Animal phys chapter 5 part 2
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Transcript of Animal phys chapter 5 part 2
Passive Solute Transport by Facilitated Diffusion
• Polar, organic, hydrophilic solutes such as glucose and amino acids
• Noncovalent and reversible binding of the solutes to transporter/carrier proteins
• Always in the direction of electrochemical equilibrium
• Faster then non-facilitated diffusion
Active Transport
• Carrier-mediated• Requires energy (ATP)• Can move solutes against the electrochemical gradient• Subject to saturation kinetics • Many different solutes – inorganic ions, amino acids, sugars• Not H2O or O2
• Can create voltage difference:– Electroneutral- do not generate a an imbalance of charge– Electrogenic-do create an imbalance of charge
Electroneutral active transport is responsible for secretion of stomach acid in the vertebrate stomach lining
Primary Active Transport
• Draws energy immediately from the hydrolysis of ATP-transporter is an ATPase
Na+-K+-ATPase• P-type ATPases: the protein becomes phosphorylated and
dephosphorylated during each pumping cycle (others include CA2+-ATPase and H+-K+-ATPase)
• Exhibit strict coupling between their molecular conformation and ATP hydrolysis
Secondary Active Transport
• Draws energy from an electrochemical gradient of a solute• Usual mechanism of transport for organic solutes• ATP is used to create the gradient• Example: glucose absorption in the small intestine of the
hummingbird-glucose is moved from [low][high]-it is carrier-mediated-the energy source for the uphill transport is metabolism:
draws energy from an electrochemical gradient of a solute
Box 5.1 Two examples of energy coupling via an intermediate step in which energy is temporarily stored as potential energy
Figure 5.12 The secondary active transport of glucose into an epithelial cell of the vertebrate small intestine
Cotransport: a transporter protein moves two solutes in a linked fashion in one direction
Countertransport: a transporter moves two solutes in obligatorily linked fashion in opposite directions (the protein is called a countertransporter)
Figure 5.13 A species of hummingbird exhibited the highest capacity for intestinal glucose absorption of 42 vertebrate species measured
Hummingbirds have an
unusually high activity of the cotransporter
for glucose
Figure 5.15 A whole-epithelium view of active ion transport across the gill epithelium of a typical freshwater fish
Summary of Active Transport
• Converts energy obtained from the catabolism of foodstuffs into solute motive energy and therefore away from electrochemical equilibrium.
• Solutes must bind noncovalently to a transporter protein for active transport to occur (carrier-mediated). A 2nd type is facilitated diffusion which does not use metabolic energy and is therefore only towards equilibrium.
• Active transport is primary if the transporter protein is an ATPase and thus draws energy directly from ATP bonds. Primary active-transport mechanisms pump ions.
• Active transport is secondary if the energy source is a solute gradient and requires transporter proteins (used for ions and organic solutes).
Diversity and Modulation of Channels and Transporters
• Channels and transporter proteins exist in multiple molecular forms.– Can have distinct transport, catalytic and modulation characteristics providing
opportunity for adaptation.
• Controlled by gene expression
• Noncovalent (ligand gating) and covalent (phosphorylation) modification occurs
• Insertion and retrieval modulation (i.e. H+-K+-ATPase in acid-secreting cells of the stomach move from intracellular membranes to extracellular membranes when a meal is ingested)
Colligative Properties of Aqueous Solutions
Depends on the number of dissolved entities per unit of volume rather than the chemical nature of the dissolved entities
1. Osmotic pressure: the property of a solution that allows one to predict whether the solution will gain or lose water by osmosis when it undergoes exchange with another solution
2. Freezing point: the highest temperature capable of inducing freezing
3. Water vapor pressure: the tendency of a solution to evaporate
Raising the concentration of dissolved entities in a solution increases the osmotic pressure of the solution and lowers the solution’s freezing point and
water vapor pressure the osmotic pressure is proportional to the concentration of dissolved entities
For example: doubling the concentration of solutes doubles the osmotic pressure
However, doubling [solute] doubles the difference between the freezing point or water vapor pressure of a solution and that of pure water (freezing-point
or water-vapor depression)
So…osmotic pressure, freezing-point depression and water-vapor-pressure depression are all proportional to each other. Therefore if you know one you can calculate the others!
Solutions of nonelectolytes that are equal in their molar chemical concentrations are identical in their osmostic pressures and other colligative properties.
Solutions of electrolytes (i.e. NaCl) will dissociate in solution and therefore have more dissolved entities and therefore corresponding colligative properties (i.e. a 0.1-M NaCl solution will have an osmotic pressure and freezing-point depression 2 times higher than a 0.1-M glucose solution)
Units of Osmolarity
A 1-osmolar (Osm) solution behaves as if it has 1 Avogadro’s number of independent dissolved entities per liter a 1-Osm solution has the same osmotic pressure as is exhibited by a 1M solution of ideal nonelectrolyte
Seawater and blood are ~1 Osm
Milliosmolarity (mOsm): a 1 mOsm behaves as if it has 0.001 Avogadro’s number of independent dissolved entities per liter
Figure 5.18 Predicting the direction of osmosis between two solutions from measurements made independently on each
Osmosis• Passive transport of water across a membrane
• Water moves from LowHigh osmotic pressure
• Water itself is more abundant per unit of volume where dissolved matter is less abundant
• Two solutions are isosmotic if they have the same osmotic pressures
• If two solutions have different pressures the lower one is termed hyposmotic and the higher one is hyperosmotic
• Osmosis can occur through simple diffusion across cell membranes or 5 to 50 fold faster through aquaporins (channel-mediated water transport)