Transcript Slide 1

Mitochondria
Chromosomes
Golgi
Apparatus
Endoplasmic
Re culum
Plasma
Membrane
Ribosomes
Nucleus
Receptors
Schematic of the plasma membrane
http://www.ncnr.nist.gov/programs/reflect/rp/biology/cell_membrane.html
Cell Division:
1) Mitosis-ordinary cell division
2) Meiosis-gamete cell division
Mitosis:
Ordinary cell division
Mitosis:
I. Chromosomes are expanded into long
structures in the nucleus and are invisible
under the light microscope.
Mitosis:
II. Chromosomes replicate and condense. With
appropriate staining, they can now be seen
under a microscope.
Mitosis:
III. The nuclear wall degrades, spindles form
and attach themselves to the chromosomes.
Mitosis:
IV. Spindles pull the chromosome pairs apart,
pulling them to opposite poles of the cell.
Mitosis:
V. Nucleus develops around each set of
chromosomes and the cell wall starts to form,
splitting the cell.
Mitosis:
VI. Nucleus and cell wall complete development
and chromosomes expand, giving two daughter cells.
Meiosis:
Cell Division
Generating Gametes
Meiosis:
I. As in mitosis, chromosomes
replicate and condense.
Meiosis:
II. Unlike mitosis, the maternal (solid) and
paternal (dotted) chromosomes pair up
and exchange genetic material.
Meiosis:
III. Spindles form, attach themselves and
pull the chromosomes to the poles of the cell.
Meiosis:
IV. The cell divides.
Meiosis:
V. Spindles form again and pull each
chromosome away from its partner.
Meiosis:
VI. Each cell divides again, reducing the number of
chromosomes to half that of the original cell.
Cell Workings:
Metabolism &
Catabolism
Key Concepts:
1) Lock & Key
2) Cut or Paste
Tyrosine
tyrosine
hydroxylase
DOPA
(dihydroxyphenylalanine)
DOPA
decarboxylase
DA
(dopamine)
dopamine
b hydroxylase
NE
(norepinepherine)
Cell Communication:
Key Concepts:
1) Lock (Receptor) & Key (Hormones,
Neurotransmitters)
2) Dimmer Switch
The Neuron
Terminal
Dendrites
Cell
Body
Axon
Nucleus
Buttons
Glial Cell
Neurons
© DennisKunkel: www.DennisKunkel.com
Neurons
http://www.alz.org/brain/05.asp
Synaptic Button
Vesicle
Neurotransmitter
molecules
Receptor
Vesicle
1. Neuron fires.
2. Vesicles release
neurotransmitter which
exits the cell.
Neurotransmitter
3. Neurotransmitter
binds with receptor
initiating a cascade
of chemical events
in the next cell.
Presynaptic
Neuron
Enzyme
Presynaptic
Receptor
4. Excess neurotransmitter chewed up by enzymes
and/or taken back by the neuron
where it may also be degraded
Enzyme
by enzymes.
Postsynaptic
Receptor
Postsynaptic
Neuron
http://www.drugabuse.gov/pubs/teaching/teaching4/largegifs/slide10.gif
http://www.driesen.com/neurotransmitter_processes.jpg
Effects of
neurotransmission:
1) Short term = ion transfer
(changes polarity of postsynaptic neuron)
2) Long term = second messenger system
(changes proteins, changes dimmer switch)
+
+
Presynap c
Neuron
Neurotransmi er
CA++ ion
NA+ ion
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
1
+
+
+
+ +
+
+
++ ++ ++ +
+
+
+ ++ + + +
+
+
+
+
+
+ +
+
+
+
+
+
+
Plasma
Membrane
+
+
+
+
+
+
+
+
+
2
3
+
+
+
Postsynap c
Cytosol
+
+
+
+ +
+
+
+
+
+
+
+
+
+
+
Presynap c
Neuron
Neurotransmi er
Binding site of the
receptor complex
Messenger unit of the
receptor complex
Plasma
Membrane
Postsynap c
Cytosol
1
2
3
Signal to
the Cell
Glu
2+
Ca
Serotonin
Plasma
Membrane
Glutamate
Receptor
Gatekeeper
Activate
“dimmer
switches”
of genes
Serotonin
Receptor
Sentinel
Second
Messenger
Serotonin projections from the Raphe
Raphe nuclei
http://learn.genetics.utah.edu/content/addiction/reward/pathways.html
Serotonin second
messenger signaling
pathway
http://www.ariadnegenomics.com/products/pathway-studio/sample-pathways/serotoninr-1/