The Foundations of Biochemistry PDF

Summary

This document provides an introduction to biochemistry. It covers the structure and function of biological molecules, including carbohydrates, proteins, lipids, and nucleic acids, as well as the cellular processes that utilize them. The document is suitable for secondary school students.

Full Transcript

The Foundations of
Biochemistry
 Chapter outline

1.1 Cellular Foundations
1.2 Chemical Foundations
1.3 Physical Foundations
1.4 Genetic Foundations
1.5 Evolutionary Foundations
 Introduction
▪ The study of the chemical substances and processes that occur in plants, animals, and
microorganisms, as well as the changes that occur during development and life, is known as
biochemistry.
▪ Living organs are made-up from biological molecules that we called biochemical compounds. The
vast number of biochemical compounds can be grouped into just four major classes: Carbohydrate,
protein, Lipid, and nucleic acids.
 Introduction

Biochemical compounds are carbon-based
compounds found in living things. They
make up and other structures of organisms
and carry out life processes. Most
biochemical compounds are macro-
molecules that consist of many repeating
units of smaller micro-molecules.
There are millions of biochemical
compounds, but all of them fall into four
major classes: carbohydrates, lipids,
proteins, and nucleic acids.
 Introduction
Proteins
Carbohydrate

Food
Energy

Vitamins Building materials Lipids

Human Growth
5
 1.1 Cellular Foundations

The unity and diversity of organisms become apparent even at the cellular level. The smallest organisms
consist of single cells and are microscopic.
 1.1 Cellular Foundations

Cells Are the Structural and Functional Units of All Living Organisms
1.1 Cellular Foundations
 1.1 Cellular Foundations

The Cell Membrane is a barrier to the free passage of inorganic ions and most other charged or polar
compounds. Transport proteins in the plasma membrane allow the passage of certain ions and molecules;
receptor proteins transmit signals into the cell; and membrane enzymes participate in some reaction pathways.
 1.1 Cellular Foundations
The internal volume enclosed by the plasma membrane, the cytoplasm is composed of an aqueous
solution, the cytosol, and a variety of suspended particles with specific functions.

Group study
 1.1 Cellular Foundations
- Most cells are microscopic, invisible to the unaided eye.
- Animal and plant cells are typically 5 to 100 mm in diameter, and many unicellular microorganisms are
only 1 to 2 mm long.

- Eukaryotic cells contain a variety of membrane-bounded organelles (mitochondria, chloroplasts) and large
particles (ribosomes, for example)
 1.1 Cellular Foundations

All living organisms fall into one of three large groups (domains) that define three branches of the evolutionary
▪ Eukaryotic
cells have a
variety of
membranous
organelles,
which can be
isolated for
study.
 1.1 Cellular Foundations
Cytoskeleton provides essentially support structures composed of numerous smaller proteins linked together. The
structure of cytoskeleton composed of microfilaments, intermediate filaments, and microtubules.

Endothelial cells from the bovine pulmonary artery. Bundles of
actin filaments called “stress fibers” are stained red;
microtubules, radiating from the cell center, are stained green;
and chromosomes (in the nucleus) are stained blue.

The cytoskeleton of animal cells is one of the most complicated and functionally versatile structures, involved in
processes such as endocytosis, cell division, intra-cellular transport, motility, force transmission, reaction to external
forces, adhesion and preservation, and adaptation of cell shape.
1.1 Cellular Foundations

The organic compounds from which most cellular materials
are constructed: the ABCs of biochemistry. Shown here are
(a) six of the 20 amino acids from which all proteins are built
(the side chains are shaded light red); (b) the five nitrogenous
bases, two five-carbon sugars, and phosphate ion from which
all nucleic acids are built; (c) five components of membrane
lipids; and (d) d-glucose, the simple sugar from which most
carbohydrates are derived. Note that phosphate is a
component of both nucleic acids and membrane lipids.
FIGURE 1–8 Subcellular fractionation of
tissue.
 1.2 Chemical Foundations
Biochemistry aims to explain biological form and function in chemical terms.

Elements essential to animal life and health. Bulk elements (shaded light red) are
structural components of cells and tissues and are required in the diet in gram quantities daily. For trace elements
(shaded yellow), the requirements are much smaller: for humans, a few milligrams per day of Fe, Cu, and Zn,
even less of the others. The elemental requirements for plants and microorganisms are similar to those shown
here; the ways in which they acquire these elements vary.
 1.2 Chemical Foundations

Biomolecules Are Compounds of Carbon with a Variety of Functional Groups
1.2 Chemical Foundations

Cells Contain a Universal Set of Small Molecules
 1.2 Chemical Foundations
▪ Macromolecules are the major constituents of cells.
 III. Physical Foundations
Living cells and organisms must perform work to stay
alive and to reproduce themselves. The synthetic reactions
that occur within cells, like the synthetic processes in any
factory, require the input of energy.

▪ Living Organisms Exist in a Dynamic Steady State, Never at
Equilibrium with Their Surroundings.
The constancy of concentration is the result of a dynamic steady
state, a steady state that is far from equilibrium. Maintaining this steady
state requires the constant investment of energy; when the cell can no
longer generate energy, it dies and begins to decay toward equilibrium
with its surroundings. We consider below exactly what is meant by
“steady state” and “equilibrium.”
▪ Organisms Transform Energy and
Matter from Their Surroundings.
▪ The Flow of Electrons Provides Energy for Organisms.

Nearly all living organisms derive their energy,
directly or indirectly, from the radiant energy of sunlight,
which arises from thermonuclear fusion reactions carried
out in the sun.
▪ Creating and Maintaining Order Requires Work and
Energy.

DNA, RNA, and proteins are informational
macromolecules. In addition to using chemical energy to form
the covalent bonds between the subunits in these polymers,
the cell must invest energy to order the subunits in their
correct sequence.
▪ Creating and Maintaining Order Requires Work and
Energy.
▪ Energy Coupling Links Reactions in Biology.
The central issue in bioenergetics (the study of energy
transformations in living systems) is the means by which energy from
fuel metabolism or light capture is coupled to a cell’s energy-requiring
reactions.

FIGURE 1–26a Energy coupling in mechanical and chemical
processes.
FIGURE 1–26b Energy coupling in mechanical and chemical
processes.
▪ Enzymes Promote Sequences of Chemical Reactions.

FIGURE 1–27 Energy changes during a chemical reaction.
FIGURE 1–28 The central roles of ATP and
NAD(P)H in metabolism.
▪ Metabolism Is Regulated to Achieve Balance and Economy.
Metabolism is the sum of many interconnected
reaction sequences that interconvert cellular metabolites.
Each sequence is regulated so as to provide what the cell
needs at a given time and to expend energy only when
necessary.
 IV. Genetic Foundations
▪ The Structure of DNA Allows for
Its Replication and Repair with
Near-Perfect Fidelity.

FIGURE 1–30 Complementarity between
the two strands of DNA.
▪ The Linear Sequence in DNA Encodes Proteins with Three-
Dimensional Structures.
 V. Evolutionary Foundations

Nothing in biology makes sense
except in the light of evolution.
—Theodosius Dobzhansky, The American Biology Teacher, March 1973
▪ Changes in the Hereditary Instructions Allow Evolution.

FIGURE 1–32 Gene duplication and
mutation: one path to generate new
enzymatic activities.
▪ Biomolecules First Arose by Chemical Evolution.
▪ Chemical Evolution Can Be Simulated in the Laboratory.

FIGURE 1–33 Abiotic production of
biomolecules. Spark-discharge apparatus
of the type used by Miller and Urey in
experiments demonstrating abiotic
formation of organic compounds under
primitive atmospheric conditions. After
subjection of the gaseous contents of the
system to electrical sparks, products were
collected by condensation. Biomolecules
such as amino acids were among the
products.
▪ RNA or Related Precursors May
Have Been the First Genes and
Catalysts.

FIGURE 1–34: A possible “RNA world”
scenario.
▪ Biological Evolution Began
More Than Three and a Half
Billion Years Ago.
▪ The First Cell Was Probably a
Chemoheterotroph.
▪ Eukaryotic Cells Evolved
from Prokaryotes in Several
Stages.

FIGURE 1–35 Landmarks in the evolution
of life on Earth.
FIGURE 1–36 Evolution of eukaryotes through endosymbiosis.