Biochemistry For Dental Students PDF

Summary

These are lecture notes on biochemistry for dental students given by Said El Shamieh at Beirut Arab University. The topics covered include an introduction to biochemistry, the distinguishing features of living organisms, the classification of organisms, and enzymes.

Full Transcript

8/31/2022

Biochemistry For Dental Students

Said El Shamieh, Msc |PhD.
Associate Professor of Human Genetics
Faculty of Health Sciences, Beirut Arab University

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Beirut Arab University
Biochemistry For Dental Students

CHAPTER 1
The Foundations of Biochemistry

Lectures notes prepared by:
Said El Shamieh, PhD | MSc.
Dr. Said El Shamieh 3

Introduction
About four billion years ago, life arose, simple microorganisms
with the ability to extract energy from chemical compounds and,
later, from sunlight, which they used to make a vast array of more
complex biomolecules from the simple elements and compounds
on the Earth’s surface.

Biochemistry studies the distinguishing features of living
organisms arising from the thousands of different biomolecules.

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What are these distinguishing features of living organisms?

Pancreatic cell section
A high degree of chemical complexity and microscopic
organization.

Systems for extracting, transforming, and using energy from
the environment.

Mechanisms for sensing and responding to alterations in their
surroundings.

A capacity for precise self-replication and self-assembly.

A capacity to change over time by gradual evolution.
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Cellular Foundation

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Three distinct domains of life

All living organisms fall into one of three large domains that define three branches.
Two large groups of single-celled microorganisms: Bacteria and Archaea.

1. Bacteria :
lack a membrane-bounded nucleus and mitochondria, are surrounded by a cell wall, and
divide by binary fission.
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Three distinct domains of life
2. Eukarya:
Organisms whose cells contain an elaborate network of internal membranes, a membrane-
bounded nucleus, and mitochondria.
Their DNA is organized into true chromosomes, and cell division takes place by means of
mitosis.

3. Archaea
Produce methane gas or that live in extreme environments (hot springs or high salt
concentrations).
Lack internal membranes.
Machinery for DNA replication and transcription resembles that of eukaryans, whereas their
metabolism strongly resembles that of bacteria.

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Structural hierarchy in the molecular organization of cells.

The organelles and other relatively large components of cells are composed of
supramolecular complexes, which in turn are composed of smaller
macromolecules and even smaller molecular subunits. 9
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CHEMICAL FOUNDATION

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Biochemistry aims to explain biological form and function in
chemical terms.

< 30 of the naturally occurring chemical elements are essential to organisms.
The four most abundant elements in living organisms; H, O, N and C which together make up
more than 99% of the mass of most cells.
Bulk elements are structural components of cells and tissues and are required in the diet in gram
quantities daily.
For trace elements, the requirements are much
Dr. Said Elsmaller:
Shamieh for humans, a few milligrams per
11 day of
Fe, Cu, and Zn, even less of the others.

Proteins
Long polymers of amino acids, constitute the largest fraction (besides water)
of a cell.

Some proteins have catalytic activity and function as enzymes; others serve
as structural elements, or transporters that carry specific substances into or
out of cells.

The most versatile of all biomolecules.

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Nucleic acids

DNA and RNA, are polymers of nucleotides.

Store and transmit genetic information, and some RNA
molecules

Have structural and catalytic roles in supramolecular
complexes.

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Polysaccharides

Polymers of simple sugars such as glucose, have
three major functions:

Energy-rich fuel stores,

Rigid structural components of cell walls (in plants and
bacteria).

Extracellular recognition elements that bind to proteins on
other cells.

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Lipids

Water-insoluble hydrocarbon derivatives.
Serve as structural components of membranes.
Energy-rich fuel stores.
Pigments.
Intracellular signals.

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Biomolecules Are Compounds of Carbon with a Variety of Functional Groups

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Biomolecules Are Compounds of Carbon with
a Variety of Functional Groups

The chemistry of living organisms is organized around carbon, which
accounts for more than half the dry weight of cells.

Carbon can form single bonds with hydrogen atoms, and both single and
double bonds with oxygen and nitrogen atoms.

Most biomolecules can be regarded as derivatives of hydrocarbons, with
hydrogen atoms replaced by a variety of functional groups:
Alcohols (>=1 hydroxyl groups)
Amines, with amino groups
Aldehydes and ketones
Carboxylic acids
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Several functional groups in a single biomolecule

Many biomolecules are polyfunctional, containing two or more types of functional groups each
with its own chemical characteristics and reactions.
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Interactions between Biomolecules Are Stereospecific
(specific in regard to the 3D )

Complementary fit between a
macromolecule and a small molecule

When biomolecules interact, the “fit” between them must be stereochemically correct.
reactant with its enzyme, hormone with its receptor on a cell surface, antigen with its
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specific antibody.

Stereoisomers have different effects in humans

Same molecular formula, but a different chemical structure.
Why do stereoisomers have different effects in humans ?
The ability to distinguish between stereoisomers, is a property of enzymes and other proteins and
a characteristic feature of the molecular logic of living cells.
If the binding site on a protein is complementary to one isomer of a chiral compound, it will not be
complementary to the other isomer, for the Dr.same
Said Elreason
Shamieh that a left glove does not fit a right
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Physical Foundations
The first law of thermodynamics describes the principle of the conservation of
energy: in any physical or chemical change, the total amount of energy in
the universe remains constant, although the form of the energy may
change.

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Classification
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of Organisms
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Classification of Organisms

All organisms can be classified according to their source of energy (sunlight or
oxidizable chemical compounds) and their source of carbon for the synthesis of
cellular material.

Two broad categories based on energy sources: phototrophs trap and use
sunlight, and chemotrophs derive their energy from oxidation of a chemical fuel.

Phototrophs and chemotrophs may be further divided into those that can
synthesize all of their biomolecules directly from CO2 (autotrophs) and those
that require some preformed organic nutrients made by other organisms
(heterotrophs).

Cyanobacteria are photoautotrophs; humans are chemoheterotrophs.
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The central roles of ATP and
NAD(P)H in metabolism.

ATP:
Shared chemical intermediate linking energy-releasing
and energy-consuming cellular processes.

Produced in exergonic reactions and consumed in
endergonic ones.

NAD(P)H:
cofactor that collects electrons.

Essential to anabolic reactions must be constantly
regenerated by catabolic reactions.

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Enzymes
Enzymes are biocatalysts.

Proteins can be hydrolyzed with hydrochloric acid by boiling for a
very long-time; but inside the body, with the help of enzymes,
proteolysis takes place within a short-time at body temperature.

The substance upon which an enzyme acts, is called the substrate.

The enzyme will convert the substrate into the product or products.

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I. Characteristics of enzymes

2. Enzymatic reactions are highly specific, both for the substrate and for
the reaction type.

3. Enzymatic reactions are carried out in relatively mild conditions
(neutral pH, low temperature, etc.).

4. Enzymatic reactions can be modulated. The regulation of enzyme
activity can be carried allosterically, by regulatory proteins, by a covalent
modification of the enzyme, by a proteolytic activation, by the amount of
enzyme produced, etc.

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II. Nomenclature: The name of the enzymes most often consists of a radical closest to the
substrate or product of catalysis followed by the suffix "ase".

1. oxidation - reduction reaction

2. transfers functional groups

3. hydrolytic reactions

4. elimination reaction to form

5. Isomerization

6. forming bonds with ATP hydrolysis

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The active site
Enzyme function is linked to the presence in their structure of a particular site called
the active site.

Schematically, it has the shape of a cavity or a furrow in which the substrates will
bind through several weak chemical bonds.

Once attached, the substrates will react and turn into product.

The active site is divided into two parts:

- Binding site / fixation/ recognition: it recognizes the complementarity of shape with
a specific substrate for the enzyme;

- Catalytic site: it allows the reaction that converts the substrate to product.
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Cofactores
Enzymes may be simple proteins, or complex enzymes, containing a non-protein
part, called Cofactors.

Other enzymes have two parts: an inactive protein part called apoenzyme and a
cofactor, which together form an holoenzyme.

Essential for the biological activity of the enzyme. A coenzyme is a low molecular
weight organic substance, without which the enzyme cannot exhibit any reaction.

Divided into:
(a) Those taking part in reactions catalyzed by oxidoreductases by donating or
accepting hydrogen atoms or electrons.
(b) Those coenzymes taking part in reactions transferring groups other than hydrogen.

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First Group of Cofactors

Nicotinamide Adenine Dinucleotide (NAD+)

The reversible reaction of lactate to pyruvate is catalyzed by the enzyme lactate
dehydrogenase, but the actual transfer of hydrogen is taking place on the
coenzyme, NAD+.
Two hydrogen atoms are removed from lactate, and two electrons are accepted
by the NAD+ to form NADH, and the remaining H+ is released into the
surrounding medium. The hydrogen is accepted by the nicotinamide group.

Lactate Dehydrogenase
O O− O O−
C NADH + H+ NAD+ C
C O HC OH
CH3 CH3
pyruvate Dr. Said El Shamieh lactate 57

Second Group of Coenzymes
Adenosine Triphosphate (ATP)

The energy currency in the body. During the oxidation of food stuffs, energy
is released, a part of which is stored as chemical energy in the form of ATP.

The second and third phosphate bonds are ‘high energy' bonds.

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VI. Factors influencing enzyme activity
1. Temperature

For temperatures between 10 and 40°C, enzymatic reaction see its rate of reaction increase.
Each enzyme is characterized by an optimal temperature at which its activity is maximal.

The enzymes are proteins, they are denatured from a certain temperature (around 40-60°C).
The loss of the three-dimensional structure results in a loss of function and therefore a drop in
enzyme activity.

Optimal temperature

Activation curve
Denaturation curve

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2. pH

Example: digestive enzymes.

The enzymes to digest food have different optimal pH to suit the pH conditions in the lumen of
the different stages of the digestive tract.

Thus the activity of pepsin is maximum for a very acidic environment like the stomach where
it is secreted.

In contrary, pancreatic enzymes such as amylase and trypsin, have an optimum pH more
alkaline action, because the duodenum where they exercise their activity pH is normally close
to 8.

Example : Trypsin

optimum pH range
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3. Concentrations of enzyme, substrate and product

The more the substrate concentration, the higher the reaction speed, until all
of the active sites are occupied (saturation).

The only way to increase the reaction rate when there is saturation of the
enzymes is to increase the enzyme concentration.

When the concentration of product is too high, the reaction rate decreases as
in any chemical reaction.

4. Presence of cofactors

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5. Effectors : Presence of activators or inhibitors

An effector is a chemical substance that modifies the enzymatic activity, that is to say, the
kinetics of an enzyme reaction.

Effectors have :

- A reversible effect that manifests itself only in the presence of the effector and disappears
at its elimination;

- An irreversible effect that can increase with the time of contact between the enzyme and
the effector and persist after its removal.

There are 2 types of effectors:

- an activator is an effector which increases the enzymatic activity.

- An inhibitor is a substance that decreases the rate of a biochemical reaction.
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Various types of inhibitors

Two types of inhibition: competitive inhibition and non-competitive inhibition.

A competitive inhibitor is a molecule with a structural similarity to the substrate, so it can compete with
the substrate to occupy the active site of the enzyme.

Examples: medication (sulfonamides).

An non-competitive inhibitor binds elsewhere of the enzyme active site, causing a conformational
change in the enzyme which decreases or stops the enzymatic activity.

Inhibitors may be of 2 types:

- irreversible inhibitors (covalent). The inhibitor
may not dissociate from the enzyme.

- reversible inhibitors also called Michaeliens
effectors.
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ENZYMES

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VIII. Isoenzymes
Isoenzymes are enzymes having a different sequence of amino acids but catalyze
the same chemical reaction.

These enzymes usually have different kinetic parameters or different regulatory
properties.

The existence of isozymes allows a better adaptation to metabolism to meet the
needs of a particular tissue or stage of development.

Examples: creatine kinase (CK): composed of 2 subunits: M or B
3 isoenzymes:
- CK-MM (muscle);
- CK-MB (heart);
- CK-BB (brain)

In case of myocardial infarction, only CK-MB increases in blood (release of their
contents by necrotic heart cells). Dr. Said El Shamieh 65

Clinical Enzymology

i. Plasma contains many functional enzymes which are actively
secreted into plasma (e.g: enzymes of blood coagulation).

ii. On the other hand, there are a few nonfunctional enzymes in
plasma, which are coming out from cells of various tissues. Their normal
levels in blood are very low; but are drastically increased during cell
death (necrosis) or disease.

-> Assays of these enzymes are very useful in diagnosis of diseases.

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Lactate Dehydrogenase (LDH)

LDH enzyme is a tetramer with 4 subunits. But the subunit may be
either H (heart) or M (muscle) polypeptide chains.

M4 form is seen in skeletal muscles; while H4 form is seen in heart.

In myocardial infarction, LDH activity is increased. Within a few hours
after the heart attack, the enzyme level starts to increase, reaches a
peak on the 5th day, and reaches normal levels by 10-12 days.

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Creatine Kinase (CK)

Dimer.
The subunits are B for brain and M for muscle.
-> 3 isoforms are seen in circulation:
MM is originating from skeletal muscles.
MB is from heart
BB is from brain.
Value in serum is increased in myocardial infarction.
Level starts to rise within 3 hours of infarction.
-> very useful to detect early cases, where ECG changes may be
ambiguous.

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Alanine Amino Transferase (ALT/SGPT)
i. Normal serum level of ALT is 10-30 U/L.

ii. Very high values (100 to 1000 U/L) are seen in acute
hepatitis, either toxic or viral in origin.

iii. Both ALT and AST levels are increased in liver disease, but
ALT >> AST. Rise in ALT levels may be noticed several days
before clinical signs such as jaundice are manifested.

iv. Moderate increase (25 to 100 U/L) may be seen in chronic
liver diseases such as cirrhosis, and malignancy in liver.

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Alkaline Phosphatase (ALP)
i. ALP is a nonspecific enzyme. optimum pH is between 9 and 10.

ii. It is produced by osteoblasts of bone, and is associated with the
calcification process.

iii. Moderate increase (2-3 times) in ALP level is seen in hepatic
diseases such as infective hepatitis, alcoholic hepatitis or hepatocellular
carcinoma.

iv. Very high levels of ALP (10-12 times of upper limit) may be noticed
in bone diseases.
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