Transcript GENETICS

GENETICS
8th Grade Science
Vocabulary
Trait – physical characteristic of an organism
Heredity – the passing of traits from parent to offspring
Purebred – having the exact same traits as the parent
Gene – factor that controls traits
Allele – the different forms of genes that control a
particular trait
Dominant allele – one whose trait shows up in an
organism
Recessive allele – one whose trait is hidden or covered
up
Hybrid – having two different alleles for the same
characteristic
Mendel – Father of Modern Genetics
• Augustinian monk who taught natural
science in high school
• Interested in plants, meteorology, and
theory of evolution
• Came from a poor family – entered
monastery at 21 – was then able to
attend university and conduct research
• After observing plants decided to
experiment by crossing pea plants
• Saw the traits were inherited in certain
ratios
Took 7 yrs to cross and record data from plants in order to prove laws of
Inheritance.
Became first person to trace characteristics of successive generations of a living
things
Published Experiments with Plant Hybrids which is the most enduring and
influential publication in history of science
Mendel continued
From studies came up with certain basic laws of heredity:
1. Heredity factors do not combine – are passed intact
2. Each member of parent generation gives only half of its hereditary
factors to each offspring (some “dominant” over others)
3. Different offspring of same parents receive different sets of hereditary
factors
Work was ignored for 30 years, but was rediscovered after his death.
Abbey of St. Thomas
Library
Photo: © Stepan Bartos
Pea Plant Experiment
Choose pea plants because they were available and easy to track
generations
Pollen was easy to see and cross-pollination was controlled
Several physical traits were easy to established
For 2 years grew different varieties to make offspring always the same
Noticed some traits disappeared in 1st generation – called them “recessive”
Those traits that appeared called “dominant”
Later generations would have recessive traits reappear in a mathematically
predictable pattern
Grew about 28,000 pea plants over 8yrs. before publishing results in 1864
Illustration: Greg Mercer
Pea Plant Experiment
Illustration: Greg Mercer
Vocabulary
Punnett square – chart showing all possible outcomes
of a genetic combination
Phenotype – physical appearance or observable traits
of an organism
Genotype – the genetic makeup of an organism
Homozygous – an organism that has 2 identical
alleles for a trait
Heterozygous – an organism that has 2 different
alleles for a trait
Co-dominance – alleles are neither dominant nor
recessive, neither allele is masked and both are
expressed
Mendel recognized that principles of probability can be used to predict results
of genetic cross
Use Punnett cross to show / predict outcomes
Cell Reproduction and Inheritance
Meiosis – process which allows chromosomes to divide to form
sex cells
Messenger RNA – copies coded message from DNA in nucleus
and carries the coded message into the cytoplasm
Transfer RNA – carries amino acids and adds them to growing
protein
Mutation – any change that occurs in gene or chromosome
Multiple alleles – a human trait controlled by a single gene with
more than 2 alleles
Sex-linked gene – genes on X and Y chromosomes, alleles are
passed from parent to offspring on a sex chromosome
Carrier – person who has one recessive allele for a trait and one
dominant allele
Pedigree – chart or “family tree” that tracks traits of a family
Amniocentesis – removal of fluid surrounding a developing baby
Karyotype – picture of all the chromosomes in a cell
Inheritance
Chromosomes are made of many genes joined together; each one contains a
large number of genes due to the number of traits of an organism
Humans have 23 pairs or 46 chromosomes, dogs 78, silkworms 56 – size of
organism does not determine number of chromosomes
Remember, one chromosome from each pair in an organism comes from
the mother and one from the father
Inside chromosome is replicated DNA
DNA contains the code to determine the size,
shape, and other traits of an organism
DNA is made up of 4 different nitrogen bases –
adenine (A), thymine (T), guanine (G),
cytosine (C)
This forms the rungs of the ladder of DNA
Adenine (A) ALWAYS pairs with thymine (T)
Guanine (G) ALWAYS pairs with cytosine (C)
One gene may contain anywhere from several
hundred to a million or more bases
The order of the bases determines the structure of proteins that make up amino
acids
Are only 20 common amino acids – can be combined in different ways to form
thousands of different proteins
The order of the nitrogen bases along a gene forms the code that determines
what type of protein will be produced –called protein synthesis
Before protein synthesis occurs a “messenger” must carry the genetic code from
the DNA inside the nucleus into the cytoplasm – is called ribonucleic
acid or RNA
Though RNA resembles DNA has some differences:
-alnost always looks like one side or strand of DNA
- contains different sugar molecule
- does not contain thymine in bases, replaces it with uracil base
Transfer RNA carries amino acids and adds them to growing protein
A 3 base code indicates a specific amino acid
Translating the Code
First DNA unzips between its base pairs, then one of the strands of DNA
directs production of a strand of messenger RNA
The RNA bases pair up with the DNA, with uracil pairing up with adenine
Messenger RNA then leaves the nucleus and attaches to a ribosome in the
cytoplasm, there transfer of RNA picks up the amino acid specified
by 3 letter code
Each transfer RNA molecule puts an amino acid in the correct order along
the growing protein chain
Process continues for each section between 3 letter code
Mutations
Any mistake in the transfer can result in a mutation
Causes a cell to produce an incorrect protein during protein synthesis
Some are result of small change in hereditary material such as substitution
of single base pair for another
Can occur during DNA replication process
Some occur when chromosomes don’t separate correctly during meiosis
Will cause too few or too many chromosomes
If mutation occurs in body cell then mutation only affects the cell that carries
it, if in a sex cell then mutation able to be passed on to offspring and
will affect offspring’s phenotype
Mutation can cause change in organism that may or may not help it to survive
Some neither helpful nor harmful
Genetic disorders causes by mutation or change in DNA
CELL DIVISION:
MITOSIS AND MEIOSIS
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Mitosis
Occurs in cells of the
body
Produces identical
offspring cells
Produces two cells
Cells have same
number of
chromosomes as parent
cell
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Meiosis
Occurs only in sex cells
Produces non-identical
offspring cells
Produces four cells
Cells have half the
number of
chromosomes as parent
cell
Sex Cells
Sex of offspring determined by sex chromosome – are the only pair of
chromosomes that may not match
Sex –linked genes produce sex-linked traits
Males are more apt to have a sex-linked trait due to having only 1 X chromosome
A person can be a carrier for a sex-linked trait but not show any sign for that
trait
Use pedigree to trace inheritance patterns of traits
Resources and pictures used for this presentation:
http://www.bioweb.uncc.edu/1110Lab/notes/notes1/lab6.htm
http://www.fieldmuseum.org/mendel/story_discovered.asp
http://search.live.com/images/results.aspx?q=Chromosome&mkt=en-US#
University of Texas Medical Branch
Cell Biology Graduate Program
http://www.ngsgenealogy.org/images/Pedchart.jpg
Science Explorer Grade 8 – Prentice Hall