BBIO109 Lecture Notes: Nucleic Acids & Carbohydrates PDF

Summary

These lecture notes cover nucleic acids, including DNA and RNA, and their components. The document details the structure, function, and various aspects of these molecules. More specifically, it outlines the roles of nucleotides, sugars, and bases in nucleic acid formation.

Full Transcript

BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
NUCLEIC ACIDS except that there is
no hydroxyl (-OH)
on C2’. The deoxy
prefix means
“without oxygen
and provides D in
DNA

NUCELEOSIDES AND NUCLEOTIDES

 Nucleosides, which are a combination of a
 Nucleic acids are large molecules found in the sugar and a base, are produced when the
nuclei of the cells in our bodies that store nitrogen atom in a pyrimidine or a purine base
information and direct activities for cellular forms an N-glycosidic bond to carbon 1 (C1’) of
growth and reproduction. a ribose or deoxyribose sugar. For example,
 Components of Nucleic Acids adenine and ribose form a nucleoside called
o There are two closely related types of adenosine.
nucleic acids: deoxyribonucleic acid (DNA),
and ribonucleic acid (RNA).
o Both are unbranched polymers of repeating
monomer units known as nucleotides.
Each nucleotide has three components:
a base, a five-carbon sugar, and a
phosphate group

 Nucleotides are nucleosides in which a
phosphate group bonds to –OH on carbon 5
(C5’) of a ribose or deoxyribose sugar. The
product is a phosphate ester. Other hydroxyl
groups on ribose can form phosphate esters
too, but only the 5’-monophosphate
The nitrogen-containing bases in
nucleotides are found in RNA and DNA.
nucleic acids are derivatives of
pyrimidine or purine.

In RNA, the five-carbon sugar is ribose,
which gives the letter R in the
abbreviation RNA.
In DNA, the five-carbon sugar is
deoxyribose, which is similar to ribose
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
COMPONENTS IN DNA AND RNA PRIMARY STRUCTURE OF NUCLEIC ACIDS

 The nucleic acids are polymers of many
nucleotides in which the 3’-OH group of the
sugar in one nucleotide bonds to the phosphate
group on the 5’-carbon atom in the sugar of the
next nucleotide.
 This phosphate link between the sugars in
adjacent nucleotides is referred to as a
phosphodiester bond.
 As more nucleotides are added using
phosphodiester bonds, a backbone forms that
consists of alternating sugar and phosphate
groups. The bases, which are attached to each
sugar, extend out from the sugar-phosphate
backbone.

NAMING NUCLEOSIDES AND NUCLEOTIDES

 The name of a nucleoside that contains a purine
ends with osine whereas a nucleoside that
contains a pyrimidine ends with idine.
 The names of the nucleosides of DNA add deoxy  Each nucleic acid has its
to the beginning of their names. own unique sequence of
 The corresponding nucleotides in RNA and DNA bases, which is known as its
are named by adding -5’-monophosphate. primary structure.
 In any nucleic acid, the
sugar at the one end has an
unreacted or free 5’-
phosphate terminal end,
and the sugar at the other
end has a free 3’-hydroxyl
group.
 A nucleic acid sequence is read from the sugar
with free 5’-phosphate to the sugar with the free
3’-hydroxyl group.
Exercise!

Identify each of the following as a pentose sugar,
base, nucleoside, nucleotide, or nucleic acid and if
it is found in DNA, RNA, or both:

a. Guanine
b. deoxyadenosine-5’-monophosphate (dAMP)
c. Ribose
d. Cytidine
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
Draw the structure of the RNA dinucleotide formed Exercise!
by two cytidine-5’-monophosphates
Write the complementary base sequence for the
following DNA segment:

-A –C –G –A –T –C –T –

VIRUSES

 Viruses are small particles of 3 to 200 genes that
cannot replicate without a host cell. A typical virus
contains a nucleic acid, DNA or RNA, but not both,
inside a protein coat.
 The only way a virus can replicate is to invade a host
DNA DOUBLE HELIX cell and take over the materials necessary for
 # of Purine = # of Pyrimidine protein synthesis and growth
A=T
G=C
 In 1953, James Watson and Francis Crick
proposed that DNA was a double helix that
consists of two polynucleotide strands winding
about each other like a spiral staircase.
 The sugar-
phosphate
backbones are
analogous to
the outside
railings with the
bases arranged
like steps along
the inside. The
two strands run
in opposite
directions. One
strand goes
from the 5’ to 3’
direction, and
the other strand
goes in the 3’ to
5’ direction.
BBIO109 LECTURE NOTES
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REVERSE TRANSCRIPTION  HIV is a retrovirus that infects and destroys T4
lymphocyte cells, which are involved in the
 A virus that contains RNA as its genetic material immune response.
is a retrovirus. Once inside the host cell, it must
first make viral DNA using a process known as
reverse transcription.
 A retrovirus contains a polymerase enzyme
called reverse transcriptase that uses the viral
RNA template to synthesize complementary
strands of DNA.

 Treatment for AIDS is based on attacking the
HIV-1 at different points in its life cycle,
including reverse transcription and protein
synthesis.
 Nucleoside analogs mimic the structures of the
nucleosides used for DNA synthesis, which
 Once produced, the DNA strands form double inhibit the reverse transcriptase enzyme.
stranded DNA using the nucleotides present in
the host cell. This newly formed viral DNA,
called a provirus, integrates with the DNA of the
host cell.

 For example, the drug AZT (3’-azido-3’-
deoxythymidine) is similar to thymidine, and
ddI (2’,3’-dideoxyinosine) is similar to
guanosine. Two other drugs are ddC (2’,3’-
dideoxycytidine) and d4T (2’,3’-didehydro-2’,3’-
dideoxythymidine).
 When a nucleoside
analog is
incorporated into
viral DNA, the lack
of a hydroxyl group
on the carbon in
the sugar prevents
the formation of
ACQUIRED IMMUNE DEFICIENCY SYNDROME
the sugar-
(AIDS)
phosphate bonds
 An HIV-1 virus (human immunodeficiency virus and stops the replication of the virus.
type 1) is now known to be the AIDS-causing
agent.
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MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
 Treatment of CARBOHYDRATES
AIDS often
 Carbohydrates such as table sugar, lactose in
combines
milk, and cellulose are all made of carbon,
reverse
hydrogen, and oxygen
transcriptase
 Simple sugars, which have formulas of
inhibitors with
𝑪𝒏(𝑯𝟐𝑶)𝒏 were once thought to be hydrates of
protease inhibitors such as saquinavir
carbon, thus the name carbohydrate.
(Invirase), indinavir, lexiva (fosamprenavir),
 In photosynthesis, energy from the Sun is used
nelfinavir, and ritonavir. The inhibition of a
to combine the carbon atoms from carbon
protease enzyme prevents the synthesis of
dioxide and the hydrogen and oxygen atoms of
proteins used by viruses to make more copies.
water into carbohydrate glucose.
 In the body, glucose is oxidized in a series of
metabolic reactions known as respiration,
which releases chemical energy to do work in
the cells.

TYPES OF CARBOHYDRATES

MONOSACCHARIDES

 Monosaccharides are sugars that have a chain
of three to eight carbon atoms, one in a
carbonyl group and the rest attached to
hydroxyl groups.
 In an aldose,
the carbonyl
group is on the
1st carbon (-
CHO), an
aldehyde.
 In a ketose, the
carbonyl group
 UNDETECTABLE = UNTRANSMITTABLE
is on the 2nd
 HIV medicine can help you get and keep an
carbon atom as a ketone (C=O)
undetectable viral load.
 This means you can stay healthy and will not
transmit HIV to HIV-negative partners through
sex.
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
 In each of the mirror images, it is important to
understand that the –OH groups on all the chiral
carbon atoms are reversed from one side to the
other.

Triose – 3 Carbons Tetrose – 4 Carbons
Pentose – 5 Carbons Hexose – 6 Carbons

Let Us Check Your Understanding!

Classify each of the following monosaccharides as Let Us Check Your Understanding!
an aldopentose, aldohexose, ketopentose, or Identify the following Fischer projection as D-or L
ketohexose: xylose:

STRUCTURES OF SOME IMPORTANT
FISCHER PROJECTIONS OF MONOSACCHARIDES MONOSACCHARIDES

 A Fischer projection is drawn with vertical and  The hexoses glucose, galactose, and fructose
horizontal lines with aldehyde group at the top are the most important monosaccharides.
and –H and –OH groups on the intersecting line.

 The most common
 Most monosaccharides to be studied have 5-6 hexose, D-glucose, also
C w/ more than one chiral C. Then the –OH known as dextrose and
group on the chiral C farthest from the carbonyl blood sugar, is found in
group is used to determine the D or L isomer. fruits, vegetables, corn
syrup, and honey.

 D-glucose is a building block of the
disaccharides sucrose, lactose, and maltose,
and polysaccharides such as amylose,
cellulose, and glycogen.
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
 Galactose is an Let Us Check Your Understanding!
aldohexose that is
Ribulose has the following Fischer projection.
obtained from the
Identify the compound as D-or L-ribulose.
disaccharide
lactose, which is
found in milk and
milk products.
 The only difference
in the Fischer projections of D-glucose and D-
galactose is the arrangement of the –OH group
of carbon 4 HAWORTH STRUCTURES OF MONOSACCHARIDES
 In a condition called galactosemia, an enzyme
needed to convert galactose to glucose is  Molecules of monosaccharides normally exist
missing. in a cyclic structure formed when a carbonyl
 The accumulation of galactose in the blood and group and a hydroxyl group in the same
tissues can lead to cataracts, mental molecule react to give ring structures known as
retardation, and cirrhosis. Haworth structures.
 The most stable for of pentoses and hexoses
are five- or six atom rings.

DRAWING HAWORTH STRUCTURES

1. Turn the open-chain condensed structural
formula clockwise 90˚. This places the –OH
groups on the right of C2 and C4 (blue) and C5
(red) of the vertical open chain below the
carbon atoms. The –OH group on the left (green)
of the open chain is drawn above C3.

 Fructose, also called levulose and fruit sugar, is
a ketohexose.
 The structure of fructose differs at carbons 1 2. Fold the carbon chain into a hexagon and bond
and 2 by the location of the carbonyl group. the O on C5 to the carbonyl group. With C2 and
 Fructose is the sweetest of the carbohydrates, C3 as the base of a hexagon, move the
twice as sweet as sucrose remaining carbons upwards. The remaining –
OH group (red) on C5 is drawn next to the
carbonyl carbon, which moves C6 in -𝐶𝐻2𝑂𝐻
above C5. To complete the Haworth structure,
draw a bond from the O of the reacting –OH
group (C5) to the carbonyl carbon.
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
3. Draw the new –OH group on C1 down to give the at the right corner of the ring. The cyclic
α isomer or up to give β isomer. In a Haworth structure forms when the hydroxyl group on C5
structure, the corners of the ring represent reacts with C2 in the carbonyl group. The new
carbon atoms. There are two ways to draw the hydroxyl group on carbon 2 gives the α and β
new –OH, either up or down, which gives two isomers of fructose
possible stereoisomers of D-glucose.

MUTAROTATION OF α- AND β-D-GLUCOSE

 In an aqueous solution, the Haworth structure Let Us Check Your Understanding!
of α-D-glucose opens to give the open chain of
D-glucose with an aldehyde group. However, D-Mannose, a carbohydrate found in
when the open chain closes again it can form β- immunoglobulins, has the following open-chain
D Glucose. In this process called mutarotation, structure. Draw the Haworth structure for β-D-
each isomer converts to the open chain and Mannose.
back again. As the ring opens and closes, the –
OH group on C1 can form either the α or β
isomer

HAWORTH STRUCTURES OF GALACTOSE Answer!

 Galactose is an aldohexose that differs from
glucose only in the arrangement of the –OH
group on C4. It’s Haworth is similar to glucose
except that the –OH on C4 is drawn up. It also
exist as α and β isomers

CHEMICAL PROPERTIES OF MONOSACCHARIDES

 In an aldose, the aldehyde group can be
oxidized to a carboxylic acid. The carbonyl
group in both an aldose and a ketose can be
reduced to give a hydroxyl group. The hydroxyl
 Fructose is a ketohexose. The Haworth groups can react with other compounds to form
structure for fructose is a five-atom ring with C2
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
a variety of derivatives that are important in Glucose is reduced to D-glucitol, better
biological structures. known as D-sorbitol.
 Oxidation of Monosaccharides
o An aldehyde group with an adjacent
hydroxyl can be oxidized to a carboxylic
acid by an oxidizing reagent such as
Benedict’s reagent. Then, the 𝐶𝑢2+ is
reduced to 𝐶𝑢+, which forms a brick-red
precipitate of 𝑪𝒖𝟐𝑶. A carbohydrate that
reduces another substance is called a
reducing sugar.

o Sugar alcohols such as
D-sorbitol, D-xylitol
from D-xylose, and D-
mannitol from D-
mannose are used as
sweeteners in many
sugar-free products
o Fructose is also a reducing sugar. In such as diet drinks and
Benedict’s solution, which is basic, a sugarless gum as well
rearrangement occurs between the ketone as products for people
group on C2 and the hydroxyl group on C1. with diabetes.
As a result, fructose is converted to
glucose, which produces an aldehyde group
with an adjacent hydroxyl that can be Let Us Check Your Understanding!
oxidized

Answer!

 Reduction of Monosaccharides
o The reduction of the carbonyl group in
monosaccharides produces sugar
alcohols, which are also called alditols. D-
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
DISACCHARIDES  The glycosidic bond in maltose is designated as
an α-1,4 linkage to show that an α-OH on C1 is
 A disaccharide is joined to C4 of the 2nd Glucose molecule.
composed of two
monosaccharides
linked together. The
most common
disaccharides are
maltose, lactose,
and sucrose.
 Because the 2nd glucose molecule still has a
 When they are split
free –OH group on C1, it can form an open chain,
by water (hydrolysis)
which allows maltose to form both α and β
in the presence of an acid or an enzyme, the
isomers. The open chain provides an aldehyde
products are two monosaccharides.
group that can be oxidized, making maltose a
reducing sugar.

 Maltose, or malt sugar, is obtained from starch
and is found in germinating grains.
 When maltose in barley and other grains is
hydrolyzed by yeast enzymes, glucose is
obtained, which can undergo fermentation to
give ethanol.
 Maltose is used in cereals, candies, and the
brewing of beverages.

 Lactose, milk sugar, is a disaccharide found in
HAWORTH STRUCTURES OF DISACCHARIDES milk and milk products.
 In the Haworth  Lactose makes up 6–8% of human milk and
structure of a about 4–5% of cow’s milk, and it is used in
disaccharide, a products that attempt to duplicate mother’s
glycosidic bond is milk.
an ether bond that  Some people do not produce sufficient
connects two quantities of the enzyme lactase needed to
monosaccharides. hydrolyze lactose. Then lactose remains
undigested, which can cause abdominal
cramps and diarrhea.
 The bond in lactose is a
β-1,4- glycosidic bond
because the –OH group
 In maltose, a glycosidic bond forms between on C1 of β-D-galactose
the –OH groups of C1 and C4 of two α-D- forms a glycosidic
Glucose molecules with a loss of a water bond with the –OH
molecule. group on C4 of a D-
glucose molecule.
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
 Because D-glucose still has a free group on C1, HOW IS YOUR SWEETENER?
it can form an open chain, which allows lactose
 Although many of
to form both α and β isomers.
the
 Sucrose, a disaccharide obtained from sugar
monosaccharides
beets and sugar cane, contains glucose and
and disaccharides
fructose.
taste sweet, they
 The sugar we use to sweeten our cereal, coffee,
differ considerably
or tea is sucrose. Most of the sucrose for table
in their degree of
sugar comes from sugar cane (20% by mass) or
sweetness. Dietetic
sugar beets (15% by mass).
foods contain
 Both the raw and refined forms of sugar are
sweeteners that are
sucrose.
noncarbohydrate or
 Sucrose consists of an α-D-glucose and a β-D-
carbohydrates that are sweeter than sucrose.
fructose molecule joined by an α, β-1,2-
glycosidic bond. BLOOD TYPES AND CARBOHYDRATES
 Unlike maltose and lactose, the glycosidic
bond in sucrose is between C1 of glucose and  The blood types A,
C2 of fructose. B, and O are
 Thus, sucrose cannot form an open chain and determined by
cannot be oxidized and react with Benedict’s monosaccharides
reagent. So, it is not a reducing sugar. attached to the
surface of red
blood cells.
 The blood types,
A, B, and O, all
contain the
monosaccharides
N-
acetylglucosamine, galactose, and fucose.
 In type A, galactose is
bonded to N-
Let Us Check Your Understanding! acetylgalactosamine.
 In type B, the
Melibiose is a disaccharide that is 30 times sweeter galactose is bonded to
than sucrose. Melibiose has the following Haworth a second galactose.
structure:  In type AB, the
monosaccharides of
both blood types A and
B are found.

POLYSACCHARIDES
(a)What are the monosaccharide units in  A polysaccharide is a polymer of many
melibiose? monosaccharides joined together. Four
important polysaccharides— amylose,
(b)What type of glycosidic bond links the
amylopectin, cellulose, and glycogen – are all
monosaccharides?
polymers of D-glucose that differ only in the
(c)Identify the structure as α-or β-melibiose. type of glycosidic bonds and the amount of
branching in the molecule.
BBIO109 LECTURE NOTES
MOD 4-5: NUCLEIC ACIDS & CARBOHYDRATES MAGBANUA, KEILAH
 Starch, a storage form of glucose in plants, is
found as insoluble granules in rice, wheat,
potatoes, beans, and cereals.  In our bodies, these complex carbohydrates are
 Starch is composed of two kinds of digested by the enzymes amylase (in saliva) and
polysaccharides, amylose and amylopectin. maltase (in the intestine). The glucose obtained
provides about 50% of our nutritional calories.
 Glycogen, or animal starch, is a polymer of
glucose that is stored in the liver and muscle of
animals.
 In glycogen, the glucose units are joined by α-
1,4-glycosidic bonds, and branches occurring
about every 10-15 glucose units are attached by
α-1,6-glycosidic bonds

 Amylose, which makes up about 20% of starch,
consists of 250–4000 α-D-glucose molecules
connected by α-1,4-glycosidic bonds in a
continuous chain.
 Sometimes called a straight-chain polymer,
polymers of amylose are actually coiled in
helical fashion
 Cellulose is the major structural material of
wood and plants. Cotton is almost pure
cellulose. In cellulose, glucose molecules form
a long unbranched chain similar to that of
amylose.
 However, the glucose units in cellulose are
linked by β-1,4-glycosidic bonds.
 Humans have enzymes called α-amylase in
 Amylopectin, which makes up as much as 80% saliva and pancreatic juices that hydrolyze the
of starch, is a branched-chain polysaccharide. α-1,4 glycosidic bonds of starches, but not the
Like amylose, the glucose molecules are β-1,4-glycosidic bonds of cellulose. Thus,
connected by α-1,4-glycosidic bonds. humans cannot digest cellulose.
 However, at about every 25 glucose units, there  Animals such as horses, cows, and goats can
is a branch of glucose molecules attached by obtain glucose from cellulose because their
an α-1,6-glycosidic bond between C1 of the digestive systems contain bacteria that provide
branch and C6 in the main chain. enzymes such as cellulase to hydrolyze β-1,4-
glycosidic bonds.

Let Us Check Your Understanding!

Identify the polysaccharide described by each of
the following:

(a) a polysaccharide that is stored in the liver and
muscle tissues
(b) an unbranched polysaccharide containing β-1,4-
 Starches hydrolyze easily in water and acid to
glycosidic bonds
give dextrins, which then hydrolyze to maltose (c) a starch containing α-1,4-and α-1-6-glycosidic
and finally glucose. bonds
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