Fwd: Biology of Least Action

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Biology of Least Action

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The Institute of Science in Society

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SiS Review

Biology of Least Action

*********************

Dr. Mae-Wan Ho reviews

 

Cells, Gels and the Engines of Life: A New, Unifying Approach to Cell Function,

by Gerald H. Pollack, Ebner & Sons, Seattle WA, USA, 2001. ISBN: Paperback:

0-9626895-2-1

 

Don’t, don’t read this book, if you’ve built your life around the notion that

cell biology consists of nothing more than enormously complicated networks of

interacting proteins and genes for carrying out a list of vital functions; like

moving the cell around, digesting food, receiving and transmitting signals from

the environment, making the cell grow bigger, and eventually dividing it into

two.

 

Don’t even think of touching this book if you believe that everything about the

cell will be understood when the function of every gene and every protein has

been worked out ad infinitum, and life itself could then be simulated by the

fastest supercomputer. For that’s what we are told by the molecular geneticists

who have sequenced the human and other genomes, and are now desperate to find

some meaning in it all. Don’t touch this book, because it will destroy your life

and puncture your illusions; or at least throw you into a terrible state of

self-doubt.

 

If, however, you have been bored out of your mind with the proliferation of

lists upon lists of molecular nuts and bolts that simply don’t add up to a

whole, and secretly wondering how the cell might really work, then beg, borrow,

steal or buy a copy of this book right now. You are in for a big treat. This

book will sweep you off your feet.

 

It is like having a thorough spring-cleaning done on your mind. The layers of

intellectual cobwebs accumulating ever since you decided to read biology - and

never really been encouraged to think your way to any modicum of understanding –

all cleared away, one by one, until you see sunlight sparkling in your mind’s

eye. You’ve regained the innocence of first gazing into life’s wonders, and

ready for more. Not a gel in sight, and no equations either.

 

With disarming lightness and charm, Gerald Pollack sweeps aside the big myths

out of which the entire subject has been spun, thus disposing of perhaps 99

percent of what one might have learned from cell biology textbooks. Well,

perhaps I should explain that the molecular ‘hardware’ does exist, but the

explanatory mechanisms may all be wrong. The most important message in this book

is that life cannot be understood without understanding some elementary physics

and chemistry. There needs to be a complete overhaul of the typical life-science

curriculum in universities and lower down.

 

The first to go is the myth that the cell is enclosed by a cell membrane that

forms a barrier to substances going in and out of the cell. And hence, an

endless list of specific channel proteins are necessary to allow various

substances such as inorganic ions, sugars, amino-acids, hormones, etc. etc. to

pass in and out, all guarded by specific receptors that make the channel

proteins ‘open’; not to mention the specific protein ‘pumps’ supposedly

operating to transport ions uphill against their concentration gradients.

 

All that is rather like a house that has a dog-flip, a cat-flip and a

mouse-flip, when it is obvious to men and beast alike that anything smaller than

the dog will be able to use the dog-flip. The artwork in this book is wonderful,

by the way.

 

Pollack reviews evidence dating from the early part of the last century that

practically all the properties attributed to the cell membrane are there even

when the membrane has been dissolved away, or great holes and tears made in it,

or even when a whole chunk of the cell has been cut away.

 

These membrane-specific properties include the so-called membrane potential, the

negative electrical potential inside the cell relative to the outside, as well

as the action potential, an electrical spike discharge generated when the cell

membrane (presumably) is electrically or otherwise stimulated. Furthermore,

these cells, denuded of membranes, or full of gaping holes in their membrane,

nevertheless keep hold of their ions and small molecules for a long time after

there are no barriers to prevent them from diffusing away.

 

The next to go are stories on how cells secrete substances that make other cells

do specific things by vesicles filled with neural transmitter, what have you,

inside the cell migrating outwards, and fusing with the cell membrane, thus

discharging their ‘payload’.

 

Or how cells can transport large cargoes by molecular machines with molecular

‘feet’ walking along molecular monorails; how cells themselves are supposed to

move and divide by ‘contractile fibres’, and how our muscles are supposed to

contract by tiny ‘cross-bridges’ walking or sliding along fixed, filaments.

 

Goodness me. How many hours have I wasted trying to make sense of it all? And

all, quite probably, to no avail, if Pollack is to be believed.

 

So, what’s the grand unifying principle that could explain all that, which is

nothing short of life itself?

 

It could be no more than phase transition involving gels, for that’s what most

proteins are, according to Pollack.

 

One is reminded of the supercomputer in Adam Douglas’ Hitch-hikers Guide to the

Galaxies, finally answering the question that’s it has been deliberating for

ages, " What is the meaning of life? "

 

" Forty-two! "

 

First thing first, why doesn’t the cell need a membrane? Because, rather than

being a bag of enzymes and other proteins enclosed in a membrane, the cell is a

highly organised state of matter, more like a poly-electrolyte gel akin to egg

white, or gelatin. This poly-electrolyte gel, with a lot of negative charges,

accommodates smaller ions such as potassium (K+) and exclude the much larger

sodium (Na+). That’s why the cell is predominantly filled with potassium, while

the extracellular fluid like our blood, lymph, tears and the sea, are rich in

sodium. There aren’t enough potassium ions adsorbed to neutralise all the

negative charges, so the cell invariably ends up with a negative electrical

potential relative to the outside. That gel potential has been mistaken for

‘membrane’ potential. And the orthodoxy is sticking to its story.

 

But surely, the potassium atom is much bigger than the sodium. Yes, so the

positively charged potassium exerts a weaker force on the surrounding water than

the sodium and ends up with a much smaller hydration shell. So water is the key,

isn’t it?

 

Our readers will be familiar with water and water in living organisms, specially

featured in " Water, water everywhere " series in SiS 15, where we said that the

water in the cell, as well as outside the cell in connective tissues, is in a

liquid crystalline state bound to proteins and other macromolecules.

 

Liquid crystals and gels are the same with regard to the large amount of water

adsorbed, except that liquid crystals are molecularly ‘aligned’, or ordered, and

gels are not. Thus collagen is liquid crystalline with all the molecules

aligned. If you cook collagen for a long time, it turns into gelatin, a gel with

the molecules randomly dispersed. So, the properties of gel apply to liquid

crystals, perhaps even more so.

 

It is the layers of adsorbed water on the surfaces of proteins and other

macromolecules in the cell cytoplasm that exclude the larger sodium ions, except

when a phase transition occurs, and the bound water comes off the surfaces.

 

Many physical measurements support the idea that most if not all of the cell

water are in this bound, ordered state, in which nothing will dissolve in it,

and it is restricted in its motion. What binds and orders the water molecules

are surface charges attracting the water molecule. The water molecule is special

as it can undergo extensive hydrogen bonds with one another and with other

molecules. Surfaces with a lot of charges will be able to capture many layers of

water molecules all lined up; whereas surfaces with few charges will be unable

to retain bound water. It is estimated that the layers of water thus adsorbed in

the cell are between 5 to10.

 

And, practically all the vital functions of the cell may be explained in terms

of phase transition of gels from a hydrated state, in which the water is

adsorbed to the enormous surfaces available, to a condensed state, in which the

water is displaced and literally squeezed out. It happens very quickly indeed.

This could well explain how ‘secretary’ vesicles can actually forcibly eject

their ‘pay-load’, when they change from a condensed state explosively to an

expanded state on reaching the outside, rather like a compressed spring is

suddenly released. No ‘membrane fusion’ necessary.

 

Now, this phase transition is quite dramatic, the difference in total volume

between a fully hydrated gel and a condensed state could be as much as a

thousand fold. This surely can’t be happening all the time, because we don’t

normally shrink and expand like Alice in Wonderland.

 

The phase transitions could be much more localised, probably because the cells

never has extensive patches of purely one kind of molecules, and more

importantly, there is organisation in the cytoplasm, with diverse molecules

aligned and arrayed next to one another in what biochemist Ricky Welch, not

mentioned in this book, referred to as a distinct and varied ‘cytosocial

environment’.

 

Localised phase transitions could account for the sudden electrical discharges

typical of action potentials, for example, when potassium ions are released with

bound water, and sodium ions coming in to dissolve in the liberated water. What

could trigger phase transition? Anything that changes surface charge

distribution, adding a phosphate group in the ubiquitous phosphorylation

reaction that appears to be involved in every ‘signal transduction’ cascade, for

example; or binding divalent cations like calcium (Ca2+) with two positive

charges that could link up two protein surfaces, thus literally squeezing the

bound water out.

 

These simple phase transitions propagating along a long fibre could

automatically make ‘molecular motors’ stream along the tracts, in what has come

to be known as ‘cytoplasmic streaming’, most prominent in the long fibres or

axons of nerve cells, but can also be seen in giant alga. Basically, it is the

tiny local turbulences of water being released from the surface and the

rebinding, coupled with the local wave-like contraction and expansion of the

molecular tract undergoing phase transition that propels the cargoes along, with

the greatest of ease.

 

And how might muscles work? By phase transition of course. All the fibres,

actin, myosin and the newly discovered connecting filaments, contribute to the

contraction of muscle by propagated phase transition, and you can see this in

sections of muscle quick frozen in the midst of a contraction.

 

I leave you to discover how cells really divide.

 

Pollack may be wrong on many details, and it is a moot point whether one should

call all movements of bound water onto and off protein surfaces ‘phase

transition’, and, I am slightly disappointed that he hasn’t gone on to talk

about liquid crystalline phases at all.

 

Pollack refers to the important work of many early pioneers, such as Professor

Gilbert Ling who went from China to the United States on a Boxer Fellowship, and

soon found himself at odds with the orthodoxy over the existence of the cell

membrane and the membrane potential. Another is Albert Szent-Gyorgyi, a founding

father of biochemistry who got a Nobel prize, but had very unorthodox ideas

nonetheless that inspired many including me. Pollack could have mentioned Joseph

Needham’s remarkable little book, Order and Life, published in 1936, which has

anticipated a lot of the new cell biology that Pollack so skilfully compels us

to think about.

 

It is clear to me, especially after reading this book, that molecular biologists

have been thinking themselves into a right muddle of molecular cogs and wheels,

cross-bridges, membrane receptors, channels, switches, signal transducers, nuts

and bolts galore that guzzle energy like our own mechanical devices, and

wondering where all that energy could come from. That, by the way, is why a lot

of nano-machines that nano-technologists intend to build will go nowhere. They

should first learn about phase transitions, and there are already some

marvellous applications described in this book developed by scientists who take

the physics and chemistry seriously.

 

The cell is not assembled from a nano-Meccanno set, nor endless nano-Lego pieces

that depends on many so isolated push-pull, drive-driven, lock and key

mechanical actions. Not, the cell has been engaged in molecular Kungfu instead,

performing all its vital functions with the greatest of ease and the least of

bother. Just imagine that.

 

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