ABE 113 Chapter 4: Genetics and Crop Improvement PDF

Summary

This document provides an overview of principles and techniques related to crop improvement. It explores Mendelian genetics, various breeding approaches, and factors influencing seed quality. The document is well-structured and includes visual aids for better understanding.

Full Transcript

ABE 113 Chapter 4
Genetics and Crop
Improvement

A. Mendelian genetics and inheritance in crops
B. Modern breeding techniques (hybridization, genetic
modification)
C. Marker-assisted selection
D. Seed quality and production
Plant genetics - is a branch of biology and botany
that studies genes, genetic variation, and
heredity in plants.
Plant genetics is closely related to the study of
information systems, as genes encode the
information that determines the traits of
plants.
Plant genetics also involves plant breeding,
which is the application of genetic principles to
produce plants that are more useful to
humans.
Plant breeding involves selecting and mating
plants with desirable characteristics, and then
choosing the best offspring among them.
A. Mendelian genetics and inheritance in crops
Mendelian genetics provides a
fundamental framework for
understanding the inheritance of
traits in crops, just as it does for
other organisms.
The principles established by
Gregor Mendel in the 19th
century can be applied to
various crop species. Here's an
overview of Mendelian genetics
and its application to crop
inheritance:
1. Mendel's Laws:
a. Law of Segregation:
Mendel's first law states that an individual
carries two alleles (gene variants) for each trait,
one inherited from each parent.
During gamete formation, these alleles
segregate, resulting in each gamete (sperm or
egg) carrying only one allele for each trait.
b. Law of Independent Assortment:
Mendel's second law states that the alleles for
different traits assort independently of each
other during gamete formation.
This law applies to genes located on different
chromosomes or genes located far apart on the
same chromosome.
2. Genotype and Phenotype:
In crops, the genotype refers
to the genetic makeup of an
individual, including the
specific alleles for each trait.
The phenotype is the
observable physical or
biochemical characteristic
resulting from the genotype.
3. Dominant and Recessive Alleles:
In many crop traits, one allele is
dominant over another, and the
dominant allele determines the
phenotype when present in the
genotype.
The recessive allele is only
expressed when two copies of it are
present (homozygous recessive).
4. Monohybrid Cross:
A monohybrid cross involves
the inheritance of a single
trait, controlled by a single
gene.
For example, in peas,
Mendel's work involved
crosses of plants with
different seed colors (yellow
and green) or flower colors
(purple and white).
5. Dihybrid Cross:
A dihybrid cross explores
the inheritance of two
different traits controlled
by two genes.
This cross helps to
understand how genes
located on different
chromosomes assort
independently.
6. Punnett Square:
Punnett squares are used to predict
the possible genotypes and
phenotypes of offspring from specific
crosses.
7. Test Cross:
A test cross involves crossing an
individual with an unknown genotype
(dominant phenotype) with a
homozygous recessive individual.
This cross helps determine whether
the individual with the dominant
phenotype is homozygous dominant
or heterozygous.
Applications in Crops:
Mendelian genetics is applied to crop
breeding to select and develop new
crop varieties with desirable traits.
It helps predict the outcomes of
crosses and allows breeders to make
informed choices about which plants
to cross to achieve specific breeding
goals.
Inheritance patterns are critical for
developing crop varieties with traits
such as disease resistance, yield,
quality, and environmental
adaptation.
Challenges in Crop Genetics:
While Mendelian genetics provides
a useful framework, many crop
traits are controlled by multiple
genes and exhibit complex
inheritance patterns. Polygenic
traits and gene interactions can
complicate the application of
Mendelian principles in crop
breeding.
In summary, Mendelian genetics plays a vital role in
understanding the inheritance of traits in crop plants. By
applying Mendel's laws and principles, crop breeders can
make informed decisions to develop improved varieties with
desired characteristics and traits. However, for complex traits
influenced by multiple genes, additional genetic and
molecular techniques are required to unravel the full genetic
complexity.
B. Modern Breeding Techniques:
Hybridization and Genetic Modification
Modern breeding techniques have revolutionized crop
improvement by accelerating the development of crop
varieties with desired traits.
Two key techniques are:
1. hybridization and
2. genetic modification (GM).
1. Hybridization:
Definition: Hybridization involves crossing two distinct
parental lines of a plant species with desired traits to
create offspring (hybrids) with a combination of these
traits.
Process:
Parental Selection: Breeders choose two distinct
parent plants with complementary traits. For example,
one parent might have high yield, and the other might
have disease resistance.
Crossing: Pollen from one parent is used to fertilize
the flowers of the other parent, leading to the
development of hybrid seeds.
Hybrid Selection: The offspring (hybrids) are evaluated
for the desired traits, and the best-performing
individuals are selected.
Seed Production: Hybrid seeds are produced on a
large scale and distributed to farmers.
Advantages:
Rapid trait introgression: Allows the
transfer of specific traits into crop
varieties.
Improved yield, disease resistance, and
other desirable characteristics.
Often simpler and less controversial than
genetic modification.
Limitations:
Requires careful parental selection and
cross-pollination.
Hybrids may not be as stable as
non-hybrids for saving seeds.
Limited to sexually compatible species.
2. Genetic Modification (GM):
Definition: Genetic
modification involves the
direct manipulation of an
organism's genetic material,
often by introducing genes
from other species, to create
specific desired traits in the
plant.
 Process:
1. Gene Identification:
Researchers identify
a gene responsible
for the desired trait,
which could be
resistance to pests,
herbicides, or
enhanced nutritional
content.
2. Gene Insertion:
The target gene is
inserted into the
plant's genome using
biotechnological
tools like
Agrobacterium-medi
ated transformation
or gene guns.
3. Plant Regeneration:
Transformed cells are
regenerated into whole
plants, and the
presence of the new
gene is confirmed.
4. Field Testing: Transgenic plants are field-tested for performance and
safety.
5. Regulatory Approval:
After thorough safety
assessments, GM crops
may receive regulatory
approval for commercial
cultivation.
Advantages:
Precision in introducing desired
traits.
Ability to confer resistance to pests,
diseases, and herbicides.
Enhanced nutritional content (e.g.,
Golden Rice with vitamin A).
Limitations:
Ethical and regulatory concerns
regarding transgenic crops.
Potential for unintended
consequences or environmental
impact.
Resistance development in pests
and pathogens (e.g., Bt-resistant
insects).
Key Examples of GM Crops:
Bt Cotton: Contains a gene from the
bacterium Bacillus thuringiensis (Bt) that
produces a protein toxic to certain insect
pests.
Roundup Ready Soybeans: Engineered to
resist the herbicide glyphosate
(Roundup).
Golden Rice: Modified to produce
beta-carotene (provitamin A), addressing
vitamin A deficiency in developing
countries.
Summary
Both hybridization and genetic modification have played
significant roles in modern agriculture, contributing to
increased crop yields, disease resistance, and other desirable
traits. The choice between these techniques depends on the
specific breeding goals, regulatory considerations, and public
acceptance. It's important to note that the development and
regulation of GM crops can vary from one country to another.
C. Marker-Assisted Selection (MAS) in Crop
Breeding:
Marker-Assisted Selection (MAS) is
a powerful technique used in crop
breeding to select plants with
desirable traits based on their
genetic makeup. MAS allows
breeders to make more informed
and precise choices when
developing new crop varieties.
Here's an overview of how MAS
works:
1. Traditional Breeding
Traditional breeding methods rely on the observation
of phenotypic traits (outward physical
characteristics) to select plants for breeding. While
effective, this process can be time-consuming and
may involve many generations of breeding.
Traditional breeding may include the use of tissue
and cell culture, techniques for overcoming
incompatibility barriers, such as wide crosses and
embryo rescue, the use of genetic bridge
intermediates, translocation breeding, advanced
pollination procedures and in vitro fertilization,
techniques for polyploidzation, generation of
seedless varieties, anther and microspore culture for
haploidization, interspecific grafting, production of
inbred and hybrid lines.
 In vitro fertilization (IVF) is a
technique that involves the
isolation of male and female
gametes and their in vitro fusion
(fertilization) culture of the in vitro
zygote to regenerate full plants.
This technique has been
developed in only two plants,
namely maize and rice
2. MAS leverages knowledge of the plant's DNA
(genotype) to select plants based on their genetic
markers, which are linked to specific traits.
Key Components of MAS:
Molecular Markers: These are specific DNA
sequences that are associated with a particular
trait of interest. Common types of molecular
markers include single nucleotide polymorphisms
(SNPs), simple sequence repeats (SSRs), and
amplified fragment length polymorphisms
(AFLPs).
Genotyping: The process of identifying and
analyzing the genetic markers in plants. This can
be done through various laboratory techniques,
such as polymerase chain reaction (PCR) and
DNA sequencing.
Phenotyping: The evaluation of plants for their
observable traits. This information is used to
validate the correlation between genetic markers
and the target trait.
3. The MAS Process:
Trait Identification: Breeders identify a trait
of interest that they want to enhance or
suppress in the crop. This could be
resistance to a specific disease, improved
yield, or other desirable characteristics.
Marker Discovery: Researchers identify and
develop molecular markers that are
associated with the target trait through
genetic studies and DNA analysis.
 Genotyping: Plants from the breeding population are genotyped to
determine which individuals carry the desired genetic markers
linked to the trait of interest.

Phenotyping: The selected plants are grown, and their phenotypic
traits are evaluated. This helps validate the accuracy of the
selected markers in predicting the trait's expression.
 Selection: Based on the genetic marker data and phenotypic results,
breeders make informed decisions about which plants to select for
further breeding.
Crossing: The selected plants are crossed to develop new generations
of crops that carry the desired trait.
Repetition: The process can be repeated through multiple
generations, refining the selection based on the markers to produce
crop varieties with the desired traits.
4. Advantages of MAS:
Precision: MAS allows for the precise
selection of plants with the desired
genetic makeup, reducing the need
for extensive field trials and speeding
up the breeding process.
Efficiency: It accelerates the
development of crop varieties with
specific traits, saving time and
resources.
Reduced Environmental Impact: By
selecting plants with targeted traits,
fewer resources are used in the
breeding process.
5. Limitations of MAS:
Cost: The initial investment in marker development and
genotyping can be expensive.
Validation: The correlation between markers and traits needs
to be confirmed through phenotyping.
Complex Traits: MAS is most effective for simple, single-gene
traits and may be less accurate for complex, multigenic traits.
Summary
Marker-Assisted Selection has become an invaluable tool in
crop breeding, especially for improving important traits and
addressing the challenges of global food security and
sustainability. It allows for more efficient and precise crop
improvement, ultimately benefiting farmers and consumers.
D. Seed Quality and Production:

Seed quality is a critical factor in
agricultural productivity, as it directly
impacts crop performance, yield, and
overall agricultural success. High-quality
seeds ensure uniform germination,
strong crop establishment, and improved
resistance to pests and diseases. Here's
an overview of seed quality and the
process of seed production:
1. Seed Quality:
a. Characteristics of High-Quality Seeds:
1. Purity: High-quality seeds should be
free from foreign matter, such as weed
seeds, debris, and inert materials.
2. Germination Rate: Seeds should have a
high germination rate, indicating the
percentage of seeds that will produce
healthy seedlings under suitable
conditions.
 Vigor: Seed vigor refers to the potential for
rapid, uniform emergence and robust
seedling growth. Vigorous seeds are more
resilient in adverse conditions.
Disease and Pest Resistance: Disease-free
and pest-free seeds are essential for
preventing crop losses.
Genetic Purity: Seeds of hybrid crops must
maintain their genetic purity to ensure
consistent traits in the offspring.
b. Seed Certification:
Many countries have seed certification programs to ensure that seeds meet specific
quality standards and are labeled with information regarding their source, quality,
and genetic identity.
c. Seed Testing:
Seed testing labs analyze seed quality parameters, including purity, germination
rate, and disease presence.
2. Seed Production:
a. Selection of Parent Plants:
Seed production starts with the selection of
healthy, high-yielding, and disease-free parent
plants.
b. Controlled Pollination:
For pure line varieties, controlled pollination is
essential to prevent cross-pollination with other
plant varieties.
c. Isolation:
To maintain genetic purity, crops that are prone
to cross-pollination should be isolated from other
varieties or potential contaminants.
d. Field Monitoring:
Fields where seed crops are grown require strict
monitoring for pests, diseases, and other potential
contaminants.
e. Harvesting:
Timing is crucial. Seeds should be harvested when they are
fully mature but before they shatter or lose viability.
f. Drying and Cleaning:
After harvest, seeds are dried to the appropriate moisture
level and cleaned to remove impurities.
g. Seed Treatment:
Some seeds may undergo treatment processes to enhance
germination, protect against pests, or improve handling
characteristics.
h. Storage:
Proper storage is essential to maintain seed
viability. Seeds should be stored in cool, dry
conditions and regularly monitored.
i. Packaging:
Seeds are packaged in containers that protect
them from physical damage, moisture, and pests.
Labels provide information on seed quality,
variety, and planting guidelines.
j. Distribution:
High-quality seeds are distributed to farmers,
commercial growers, and nurseries for planting.
3. Challenges in Seed Production:
Disease and Pest Management: Maintaining seed health
requires ongoing efforts to prevent disease and pest
infestations.
Genetic Drift: Preventing genetic contamination from
neighboring crops or varieties can be challenging.
Environmental Factors: Weather conditions can impact seed
quality and yield.
Summary
High-quality seed production and distribution are critical
components of sustainable agriculture. By ensuring that
farmers have access to reliable, disease-free, and high-yielding
seeds, we contribute to food security, improved crop
productivity, and overall agricultural success.
-------------end of presentation----------------
Quiz No. 4