BIO 202_ General Physiology I (FULOKOJA).docx

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**BIO 202: GENERAL PHYSIOLOGY (2 UNITS)**

**PHOTOSYNTHESIS**

Literally photosynthesis is synthesis with the help of light. It can
also be defined as the process by which the green plants synthesis
organic matter in the presence of light. It is represented by this
equation:

6CO2 + 6H2O → C6H12O6 + 6O2

During the process of photosynthesis, light energy is converted into
chemical energy and is stored as organic matter (carbohydrate) along
with O2 as the end product of photosynthesis. CO2 and H2O constitute the
raw material for the process and it is an anabolic process.

**History of Photosynthesis**

a\. Van Helmont (1648) proposed that increase in weight of willow tree
come from water alone.

b\. Stephan Hales (1727) pointed out that plants obtained a part of their
nutrition from the air and that sunlight plays a role.

c\. Priestley (1772) proposed that plants might restore the air laden
with CO2 by the burning of candles

d\. Ingen Houz (1779) noticed that only the green parts of plant can
purify the air in the presence of sulight.

e\. Jean Senebier (1783) observed that the air-purifying activities of
plants depend on the presence of CO2.

f\. Nicolas Theodore de Saussure (1804) concluded that CO2 and water must
constitute the raw material for this process.

g\. Meyer (1845) recognized the role of light as a source of energy for
the process.

h\. Julius Sachs (1862) proved that the process of photosynthesis takes
place in the chloroplasts and result in the production of organic
matter.

**Importance of Photosynthesis to Man**

a\. It provides food directly to man and indirectly as meat or milk of
animal.

b\. It maintains equilibrium of O2 in the atmosphere.

c\. It provides least resources of energy to man as fuel such as coal,
oil, wood and dung.

***Questions:***

***Mention four scientists that worked on photosynthesis***

***What are the four conditions necessary for photosynthesis?***

**Photosynthetic Pigments**

There are three types of photosynthetic pigments:

a\. Chlorophylls

b\. Carotenoids

c\. Phycobillins

i. Chlorophylls and carotenoids are insoluble in water and can be
extracted only with organic solvents.

ii. Phycobillins are soluble in water.

iii. Carotenoids include carotenes and Tanthophylls (carotenols).

iv. Different pigment absorbs light of different wavelength and show
characteristics absorption peak in vivo and in vitro.

v. Pigments also show florescence property.

**Absorption and Utilization of Light Energy By Photosynthetic
Pigments**

Sun is the chief source of light energy for photosynthesis. The plant
receives only 40% of the total solar energy, the rest is either absorbed
by the atmosphere or is scattered into the space.

Not all the light energy falling on green parts of plants is absorbed
and utilized by pigments. Some of the light is reflected, some is
transmitted through the plants while only a small portion is absorbed by
the pigments.

Photosynthetic pigment absorb light energy only in the visible part of
the spectrum ranging usually between 400-700mμ (nm). Such radiations are
called Photosynthetically Active Radiations (PAR).

Only about 1% of the total solar energy received by the earth is
absorbed by the pigments and is utilized in photosynthesis.

There is very weak absorption by pigments in green part of the spectrum,
thus, the chloroplast appears green in green plants.

Q: *What is the main source of energy in photosynthesis?*

**Mechanisms of Photosynthesis**

The process of photosynthesis is the oxidation of water and reduction of
CO2. The mechanism of photosynthesis consists of two parts:

1\) Primary photochemical reaction or light reaction or Hill's reaction.

2\) Dark reaction or black man's reaction or part of carbon in
photosynthesis.

**A. Light reaction or Hill's reaction**

Light reaction which is faster than the dark reaction takes place only
in the presence of lipids in the grains portion of the chloroplasts. The
reaction follows these steps:

i\. Different chloroplast pigments absorb light in different regions of
the visible part of the spectrum.

ii\. The light energy absorbed by the pigments is transferred by
resonance to chlorophyll-a which alone takes place in the light
reaction.

iii\. The chlorophyll becomes an excited molecule having more energy than
the ground state energy. It is this excited form of Chlorophyll-a that
takes part in the light reaction. It expels its energy along with an
electron and a positive charge comes on the chlorophyll-a which is now
oxidized.

iv\. When pigment system II is active, that is, it receives light, the
water molecules split into OH- and H+ ions (photolysis of water). The
OH- ions unite to form some water molecules again and release O2
electrons

4H2O → 4H^-^ + 4(OH^-^)

4(OH) → 2H2O + O2 + 4^e-^

2H2O → 4H^+^ + O2 + 4^e-^

v\. The electron released by the excited chlorophyll-a travels through a
number of electron carrier system where it is either recycled or
consumed in reducing NADP to NADPS + H+. The extra light energy carried
by the electron is utilized in the formation ATP molecules at certain
places during its transport. This process of the formation of ATP from
ADP and inorganic phosphate (Pi) in photosynthesis is called
PHOSPHORYLATION or PHOTOPHORYLATION.

**Dark reaction / Black man's reaction**

The dark reaction of photosynthesis is purely enzymatic and slower than
the light reaction or primary photochemical reaction. It takes place in
stroma portion of the chloroplast and is independent of light, that is,
it can place either in presence or absence of light provided the
assimilatory power is available.

It involves the conversion of CO2 to carbohydrate with the help of
assimilatory power (NADPH + H+ and ATP) in dark reaction.

By using ^14^C labeled carbon(IV)oxide (^14^CO2) in photosynthesis and
observing the appearance of characteristics radiation in different
reaction intermediates and products, Calvin Melvin and others formulated
the complete pathways of carbon assimilation in the form of a cycle
called Calvin cycle.

*Q: Mechanism of photosynthesis involves what two reactions?*

**Summary**

Photosynthesis is the process by which green plants synthesize organic
matter in presence of sunlight. During the process, the light energy is
converted to chemical energy and is stored in organic matter which is
usually carbohydrate and oxygen.

**The Calvin Cycle (C3 Pathway)**

The following steps are followed in Calvin cycle:

a\. Carboxylation- the CO2 is accepted by ribulose 1,5-biphospahte (RUBP)
already present in the cells and an unstable 6-carbon addition is
formed. The 6-carbon compound is hydrolysed into 2 molecules of
3-phosphoglyceric acid (3PGA).

b\. Reduction- 3PGA is reduced to 3-phosphoglyceraldehyde by the
assimilatory power in the presence of triose phosphate dehydrogenate.

c\. Formation of hexose sugar and regeneration of RUBP- some molecules of
3-phosphoglyceraldehyde isomerise into dihydroxyacetone phosphate, which
unite in the presence of aldolase to form fructose 1,6-biphosphate.

d\. Fructose 1, 6-biphosphate is converted into fructose 6-phospahte in
the presence of phosphatase.

e\. The fructose 6-phosphate (Hexose sugar) is taken off the Calvin cycle
and is converted into glucose, sucrose of starch.

f\. Some of the molecules of 3-phosphoglyceraldehyde produced in step (b)
are diverted ton regenerate ribulose 1,3-biphosphate.

The first visible product of Calvin cycle is 3-phosphoglyceride acid
which is a 3-C compound. Hence it is also called C3 pathway or PCR
(photosynthetic carbon reduction) pathway. Calvin cycle is also known as
Reductive Pentose Phosphate (RPP) cycle.

*Q: What is the first product of the Calvin Cycle?*

**C4 --Dicarboxylic Acid Pathway (Hatch-Slack Pathway)**

For many years the Calvin cycle was thought to be the only
photosynthetic reaction sequence operating in higher plants and algae.
But in 1965 Kortschak, Hartt and Burr reported that 4-C containing
dicarboxylic acids, malate and aspertase where major labeled products
when sugarcane leaves were allowed to photosynthesize for short period
of time in ^14^CO2. It was thus established that CO2 reduction has
another pathway which is called Hatch-Slack pathway and because C4
dicarboxylic acids are the earliest product, it is also called C4
dicarboxylic acid pathway.

Plants using this pathway (c4 plants) are sugarcane, maize, sorghum,
amaranthus. These plants are different from other plants by

i\. Absence of photo-respiration

ii\. Anatomical similarities of the leaves (cane type)

The anatomy of the C4 plants is also called Krantz' anatomy because of
the presence of partially arranged cells of bundle sheath around their
vascular bundle which look like a ring or wreath.

Steps in Hatch-Slack pathway involves 2 carboxylation reactions, one
taking place in chloroplasts of mesophyll cells and another in
chloroplast of bundle sheath cells. Hatch-Slack pathway is significant
in

i\. It is a modification of Calvin cycle and beneficial for growing
plants in tropical vegetation where Co2 concentration is reduced.

ii\. It is adaptation to plants due to plants due to reduction in CO2
concentration in the atmosphere due to photosynthesis.

iii\. It proves existence of alternative pathway to Calvin cycle.

**Factors Affecting Photosynthesis**

The rate of photosynthesis is affected by external and internal factors

A. External factors

i\. Light

ii\. Temperature

iii\. CO2

iv\. Water

v\. O2

B. Internal factors

i\. Chlorophyll content

ii\. Protoplasmic factors

iii\. Anatomy of leave

iv\. Accumulation of end product of photosynthesis

v\. Microstructure of chloroplasts.

*Q: List three examples of C4 plants.*

**Question**: *List five external factors affecting photosynthesis*

**Answer**: *Light, temperature, oxygen, water, carbon (IV) oxide*

**PROTEINS**

**What are Proteins?**

Proteins are known as the building blocks of life because they are the
most abundant molecules present in the body and form about 60% of the
dry weight of cells. They make up the majority of the cells in all
living things. Aside from cells, proteins make up the majority of the
body's structural, regulatory, and enzyme components. They are therefore
crucial for an individual's [growth and
development](https://byjus.com/biology/growth-development/). Food like
eggs, pulses, milk and other milk products form the major high-protein
foods for the body.

**Composition of Proteins**

Proteins are composed of:

- Amino acids (building blocks of proteins)

- Carbon

- Hydrogen

- Oxygen

- Nitrogen

- Sulfur (in some proteins)

**Structure of Proteins**

The structure of proteins is organized in a hierarchical manner:

1. **Primary Structure**: sequence of amino acids

2. **Secondary Structure**: local arrangements of amino acids (alpha
helices, beta sheets)

3. **Tertiary Structure**: overall 3D shape of a single protein
molecule

4. **Quaternary Structure**: arrangement of multiple protein molecules
(subunits)

A polymeric chain of amino acid residues constitutes proteins. A
protein's structure is primarily made up of long chains of amino acids.
The arrangement and placement of amino acids give proteins certain
characteristics. All [amino
acid](https://byjus.com/biology/amino-acids/) molecules contain an amino
(-NH2) and a carboxyl (-COOH) functional group. Hence, the name
"Amino-Acid".

Polypeptide chains are synthesized by linking together amino acids. A
protein is created when one or more of these chains fold in a specific
way. Methane is substituted by amino acids, with hydrogen, amino groups,
carboxyl groups, and a variable R- group filling the first three
valencies of the -- alpha carbon.\
There are many sorts of amino acids depending on the R-group, and a
polypeptide chain contains 20 of them. The final structure and purpose
of proteins are determined by all these characteristics of amino acids.

The structure of the protein is classified at 4 levels:-

- **Primary** -- The primary structure of a protein is the linear
polypeptide chain formed by the amino acids in a particular
sequence. Changing the position of even a single amino acid will
result in a different chain and hence a different protein.

- **Secondary** -- The secondary structure of a protein is formed by
hydrogen bonding in the polypeptide chain. These bonds cause the
chain to fold and coil in two different conformations known as the
α-helix or β-pleated sheets. The α-helix is like a single spiral and
is formed by hydrogen bonding between every fourth amino acid. The
β-pleated sheet is formed by hydrogen bonding between two or more
adjacent polypeptide chains.

- **Tertiary** -- The tertiary structure is the final 3-dimensional
shape acquired by the polypeptide chains under the attractive and
repulsive forces of the different R-groups of each amino acid. This
is a coiled structure that is very necessary for protein functions.

- **Quaternary** -- This structure is exhibited only by those proteins
which have multiple polypeptide chains combined to form a large
complex. The individual chains are then called subunits.


**Structure of Proteins**

**Properties of Proteins**

- **Solubility**: ability to dissolve in water or other solvents

- **Viscosity**: thickness and flowability

- **Conductivity**: ability to conduct electricity

- **Optical activity**: ability to rotate plane-polarized light

- **Stability**: resistance to changes in temperature, pH, and other
environmental factors

**Functions of Proteins**

Proteins perform a wide range of functions in the body, including:

- **Enzymes**: catalyze chemical reactions

- **Structural proteins**: provide structure and support (e.g.,
collagen, keratin)

- **Transport proteins**: carry molecules or ions across cell
membranes (e.g., hemoglobin)

- **Defense proteins**: help fight off pathogens (e.g., antibodies)

- **Storage proteins**: store and release nutrients (e.g., casein in
milk)

- **Hormones**: regulate various bodily functions (e.g., insulin,
growth hormone)

- **Receptor proteins**: receive and respond to signals from other
molecules

- **Digestion** -- The digestive enzymes, which are primarily
proteinaceous in origin, carry out digestion.

- **Movement** -- Muscles include a protein called myosin, which helps
muscles contract, allowing for movement.

- **Structure and Support** -- The structural protein known as keratin
is what gives humans and other animals hair, nails, and horns.

- **Cellular communication** -- Through receptors on their surface,
cells can communicate with other cells and the outside world. These
receptors are made of proteins.

- **Act as a messenger** -- These proteins serve as chemical
messengers that facilitate communication among cells, tissues, and
organs.

The amino acids present in proteins differ from each other in the
structure of their side (*R*) chains. The simplest amino acid
is [glycine](https://www.britannica.com/science/glycine-amino-acid), in
which *R* is a hydrogen atom. In a number of amino acids, *R* represents
straight or
branched [carbon](https://www.britannica.com/science/carbon-chemical-element) chains.
One of these amino acids
is [alanine](https://www.britannica.com/science/alanine), in
which *R* is the [methyl
group](https://www.britannica.com/science/methyl-group) (―CH~3~). [Valine](https://www.britannica.com/science/valine), [leucine](https://www.britannica.com/science/leucine),
and [isoleucine](https://www.britannica.com/science/isoleucine), with
longer *R* groups, complete the alkyl side-chain series. The alkyl side
chains (*R* groups) of these amino acids are nonpolar; this means that
they have
no [affinity](https://www.merriam-webster.com/dictionary/affinity) for [water](https://www.britannica.com/science/water) but
some affinity for each other. Although plants can form all of the alkyl
amino acids, animals can synthesize only alanine and glycine; thus
valine, leucine, and isoleucine must be supplied in the diet.

Two amino acids, each containing three carbon atoms, are derived from
alanine; they
are [serine](https://www.britannica.com/science/serine) and [cysteine](https://www.britannica.com/science/cysteine).
Serine contains
an [alcohol](https://www.britannica.com/science/alcohol) group
(―CH~2~OH) instead of the methyl group of alanine,
and [cysteine](https://www.britannica.com/science/cysteine) contains a
mercapto group (―CH~2~SH). Animals can synthesize serine but not
cysteine or [cystine](https://www.britannica.com/science/cystine).
Cysteine occurs in proteins predominantly in its oxidized form
(oxidation in this sense meaning the removal of hydrogen atoms), called
cystine. Cystine consists of two cysteine molecules linked by the
disulfide bond (―S―S―) that results when a hydrogen atom is removed from
the mercapto group of each of the cysteines. Disulfide bonds are
important in protein structure because they allow the linkage of two
different parts of a protein molecule to---and thus the formation of
loops in---the otherwise straight chains. Some proteins contain small
amounts of cysteine with free sulfhydryl (―SH) groups.

Four amino acids, each consisting of four carbon atoms, occur in
proteins; they are [aspartic
acid](https://www.britannica.com/science/aspartic-acid), [asparagine](https://www.britannica.com/science/asparagine), [threonine](https://www.britannica.com/science/threonine),
and [methionine](https://www.britannica.com/science/methionine).
Aspartic [acid](https://www.britannica.com/science/acid) and asparagine,
which occur in large amounts, can
be [synthesized](https://www.britannica.com/dictionary/synthesized) by
animals. [Threonine](https://www.britannica.com/science/threonine) and [methionine](https://www.britannica.com/science/methionine) cannot
be synthesized and thus are essential amino acids; i.e., they must be
supplied in the diet. Most proteins contain only small amounts of
methionine.

Proteins also contain an amino acid with five carbon atoms (glutamic
acid) and a secondary amine
(in [proline](https://www.britannica.com/science/proline)), which is a
structure with the amino group (―NH~2~) bonded to the alkyl side chain,
forming a ring. [Glutamic
acid](https://www.britannica.com/science/glutamic-acid) and aspartic
acid are dicarboxylic acids; that is, they have two carboxyl groups
(―COOH). 

[Glutamine](https://www.britannica.com/science/glutamine) is similar to
asparagine in that both are the amides of their corresponding
dicarboxylic acid forms; i.e., they have an amide group (―CONH~2~) in
place of the carboxyl (―COOH) of the side chain. Glutamic acid and
glutamine are abundant in most proteins; e.g., in plant proteins they
sometimes [comprise](https://www.merriam-webster.com/dictionary/comprise) more
than one-third of the amino acids present. Both glutamic acid and
glutamine can be synthesized by animals.



The amino acids proline
and [hydroxyproline](https://www.britannica.com/science/hydroxyproline) occur
in large amounts
in [collagen](https://www.britannica.com/science/collagen), the protein
of the [connective
tissue](https://www.britannica.com/science/connective-tissue) of
animals. Proline and hydroxyproline lack free amino (―NH~2~) groups
because the amino group is enclosed in a ring structure with the side
chain; they thus cannot exist in a zwitterion form. Although the
nitrogen-containing group (\>NH) of these amino acids can form a peptide
bond with the carboxyl group of another amino acid, the bond so formed
gives rise to a kink in the peptide chain; i.e., the ring structure
alters the regular bond angle of normal peptide bonds.

Proteins usually are almost neutral molecules; that is, they have
neither acidic nor basic properties. This means that the acidic carboxyl
( ―COO^−^) groups of aspartic and glutamic acid are about equal in
number to the amino acids with basic side chains. Three such basic amino
acids, each containing six carbon atoms, occur in proteins. The one with
the simplest
structure, [lysine](https://www.britannica.com/science/lysine), is
synthesized by plants but not by animals. Even some plants have a low
lysine
content. [Arginine](https://www.britannica.com/science/arginine) is
found in all proteins; it occurs in particularly high amounts in the
strongly basic protamines (simple proteins composed of relatively few
amino acids) of fish sperm. The third basic amino acid
is [histidine](https://www.britannica.com/science/histidine). Both
arginine and histidine can be synthesized by animals. Histidine is a
weaker base than either lysine or arginine. The imidazole ring, a
five-membered ring structure containing two nitrogen atoms in the side
chain of histidine, acts as a buffer (i.e., a stabilizer of hydrogen ion
concentration) by binding hydrogen ions (H+) to the nitrogen atoms of
the imidazole ring.

The remaining amino
acids---[phenylalanine](https://www.britannica.com/science/phenylalanine), [tyrosine](https://www.britannica.com/science/tyrosine),
and [tryptophan](https://www.britannica.com/science/tryptophan)---have
in common an aromatic structure; i.e.,
a [benzene](https://www.britannica.com/science/benzene) ring is present.
These three amino acids are essential, and, while animals cannot
synthesize the benzene ring itself, they can convert phenylalanine to
tyrosine.

Because these amino acids contain benzene rings, they can
absorb [ultraviolet
light](https://www.britannica.com/science/ultraviolet-radiation) at
wavelengths between 270 and 290 nanometres (nm; 1 nanometre =
10^−9^ metre = 10 angstrom units). Phenylalanine absorbs very little
ultraviolet light; tyrosine and tryptophan, however, absorb it strongly
and are responsible for the absorption band most proteins exhibit at
280--290 nanometres. This absorption is often used to determine the
quantity of protein present in protein samples.

Most proteins contain only the amino acids described above; however,
other amino acids occur in proteins in small amounts. For example, the
collagen found in connective tissue contains, in addition to
hydroxyproline, small amounts
of [hydroxylysine](https://www.britannica.com/science/hydroxylysine).
Other proteins contain some monomethyl-, dimethyl-, or
trimethyllysine---i.e.,
lysine [derivatives](https://www.britannica.com/dictionary/derivatives) containing
one, two, or three methyl groups (―CH~3~). The amount of these unusual
amino acids in proteins, however, rarely exceeds 1 or 2 percent of the
total amino acids.

Physicochemical properties of the amino acids
=============================================

The physicochemical properties of a protein are determined by
the [analogous](https://www.merriam-webster.com/dictionary/analogous) properties
of the amino acids in it.

The α-carbon [atom](https://www.britannica.com/science/atom) of all
amino acids, with the exception of glycine, is asymmetric; this means
that four different chemical entities (atoms or groups of atoms) are
attached to it. As a result, each of the amino acids, except glycine,
can exist in two different spatial, or geometric, arrangements
(i.e., [isomers](https://www.britannica.com/science/isomerism)), which
are mirror images akin to right and left hands.

These isomers exhibit the property
of [optical](https://www.britannica.com/science/optical-activity) rotation.
Optical rotation is the rotation of the plane of polarized light, which
is composed of light waves that vibrate in one plane, or direction,
only. Solutions of substances that rotate the plane of polarization are
said to be optically active, and the degree of rotation is called the
optical rotation of
the [solution](https://www.britannica.com/science/solution-chemistry).
The direction in which the light is rotated is generally designed as
plus, or *d*, for dextrorotatory (to the right), or as minus, or *l*,
for levorotatory (to the left). Some amino acids are dextrorotatory,
others are levorotatory. With the exception of a few small proteins
(peptides) that occur
in [bacteria](https://www.britannica.com/science/bacteria), the amino
acids that occur in proteins are l-amino acids.


In bacteria, d-alanine and some other d-amino acids have been found as
components of gramicidin and bacitracin. These peptides
are [toxic](https://www.britannica.com/dictionary/toxic) to other
bacteria and are used in medicine
as [antibiotics](https://www.britannica.com/science/antibiotic).
The d-alanine has also been found in some peptides of bacterial
membranes.

**Amino Acid Sequence in Protein Molecules**

Since each protein molecule consists of a long chain of amino acid
residues, linked to each other by peptide bonds, the hydrolytic cleavage
of all peptide bonds is a prerequisite for the quantitative
determination of the amino acid residues. Hydrolysis is most frequently
accomplished by boiling the protein with concentrated hydrochloric acid.
The quantitative determination of the amino acids is based on the
discovery that amino acids can be separated from each other by
chromatography on filter paper and made visible by spraying the paper
with ninhydrin. The amino acids of the protein hydrolysate are separated
from each other by passing the hydrolysate through a column of
adsorbents, which adsorb the amino acids with different affinities and,
on washing the column with buffer solutions, release them in a definite
order. The amount of each of the amino acids can be determined by the
intensity of the color reaction with ninhydrin.

To obtain information about the sequence of the amino acid residues in
the protein, the protein is degraded stepwise, one amino acid being
split off in each step. This is accomplished by coupling the free
α-amino group (―NH2) of the N-terminal amino acid with phenyl
isothiocyanate; subsequent mild hydrolysis does not affect the peptide
bonds. The procedure, called the Edman degradation, can be applied
repeatedly; it thus reveals the sequence of the amino acids in the
peptide chain.

Unavoidable small losses that occur during each step make it impossible
to determine the sequence of more than about 30 to 50 amino acids by
this procedure. For this reason the protein is usually first hydrolyzed
by exposure to the enzyme trypsin, which cleaves only peptide bonds
formed by the carboxyl groups of lysine and arginine. The Edman
degradation is then applied to each of the few resulting peptides
produced by the action of trypsin. Further information can be gained by
hydrolyzing another portion of the protein with another enzyme, for
instance with chymotrypsin, which splits predominantly peptide bonds
formed by the amino acids tyrosine, phenylalanine, and tryptophan. The
combination of results obtained with two or more different proteolytic
(protein degrading) enzymes was first applied by English biochemist
Frederick Sanger, and it enabled him to elucidate the amino acid
sequence of insulin. The amino acid sequences of many other proteins
subsequently were determined in the same manner.

Protein Synthesis
-----------------

Synthesis of proteins occurs in the ribosomes and proceeds by joining
the carboxyl terminus of the first amino acid to the amino terminus of
the next one. The end of the protein that has the free α-amino group is
referred to as the amino terminus or N-terminus. The other end is called
the carboxyl terminus or C-terminus , since it contains the only free
α-carboxyl group. All of the other α-amino groups and α-carboxyl groups
are tied up in forming peptide Linking of amino acids through peptide
bond formation bonds that join adjacent amino acids together. Proteins
are synthesized starting with the amino terminus and ending at the
carboxyl terminus.

Cis vs trans orientation of R-groups around peptide bond Image by Aleia
Kim

### Primary Structure

Primary structure is the ultimate determinant of the overall
conformation of a protein. The primary structure of any protein arrived
at its current state as a result of mutation and selection over
evolutionary time. Primary structure of proteins is mandated by the
sequence of DNA coding for it in the genome. Regions of DNA specifying
proteins are known as coding regions (or genes).

The base sequences of these regions directly specify the sequence of
amino acids in proteins, with a one-to-one correspondence between the
codons (groups of three consecutive bases) in the DNA and the amino
acids in the encoded protein. The sequence of codons in DNA, copied into
messenger RNA, specifies a sequence of amino acids in a protein.

The order in which the amino acids are joined together in protein
synthesis starts defining a set of interactions between amino acids even
as the synthesis is occurring. That is, a polypeptide can fold even as
it is being made. The order of the R-group structures and resulting
interactions are very important because early interactions affect later
interactions. This is because interactions start establishing structures
- secondary and tertiary. If a helical structure (secondary structure),
for example, starts to form, the possibilities for interaction of a
particular amino acid R-group may be different than if the helix had not
formed. R-group interactions can also cause bends in a polypeptide
sequence (tertiary structure) and these bends can create (in some cases)
opportunities for interactions that wouldn't have been possible without
the bend or prevent (in other cases) similar interaction possibilities.

  

From RNA to amino acids - the genetic code

**CARBOHYDRATES**

Carbohydrates are a group of biomolecules that serve as the primary
source of energy for the body. They are composed of carbon, hydrogen,
and oxygen atoms, usually in a ratio of 1:2:1. Carbohydrates are the
major components of plant tissue, making up to 60% to 90% of the dry
matter (DM). Carbohydrates contain carbon, hydrogen, and oxygen in the
proportion found in water (CH~2~O) and is hence hydrates of carbon.
Carbohydrates are the basic energy source in animal cells. Dietary
carbohydrates obtained from plant-based products serve as a major source
of energy for the animal. The chlorophyll in plant cells traps solar
energy and produces carbohydrates using carbon dioxide and water and
gives off oxygen, as shown in the following equation:

**Solar energy + 6 CO~2~ + 6 H~2~O → C6H~2~O + 6 O~2~**

**Composition of Carbohydrates**

Carbohydrates are composed of:

- Carbon (40-45%)

- Hydrogen (6-7%)

- Oxygen (45-50%)

- Sometimes, nitrogen, sulfur, or phosphorus

**Structure of Carbohydrates**

The structure of carbohydrates can be classified into:

1. **Monosaccharides** (simple sugars): single sugar unit (e.g.,
glucose, fructose)

2. **Disaccharides**: two sugar units bonded together (e.g., sucrose,
lactose)

3. **Polysaccharides** (complex carbohydrates): long chains of sugar
units (e.g., starch, cellulose, glycogen)

**Structure and Classification**

One method of classifying carbohydrates is based on the number of carbon
atoms per each molecule of a carbohydrate and on the number of molecules
of sugar in the compound. Based on the number of carbon atoms, a
carbohydrate can be classified as triose (3 C), tetrose (4 C), pentose
(5 C), and hexose (6 C). The suffix "*ose*" at the end of a biochemical
name flags the molecule as a "sugar." Among these, pentoses (e.g.,
ribose in ribonucleic acid (RNA)) and hexoses (e.g., glucose, or blood
sugar) are the most common sugars in animal tissues. Based on the number
of molecules of sugar in the compound, carbohydrates can be classified
as (1) monosaccharide, one unit of sugar; (2) disaccharide, two
monosaccharides; (3) oligosaccharide, three to fifteen monosaccharides;
and (4) polysaccharides, large polymers of simple sugars.

**A. Monosaccharides** are often referred to as simple sugars (e.g.,
glucose) and cannot be hydrolyzed into simpler compounds.

Monosaccharides can be subdivided based on the number of carbon (C)
atoms. The following list shows the prefixes for numbers of carbons in a
sugar.

1. Triose (3 C)

2. Tetrose (4 C)

3. Pentose (5 C; e.g., Xylose and Ribose)

4. Hexose (6 C; e.g., glucose, fructose, galactose, and mannose)Most
monosaccharides in animal tissues are of 5 C and 6 C sugars. Simple
sugars are also subdivided into aldose, a sugar that contains an
aldehyde structure, or ketose, a sugar that contains a ketone group.
Both glucose and fructose have the same molecular formula C6H12O6
and are hexoses (6 C). But glucose is an aldose (also called
aldohexose) and fructose is a ketose, or a ketohexose.

The three hexoses that are nutritionally and metabolically important are
glucose, fructose, and galactose


Structure of simple sugars (Glucose) (Source: Wikipedia)

The chemical structure of glucose can be represented as a straight chain
form and in cyclic form (also shown in figures above). In a biological
system, glucose exists primarily as a cyclic form and very rarely in a
straight form (in aqueous solution). Glucose is the form of
carbohydrates found in circulating blood (blood sugar) and is the
primary carbohydrate used by the body for energy production. Fructose,
or "fruit sugar," is found in ripened fruits and honey and is also
formed by digestion of disaccharide sucrose. Galactose is found along
with disaccharide lactose in mammalian milk and is released during
digestion.

**B. Disaccharides** are made up of two monosaccharides bonded together
by a glycosidic (covalent) bond. The following are some of the common
disaccharides:

1. Sucrose-glucose + fructose (e.g., table sugar)

2. Lactose-glucose + galactose (milk sugar)

3. Maltose-α-D-Glucose + β-D-Glucose (malt sugar)

4. Cellobiose-β-D-Glucose + β-D-Glucose (cellulose)

Among the different disaccharides, lactose (milk sugar) is the only
carbohydrate of animal origin. However, cellobiose as a component of
cellulose is important in animal nutrition. Monogastric animals cannot
digest cellulose because they do not produce the cellulase enzyme that
can split β-D-Glucose.

https://open.oregonstate.education/app/uploads/sites/85/2019/10/Untitled-1-02-1-scaled.jpg
Important disaccharides in animal nutrition and feeding, lactose and
cellobiose Source: Wikipedia

**C. Oligosaccharide are made by bonding together three or more (3 to
15) monosaccharides bonded together.**

1. Raffinose (glucose + fructose + galactose; 3 sugars)

2. Stachyose (glucose + fructose + 2 galactose; 4 sugars)

In animal diets, oligosaccharides are commonly found in beans and
legumes. Some oligosaccharides are used as substances to enhance the
growth of good microbes (prebiotics). Recently, there has been an
increased interest in the use of different oligosaccharides as feed
additives to enhance hindgut health (e.g., fructooligosaccharides,
mannan oligosaccharides).

**D. Polysaccharides, as their name implies, are made by joining
together large polymers of simple sugars.**

Polysaccharides are the most important carbohydrate in animal feed.
Polysaccharides are composed of many single monosaccharide units linked
together in long, complex chains. The functions of polysaccharides
include energy storage in plant cells (e.g., seed starch in cereal
grains) and animal cells (e.g., glycogen) or structural support (plant
fiber). Components of cell wall structure are also called nonstarch
polysaccharides, or resistant starch, in animal nutrition, as they
cannot be digested by animal enzymes but are fermented by hindgut and
rumen microbes.

Polysaccharides can be homopolysaccharides or heteropolysaccharides.

- a\. Homopolysaccharide

- b\. Heteropolysaccharide

a. **Homopolysaccharide:** Contains only one type of saccharide unit.

Examples of homopolysaccharides that are important in animal nutrition
include starch (nonstructural form), glycogen (animal form), and
cellulose (plant structural form).

1. **Starch:** Principal sugar form of carbohydrate in cereal grains
(seed energy storage). The basic unit is α-D-Glucose. Forms of
starch in cereal grains include

a. Amylose-α 1,4 linkage-straight chain, nonbranching, helical
structure

b. Amylopectin-α 1,4 linkage with alpha 1,6 linkage at branch
points

**Amylose** is the simplest of the polysaccharides, being comprised
solely of glucose units joined in an alpha 1,4 linkage (Figure 3.4).
Amylose is water soluble and constitutes 15% to 30% of total starch in
most plants.

Figure 3.4. Amylose structure showing straight α 1,4 linkage  Source:
Wikipedia

**Properties of Carbohydrates**

- **Solubility**: ability to dissolve in water

- **Sweetness**: varying levels of sweetness

- **Viscosity**: thickness and flowability

- **Fermentability**: ability to be broken down by microorganisms

- **Crystallinity**: ability to form crystals

**Functions of Carbohydrates**

Carbohydrates perform several functions in the body:

- **Energy source**: primary source of energy for cells

- **Structural components**: cell walls, exoskeletons, and connective
tissue

- **Storage molecules**: glycogen and starch store energy for later
use

- **Cell signaling**: involved in cell recognition and signaling

- **Fiber**: indigestible carbohydrates promoting digestive health

- **Nutrient absorption**: aid in absorption of other nutrients.

**Importance of Carbohydrates:**

1. **Brain function**: carbohydrates are the primary energy source for
the brain

2. **Physical performance**: carbohydrates provide energy for muscles

3. **Fiber**: indigestible carbohydrates promote digestive health

**LIPIDS**

Lipids are a group of biomolecules that are insoluble in water but
soluble in organic solvents. They are an essential component of living
organisms and serve various functions. Lipids are a diverse group of
molecules that all share the characteristic that at least a portion of
them is hydrophobic. Lipids play many roles in cells, including serving
as energy storage (fats/oils), constituents of membranes
(glycerophospholipids, sphingolipids, cholesterol), hormones (steroids),
vitamins (fat soluble), oxygen/ electron carriers (heme), among others.

**Composition of Lipids**

Lipids are composed of:

- Carbon (70-80%)

- Hydrogen (10-15%)

- Oxygen (5-15%)

- Sometimes, phosphorus, nitrogen, or sulfur

**Structure of Lipids**

The structure of lipids can be classified into:

1. **Triglycerides** (fats and oils): glycerol backbone with three
fatty acid chains

2. **Phospholipids**: glycerol backbone with two fatty acid chains and
a phosphate group

3. **Steroids**: four fused carbon rings (e.g., cholesterol)

4. **Waxes**: long-chain fatty acids with a hydrocarbon chain

***Assignment: Draw the structure of a named triglycerides,
phospholipids, and steroids.***

**Properties of Lipids**

- **Hydrophobicity**: insoluble in water, soluble in organic solvents

- **Viscosity**: varying levels of thickness and flowability

- **Melting point**: varying levels of heat stability

- **Saponification**: ability to react with alkali to form soap

- **Emulsification**: ability to mix with water and other liquids

**Functions of Lipids**

Lipids perform several functions in the body:

- **Energy storage**: stored energy source (triglycerides)

- **Cell membrane structure**: phospholipids and cholesterol maintain
membrane integrity

- **Hormone regulation**: steroids regulate various bodily functions
(e.g., cortisol, estrogen)

- **Vitamin absorption**: aid in absorption of fat-soluble vitamins
(A, D, E, K)

- **Protection**: waxes and oils protect skin and hair

- **Signaling**: involved in cell signaling and communication