Diffusion, , and NOTES January 23, 2012

DIFFUSION, OSMOSIS, and OSMOREGULATION Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

DIFFUSION

* All are in constant random motion (Brownian Motion).

* The rate of this motion increases with increasing and decreases with decreasing temperature.

* Diffusion - the directional movement of molecules from and area of high of that to an area of lower concentration of that molecule.

* Molecules moving from high to low concentration are said to be moving "with the concentration gradient".

* No is required.

* Diffusion occurs in the air and in . Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

OSMOSIS * A specialized type of diffusion.

Osmosis - the diffusion of water through a .

* No energy is required

* In , osmosis will always deal with the movement of water into cells or out of cells. = water molecule Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

What's wrong with this picture?????

Jim Davis didn't study his Biology. Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

Passive vs.

Passive Transport - the movement of molecules, into or out of cells, with the concentration gradient.

* No energy required by the .

* Examples: diffusion and osmosis

*Active Transport - the movement of molecules, into or out of cells, against the concentration gradient. (from low to high concentration)

* This requires the cell to expend energy (ATP's).

* Specialized in cell , called carrier proteins, pump the molecules against the concentration gradient. ACTIVE TRANSPORT Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

Movement Into/Out of Cells

* All cells are surrounded by a .

* Composition?

* Cell membranes are selectively permeable; they discriminate based on the size of the molecule. Cell's environment

Cell

Cell Membrane Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012 Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

Osmoregulation

* that live in water must regulate the water concentration inside their cells to maintain .

* The osmosis problem is different for fresh water and salt water organisms. Fresh water is a hypotonic , while salt water is a hypertonic solution.

FRESH WATER SALT WATER FISH Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

Different evolutionary strategies have evolved to osmoregulate.

Osmoconformers:

-Don't actively maintain internal salt and . Their internal change as salinity changes.

- Unable to control the flooding of tissues at low salinity.

- Often stay in a salinity that matches body fluids. They don't expend energy to maintain levels but, if they get outside this range, they have a problem. Many conformers are found in areas of the ocean with stable salinity.

- Most marine invertebrates. Ex: Starfish, Jellyfish, Squid Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

Osmoregulators: -Actively maintain internal salt and water balance regardless of external conditions. -Most marine vertebrates are osmoregulators. Ex: Tuna, Sharks, Salmon

Two regulation strategies: 1. Sharks will actively maintain a high level of the solute urea, in their tissues to match the water's solute concentration. In this way, their internal solute/water concentrations match their environment's. Not many shark species in/near fresh water.

The Dunaliella can concentrate glycerol to regulate from fresh to 9x saltier.

2. Marine fish, use active transport to move solutes out of the cells and use their kidneys to conserve water. In addition, many marine fish will drink the salt water to replace the water lost by osmosis.

Some species, like salmon, are able to go from salt to fresh water. Diffusion, Osmosis, and Osmoregulation NOTES January 23, 2012

In marine fish, what cells must be in direct and constant contact with the surrounding water?

Ways to "shield" cells from direct contact with the watery environment: