Human Nutrition and Metabolism Introduction PDF

Summary

This document provides an introduction to human nutrition and metabolism. Topics covered include catabolism, anabolism, energy storage, and enzyme regulation. It also discusses the importance of energy transformations and the role of ATP in cellular processes.

Full Transcript

Human Nutrition and
Metabolism
Introduction
Introduction
Catabolism is the degradative phase of metabolism in which organic nutrient
molecules (carbohydrates, fats, and proteins) are converted into smaller, simpler
end products (such as lactic acid, CO2, and NH3).
Catabolic pathways release energy, some of which is conserved in the formation
of ATP and reduced electron carriers (NADH or NADPH); the rest is lost as heat.
In anabolism, also called biosynthesis, small, simple precursors are built up into
larger and more complex molecules, including lipids, polysaccharides, proteins,
and nucleic acids.
Anabolic reactions require an input of energy, generally in the form of the
phosphoryl group transfer potential of ATP and the reducing power of NADH and
NADPH.
Introduction
Most cells have the enzymes to carry out both the degradation and the synthesis of the important categories
of biomolecules — fatty acids, for example.
The simultaneous synthesis and degradation of fatty acids would be wasteful, however.
This is prevented by reciprocally regulating the anabolic and catabolic reaction sequences: when one
sequence is active, the other is suppressed.
Such regulation could not occur if anabolic and catabolic pathways were catalyzed by exactly the same set of
enzymes, operating in one direction for anabolism, the opposite direction for catabolism: inhibition of an
enzyme involved in catabolism would also inhibit the reaction sequence in the anabolic direction.
Catabolic and anabolic pathways that connect the same two endpoints (glucose →→ pyruvate, and pyruvate
→→ glucose, for example) may employ many of the same enzymes; but at least one of the steps is catalyzed
by different enzymes in the catabolic and anabolic directions, and these enzymes are the sites of separate
regulation.
Moreover, for both anabolic and catabolic pathways to be essentially irreversible, the reactions unique to
each direction must include at least one that is thermodynamically very favorable — in other words, a
reaction for which the reverse reaction is very unfavorable.
Introduction
As a further contribution to the separate regulation of catabolic and anabolic reaction sequences, paired
catabolic and anabolic pathways commonly take place in different cellular compartments: for example, fatty
acid catabolism occurs in animal mitochondria, whereas fatty acid synthesis occurs in the cytosol.
The concentrations of intermediates, enzymes, and regulators can be maintained at different levels in these
different compartments.
Because metabolic pathways are subject to kinetic control by substrate concentration, separate pools of
anabolic and catabolic intermediates also contribute to the control of metabolic rates.
Introduction
Metabolic pathways are regulated at several levels, from within the cell and from outside.
A key enzyme in a pathway may be activated allosterically, or its amount may be changed by the rates of
synthesis and breakdown of the enzyme.
In multicellular organisms, the metabolic activities of different tissues are regulated and integrated by
growth factors and hormones that act from outside the cell.
Introduction
Living cells and organisms must perform work to stay alive, to grow, and to reproduce.
The ability to harness energy and to channel it into biological work is a fundamental property of all living
organisms.
Modern organisms carry out a remarkable variety of energy transductions, conversions of one form of
energy to another.
They use the chemical energy in fuels to bring about the synthesis of complex, highly ordered
macromolecules from simple precursors.
They also convert the chemical energy of fuels into concentration gradients and electrical gradients, into
motion and heat, and, in a few organisms such as fireflies and some deep-sea fish, into light.
Introduction
The chemical changes and energy transductions in living organisms follow the laws of thermodynamics.

The free-energy change is the maximum energy made available to do work when a chemical reaction
occurs.
If two reactions can be combined to yield a third reaction, the overall free energy change is the sum of the
two.
Cells accomplish energy-requiring chemical work by coupling an energy-releasing (exergonic) reaction such
as the cleavage of ATP to an endergonic reaction (which requires energy input).
ATP is the universal energy currency in living organisms
Transfer of its phosphoryl group to a water molecule or metabolic intermediates provides the energetic push
for muscle contraction, the pumping of solutes against concentration gradients, and the synthesis of
complex molecules.
Introduction
Oxidation-reduction reactions indirectly provide much of the energy needed to make ATP.
Reduced substrates such as glucose are oxidized in several steps, with the energy of oxidation steps
conserved in the form of a reduced cofactor, NADH.
Energy stored in NADH is used to drive the synthesis of ATP.
To respond to changes in external circumstances, cells must regulate enzyme activities, by changing either
the number of enzyme molecules or the catalytic activity of preexisting enzyme molecules.
Introduction
13.1 Bioenergetics and
Thermodynamics
Bioenergetics is the quantitative study of energy transductions — changes of one form of energy into
another — that occur in living cells, and of the nature and function of the chemical processes underlying
these transductions.
Introduction
Biological Energy Transformations
Obey the Laws of Thermodynamics
Many quantitative observations made by physicists and chemists on the interconversion of different forms of
energy led, in the nineteenth century, to the formulation of two fundamental laws of thermodynamics.
The first law is the principle of the conservation of energy: for any physical or chemical change, the total
amount of energy in the universe remains constant; energy may change form or it may be transported from
one region to another, but it cannot be created or destroyed.
The second law of thermodynamics, which can be stated in several forms, says that the universe always
tends toward increasing disorder: in all natural processes, the entropy of the universe increases.
Introduction
The reacting system is the collection of matter that is undergoing a particular chemical or physical process; it
may be an organism, a cell, or two reacting compounds.
The reacting system and its surroundings together constitute the universe.
In the laboratory, some chemical or physical processes can be carried out in isolated or closed systems, in
which no material or energy is exchanged with the surroundings.
Living cells and organisms, however, are open systems, exchanging both material and energy with their
surroundings; living systems are never at equilibrium with their surroundings, and the constant transactions
between system and surroundings explain how organisms can create order within themselves while
operating within the second law of thermodynamics.
Introduction
Below are the three thermodynamic quantities that describe the energy changes occurring in a chemical
reaction:
Free energy, G (for J. Willard Gibbs), expresses the amount of energy capable of doing work during a
reaction at constant temperature and pressure.
When a reaction proceeds with the release of free energy (that is, when the system changes so as to possess
less free energy), the free energy change, ΔG, has a negative value and the reaction is said to be exergonic.
In endergonic reactions, the system gains free energy and ΔG is positive.
Introduction
Enthalpy, H, is the heat content of the reacting system.
It reflects the number and kinds of chemical bonds (covalent and noncovalent) in the reactants and
products.
When a chemical reaction releases heat, it is said to be exothermic; the heat content of the products is less
than that of the reactants, and the change in enthalpy, ΔH, has, by convention, a negative value.
Reacting systems that take up heat from their surroundings are endothermic and have positive values of ΔH.
Introduction
Entropy, S, is a quantitative expression for the randomness or disorder in a system.
When the products of a reacting system are less complex and more disordered than the reactants, the
reaction is said to proceed with a gain in entropy.

The units of ΔG and ΔH are joules/mole or calories/mole (recall that 1 cal =4.184 J); units of entropy are
joules/mole Kelvin (J/mol ∙ K).
Introduction
Under the conditions existing in biological systems (including constant temperature and pressure), changes
in free energy, enthalpy, and entropy are related to each other quantitatively by the equation
Introduction
in which ΔG is the change in Gibbs free energy of the reacting system, ΔH is the change in enthalpy of the
system, T is the absolute temperature, and ΔS is the change in entropy of the system.
By convention, ΔS has a positive sign when entropy increases and ΔH, as noted above, has a negative sign
when heat is released by the system to its surroundings.
Either of these conditions, both of which are typical of energetically favorable processes, tends to make ΔG
negative.
In fact, ΔG of a spontaneously reacting system is always negative.
Introduction
Cells are isothermal systems — they function at essentially constant temperature (and also function at
constant pressure).
Heat flow is not a source of energy for cells, because heat can do work only as it passes to a zone or an
object at a lower temperature.
The energy that cells can and must use is free energy, described by the Gibbs free-energy function G, which
allows prediction of the direction of chemical reactions, their exact equilibrium position, and the amount of
work they can (in theory) perform at constant temperature and pressure.
Heterotrophic cells acquire free energy from nutrient molecules, and photosynthetic cells acquire it from
absorbed solar radiation.
Both kinds of cells transform this free energy into ATP and other energy-rich compounds capable of
providing energy for biological work at constant temperature.
Introduction
In living cells, reactions that would be extremely slow if uncatalyzed are caused to proceed not by supplying
additional heat but by lowering the activation energy through use of an enzyme catalyst.
An enzyme provides an alternative reaction pathway with a lower activation energy than the uncatalyzed
reaction, so that at body temperature a large fraction of the substrate molecules have enough thermal
energy to overcome the activation barrier, and the reaction rate increases dramatically.
The free-energy change for a reaction is independent of the pathway by which the reaction occurs; it
depends only on the nature and concentration of the initial reactants and the final products.
Enzymes cannot, therefore, change equilibrium constants; but they can and do increase the rate at which a
reaction proceeds in the direction dictated by thermodynamics (see Section 6.2).
Introduction
Standard Free-Energy Changes Are Additive
In the case of two sequential chemical reactions, A ⇌ B and B ⇌ C, each reaction has its own equilibrium
constant and each has its characteristic standard free-energy change, ΔG′1° and ΔG′2°. As the two reactions
are sequential, B cancels out to give the overall reaction A ⇌ C, which has its own equilibrium constant and
thus its own standard free-energy change, ΔG′ ‹ Sum.
Introduction
Introduction
Introduction
This principle of bioenergetics explains how a thermodynamically unfavorable (endergonic) reaction can be
driven in the forward direction by coupling it to a highly exergonic reaction.
For example, in many organisms, the synthesis of glucose 6-phosphate is the first step in the utilization of
glucose.
In principle, the synthesis could be accomplished by this reaction:
But the positive value of ΔG′° predicts that under standard conditions the reaction will tend not to proceed
spontaneously in the direction written.
Another cellular reaction, the hydrolysis of ATP to ADP and Pi, is highly exergonic:
Introduction

But the positive value of ΔG′° predicts that under standard conditions the reaction will tend not to proceed
spontaneously in the direction written.

Another cellular reaction, the hydrolysis of ATP to ADP and Pi, is highly exergonic:
Introduction
These two reactions share the common intermediates Pi and H2O and may be expressed as sequential
reactions:
Introduction
The overall standard free-energy change is obtained by adding the ΔG′° values for individual reactions:
Introduction
The overall reaction is exergonic.
In this case, energy stored in ATP is used to drive the synthesis of glucose 6- phosphate, even though its
formation from glucose and inorganic phosphate (Pi) is endergonic.
The pathway of glucose 6- phosphate formation from glucose by phosphoryl transfer from ATP is different
from reactions (1) and (2), but the net result is the same as the sum of the two reactions.
The standard free-energy change is a state function.
In thermodynamic calculations, all that matters is the state of the system at the beginning of the process and
its state at the end; the route between the initial and final states is immaterial.
Introduction
SUMMARY 13.1 Bioenergetics and Thermodynamics
Bioenergetics is the quantitative study of energy relationships and energy conversions in biological
systems.
Biological energy transformations obey the laws of thermodynamics.
Living cells constantly perform work. They require energy for maintaining their highly organized
structures, synthesizing cellular components, transporting small molecules and ions across
membranes, and generating electric currents.
All chemical reactions are influenced by two forces: the tendency to achieve the most stable bonding
state (for which enthalpy, H, is a useful expression) and the tendency to achieve the highest degree of
randomness, expressed as entropy, S.
The driving force in a reaction is ΔG, the free-energy change, which represents the net effect of these
two factors: ΔG = ΔH − T ΔS. The standard transformed free-energy change, ΔG′°, is a physical constant
that is characteristic for a given reaction and can be calculated from the equilibrium constant for the
reaction: ΔG′° = −RT ln K′ eq.
Introduction

The actual free-energy change, ΔG, is a variable that depends on ΔG′° and on the concentrations of
reactants and products: ΔG = ΔG′° + RT ln([products]/[reactants]). When ΔG is large and negative, the
reaction tends to go in the forward direction; when ΔG is large and positive, the reaction tends to go
in the reverse direction; and when ΔG = 0, the system is at equilibrium.
The free-energy change for a reaction is independent of the pathway by which the reaction occurs.
Free-energy changes are additive; the net chemical reaction that results from successive reactions
sharing a common intermediate has an overall free energy change that is the sum of the ΔG values for
the individual reactions.
Oxidation-reduction reactions involve the loss or gain of electrons: one reactant gains electrons and is
reduced, while the other loses electrons and is oxidized. Oxidation reactions generally release energy
and are important in catabolism.