Mitosis

Why do cells need to divide?

Recap…

Cell theory…

Cells are the basic structural unit of life

Cells are the functional units of life

Cells come from pre-existing cells

Overview

Why do cells need to divide?

Repair, growth, development

Types of reproduction

Sexual

Genetically different

2 parents

Takes time to develop, better chance of survival

asexual

Genetically identical

One parent

Many offspring very quickly

DNA

Blueprint of life, nucleic acid

Chromatin

Granular genetic material, spread out in

nucleus of non-dividing cells

Chromosomes

Condensed genetic material, in dividing cells

Sister chromatids

Identical copies of Chromosomes joined by

a centromere (“centro-” middle)

Humans

46 chromosomes

46 sister chromatids

One from your mom, one from your dad

Cell Cycle: Life of a Cell

Cell Cycle

Interphase

90 % of cell’s life, non dividing

G1 phase

Grows, makes organelles

S phase

DNA Synthesis…DNA replicates

G2 phase

Cell prepares to divide, makes sure it has all important

organelles for division

M phase

When the cytoplasm and nucleus of the cell

divides

Cell Cycle

There are check points in G1, S, and G2

Make sure cell is ready to move onto the

next phase (has all necessary organelles,

copied DNA, etc.)

Once the cell has past the G1

checkpoint, it will complete the cell cycle

Some cells stay in the G1 phase all their

life (muscle cell, brain cells)

Regulators of Cell Cycle

Cyclins

Protein that regulates the timing of the cell

cycle in eukaryotic cells

Levels of cyclins rise and fall throughout the

cell cycle

Cyclin-dependent Kinases (cdks)

Enzymes that are activated when they bind

with cyclin and they make the cell cycle

continue

Regulators

Internal

Factors within the cell that control cell cycle

Cyclin and CDKs

Allow cell cycle to proceed only when certain processes

have occurred

Replication of chromosomes

Chromosome Attachment to spindle before anaphase

External

Factors Outside the cell

Growth factorsmolecules that bind to cell surface that

signal cell to divide

Similar cells have molecules that have opposite effect so

that when it becomes to crowded, cells stop dividing

M-phase

Consists of mitosis and

cytokinesis

Mitosis

Process by which the

nucleus of a cell divides

One parent cell makes two

identical daughter cells

This is how organisms

repair tissue and grow and

develop

Cytokinesis-division of the

cytoplasm

Depending on cell type…

Mitosis can take a few minutes or a few

days

Muscle cells (non-dividing)

Nerve cells (non-dividing)

Skin cells (divide all the time)

Digestive Tract cells (divide all the time)

Life Span of Some Human

Cells

Cell type Life span Cell division

Lining of esophagus 2-3 days Can divide

Lining of small intestine 1-2 days Can divide

Lining of the large

intestine

6 days Can divide

Red blood cells Less than 120 days Cannot divide

White blood cells 10 hours to decades Many do not divide

Smooth muscle Long-lived Can divide

Cardiac (heart) muscle Long-lived Cannot divide

Skeletal muscle Long-lived Cannot divide

Neurons (nerve) cells Long-lived Most do not divide

Prophase

50-60% of time

Chromosomes become visible

Centrioles develop in cytoplasm near nuclear

envelope

Centrioles separate and migrate to opposite ends

of nuc. Env.

Centrosome

Region where Centrioles are found

Organize the “spindle”

Fan like microtubule structure that helps separate

chromosomes

Plants do NOT have Centrioles

End of prophase

Chromosomes coil together tightly

Nucleolus disappears

Nuclear envelope breaks down

Metaphase

Few minutes

Chromosomes line up in middle (M in

metaphase MIDDLE)

Microtubules connect centromere of each

chromosome to the 2 poles of spindle

Anaphase

Centromeres joining sister chromatids

separate and become individual

chromosomes

They are dragged by fibers to opposite

poles

Ends when chromosomes stop moving

Telophase

Opposite of prophase

Condensed chromosomes disperse into

tangle of material

Nuclear envelope reforms

Spindle breaks apart

Nucleolus becomes visible

At the end 2 identical nuclei in one cell

Cytokinesis

Happens at the same time as Telophase

Division of cytoplasm

Animal Cells

Cell membrane drawn inward until it pinches

off and forms 2 id daughter cells

Plant Cells

Cell plate forms between nuclei

Cell Plate develops into separate membrane

Cell wall appears

Regulators of Cell Cycle

Cyclins

Protein that regulates the timing of the cell

cycle in eukaryotic cells

Levels of cyclins rise and fall throughout the

cell cycle

Cyclin-dependent Kinases (cdks)

Enzymes that are activated when they bind

with cyclin and they make the cell cycle

continue

Regulators

Internal

Factors within the cell that control cell cycle

Cyclin and CDKs

Allow cell cycle to proceed only when certain processes

have occurred

Replication of chromosomes

Chromosome Attachment to spindle before anaphase

External

Factors Outside the cell

Growth factorsmolecules that bind to cell surface that

signal cell to divide

Similar cells have molecules that have opposite effect so

that when it becomes to crowded, cells stop dividing

MEIOSIS

Gregor

Mendel

1822

Austrian monk

University of

Vienna

In charge of

the Garden

What Gregor Mendel

Knew…

Each organism must inherit a single copy of every gene from each of its “parents”

Each of the organisms gametes must contain just one set genes

When gametes are formed, there must be a process that separates the 2 sets of genes so each gamete gets one set

Karyotype

A photograph of a organism’s

chromosomes, arranged according to

size

http://upload.wikimedia.org/wikipedia/commons/5/53/NHGRI_human_male_karyotype.png

http://en.wikipedia.org/wiki/File:Down_Syndrome_Karyotype.png

Chromosome Number

Homologous chromosomes

Chromosome that has a corresponding

chromosome from the opposite-sex parent

Fruit fly has 8 chromosomes

4 from mom

4 from dad

Diploid

Di= two sets

Cell that contains both sets of homologus chromosomes Cell contains

2 complete sets of chromosome

2 complete sets of genes

Number of chrms in diploid cell represented by 2N

For Drosophilia (fruit fly) 2N=8

Mendel said: Each adult cell contains two copies of each gene

Haploid

Means “one set”

Refers to cells that contain only one set

of chromosomes

Gametes (sex cells)

Represented by N

Drosophilia fruit fly

N=4

How are

haploid (N)

gametes made

from diploid

(2N) cells?

Meiosis

Process of reduction division in which the

number of chromosomes per cell is cut in

half through the separation of

homologous chromosomes in a diploid

cell

Meiosis

2 distinct stages

Meiosis I

A diploid cell enters here

Meiosis II

At the end of this, the diploid cell that

entered meiosis has become 4 haploid cells

Meiosis I

Before meiosis 1, each chromosome is replicate

Then they divide like in mitosis

What happened in mitosis? PMAT

Tetrad STRUCTURE MADE WHEN EACH

CHROMOSOME PAIRS UP WITH ITS HOMOLOGOUS CHROMOSOME

4 CHROMATIDS IN A TETRAD

Prophase 1

Each chromosome pairs with its

homologous chromosome making a

tetrad

As they pair up in tetrads, chromosomes

exchange portions of their chromatids in

the process …. CROSSING OVER

Crossing Over

Metaphase1

Spindle fibers attach to chromosomes

Anaphase 1• The spindles pull homologous

chromosomes apart to opposite

poles/ends

Telophase 1• Nuclear membranes form and cell

separates into two new cells

Now what do we have?

2 new daughter cells

Are they identical to the parents?

No

The parent has 4 chromosomes

Each daughter cell has 4 chromosomes but they

are different because of crossing-over

Each daughter cell has a set of chromosomes

and alleles different from each other and

different from the parent diploid cell

Meiosis II

Unlike Mitosis, Neither cell goes through

a round of chromosome replication

Each cell’s chromosome has 2

chromatids

Prophase II

Meiosis I resulted in 2 “seemingly” diploid

cells

Remember they are genetically different b/c

of crossing over in prophase I

We still need to cut this number in half to

reach our goal of 4 haploid cells

Metaphase 2

Chromosomes line up in middle

Anaphase 2• Sister chromatids separate and move to

opposite poles

Telophase 2• Meiosis II results in 4 haploid (N)

daughter cells

• 4 daughter cells contain haploid number

of chromosomes, just 2 each

Gamete Formation

Male

Haploid gametes produced by meiosis are called

sperm

Female

Haploid gamete produced by meiosis is called an

egg

Cell divisions at the end of meiosis one and two

are uneven so one cell gets most of the cytoplasm

(the EGG) and the other three are called polar

bodies (don’t participate in reproduction)

Mitosis vs. Meiosis

Mitosis Results in the production of two genetically

identical DIPLOID cells

Daughter cells have sets of chromosomes identical to each other and to parent cell

MITOSIS allows body to grow and replace other cells

Asexual reproduction

Meiosis Results in four genetically different HAPLOID cells

MEIOSIS is how sexually reproducing organisms make gametes

Genes

Microscope Lab Analysis

Mitosis/Meiosis Microscope Lab Lab notebooks Title

“Cell Division Microscope Lab”

MUST sketch each stage and label the power

Label slide name

Stage of mitosis or meiosis

Power of the objective used to observe cell

Need to observe each stage of mitosis and meiosis