1 The Plasma Membrane The Plasma Membrane - Gateway to the Cell.
The Plasma Membrane Cell-Environment Interactions.
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Transcript of The Plasma Membrane Cell-Environment Interactions.
Goals
• Describe the Role of the glycocalyx when the cells interact with their environment
• Describe the roles of the membrane receptor and voltage sensitive membrane channel proteins
Interactions
• The cell can interact directly with other cells by direct contact.
• Or indirectly through chemicals such as hormones and neurotransmitters
Interactions
• The glycocalyx is involved in these interactions• To accomplish this, glycocalyx molecules fall
into two broad categories– Cell adhesion molecules &
Interactions
• The glycocalyx is involved in these interactions• To accomplish this, glycocalyx molecules fall
into two broad categories– Cell adhesion molecules &– Plasma membrane receptors
Role of Cell Adhesion Molecules(CAM)
• Every cell has thousands of CAM proteins.
• CAM’s are classified as– Cadherins &– Integrins
Role of Cell Adhesion Molecules(CAM)
They act as :• Molecular Velcro such as the
desmosomes and other cell attachment points
Role of Cell Adhesion Molecules(CAM)
They act as :• Molecular Velcro such as the
desmosomes• The arms of migrating cells, that
allow cells to pull past each other
Role of Cell Adhesion Molecules(CAM)
They act as :• Molecular Velcro such as the
desmosomes• The arms of migrating cells that
allow cells to pull past each other• SOS signals for broken blood vessels
that attract white blood cells
Role of Cell Adhesion Molecules(CAM)
They act as :• Molecular Velcro such as the
desmosomes• The arms of migrating cells• SOS signals for broken blood vessels that
attract white blood cells• Mechanical stressors that respond to
local tension on the cell surface stimulating or degrading membrane components
Role of Cell Adhesion Molecules(CAM)
They act as :• Molecular Velcro such as the desmosomes• The arms of migrating cells• SOS signals for broken blood vessels that
attract white blood cells• Mechanical stressors that respond to local
tension on the cell surface stimulating or degrading membrane components
• Transmitters of intracellular signals that direct cell migration and proliferation
Role of Membrane Receptors
Glycoproteins can serve as membrane receptors.
There are several types:– Contact signaling receptors– Chemical Signaling receptors – G protein receptors
Role of Membrane Receptors
Contact Signaling Receptors occur when cells come into contact with each other. This is important in normal development and immunity. For example, the histocompatibility markers used in organ tansplants
Role of Membrane Receptors
Chemical signaling represents the most common group.
Ligands, the signaling molecule, binds to a membrane receptor. Examples of ligands include neurotransmitters and hormones.
Role of Membrane Receptors
• Different cells can respond differently to the same ligand
• For example, the neurotransmitter, norepinephrine contracts the smooth muscle in the arteries and dilates the smooth muscle in the bronchi
Role of Membrane Receptors
This is due to how the internal machinery of the cell is attached to the receptor.
This can be accomplished several ways:
Role of Membrane Receptors
This can be accomplished several ways:• By the receptor acting as an enzyme
Role of Membrane Receptors
This can be accomplished several ways:• By the receptor acting as an enzyme• By being a chemically gated channel
where ion gates are open or closed briefly
Role of Membrane Receptors
This can be accomplished several ways:• By the receptor acting as an enzyme• By being a chemically gated channel
where ion gates are open or closed briefly
• Others are coupled to a regulatory molecule called the G protein
The G Protein
The G protein acts as a relay between the receptor and its effector (enzyme or channel)A second messenger is generated to accomplish this.Two major second messengers are cyclic AMP and Ca+2
The G Protein
These second messengers activate protein kinases which go on and activate other enzymes amplifying the effect on the receptor stimulation.
Brugada Syndrome
• Brugada is a genetic disease characterized by an abnormal EKG that carries an increased risk of sudden death.
• It is a cause of Sudden Adult Death Syndrome (SADS)
• It has been associated with a defect in the sodium ion channel. This can lead to potentially fatal cardiac arrhythmias
Brugada Syndrome
• Warning Signs of SADS• family history of unexpected, unexplained
sudden death under age 40• fainting or seizure during exercise,
excitement or startle• consistent or unusual chest pain and/or
shortness of breath during exercise.