (4) identification of the K+ ion absorption sites

as the aspartate and glutamate side chains of the

intracellular proteins.

 

The importance of protein mobility

 

Actin is a highly conserved and widespread eukaryotic

protein (42-43 kDa) responsible for many functions in cells.

Non-muscle cells contain actin in amounts 5-10% of all

protein, whereas muscle cells contain about 20%. Actin is

converted between a freely rotating monomer molecule (G-

actin; about 4 - 6 nm diameter) and a static right-handed

double helical polymer protein filament (F-actin; up to

several microns in length) by ATP; a process involving the

conversion of an a-helix to a b-turn in one of its

structural domains. Each molecule of the freely rotating G-

actin can stir a large volume of water, whereas F-actin has

a much more ordered structure so creating more order in its

surrounding water. The protein fibres trap water, reducing

its movement and compensated by greater hydrogen bonding.

Also, capillary action stretches the confined water, so

ensuring that it is of lower density and hence more highly

structured than the bulk water.

 

All actin molecules contain a conserved negatively charged

N-terminus, for example the N-acetyl-aspartyl-glutamyl-

aspartyl-glutamyl sequence in rabbit muscle a-actin. When G-

actin polymerises in the cell under the action of ATP to

form F-actin, this highly carboxylated antenna is placed on

the exposed outer edge of the helix, where it may be

additionally used as a binding site for other proteins, such

as myosin. Tubulin, another intracellular structural protein

that forms immobile structures within cells, possesses an

even more extensive negatively charged acidic C-terminal

conserved antenna of about eight carboxylate groups that

serves similar functions.

 

F-actin's multiply negatively charged N-terminus attracts

positively charged cations. Under conditions when the

carboxylic acids are weaker, both K+ and Na+ ions may form

solvent separated species. This competition results in a

preference for Na+ ions and high-density water. However, the

natural rotation of the protein will tend to sweep such

ions, and their associated water, away. If the protein is

prevented from rotating, Na+ ions tend to destroy any low

density structuring around carboxylate groups of the

protein. However, the intracellular Na+ ion concentration is

generally far lower than that of K+ ions, which allows K+

ions to compete successfully for these sites, forming ion

pairs and encouraging clathrate formation.

 

Cooperative conversion of the water structuring

 

Binding of K+ ions by the carboxylate groups lowers the

ionic strength of the intracellular solution. As this ionic

strength decreases, the acidity of phosphate groups

decreases, resulting in the conversion of the intracellular

doubly charged HPO42- ions to the singly charged H2PO4-

ions, more favourable to low density water clustering. All

intracellular phosphate entities will behave similarly. The

cooperative effects of the change between static filament

formation and freely diffusional protein are summarized in

Fig. 3.

 

Figure 3. A summary of the cooperative effects when mobile

proteins such as actin are polymerised,

 

Formation of K+-carboxylate ion pairs leads to the formation

of a surrounding clathrate water structuring that further

guides icosahedral water structuring (so ensuring maximal

hydrogen-bond formation) and informing neighbouring

carboxylate groups. This signalling cooperatively reinforces

the tetrahedrality of the water structuring found between

these groups. The clathrate cage allows rotational mobility

(like a ball-and-socket joint), enabling the hydrogen

bonding to search out cooperative partners (Fig. 4).

 

Figure 4. This diagram shows the clustering around two K+-

carboxylate ion pairs (about 4 nm apart) as may be attached

to part of two protein's structures. There are 7-8 shells of

water around each surface as is typically found between

intracellular proteins. The K+ ions are shown as violet and

the water network is shown as linked (i.e. hydrogen bonded)

oxygen atoms (shown red) without showing their associated

hydrogen atoms. The hydrogen bonding initially forms

clathrate cages around the ion pairs, followed by a more

extensive icosahedral arrangement. This is then followed by

extension of the hydrogen bonding along 'rays' connecting

the neighbouring sites. Once these 'rays' link, the hydrogen

bonding of each reinforces the other in a cooperative

manner, so strengthening the linkage and reinforcing the

overall low density aqueous environment. As the aqueous

clathrate cage possesses a more negative charge on its

interior and a more positive charge on the outside, there is

a marked polarization in the water molecules that reinforces

the hydrogen bonding interactions.

 

Although the clustering involves a major drop in aqueous

mobility, the stronger 4-coordinated bonding compensates

this. This theory offers a molecular explanation for Ling's

association-induction polarized multilayer model (see

" Strong medicine needed in cell biology " , this issue). The

initial icosahedral size (3 nm diameter), surrounding each

ion pair, also equals the water domain size proposed by John

Watterson. The tetrahedral structuring possesses five-fold

symmetry, which prevents easy freezing in line with the

pronounced supercooling found for intracellular water.

 

Extension of the clathrate network and its associated low

density water enables K+ ion binding to all aspartic and

glutamic acid groups, not just the key ones within the

crucial N-terminal acidic centres. Thus, the sol-gel

transition of Pollack (see " Biology of least action " , SiS

18) may be interpreted as due to the formation of low

density water clustering (the gel state) due to clathrate

clustering around K+-carboxylate ion pairs.

 

In the presence of raised levels of Na+ and/or Ca2+ ions, as

occasionally occurs during some cell functions, these ions

will replace some of the bound K+ ions. These newly formed

solvent separated Na+ and/or Ca2+ ion pairings destroy the

low-density clathrate structures and initiate a cooperative

conversion of the associated water towards a denser

structuring.

 

Conclusion

 

In conclusion, the aqueous information transfer within the

cell involves the following:

 

Intracellular water favours K+ ions over Na+ ions.

 

Freely rotating proteins create zones of higher density

water, which tend towards a lower density clustering if the

rotation is prevented.

 

Static charge-dense intracellular macromolecular structures

prefer K+ ion pairs to freely soluble K+ ions.

 

Ion paired K+-carboxylate groupings prefer local clathrate

water structuring.

 

Clathrate water prefers local low density water structuring.

 

Low density water structuring can reinforce the low-density

character of neighbouring site water structuring.

 

Na+ and Ca2+ ions can destroy the low density structuring in

a cooperative manner.

 

 

 

 

 

 

 

Martin Chaplin is Professor of Applied Science, London South

Bank University, UK, with special interests in the

interactions between water and biological molecules.

 

 

 

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