Chapter 6 Production of Chemicals from Plants PDF

Summary

This document provides information on the production of chemicals from plants. It discusses various aspects of plant metabolism, including primary and secondary metabolites, carbohydrates, proteins, lipids, and enzymes.

Full Transcript

AGR569 BIOTECHNOLOGY FOR
PLANTATION CROPS

CHAPTER 6
Production of Chemical from
Plants
 Metabolism & Metabolite
Metabolism refers to the chemical
processes that occur within a living
organism in order to maintain its life
Metabolites are the intermediates and
products of metabolism
Metabolites are usually small molecules/
chemical compounds that have various
functions including structure, signaling,
stimulatory, defense….
 METABOLIC ENGINEERING IN
PLANTS
Plants are the most prolific factories for small
molecules
More than 100,000 metabolites have been
identified at 2004 (this may be only 10% of
total(
Among the organisms from different
kingdoms, plants are the richest in secondary
metabolites (5,000 – 25,000 per plant)
 Plant
Metabolis
m
 Primary metabolites
Primary metabolites are compounds that
are commonly produced by all plants and
directly involved in normal growth,
development, and reproduction
The main primary metabolites are
carbohydrates, proteins, nucleic
acids, and lipids
Some primary metabolites serve as the
precursors for the production of secondary
metabolite
 Secondary metabolites
The secondary metabolites are not
directly involved in plant growth,
development, and reproduction
usually has an important ecological
function, for example defense,
attracting pollinators, seed dispersal…..
Examples of secondary metabolite:
lignin, anthocyanin, phytoalexin,
alkaloids
 Carbohydrates
Carbohydrates are the sugars made up
of glucose and its isomers
Carbohydrates come in many different
sizes:
Monosaccharides made up of one
sugar unit (glucose or fructose)
Disaccharides made up of two sugar
units (sucrose is a glucose and a
fructose)
Polysaccharides are polymers made
up of more than two sugar units
 Sources of Sucrose

Sugar beet (Beta vulgaris)

Maple Syrup

Sugar
Sugar Cane
 Polysaccharides
Structural polysaccharides are used to provide
support to the plants. Example: Cellulose

Storage polysaccharides are used to store
energy for later use by the plant. Example:
Starch
 Structural Polysaccharides
The most common structural
polysaccharide in plants is cellulose. It
makes up 40 to 60% of the cell wall. It
is also the most common polymer on
earth
Cellulose is extremely strong due to its
chemical organization. It is made of a
long chain of beta-glucose molecules –
100 to 15,000 glucose molecules
 Proteins
Proteins make up most of the remaining
biomass of living plant cells.
A protein consists of one or more
polypeptides made up of amino acids.
Plants make amino acids from the products
of photosynthesis through a very complex
process involving the acquisition of N,
usually in the form of NH4, and involving
the use of large amounts of energy, in the
form of ATP and NADPH.
 Structural Proteins

Structural proteins make up 2 to 10% of the
cell wall in plants. Expansins help increase
the surface area of cell walls. Extensins help
protect or repair damaged cell walls. The
plant cell membrane is about 50% structural
proteins.
 Storage Proteins
Storage proteins are used mostly in
seeds and are used as source of
nutrition for the early development of
seedlings.
Storage proteins used in seeds vary
considerably between plant species.
Corn produces a storage protein
called ZEIN. Wheat produces a
storage protein called GLIADIN
 Enzymes
Enzymes catalyze biochemical reactions.
Most proteins in living cells are enzymes

Some enzymes are good for human
health

Pure enzymes that maintain their activity
when removed from plants are
commercially important to us
 Enzymes
Papain & Bromelain:
Chymopapain : enzymes isolated
enzymes isolated from pineapple
from papaya
Nucleic Acids

The most complex
biological polymers
are the nucleic
acids that make up
RNA and DNA. The
basic content of
bases (adenine,
thymine, gaunine
and cytosine) are
similar in all plants
 Lipids
Lipids are the substances from living
organisms that dissolve in nonpolar
solvents such as ether, chloroform
and acetone but not in water.
Some lipids store energy
Some are the primary structural
components of biological membranes
Some act as hormones, antioxidants,
pigments…….
 Lipids
Most lipids are made up of nonpolar
hydrocarbon groups (CH3, CH2, and
CH)
Major classes of lipids
– Fatty acids
– Triacylglycerols
– Wax
– phospholipid
Example of fatty acids
 Oils
Oils occur in all parts of a plant, but are most
common in seeds. Some seeds have so much
oil that it can be commercially harvested. The
most commonly used oils are oil palm, cotton,
sesame, safflower, sunflower, olive, coconut,
peanut, corn, castor bean, and soybean oils.
The most common seed oil fatty acids are oleic
acid (one double bond), linoleic acid (two
double bonds), and linolenic acid (three double
bonds).
Linoleic and linolenic are essential fatty acids –
we can’t make them ourselves.
 Waxes
Waxes are complex mixtures of fatty acids linked to
long-chain alcohols. Waxes comprise the outermost
layer of leaves, fruits, and herbaceous stems and are
called epicuticular waxes.
Waxes embedded in the cuticle of the plant are
cuticular waxes.
Cutin is another wax in the cuticle and it makes up
most of the cuticle.
Suberin is a similar wax that is found in cork cells in
bark and in plant roots. Both help prevent water loss
by the plant.
Structures of waxes vary depending on which plant
produced them.
Waxes are usually harder and more water repellant
than other fats.
Wax on the leaf cuticle prevents water loss
Part 2
 Plant Secondary
Metabolites
Plants produce a variety of less widely
distributed compounds such as
morphine, caffeine, nicotine, menthol,
and rubber
Certain secondary metabolites are
selectively produced by a specific plant

Secondary metabolites in plants play
important ecological roles that govern
interactions between plants and other
organisms.
Plant Secondary Metabolites
Secondary compounds are grouped into
classes based on similar structures,
biosynthetic pathways, or the kinds of plants
that make them.
The largest such classes are the alkaloids,
terpenoids, and phenolics.
Secondary compounds often occur in
combination with one or more sugars. These
combination molecules are known as
glycosides.
Usually the sugar is a glucose, galactose or
rhamnose. But some plants have unique
sugars. Apiose sugar is unique to parsley
and its close relatives.
 Functions of Secondary
Metabolites
Many secondary compounds are brightly colored
pigments like anthocyanin that color flowers red
and blue. These attract pollinators and promote
fruit and seed dispersers

Nicotine and other toxic compounds may protect
the plant from herbivores and microbes.

Lignin is a complex polymers that deposited in
plant cell walls and vascular tissues. It provides
support to the vascular plants, allow transport of
water and nutrients throughout the plant.
 Alkaloids

naturally occurring chemical
compounds (natural products) that
contant mostly basic nitrogen atoms
Many alkaloids are toxic to other
organisms.
They often have pharmacological
effects and are used as medications
and as recreational drugs
More than 6500 alkaloids are known
and are the largest class of secondary
compounds.
 Opium is the dried latex
obtained from the opium
poppy. Opium latex
contains approximately 12
% of the analgesic alkaloid
morphine, which is
processed chemically to
produce heroin and other
synthetic opioids for
medicinal use and for
illegal drug trade.
Morphine was the first
individual alkaloid isolated
from poppy in 1804.
 Terpenoids
Terpenoids (sometimes called isoprenoids)
are dimers and polymers of isoprene (C5
H8).
Terpenoids contribute to the scent of
eucalyptus, the flavors of cinnamon,
cloves, and ginger, the yellow color in
sunflowers, and the red color in tomatoes.
Well-known terpenoids include citral,
menthol, camphor…..
 Phenolics
Phenolic compounds are the chemical
compounds consisting of a hydroxyl group
(—OH) bind directly to an aromatic
hydrocarbon group (unsaturated six
carbon ring or benzene ring )

Salicylic acid (basic part of aspirin) is a
simple phenol.
 Phenolics
Myristicin is a more complex phenol that
provides the flavor of nutmeg
Flavonoids are complex phenolics. They are
often sold in health food stores as supplements
to vitamin C. The most commonly available
flavonoid is rutin from buckwheat
Anthocyanins are a type of flavonoid that give
flowers red and blue pigments
Tannins are astringent to the taste. They give
dryness (astringency) to dry wines. They can
also be used to tan leather. They often give
water a tea-colored look. Tannins are common
in pines and oaks
 Phenolics
Lignin is a major structural component of
wood. It is a complex polymer.
How Phytochemical Compounds extracted
and screened?

https
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 Primary VS Secondary
Metabolite
PRIMARY METABOLITES SECONDARY METABOLITES
essential for cell growth, and aid in the growth and
involved directly in metabolic development of plants (for plant
reactions such as respiration to stay healthy) but are not
and photosynthesis required for the plant to survive/
components or products of live
fundamental metabolic
pathways or cycles such as colored, fragrant, or flavorful
glycolysis, the Krebs cycle, and
compounds
the Calvin cycle.
Most primary metabolites are numerous and wide spread
identical among most organisms
Do not have end product derived by pathways in which
primary metabolites involve,
considered as the end products
 Primary VS Secondary
Metabolite
PRIMARY METABOLITES SECONDARY METABOLITES
produced during the growth produced during the non-
phase of cell growth phase of the cell.
essential for cell growth and accumulated by plant cells in
accumulated in large quantity very small quantities

Not involved in defense involved in defense reactions

Example: Example:
Nucleic acids, Proteins, alkaloids, phenolics, sterols,
carbohydrates, and lipids steroids, essential oils and
lignins etc.
Enhancing Product Yield in
Major Crop Through
Biotechnology
 BIOTECH STRATEGIES FOR
ENHANCING PRODUCT YIELD IN
MAJOR CROPS
A) Breeding strategies
- Through many different techniques ranging from simply
selecting species with high yield traits for propagation, to
more complex molecular techniques.
- example: bio/molecular marker, DNA fingerprinting, reverse
breeding
b) Plant cloning – tissue culture
- Commercial production of high yield oil palm clones through
plant tissues culture (produce exact copies of plants)
- Advantages : regeneration of whole plants from plant cells
that have been successfully genetic engineered, reduced
chances of transmitting diseases, pests, and pathogens,.
 BIOTECH STRATEGIES FOR
ENHANCING PRODUCT YIELD IN
MAJOR CROPS
c) Genetic engineering/genetic modification
- High yield oil palm species can be produce through genetic engineering
- introduce a new trait to the plant which does not occur naturally in the
species
d) Biofertilizer
-Application of biofertilizer: increasing the supply or availability of
primary nutrients to the host plant
- microorganism symbiosis: Mycorriza, produce hyphae permeate soil,
enable the roots to explore a larger soil volume and have a greater
absorptive area, the fungus also penetrates the intracellular site of
the root cortex,
e) Biocontrol
- production of Bacillus thuringiensis (Bt) to control
bagworm, Metarhizium to control rhinoceros beetle
andTrichoderma to control Ganoderma