Biology 30 Cell Division Curriculum Outline PDF

Summary

This document outlines the curriculum for Biology 30, focusing on cell division, genetics, and molecular biology. It covers topics such as the cell cycle, chromosome number, mitosis, and meiosis in eukaryotic cells.

Full Transcript

Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline

Specific Outcome 1.1
Define and explain the significance of chromosome number
in somatic and sex cells.
p.550-552

Cell Division and the Cell Cycle
§ Cell cycle – the life cycle of the cell
§ Somatic cells – body cells
o Some examples include blood cells, skin cells, nerve cells
o The parent cell will pass on genetic information to its daughter cell
§ Sex cells- cells that contain half of the genetic information in humans

Genetic information in Eukaryotic Cells ( organized membrane bound
nucleus )
§ Deoxyribonucleic Acid (DNA) – nucleic acids that control all processes of
heredity in cells
§ Chromosomes – DNA and associated proteins are found in these in the nucleus
o Single human cell = 3 m DNA that is organized into chromosomes using proteins
(histones) to compact the material within the cell
o Chromatin – long intertwined strands that condense to make chromosomes
visible to a microscope
o Centromere – specialized region where the chromosome is pinched in that helps
in the cell division process

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
Chromosome Number
§ Humans – 22 homologous chromosomes (similar looking) as well as 2 sex
chromosomes
o Diploidy (Homologous chromosomes)
§ A cell containing pairs of homologous chromosomes
§ carry the same genes at the same location(locus)
§ They appear to look the same yet they carry different forms of genes (alleles)
§ Eg. Humans – the diploid number is 46 or 23 pairs
o Haploidy (Sex Chromosomes)
§ A cell that contains unpaired chromosomes
§ Eg. Human gametes (eggs or sperm) are haploid
§ Haploid number is represented by, n.

EXAMPLE: Humans:
§ All species differ in numbers of chromosomes
§ n=23 and diploid cells have 2n chromosomes (2n=46)

o Polyploidy
§ Sets of more than two homologous chromosomes
o assessing results.

Specific Outcome 1.2
Explain, in general terms, the events of the cell cycle.
p.553-559

Stages of the Cell Cycle
§ Mitosis is a process produces diploid cells from diploid cells that ARE identical.
§ Interphase
o This is the growth stage and the cells spends most time here
o Cell continues metabolic functions and prepares for its next division
o G1 (Gap 1)
§ Cells grows quickly here
o S (Synthesis)
§ New genetic material is synthesized here
§ DNA in the chromatin replicates to create a second identical set of DNA (sister
chromatids joined by the centromere forming the chromosome)
o G2 (Gap 2)
§ Second growth phase to allow the cell to rebuild its reserve energies to
prepare for cell division
§ Also produces proteins and structures required for division

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline

§ Phases of Mitosis
§ This is the division of the genetic material and the contents of the nucleus into two
complete and separate sets
§ Purpose:
o Growth
o Maintenance
o Repair
§ Prophase
o Chromatin condenses into tightly packed chromosomes
o Nuclear membrane breaks down, releasing the chromosomes into the cytoplasm
o Nucleolus disappears
o Centrioles (cylindrical organelles) will move part to opposite sides of the cell
o Network of spindle fibres (spindle apparatus) will form to help facilitate movement
of chromosomes within a cell
§ Metaphase
o Spindle fibres guide the chromosomes to the equator or centre line
o Spindle fibres will attach to the centromere of each chromosome
o The fibres will align so that the sister chromatids will be pulled to opposites sides
(centromeres)
§ Anaphase
o Each centromere is splits apart and the sister chromatids separate from one
another
o The spindle fibres connected to the centromeres begin to shorten thereby pulling
sister chromtids to opposite sides
o One diploid set of chromosomes has been gathered at each pole

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
§ Telophase
o Chromatids begin to unwind into longer and less visible strands of dna
o Spindle fibres break down
o Nuclear membrane forms around each set of new chromosomes and a nucleolus
forms within each new nucleus

§ Cytokinesis
o The division of the cytoplasm and the organelles into two separate daughter cells
o Indentation depends until the cytoplasm and organelles pinch into two identical
cells
o The cells are now in G1 phase.

Specific Outcome 1.3
Describe the process of meiosis and the necessity for
the reduction of chromosome number.
p.563-565

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
Meiosis
§ The purpose of meiosis is for female and male gametes to come together to produce a
unique zygote (sexual reproduction)
§ The zygote is NOT identical to either parent but has genetic information from both
§ Meiosis is a process produces haploid gametes from diploid cells in the ovaries and
testes

Reduction division
§ Meiosis
§ Cell division that produces daughter cells with fewer chromosomes than the parent
cells

§ Recombination division
§ Products of meiosis have different combinations of genes
§ Offspring are not identical to parents (unlike mitosis)

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline

Phases of Meiosis
§ Meiosis I
o Interphase
§ Growth and synthesis
§ Chromosomes are replicated in the S phase of interphase allowing the germ
cell to begin meiosis with duplicated chromosomes
Identical sister chromtids held together by a centromere

o Prophase I
§ Homologous chromosomes does not mean identical (same genes different
alleles)
§ Synapsis – aligning of homologous chromosomes (4 sister chromatids line up
= tetrad)
§ Non-sister chromatids – homologous chromosomes that are non-identical lies
side by side
o Metaphase I
§ Spindle fibres from each pole attach to the centromeres of each homologous
chromosome
§ They line up at the equator of the cell as homologous chromosomes (not single
file like mitosis)
o Anaphase I
§ Spindle fibres shorten causing the homologous chromosomes to separate to
opposite poles of the cell
§ A single homologous chromosome (two sister chromatids) move to each pole
o Telophase I
§ Homologous chromosomes will begin to uncoil and spindle fibres disappear
§ Cytoplasm is divided, nuclear membrane forms around each group of
homologous chromosomes
§ Each of the two cells is haploid but with duplicated sister chromatids

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
§ Meiosis II
o The phases to this cell division are very similar to mitosis
o Each cell enters as haploid (n) but with duplicated chromatids
o Each cell that leave will also be haploid with unreplicated chromosomes

Gamete Formation in Animals
o Mitosis is also happening to keep a supply of germ cells
o Spermatogenesis
§ Testes
§ Begins with a diploid cell (spermaogonium) which will split at puberty
creating two cells:
One cell will replenish the spermatogonia cell population
One cell will form a primary spermatocyte (undergoes meiosis I)
that undergoes meiosis I to form two secondary spermatocytes
The secondary spermatocytes will undergoes meiosis II to form 4
spermatids
Spermatids will develop into mature sperm by:
o Head region = Nucleus and certain enzymes
o Midsection = many mitochondria (energy source)
o Long tail flagellum = locomotion

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
Oogenesis
§ Ovaries
§ Begins with a diploid cell (oogonium) which will undergo mitosis to form two
primary oocytes
§ One primary oocyte (diploid) will undergo meiosis and an unequal splitting
of cytoplasm and two cells are formed:
Polar body – not functional and will soon degenerate
Secondary oocyte - most cytoplasm
§ Secondary oocyte (haploid) undergoes meiosis II again dividing cytoplasm
unequally
Mature egg – contains large amount of nutrients for implantation
Second polar body – not a viable gamete

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
Specific Outcome 1.4
Compare the processes of meiosis and mitosis.
p.568

Specific Outcome 1.5
Describe the process of crossing over and non-disjunction and evaluate their
significance to organism inheritance and development.
p.566-567

Genetic Recombination
§ Independent Assortment
o Metaphase I, the chromosomes will align so that the paternal chromosomes will
move in opposite directions to allow for exchange of genetic information
§ Crossing Over
o Prophase I; homologous chromosomes pair up
o Crossing over – sister chromatids will exchange pieces of chromosomes
o May contain 100’s to 1000’s of genes

Nondisjunction
§ Nondisjunction occurs when chromosomes or chromatids do not separate as they
should producing too many (trisomy – down syndrome) or too few (monosomy –
turner syndrome) chromosomes
§ Occurs in anaphase I and II of meiosis
§ Anaphase I – homologous chromosome pairs do not separate to opposite poles
§ Anaphase II – when sister chromatids are pulled toward the same pole together

o Prophase I
§ Homologous chromosomes does not mean identical (same genes different
alleles)
§ Synapsis – aligning of homologous chromosomes (4 sister chromatids line up
= tetrad)
§ Non-sister chromatids – homologous chromosomes that are non-identical lies
side by side
o Metaphase I
§ Spindle fibres from each pole attach to the centromeres of each homologous
chromosome
§ They line up at the equator of the cell as homologous chromosomes (not single
file like mitosis)

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
o Anaphase I
§ Spindle fibres shorten causing the homologous chromosomes to separate to
opposite poles of the cell
§ A single homologous chromosome (two sister chromatids) move to each pole
o Telophase I
§ Homologous chromosomes will begin to uncoil and spindle fibres disappear
§ Cytoplasm is divided, nuclear membrane forms around each group of
homologous chromosomes
§ Each of the two cells is haploid but with duplicated sister chromatids

§ Meiosis II
o The phases to this cell division are very similar to mitosis
o Each cell enters as haploid (n) but with duplicated chromatids
o Each cell that leave will also be haploid with unreplicated chromosomes

§ Gamete Formation in Animals
o Mitosis is also happening to keep a supply of germ cells
o Spermatogenesis
§ Testes
§ Begins with a diploid cell (spermaogonium) which will split at puberty
creating two cells:
One cell will replenish the spermatogonia cell population
One cell will form a primary spermatocyte (undergoes meiosis I)
that undergoes meiosis I to form two secondary spermatocytes
The secondary spermatocytes will undergoe meiosis II to form 4
spermatids
Spermtids will develop into mature sperm by:
o Head region = Nucleus and certain enzymes
o Midsection = many mitochondria (energy source)
o Long tail flagellum = locomotion
o Oogenesis
§ Ovaries
§ Begins with a diploid cell (oogonium) which will undergo mitosis to form two
primary oocytes
§ One primary oocyte (diploid) will undergo meiosis and an unequal splitting
of cytoplasm and two cells are formed:
Polar body – not functional and will soon degenerate
Secondary oocyte - most cytoplasm
§ Secondary oocyte (haploid) undergoes meiosis II again dividing cytoplasm
unequally

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
Mature egg – contains large amount of nutrients for implantation
Second polar body – not a viable gamete

Specific Outcome 1.6
Compare the formation of fraternal and paternal offspring in a single birthing
event.
p.570-571

Specific Outcome 1.7
Describe the different reproductive strategies by comparing the alternation of
generations a range of organisms
p.573-579

Sexual reproduction – production of gametes by meiosis followed by fertilization
between genetically different individuals to produce genetically distinct offspring

Reproduction in Prokaryotes (bacteria)
§ Binary fission – asexual reproductive process of cell division in bacteria producing
genetically identical offspring (instead of mitosis)
o Single circular chromosome and nonucleus
o Exponential growth (cells can divide in as little as 20 minutes and then each
daughter cell doubles in another 20 minutes
o BENEFIT: Huge population growth in little time
o DOWNFALL: genetically identical individuals could be wiped out by toxins or
viruses
§ Conjunction – transfer of genetic material from one cel to another by cell-to-cell
contact through a pilus (bridging structure)
o Creates cells with new genetic information
o BENEFIT: creates fenetically unique daughter cells
o DOWNFALL: new cell can reproduce through binary fission to create colony

Asexual reproduction
§ reproductive process in which a parent organism produces genetically distinct
offspring
§ Budding – a complete but minature version of the parent will grow out from the
parents body
o Example - hydra
§ Vegetative reproduction – spreading of stems across an area that will eventually
develop roots and separate from its parent.
o Example – strawberry plants

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.
 Biology 30
Unit C: Cell Division, Genetics & Molecular Biology
Curriculum Outline
§ Fragmentation – creation of new plants from a fragment of a parent plant
o Example - Cultivation of potatoes using tubers(fragments) or gardeners
cuttings’
§ Parthenogenesis – a form of asexual reproduction in which an unfertilized egg
develops into an adult
o Example – honeybees lay both fertilized and unfertilized eggs; fertilized eggs
develop into female worker bees; unfertilized eggs will develop into male drones
§ Spores – structure that will contain genetic information and can be spread over
large distances
o Enables the offspring to take advantage of a favourable environment, limits the
organism’s ability to spread quickly to more distant environments
o Also has a protective covering that will protect the spore until a favourable
environment
o Spores may be haploid or diploid

Alternation of Generations
§ Life cycle of plants consists of two alternate generations; a haploid generation as
well as a diploid generation
§ Sporophyte
o Diplod generation
o meiosis will produce one or more haploid spores
§ Gametophyte
o Haploid generation
o gamete making body
o produces female and male gametes that fuse at fertilization and develop another
sporophyte … on and on…
§ one generation is usually dominant over the other generation
§ Vascular plants – diploid sporophyte
§ Non-vascular plants – haploid gametophyte
§ Mosses
o Gametophyte – leafy green mat produces sperm and egg; sperm swim to eggs in
moist environments
o Sporophyte – stalk that grows up from the mat (only a few times a year)
§ Conifers
o Sporophyte – tree itself (diplod)
o Gametophyte – male cones (smaller releases pollen to fertilize female cones) and
female cones (larger)

Alternation in Sexual Cycles
§ Found only in plants
§ Alternation between sexual reproduction and asexual reproduction
§ Example – phylum cnidaria (jellyfish, sea anemones, corals)
o Polyp – adult form (non-motile)
o Medusa – adult form (motile)
Describe Advantages and Disadvantages of Reproductive Strategies:

GENERAL OUTCOME 1
You will be able to describe the processes of mitosis and meiosis.