BI105_FA24_14 Energy and Enzymes I PDF

Summary

This document discusses energy relationships and metabolism, covering topics such as kinetic energy, potential energy, thermal energy, and chemical potential energy. It also touches on important biological concepts like the 1st and 2nd laws of thermodynamics, and the relationship between exergonic and endergonic reactions.

Full Transcript

ENERGY RELATIONSHIPS AND
METABOLISM
 ENERGY IS THE C APACITY TO PERFORM WORK

The most basic types of energy are:
Kinetic energy: the energy of motion.
Potential energy: energy stored in something’s structure or position.
These types of energy can be converted into one another and transferred between
objects – these are forms of work.
All organisms require energy to grow, move, and change
IMPORTANT TYPES OF ENERGY FOR
LIVING ORGANISMS

Kinetic energy of movement – important for
animal behavior.
IMPORTANT TYPES OF ENERGY FOR
LIVING ORGANISMS

Thermal energy is a type of kinetic energy associated
with the random movement of atoms/molecules.
Thermal energy that is transferred from one object to another
is heat.
Energy is often lost from biological systems in the form of heat.
 IMPORTANT TYPES OF ENERGY FOR
LIVING ORGANISMS

Chemical potential energy is the potential energy stored in the
bonds of a molecule, which can be released in a chemical reaction.
The most important type of energy for living organisms, which powers work done
by all living cells.

Other forms of energy
can be very important in
biology (e.g. light), but we
will skip them for now.
Depends both on the chemicals present in the
food and on which chemicals we can
effectively break down in our digestive system

Calories are an estimate of
the chemical potential
energy in the food that is
available to the human body
 THE BRANCH OF PHYSICS CONCERNED WITH
STUDYING ENERGY TRANSFORMATIONS IS
THERMODYNAMICS

Two critical laws of thermodynamics

1st law of thermodynamics: “law of conservation
of energy”.
energy can be neither created nor destroyed—just
converted from one form to another.
 ENERGY IS CONSTANTLY BEING
CHANGED FROM ONE FORM TO
ANOTHER

Chemical potential energy
in bonds of food
Kinetic energy of muscle
contraction

Kinetic energy of the flying arrow

Potential energy stored in the bent bow
ENERGY TRANSFORMATIONS POWER WORK
DONE BY HUMAN BODIES AND HUMAN
TECHNOLOGIES
 THE BRANCH OF PHYSICS CONCERNED
WITH STUDYING ENERGY
TRANSFORMATIONS IS THERMODYNAMICS
Two critical laws of thermodynamics

2nd law of thermodynamics: when energy is
converted from one form to another, some of that
energy becomes unavailable to do work.
As entropy increases, less energy is available for organisms to
do work (less free energy [G] is available).
In a biological context, energy is lost to the environment as
heat
ENERGY AND CHEMICAL
REACTIONS
MOST BIOLOGIC AL REACTIONS ARE
REVERSIBLE

Going this way →: Going this way ←: forms
breaks high energy high energy bonds and
bonds and releases a requires a lot of energy
lot of energy (burning input (e.g. heating:
methane as fuel) carbon capture)
 BASIC THERMODYNAMICS IS CRITIC AL FOR
UNDERSTANDING HOW CHEMIC AL
REACTIONS OCCUR

If more chemical energy in the It will be converted into some
bonds of A&B than C&D, where other form and released
does the extra energy go? energy

A+B C+D

1) Energy is neither created nor destroyed.

2) Different chemical bonds in these molecules contain different amounts
of chemical energy.
 BASIC THERMODYNAMICS IS CRITIC AL FOR
UNDERSTANDING HOW CHEMIC AL
REACTIONS OCCUR
Imagine a reaction that involves four different molecules:
If less chemical energy in the bonds of A&B
than C&D, where does the extra energy come
from? It will need to be
added to the reaction
energy

A+B C+D

1) Energy is neither created nor destroyed.
2) Different chemical bonds in these molecules contain different amounts of chemical energy.
 REACTIONS THAT RELEASE ENERGY ARE EXERGONIC;
REACTIONS THAT REQUIRE ENERGY ARE ENDERGONIC

energy
A+B C+D

Exergonic

energy
A+B C+D

Endergonic
QUESTIONS?
TOPHAT QUESTION 14.1
METABOLISM
 METABOLISM IS THE SUM OF ALL
CHEMICAL REACTIONS WITHIN CELLS OF
LIVING ORGANISMS

Two categories of metabolic reactions:
Catabolism: the breakdown of a molecule into
smaller components. These are generally exergonic reactions
Anabolism: synthesis of molecules from smaller
precursors. These are generally endergonic reactions
 WHERE DO ORGANISMS GET THE
ENERGY REQUIRED FOR ALL THE
ENDERGONIC REACTIONS NEEDED
FOR LIFE?
They couple an exergonic and endergonic reaction at the same
place/time, and use the energy released from the first to fuel the
second.
One specific exergonic reaction is used for this purpose
overwhelmingly across living organisms: the hydrolysis of ATP.

In other words, ATP is a
general-purpose energy
storage molecule: it can be
used to drive many
endergonic reactions in a cell
 THE HYDROLYSIS OF ATP

ATP is a modified
nucleotide with extra
high-energy
phosphate groups This liberated energy is
what is used to drive
Adenosine triphosphate (ATP)
other endergonic
reactions

Energy
Inorganic
phosphate Adenosine diphosphate (ADP)
Uses of ATP
that we have
already POLYMERIZATION AND
encountered: DEPOLYMERIZATION

Building a polymer from monomers is usually done by
dehydration reactions

ATP
ATP drives
most anabolic
reactions inside
cells ADP + Pi
Uses of ATP
that we have
already
encountered:
MOTOR PROTEINS

ATP

ADP + Pi

ATP powers
intracellular
transport
Uses of ATP
that we have PUMPS AND MEMBRANES C AN BE USED TO
CONVERT STORED CHEMIC AL ENERGY FROM
already
ATP TO POTENTIAL ENERGY IN THE FORM OF
encountered: A CONCENTRATION GRADIENT
 CELLS REPLENISH THEIR SUPPLY OF ATP BY
HARNESSING THE ENERGY OF C ATABOLIC ALLY
BREAKING DOWN OTHER SUBSTANCES

Cells must do this
constantly since they
ATP H2O
are using ATP
constantly to live

Energy from Energy for cellular
catabolism (exergonic, work (endergonic,
energy-releasing ADP Pi energy-consuming
processes) processes)
We will discuss how we “recharge” ATP using
the food we eat when we cover cellular
respiration starting in the next lecture
QUESTIONS?