Body In Motion - Homeostasis PDF

Summary

This document covers the concept of homeostasis and its relevance in biochemical reactions. It details how the body maintains order despite the tendency towards disorder and how energy is used to drive biochemical reactions within cells, using detailed examples.

Full Transcript

Body in motion - Homeostasis
L1
eV is used for energy in biochemical reactions instead of calories or joules
because the number in joules will be extremely small

Typical biochemical reactions involve energy changes of about 0.2eV

Very many of them ae driven by 0.3 eV packets of energy

Homeostasis involves

Avoiding change caused by internal processes inherent to the body

Avoiding change driven by external factors

Many common diseases are failures of homeostasis

Infection

Diabetes melitus

Hypertension

Cancer

Alzheimer’s disease

Ageing (although debatable)

There is a problem in maintaining order in homeostasis as ordered things
tend to become disorganised over time

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 eg desk entropy - your desk becomes more disordered as you are
looking for things

ink spreading in water through a drop of ink. Transition from ordered
state (clean water) to full glass becoming disinfected (full of ink)

example of the ‘spreading ink’ problem within the body: oxygen
spreading through the blood vessels.

To fight back against this, the body has to expend energy just to
‘stand still’ to maintain its organisation against the action of the
second law. The body cannot be a ‘closed system’ in which
disorder inevitably decreases.

To maintain homeostasis, the body has to expend energy to ‘stand still’ - to
maintain its organisation against the action of the second law.

So it cannot be a ‘closed system’ (in which disorder inevitably
decreases)

Sugars (glucose, fructose) are examples of plant-derived molecules we
use for energy.

Oxidising sugar gives a lot of energy

Body in motion - Homeostasis 2
 Energetics of typical biochemical reactions

Reactions always run ‘downhill’ in energy terms*, but one reaction
running a lot ‘downhill’ can be coupled to driving another reaction a bit
uphill

The conversion of ATP to ADP and Pi (downhill reaction) provides
energy for the uphill reaction

* strictly, ‘uphill’ in entropy terms, but ‘downhill in energy’ is good enough for almost
all biology. n.b. in this context, the glucose is not providing the energy, but is simply
acting as a substrate fo the reaction

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 In the conversion of glucose to fructose-1,6-bisphosphate, there are two
phosphorylations

First phosphorylation

Second phosphorylation

Why are we, oxidising sugar as we are, not on fire?

Body in motion - Homeostasis 4
 Typical biochemical reactions involve energy changes of about 0.2eV

Very many of them are driven by 0.3eV ‘packets’ of energy donated by
the energy carrier ATP (the difference appears as extra molecular
motion, ie heat)

But oxidising a molecule of glucose releases 29eV of energy, which
is way too much

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 NADH is then converted to ATP at the end as it releases electrons,
which travel down the electron transport chain, releasing energy.
This energy is used to actively transport H+ ions against a
concentration gradient and the H+ ions then diffuse back down

Body in motion - Homeostasis 6
 through the ATP synthase enzymes, producing ATP. Cyanide is
poisonous because it interrupts this chain.

Summary of the biochemistry

Glucose is processed in a series of small steps, most of which allow the
recovery of small amounts of energy

Some steps pass this energy direct to ATP

Some steps pass it to intermediate carriers such as NADH

Metabolism is complicated because it has to be in small steps. These
steps make lots of ATP molecules from the high energy molecules in
food

So… the result of all of this is that we can turn food into ‘packets’ of
energy, in the form of ATP, that can bring 0.3eV each to drive reactions
in cells (by coupling downhill ATP → ADP + Pi to an uphill reaction)

L2
There are many examples of two compartments being separated by a
membrane (this is common)

Phase separation

Body in motion - Homeostasis 7
 Why does this happen?

Water would rather interact with its own molecules than other
molecules, which is why there is a phase separation between water
and oil.

The polar nature of water means that adjacent molecules can lower
their free energy by interacting, +ve end of one to -ve middle of the
other

If you add non-polar molecules (pink), you stop water molecules
adjacent to them from having polar interactions

This stops them reaching their lowest energy state

Systems want to run ‘downhill’ in terms of free energy*, so they
minimise contact between polar and non-polar components by

Body in motion - Homeostasis 8
 grouping all the polar in one place (’phase’)

In Entropy terms, which are the strictly correct way of looking at
this, separating the phases increases entropy at the micro-level
(by erasing all those ‘special’ places where polar bonding is
messed up) enough to more than pay for the small decrease in
entropy at the macro-level (two distinct layers you can see). But
again, just thinking of minimizing free energy is fine for most
biological thinking and few biologists talk about entropy.

Key Concept:

Micro-level entropy: When the system separates the
phases, it frees the molecules from the constraints
imposed by unfavorable polar-non-polar interactions.
This increase in freedom at the micro-level leads to an
increase in microscopic entropy.

Macro-level entropy: On a larger, visible scale, the
system looks more organized after phase separation
because the molecules are grouped into two distinct
phases (polar and non-polar). This makes the system
appear more orderly, suggesting a decrease in
macroscopic entropy.

The overall change in entropy is positive because the
increase in entropy at the micro-level (due to removing
the disrupted polar-non-polar interactions) outweighs
the decrease in entropy at the macro-level (where the
system appears more organized after separating into
two phases).

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 Large hydrophobic spaces are rare in the body (fat droplets in adipocytes
are one example)

Much more common is the use of very thin hydrophobic regions to
make barriers between aqueous compartments

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 How can such a thin layer be stable? (not just coalesce into a droplet)

There are molecules that are hydrophilic at one end and hydrophobic at
the other (amphipathic)

Body in motion - Homeostasis 11
Body in motion - Homeostasis 12
 Water is attracted to hydrophilic substances, because they are polar, and
they are not attracted to hydrophobic substances, because they ae non-
polar.

There is a problem with the basic arrangement of the phospholipid bilayer

The tails pack so regularly the bilayers would be solid even at body
temperature

Therefore, the cell adds cholestrol to lipid bilayers to mess up their
packing and stop them freezing at 37ºC (it essentially acts as an anti-
freeze.

Lipid bilayers themselves are selectively permeable: hydrophilic molecules
cannot cross.

Body in motion - Homeostasis 13
 Water will not want to break off its bonds with other water molecules
and enter a hydrophobic region

However, some hydrophilic molecules need to get across the
membrane:

Food (eg glucose)

Raw materials (eg amino acids)

Waste products (eg urea)

Ions

Water (which can get through, but very slowly)

Signals and information

The membrane therefore needs selective channels

Body in motion - Homeostasis 14
 So far, we have four types of transport: (none of these mechanisms can
create order on its own)

Direct free diffusion

Uniporter

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 Co-transporter (channels that can transport substances ‘together’ in
the same direction)

Antiporter (channels that can transport substances ‘together’ but in
opposite directions)

In all of these, net transport is down-gradient, and will reduce
differences in concentration (like ink spreading in water again).
They are all passive

Body in motion - Homeostasis 16
 Diagram of the phospholipid bilayer

A ‘universal’ example of a maintained non-equilibrium is seen with Na+ and
K+:

Body in motion - Homeostasis 17
Body in motion - Homeostasis 18
Body in motion - Homeostasis 19
 Summary
Making and maintaining organization needs energy
We turn high-energy foods into usable 0.3eV packets of energy (ATP) by
set-by-step reaction schemes
We use phospholipid membranes to separate compartments

One use of ATP is to expel Na+ from cells and bring K+ in to create an
electro-chemical gradient.
Co-transporters can ‘parasitize’ this gradient to move solute uphill, at the
expense of letting Na+ run back downhill.
Thus cells can keep compartment contents distinct
These transport processes are often useful drug targets.

L3
A signal is a communication that conveys meaning (in science)

Body in motion - Homeostasis 20
 A “signal” and its meaning are defined from the point of view from the
receiver

The same signal can have different meanings to different receivers

The amount of information that can be passed per unit time is the
bandwidth

High bandwidth is expensive

This explains why long-distance messaging is done by passing
simple signals, like yes no now from sender cells to receiver cells
that already have the information necessary to know what to do
(they have it by reading their genes)

Signals can have different information content. For example:

Body in motion - Homeostasis 21
 ‘Please lift your foot off the throttle pedal, depress the clutch pedal, pull
the gearstick to neutral*, release the clutch pedal, depress the
accelerator for a moment, depress the clutch pedal, pull the gearstick
into 2nd, and press the throttle pedal as you release the clutch’

‘Please change from 3rd to 2nd gear’

‘Now’

all can achieve the same thing, depending on what the listener
already knows.

Some biological systems have to carry vast amounts of information

So, as far as possible, long-distance messaging is done by passing
SIMPLE SIGNALS (‘Yes’, ‘No’, ‘Now’) from sender cells to receiver cells
that already have the information necessary to know what to do (they
have it by reading their genes)

Body in motion - Homeostasis 22
 The body’s use of SIMPLE signals to mediate communication between
cells, tissue and organs is really useful to medicine.

It means that if we can change the messages by making alterations to
how well these simple signals are received, or by making simple signals
of our own. (This is how most drugs work.)

Classification of paths

Autocrine signals - when a cell/group of cells signal to themselves

Paracrine - one cell signalling to another cell

Body in motion - Homeostasis 23
 endocrine - used for long-distance signalling, reaching everywhere

juxtacrine - direct contact between neighbouring cells

How do signals get into cells?

Sufficiently hydrophobic molecules can cross the membrane directly.

The most famous class of these is steroids

An example of how a steroid-mediated signal alters gene expression

This kind of pathway is efficient, but relatively slow, and is often
used for long-term things like sex determination, regulating
puberty, menstrual cycles, stress and inflammation

Use of receptors

These are used for signals involving hydrophilic molecules (as they
cannot directly travel through the membrane due to their
hydrophilic nature)

Body in motion - Homeostasis 24
Body in motion - Homeostasis 25
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 Problem: What are the tradeoffs in signalling, between sensitivity, speed
and economy?

Sensitivity can be increased by amplification (despite a huge energy
cost) eg here, think about the cost of putting all of that Ca2+ back, and

Body in motion - Homeostasis 27
 rebuilding all that PIP2!

Ways of avoiding false signals from noise:

Average over time (costs in speed of response)

Average over a group of cells (but now we need some way of them
communicating among themselves)

Speed

For high speed in both directions (on and off), we need

rapid production of second messengers and activated effectors

High energy costs

Rapid destruction of the second messengers and activated
effectors

High energy costs

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 To achieve high-speed cellular responses (both activation and deactivation),
there must be fast synthesis and rapid destruction of second messengers,
which requires high energy expenditure.

Body in motion - Homeostasis 29
 The challenges of long-distance communication:

Low speeds (eg brain to gonads to regulate ovulation)

Slow as signals travel through the bloodstream

Choice between producing lots of signals (eg to overcome dilution
in the circulation) and using high sensitivity

Generally, it is cheaper to produce small amounts of signal and
a having the receiving cells sensitive

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 High-speed (eg brain to finger to control writing):

‘Pipe’ the signal down a direct high-speed path (see lectures on the
nervous system).

This avoids the dilution problem in hormonal movement

Another advantage of nervous communication

The idea of ‘wiring’ allows the same chemical signals to be used, and
the same response systems to be used (‘contract a muscle’) to make
the body do many different things, according to which ‘wires’ (nerves,
axons) are activated and which muscles therefore fire. (another
advantage of nervous communication)

Body in motion - Homeostasis 31
 Neurons and neurotransmitters

For now

Body in motion - Homeostasis 32
 Hormones “broadcast” to every part of the body

Neurons “text” their intended recipient only

Both can result in inter-individual communication aswell

L4

An example of an open-loop control is when you power a heater on low-
medium-high. Thee is no loop to maintain the temperature at a certain
point. However, an example of a closed loop control is when the heater
turns on and then it reaches 20C and then it stops until the heat deceases
again and then it reaches 20 again.

Body in motion - Homeostasis 33
 Homeostasis is a closed-loop control.

This is required for holding steady in the face of unpredictable change.

The body has to keep its proper internal environment in the face of both
internal and external changes;

Internal

wake-sleep

resting-active

standing-recumbant

Body in motion - Homeostasis 34
 pregnancy

External:

warm-cold

injured by animal or falling tree branch

drought/famine - plenty

Body in motion - Homeostasis 35
 This is a bit like Zeno’s paradox, except it is not an illusion caused by faulty
thinking

In homeostasis, we have proportional control & integrative control.

Proportional control - looks at how big the error is

integrative control - looks at the integral of the error with respect to
time

Proportional control gets weaker as the error decreases. This means that as the system
approaches the baseline, the correction becomes so small that it may not be enough to bring
the system all the way to the target,. This leaves a small residual error.

Body in motion - Homeostasis 36
 So far, we have covered homeostasis through a reactive measure.

Body in motion - Homeostasis 37
 A parameter is normal → Something pulls the parameter up or down →
A response is initiated to restore the parameter

However, if the parameter is really critical to health, allowing it to
run away in the first place may be a very bad idea - there are some
times when you cannot afford to have the system play catch-up.

This explains anticipative physiological changes, which prepare
the body for running or fighting. However, these are unhelpful
for ‘modern’ scares eg driving that makes no physiological
demands.

Chronic activation of the ‘fight or flight’ pathway is dangerous

Can lead to myocardial infarction

Examples of anticipatory mechanisms

Eating - extra saliva production for digestion of starch

Female sexual response - enhanced mucus secretion to prevent
damage

Anticipatory changes almost always involve the brain doing some pattern-
recognition and 'reading' the short-term future.

Body in motion - Homeostasis 38
 In all mammals, anticipatory homeostasis is common in the three great
drives, which physiologists have long called the thee Fs

Fleeing

Fighting

Mating

L5
Failures of homeostasis

Damage to effectors

eg traumatic breach of barriers integument and of blood vessels,
allowing fluids to be where they should not be. The main treatment
at this trivial or more serious levels, is to clean, then restore.

eg renal failure. Main treatment: renal dialysis. This uses an external
machine to replace the functions of the kidney (to an imperfect
extent)

damage to pacemaker → treatment: artificial pacemaker

Doctors rarely repair these defects, but instead they produce
new artificial mechanisms to fix these.

Damage to control systems (here, we normally use a drug that mimics
a missing signal or one that blocks a pathway inappropriately active)

Congenital absence of a regulator (eg leptin > obesity)

Damage to a critical feedback system (eg Addison’s disease - no
signals from adrenal cortex)

Inappropriate activation of a homeostatic signal (eg allergy)

Cell wrongly interpreting valid signals (eg neoplasia)

Body in motion - Homeostasis 39
 Positive feedback:

Body in motion - Homeostasis 40
 many drugs have side effects

Body in motion - Homeostasis 41
 Take-home messages from this week:

Homeostasis is essential to life: it can be achieved only with the
expenditure of energy, and is indeed the main consumer of the human
energy budget

Homeostasis is usually achieved using feedback loops, featuring
proportional, integrative and sometimes differential control. It may be
anticipative.

Many types of diseases are failures in some aspect of homeostasis, either
in control systems of effectors

When confronted with a failure in an effector, doctors typically turn to
artificial substitute effectors. These seldom actually fix the underlying
problem, although they may allow the body to fix itself (healing under a
bandage)

Body in motion - Homeostasis 42