I have just started reading The Rainbow and the Worm, by Mae-Wan Ho, one of the books
recommended by my sister. I would like
all of you to read the following two page selection taken from the introductory
first chapter, "What is it to be alive?" The passage describes what happens when a
muscle contracts. I find this passage
simply astonishing. Think, as you read
it, of how many thousands of research scientists had to carry through carefully
conceived experimental programs in order for her to write this brief summary
for the non-specialist. This is the sort
of thing I wish Thomas Nagel had spent his time writing about in his book, Mind and Cosmos. By the way, Ho indicates that later in the book
[I have only read chapter one], she will talk about quantum entanglement and a
host of other topics from theoretical Physics in their relation to Biology.
"Another instructive example is muscle
contraction. About 40% of our body is made
up of skeletal muscle, i.e., muscle attached to bones, like those in our arms
and legs and trunk. Another 5 or 10% is
smooth muscle such as those of our gut and body wall, and cardiac muscle in the
heart. Skeletal muscle consists of long
thin muscle fibres, which may be discerned under a magnifying glass. these fibres are several centimetres in length,
each of which is actually a giant cell formed by the fusion of many separate
cells. A single muscle fibre, magnified
a hundred times or more under the light microscope, can be seen to be made up
of a bundle of 20 to 50 much smaller fibres, or myofibrils, each 1 to 2 μm
(micrometre, one-millionth of a metre] in diameter. A myofibril has regular, 2.5μm repeating units called
sarcomeres, along its length. Adjacent myofibrils are aligned so that their
sarcomeres are in register. Under the
much higher magnifications from the electronmicroscope -- thousands to tens of
thousands of times -- one will see extremely regular arrays of the periodic
structures. One will also see that each
sarcomere consists of alternating thin and thick filaments, made up
respectively of the two main muscle proteins, actin and myosin.
In three dimensions, there are actually six thin actin filaments
surrounding each thick myosin filament, and the six actin-filaments are
attached to an end-plate, the Z-disc.
Contraction occurs as the actin filaments surrounding the myosin
filaments slide past each other by cyclical molecular tread milling between
myosin 'head' groups and serial binding sites on the actin filament, forming
and breaking cross-bridges between the filaments, in all three dimensions in
the entire array.
The actin and myosin molecules are packed and arranged very
precisely, approaching the regularity of crystals, and the study of the detailed
structure of resting as well as contracting
muscle is done by means of x-ray crystallography. There are 624 myosin head groups on each
myosin filament, and when the entire muscle contracts, each sarcomere in it
shortens proportionately. Thus, when a
myofibrile containing a chain of 20,000 sarcomeres contracts from 5 to 4 cm.,
the length of each sarcomere shortens correspondingly from 2.5 to 2 μm. The energy for contraction comes from the
hydrolysis of a special molecule that acts as the universal energy transacting
intermediate in the body. In its
'charged up' form, it is ATP, or adenosine triphosphate, with three phosphate
groups joined one to another in series and then to the chemical group
adenosine. ATP 'discharges' its energy
by splitting off a phosphate group at the end, to give the partially
'discharged' form, ADP or adenosine diphosphate.
Muscle contraction is triggered by an action potential at the site where a nerve impinges on the
muscle-cell membrane. An action
potential is a quick electrical discharge followed by recovery of the pre-existing
baseline electrical potential. This
releases calcium ions, Ca2+, from intracellular calcium ion stores
to initiate contraction simultaneously in the entire cell within a
millisecond. Contraction involves
numerous autonomously occurring cycles of attachment and detachment of all the
individual myosin heads to and from the binding sites on the actin filaments at
the rate of 50 cycles or more per second -- each of which molecular event
requiring the transfer of energy contained in one molecule of ATP -- precisely
coordinated over the whole cell.
In a typical muscle contraction, all the cells in the muscle -- billions of them at the very least
-- are executing the same molecular treadmilling in concert. Simply waving our arms about is a veritable
feat requiring a series of actions coordinated instantaneously over a scale of
distances spanning nine orders of magnitude from 10-9 metre
[nanometre, one billionth of a metre] for intermolecular spacing between the
actin and myosin heads, to about one metre for the length of our arm; each action, furthermore, involving the
coordinated splitting of 1019 individual molecules of ATP. Now, think, imagine what has to happen when a
top athlete runs a mile in under four minutes;
the same instantaneous coordination over macroscopic distances involving
astronomical numbers of molecules, only more so, and sustained for a long
period without break."
1 comment:
IIRC, you were once an avid science fiction reader. I wonder if you'd like Blindsight by Peter Watts. It is dense, "hard sf", but Dr. Watts is a biologist and also touches on the philosophy of mind.
In case you get the itch, you can find Blindsight and many of his other works on his Web site.
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