Bio-31-Lecture-2.-Part-1 PDF

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This document provides an overview of genetics, its history, and various branches. It also discusses different techniques used for studying genetics and examples of real-world applications.

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(Take 2) Grounding Together

https://www.cmu.edu.ph/home/the-university/mission-vision/

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Branches of Genetics
1. Cytogenetics – studies the chromosomes which are the carriers of
DNA/genes

2. Molecular Genetics – studies the structure & function of genes at
the molecular level

3. Developmental Genetics – studies how genes control growth &
development of an organism throughout its life cycle

4. Quantitative Genetics – studies the role of genetics &
environmental factors on the inheritance of traits that are controlled
by many genes & highly affected by the environment (e.g. grain yield)

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5. Population Genetics – studies the fate of genes in a population &
the factors that would change the frequencies of genes & alleles in
populations over space & time
6. Biochemical Genetics – studies the relationship of genes & their
control over the function of an enzyme in a metabolic pathway
7. Evolutionary Genetics – studies how genetic variation leads to
speciation & adaptation, & genetic change in response to selection
within populations
8. Human Genetics – studies traits, diseases & abnormalities in
humans that are inherited
9. Behavioral Genetics – studies how genetic & environmental
influences would affect behavior
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Some Applications of Genetics
∞ Food production
∞ Plant breeding/crop improvement
∞ Animal breeding/animal improvement
∞ Genetic counselling (human concerns such as diseases)
∞ Forensics & legal matters
∞ Genetic resources conservation & management
(plants, animals, microbes)
∞ Medicine: gene therapies, diagnosis of genetic diseases, vaccine
development, personalization of medical treatments, etc.
∞ Others

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Methods Used in Genetic Studies
1. Hybridization or crosses: monohybrid, dihybrid, trihybrid,
etc.
2. Phenotyping: qualitative, quantitative & intermediate traits;
morphological, agronomic, physiological, biochemical traits
3. Mutation studies/mutagenesis
4. Statistical analyses: ANOVA, Chi-square test, cluster
analysis, principal component analysis (PCA), Standardized
Shannon-Weaver Diversity Index (SSWDI), etc.
5. Molecular methods: polymerase chain reaction (PCR), gel
electrophoresis, DNA sequencing, QTL analysis, association
mapping, GWAS (genome-wide association studies), genotyping
using molecular markers, etc. 5
 BIO 31
Genetics

Chapter 1. INTRODUCTION
(History, Theories & Important People…)
Prepared by:

Joy M. Jamago, PhD
Department of Agronomy & Plant Breeding
College of Agriculture, Central Mindanao University
Musuan, Bukidnon, 8710 Philippines

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https://biology.mit.edu/faculty-and-research/areas-of-research/genetics/
 Who am I?
What did I do?

Next:
Historical background
Early theories of genetics
Pillars of genetics
Milestones in genetics
https://www.britannica.com/biography/Gregor-Mendel

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https://www.femtechleaders.com/the-top-8-famous-geneticists-in-the-world/

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https://www.femtechleaders.com/the-top-8-famous-geneticists-in-the-world/
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https://www.facebook.com/photo/?fbid=1822756071093281&set=a.109350895767149
https://www.asianscientist.com/scientist/emil-q-javier/

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 Genetics
▪ derived from the Greek word “gen” – to
become or to grow into something
▪ Genetics – coined by William Bateson,
1905 (119 y.a.)
▪ deals with fundamental properties &
problems of life & living, hence impinging on
all aspects of biology, biochemistry,
physiology, development, morphology,
anatomy, evolution, ecology & other sciences
https://dnalc.cshl.edu/view/16197-Gallery-5-William-Bateson-Portrait.html

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Beginning of Genetics
▪ Science of genetics began with the works of
Gregor Mendel (1822-1884); Austrian monk
▪ 1866: discovered that hereditary
characteristics were determined by
“factors” (now called genes)
▪ factors – transmitted (passed on) between
generations in uniform predictable pattern

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 ▪ 2 important attributes of the gene
(factor):
1. Gene is inherited from generation to
generation in such a fashion/pattern
that each progeny (offspring,
descendants) has a physical copy of
the gene;
2. Gene provides information regarding
https://www.thespruceeats.com/taste-of-different-color-carrots-2215929 the structure, function, & other
E.g. Trait – color of carrot roots biological properties of the
characteristic or trait it controls
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 Before Mendel:
 Heredity was a “blending process”, offspring were thought to
be mixtures of characteristics from both parents
 True for some cases, not for other cases (i.e. some children would
closely resemble 1 parent) → do, other explanation were needed
(1) Theory of Pangenesis: by Aristotle (384-322 BC)
 Lasted until 19th century, accepted by Charles Darwin (1809-1882)
 “semen was formed everywhere in a man’s body & such semen
reflected the characteristics of the body part from where it was
formed”, semen traveled through blood vessels into male
https://investinhistory.ca/2024/02/14/aristotle-athens-greatest-philosopher/ reproductive organs
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(2) Theoryof
Inheritance of
Acquired
Characteristics:
by Jean Baptiste
de Lamarck
(1744-1829)

https://byjus.com/question-answer/theory-of-inheritance-of-acquired-characters-was-given-bydarwinde-vrieswallacelamarck/

 based on the Pangenesis Theory
 proposed as the fundamental mechanism of evolutionary change
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(3) Germplasm Theory by August Weismann (1834-1914)
o Challenged Aristotle’s & de Lamarck’s theories
o Experiments: cut off tails of for many generations but offspring
always had normal tail length
o Conclusion: inheritance of tail length did not depend on particles
produced in the tails of parent mice, but on the germplasm cell(s)
which were not affected when tails were cut
o Germplasm Theory: germplasm or sex cells perpetuated
themselves in reproduction generation after generation, whereas,
the somatoplasm or other body parts were produced only to
protect & reproduce itself
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August Weismann
1st to distinguish heritable changes &
non-heritable changes
Other books call his theory: the
Weismann Barrier
“Germline (sex cells) contain
information that is passed on to
the next generation unaffected https://www.britannica.com/biography/August-Weismann

by experience & independent of
somatic cells (from other parts of
the body)”
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Joseph Kolreuter (1733-1806):
o Crossed red carnations x white carnations = produced pink
carnations
o Crossed pink x pink = red, white & pink carnations
o Conclusion: hybrids between species might show uniform
appearance but their fertile offspring would usually produce diverse
outputs

Gartner (1772-1850)
Naudin (1815-1899) similar observations
Darwin (1809-1882)
Dzierzon (bee-hybridizer) – reported similar observations & considered
the numerical ratios of the diverse offspring
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 Most likely due
to his brilliant
insights &
methodologies*

Mendel – not first to study biological inheritance but still was
named the “Father of Genetics”
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1. Choice of garden peas (Pisum sativum L.) as experimental crop
was advantageous
Peas: self-pollinating, starting materials were relatively the same (or
homozygous)
Peas produce many seeds so ratios or proportions of characteristics being
studied could be monitored/accounted easily
2. Mendel concentrated on 1 single trait at a time (whereas, other
scientists observed whole plants or more complex traits)
Selected plant traits with clear-cut differences or the alternative types
contrasted sharply; e.g. round vs. wrinkled seeds
3. Made sure that pea strains or varieties used in hybridization
were “true breeding” by growing them for 2 years; selected
parent materials only those that produced progenies or offspring
that resembled the parents
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 4. Mendel introduced
quantitative approach in his
experiments: classified
hybrid progenies (based on
type) & determined their
respective frequencies
5. He formulated theories that
explained his experimental
results
6. He formulated appropriate
https://www.istockphoto.com/photos/mendel
experimental tests to
validate his theories
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 Reflection:
Mendel’s important contribution to science of genetics: demonstrated that
appearance of different characters in heredity followed specific laws & can be
determined by counting the diverse kinds of offspring produced from any
sets of crosses
Published his work in 1866 but was ignored for almost 40 years

 He had wrong timing : during his time, most biologists had
Hawkweed little interest in mathematics & vice versa, & Mendel tried to
bridge the gap
 But, he wasn’t able to show similar results in other plants or
animals
 Studied hawkweed (Hieracium sp.) – which unfortunately was
an apomictic species
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https://en.wikipedia.org/wiki/Hieracium_lachenalii
 https://species.wikimedia.org/wiki/Hugo_de_Vries
https://dnalc.cshl.edu/view/16216-Gallery-6-Carl-Correns-signed-portrait.html https://dnalc.cshl.edu/view/16218-Gallery-6-Erich-von-Tschermak-Seysenegg-1941-signed.html

Carl Correns (German) Erick Von Tschermak (Austrian) Hugo de Vries (Dutch)
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The “Rediscoverers of Mendel”
In 1990, independently duplicated Mendel’s experiments on garden peas,
corn, primroses, poppies & other flowering plants.
https://species.wikimedia.org/wiki/Hugo_de_Vries
https://dnalc.cshl.edu/view/16216-Gallery-6-Carl-Correns-signed-portrait.html https://dnalc.cshl.edu/view/16218-Gallery-6-Erich-von-Tschermak-Seysenegg-1941-signed.html

Obtained same ratios as Mendel
German Austrian Dutch
Provided the follow-up work that Mendel was unable to do
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 William Bateson Edith Rebecca Saunders Lucien Cuenot
(British/English) (British) (French)

https://en.wikipedia.org/wiki/William_Bateson https://www.lib.cam.ac.uk/women-of-cambridge/edith-rebecca-saunders

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 William Bateson Edith Rebecca Saunders Lucien Cuenot
(British/English) (British) (French)

https://en.wikipedia.org/wiki/William_Bateson https://www.lib.cam.ac.uk/women-of-cambridge/edith-rebecca-saunders

1902: showed that Mendelian principles also applied to animals
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