renal trasport.pdf

Transcript

Renal Transport
Mechanisms
Dr. Mohammed Hamza

Tubular Reabsorption
• Tubular reabsorption is the transfer of materials from
kidney tubule lumen to peritubular capillaries.
• There are three important conclusions as to the
glomerular filtration and tubular reabsorption processes:
1. The filtered loads are enormous, generally larger
than the total amounts of the substances in the
body.
• For example, the body contains about 40 L of
water, but the volume of water filtered each day
is 180 L.

Tubular Reabsorption
• There are three important conclusions as to the
glomerular filtration and tubular reabsorption processes
(continued):
2. Reabsorption of waste products is relatively
incomplete (as in the case of urea), so that large
fractions of their filtered loads are excreted in the
urine.

Tubular Reabsorption
• There are three important conclusions as to the
glomerular filtration and tubular reabsorption processes
(continued):
3. Reabsorption of most useful plasma components,
such as water, inorganic ions, and organic
nutrients, is relatively complete so that the
amounts excreted in the urine are very small
fractions of their filtered loads.

Average Values for Several Components
That Undergo Filtration and Reabsorption

Tubular Reabsorption
• An important distinction should be made between
reabsorptive processes that can be controlled
physiologically and those that cannot.
• The reabsorption rates of most organic nutrients, such
as glucose, are always very high and are not
physiologically regulated.
• Therefore, the filtered loads of these substances are
completely reabsorbed in a healthy kidney, with none
appearing in the urine.

Tubular Reabsorption
• Therefore, the kidneys do not regulate the plasma
concentrations of these organic nutrients.
• Rather, the kidneys merely maintain whatever plasma
concentrations already exist.

Tubular Reabsorption
• Recall that a major function of the kidneys is to
eliminate soluble waste products.
• To do this, the blood is filtered in the glomeruli.
• One consequence of this is that substances necessary
for normal body functions are filtered from the plasma
into the tubular fluid.

Tubular Reabsorption
• To prevent the loss of these important nonwaste
products, the kidneys have powerful mechanisms to
reclaim useful substances from tubular fluid while
simultaneously allowing waste products to be excreted.
• The reabsorptive rates for water and many ions,
although also very high, are under physiological
control.
• For example, if water intake is decreased, the kidneys
can increase water reabsorption to minimize water loss.

Tubular Reabsorption
• In contrast to glomerular filtration, the crucial steps in
tubular reabsorption do not occur by bulk flow.
• Instead, two other processes are involved
1. Reabsorption of some substances from the tubular
lumen by diffusion
2. Reabsorption of all other substances by mediated
transport

Tubular Reabsorption
Tubular reabsorption
begins as soon as filtrate
enters the tubule cells.
Paracellular transport
occurs between cells
(even though they have
tight junctions) and is
seen mainly with ions.
Transport can be active
(requires ATP) or passive
(no ATP).

Reabsorption by Diffusion
• The reabsorption of urea by the proximal tubule
provides an example of passive reabsorption by
diffusion.
• Some urea, although it is a waste product, is reabsorbed
from the proximal tubule.
• Because the corpuscular membranes are freely
filterable to urea, the urea concentration in the fluid
within Bowman’s space is the same as that in the
peritubular capillary plasma and the interstitial fluid
surrounding the tubule.

Reabsorption by Diffusion
• As the filtered fluid flows through the proximal tubule,
water reabsorption occurs.
• This removal of water increases the concentration of
urea in the tubular fluid so it is higher than in the
interstitial fluid and peritubular capillaries.
• Therefore, urea diffuses down this concentration
gradient from tubular lumen to peritubular capillary.
• Urea reabsorption is thus dependent upon the
reabsorption of water.

Reabsorption by Mediated Transport
• Many solutes are reabsorbed by primary or secondary
active transport.
• These substances must first cross the apical membrane
(also called the luminal membrane).
• Then, the substance diffuses through the cytosol of the
cell and, finally, crosses the basolateral membrane.
• The movement by this route is termed transcellular
epithelial transport.

Reabsorption by Mediated Transport
• A substance does not need to be actively transported
across both the apical and basolateral membranes.
• For example, Na+ moves “downhill” (passively) into
the cell across the apical membrane through specific
channels or transporters.
• Then, it is actively transported “uphill” out of the cell
across the basolateral membrane via Na+/K+-ATPases
in this membrane.

Reabsorption by Mediated Transport
• The reabsorption of many substances is coupled to the
reabsorption of Na+.
• The cotransported substance moves uphill into the cell
via a secondary active cotransporter as Na+ moves
downhill into the cell via this same cotransporter.
• This is precisely how glucose, many amino acids, and
other organic substances undergo tubular reabsorption.
• The reabsorption of several inorganic ions is also
coupled in a variety of ways to the reabsorption of Na+.

Reabsorption by Mediated Transport
• Many of the mediated-transport-reabsorptive systems
in the renal tubule have a limit to the amounts of
material they can transport per unit time known as the
transport maximum (Tm).
• This is due to the saturation of the binding sites on the
membrane transport proteins.
• An important example is the secondary active-transport
proteins for glucose, located in the proximal tubule.

Reabsorption by Mediated Transport
• As noted earlier, glucose does not usually appear in the
urine because all of the filtered glucose is reabsorbed.
• Plasma glucose concentration in a healthy person
normally does not exceed 150 mg/100 mL.
• This concentration of plasma glucose is below the
threshold value of 200 mg/100 mL at which glucose
starts to appear in urine (glucosuria).

Tubular Reabsorption of Glucose
This transport
maximum is why
untreated diabetic
patients have
glucose in their
urine.

Reabsorption by Mediated Transport
• Like glucose, most amino acids and water-soluble
vitamins are filtered in large amounts each day.
• But almost all of these filtered molecules are reabsorbed
by the proximal tubule.
• If the plasma concentration increases, the filtered load
may exceed the tubular reabsorptive Tm and the
substance will appear in the urine.

Tubular Secretion
• Tubular secretion is the transfer of materials from
peritubular capillaries to kidney tubule lumen.
• Like glomerular filtration, it constitutes a pathway from
the blood into the tubule.
• Like reabsorption, secretion can occur by diffusion or
by transcellular mediated transport.

Tubular Secretion
• The most important substances secreted by the tubules
are H+ and K+.
• However, a large number of normally occurring
organic anions, such as choline and creatinine, are also
secreted; so are many foreign chemicals such as
penicillin.

Tubular Secretion
• Active secretion of a substance requires active
transport
 either from the blood side (the interstitial fluid) into
the tubule cell (across the basolateral membrane)
 or out of the cell into the lumen (across the apical
membrane).
• As in reabsorption, tubular secretion is usually coupled
to the reabsorption of Na+.

Tubular Secretion
• Tubular secretion is a mechanism to increase the ability
of the kidneys to dispose of substances at a higher rate
rather than depending only on the filtered load.

Metabolism by the Tubules
• The cells of the renal tubules synthesize glucose during
fasting and add it to the blood.
• They can also catabolize certain organic substances,
such as peptides, taken up from either the tubular
lumen or peritubular capillaries.
• Catabolism eliminates these substances from the body
just as if they had been excreted into the urine.

Regulation of Membrane Channels
and Transporters
• Tubular reabsorption or secretion of many substances
is under physiological control.
• For most of these substances, control is achieved by
regulating the activity or concentrations of the
membrane channel and transporter proteins involved in
their transport.
• This regulation is achieved by hormones and paracrine
or autocrine factors.

Summary—Division of Labor
• The majority of the reabsorption is accomplished by
the proximal tubule and the loop of Henle.
• Extensive reabsorption by the proximal tubule and loop
of Henle ensures that the masses of solutes and the
volume of water entering the tubular segments beyond
the loop of Henle are relatively small.
• These distal segments then do the fine-tuning for most
substances, determining the final amounts excreted in
the urine by adjusting their rates of reabsorption and, in
a few cases, secretion.