Proximal Tubule Tm Mechanisms PDF

Summary

This document contains learning objectives for a renal physiology lecture regarding the proximal tubule, iso-osmotic reabsorption, Tm, glomerular tubular balance and different types of transport.

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WSUSOM Medical Physiology Rossi-Renal Physiology Page 1 of 15
Proximal Tubule Tm Mechanisms

Proximal Tubule Tm Mechanisms

Learning Objectives:
1. Proximal tubule
A. Compare relative quantitative transport that occurs in the proximal tubule with
the rest of the nephron
B. Recognize that reabsorption in the proximal tubule is iso-osmotic and the
underlying mechanisms responsible
C. Distinguish between Tm and non-Tm reabsorptive processes in the proximal
tubule and the substances handled by each of these mechanisms
D. Identify the concept and mechanisms involved in glomerular tubular balance
E. Distinguish between different types of transport
a. primary and secondary active transport, facilitated diffusion, passive
transport and endocytosis
b. co-transport, counter-transport (or exchanger) or channel
c. water transport via osmotic forces
F. Tm reabsorption
a. Articulate the concepts of threshold and Tm and be able to calculate them
b. Recognize the influence glomerular filtration rate exerts on threshold
c. Understand the concept of splay
d. Distinguish the major categories of solute that are reabsorbed via Tm
mechanisms and the unique characteristics of the major categories,
including the transporters involved
G. Tm secretion
1) Recognize that the concept of threshold does not apply to secretory
processes
2) Identify the major cations and anions that are secreted by the proximal
tubule and the general transport mechanisms involved
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Proximal Tubule Tm Mechanisms

This lecture focuses on the Rx and Sx components of the excretion equation, that is, the
reabsorptive and secretory functions of the tubules, respectively.

Excretion
Ux * V = (GFR * Ax) - Rx + Sx
Clearance
Cx = Ux* V = GFR _ Rx + Sx
Ax Ax Ax
Normal GFR is 125 ml/min. In one day 180 liters of fluid are filtered into Bowman’s space
each day:
125 ml/min * 1,440 min/day = 180,000 ml/day = 180 L/day
Since typically, humans excrete 1 - 2 liters of urine per day, the tubules must
- reabsorb 178 - 179 liters of fluid each day
- reclaim essential solutes that are filtered at the glomerulus
- eliminate solutes (including drugs, toxins, etc.) that are not filtered in sufficient quantity
Theoretical Problem: If a 70 kg “ideal” male with a GFR of 125 ml/min does not reabsorb
any fluid, how long would it take for him to excrete his total body water (as if this were
possible)?
Total body water (TBW) = 0.6 * 70 kg = 42 L
42 L ÷ 0.125 L/min = 336 min = 5.6 hr
More scary, if [Na] in ECV = 150 mM, then Na content of ECV = 2,100 mmol. At a GFR
of 125 ml/min, 18.75 mmol Na are filtered/min. It would take only 112 minutes (< 2 hrs)
to lose all ECV Na. Note that 80% of the ATP used by the kidney (2 kg/d) is spent to
reabsorb Na.
Recall: ECV = 1/3 * TBW; ICV = 2/3 * TBW. PV = 1/4 * ECV; ISV = 3/4 * ECV
(Note that I use 150 mM for extracellular Na concentration. This is because strictly
speaking I will be discussing Na dissolved in plasma water and it is the Na dissolved in
plasma water that the cells respond to. Those of you who have seen lab results or worked
in hospitals know that “normal” Na is 140 mM. This is the Na concentration in plasma or
serum, which is normally only 93% water. When the lab measures the [Na] it calculates it
as if all the serum were water. This is actually not true. This is why the fluids given to
patients “normal saline” is 0.9% NaCl or ~ 154 mM instead of 140 mM!)
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Proximal Tubule Tm Mechanisms

Just a reminder of where we are going…following the filtered fluid and its contents into
the proximal tubule…

Proximal Tubule
Proximal tubule
~60-80% of filtered solutes and water reabsorbed isotonically
as solutes reabsorbed, water reabsorbed passively by osmosis
solutes secreted, but negligible QUANTITATIVELY overall
Proximal tubular mechanisms responsible for reclaiming and eliminating solute/fluid:
1. Reabsorption: Tm and non-Tm mechanisms
2. Secretion - Tm mechanisms
3. H2O reabsorption
“Tm” means “tubular maximum” or “transport maximum”
Although conceptually the Tm may be considered analogous to the Bmax of an enzyme,
the Tm is not for a single transporter but for the proximal tubule as whole. Several
transporters may contribute to the Tm. For example, for glucose which we will discuss
below there are two transporters, SGLT1 and SGLT2 but ONE and only ONE Tm for the
tubule.
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Glomerulo-tubular Balance
Spontaneous changes in GFR lead to parallel changes in proximal tubule reabsorption
­ or ¯ in GFR leads to proportional ­ or ¯ in proximal tubule reabsorption,
respectively

Mechanisms
- Parallel change in pc in peritubular capillaries → parallel change in solute and H2O
reabsorption
- Change in filtered load of glucose ® parallel change in Na reabsorption
Glomerulo-tubular balance: When body Na+ balance is normal, an increase in GFR
results in a higher filtered load of Na (GFR x ANa). If this is not accompanied by a
proportional increase in proximal tubular reabsorption of Na+ and H2O, too much Na+ and
water will be delivered downstream (more than the distal segments can handle) and result
in more Na+ and water being excreted. Thus, a constant fraction (»80%) of the filtered
load of and H2O is reabsorbed from the proximal tubule despite variations in GFR. The
net result of glomerulo-tubular balance is to mitigate the influence that even small
changes in GFR have on the amount of Na+ and H2O delivered to the more distal nephron
segments and ultimately the amount of Na+ and H2O excreted in the urine.
Two mechanisms are responsible for G-T balance:
1. Starling forces: At constant RPF, a rise in GFR raises protein concentration in the
plasma leaving by the efferent arteriole. This plasma enters the peritubular
capillaries; the higher pc in the peritubular capillaries increases reabsorption of
solutes and water.
2. A rise in GFR increases filtered load of glucose and amino acids. The rate of Na+
reabsorption depends on the filtered load of glucose and amino acids (see below
as they are “co-transported”). So, as GFR increases, Na+ reabsorption increases
as well.
G-T balance occurs ONLY due to spontaneous changes in GFR with NORMAL Na+
balance (ie., normal volume, normal blood pressure, etc.). There are pathologic situations
when glomerulo-tubular balance does not occur, such as severe volume loss, when
proximal reabsorption may increase while GFR decreases. Under these circumstances,
extrinsic influences signal the proximal tubule so that up to 90% of the filtered fluid and
solute may be reabsorbed.
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Proximal Tubule Tm Mechanisms

Tm : Tubular Transport Maximum
Tm reabsorption: from TF to P (lumen to capillary)
carbohydrates
amino acids
metabolites
HPO42- and H2PO4-
Tm secretion: from P to TF
organic acids (PAH, penicillin, indomethacin)
organic bases (creatinine, cimetidine, uric acid)

Tm Reabsorption
UgluV = (GFR * Aglu) – Rglu
when Rglu = Tmglu, then glucose appears in urine
Colors would be good here...see slide show on video if it helps you...or bring colored
pencils to class. (see full explanation below)

non-Tm Reabsorption
A maximal transport rate is not apparent for some substances reabsorbed by the PCT
Ionic: Na, K, Cl, HCO3
Nonionic: urea
This does not imply that transport proteins are not involved in non-Tm reabsorptive
mechanisms!!! It just means that there does not seem to be a maximum level or ceiling
above which the substance cannot be transported.
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Proximal Tubule Tm Mechanisms

H2O Reabsorption by Proximal Tubule
Proximal tubule has high water permeability
60-80% of filtered solutes are reabsorbed by the proximal tubule cells
Water follows by osmosis in isotonic fashion via aquaporin 1
(see explanation below re: “micro environments”)
Proximal tubule fluid is always isotonic to renal cortical ISF
Water in the interstitium then moves into the peritubular capillary because of high
oncotic pressure (remember the proteins stayed behind after filtration in the
glomerulus)

In the proximal tubule, water is reabsorbed passively by osmosis and isotonically via
water channels known as aquaporin 1.

(see animation during lecture)

The driving force for H2O is provided by the active reabsorption of solute, primarily Na+.
As Na+ and other solutes are reabsorbed across the apical (luminal) membrane into the
cell and then are extruded by the basolateral membrane into the ISF, small osmotic
gradients develop from the TF to the intracellular compartment and then from the
intracellular compartment to the ISF. This sets up a “micro-environment” just below the
cell membrane surface, with higher osmolality, to cause water to move into the cell
(likewise, pulling water out of the cell on the basolateral side). These tiny changes in
osmolality ~6 mosm/kgH2O are the driving force for water to move. Overall, however, the
movement of water when looked at a “macro” level appears to be, and is CALLED,
isotonic movement. This provides the osmotic force that permits H2O to flow from the TF
into the cell then to the ISF and finally into the peritubular capillary.
Some H2O passes through the tight junction between the cells because of the osmotic
gradient, but more goes through the cells in the proximal tubule via aquaporin 1.
Recall also that the peritubular capillary just came off the efferent arteriole so that the
plasma has a very high protein concentration and, therefore, a high oncotic pressure.
Thus, fluid and salts are drawn into the capillary and reabsorption is achieved.
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Proximal Tubule Tm Mechanisms

Tm for Glucose
Tm = the maximum rate of transport by the tubule for that substance; it was considered a
constant (until very recently, but still a good approximation under most circumstances)
Threshold = plasma concentration at which reabsorptive mechanism is saturated.
In other words, the threshold is the highest plasma concentration at which UgluV = 0
If 0 = (GFR * A glu) - Rglu and when Aglu = threshold
Then when Tm = maximum Rglu
0 = (GFR * threshold) – Tm
Thus Tm = GFR * threshold
Note: If GFR doubles, then threshold is halved.
IN untreated diabetes mellitus: Aglucose may be > threshold
The reabsorption of glucose is a classic example of a proximal tubule Tm mechanism.
The diagram shows filtered, reabsorbed, and excreted glucose as a function of arterial
glucose concentration, Aglucose. In this
example,GFR = 125 ml/min.
Definition of concepts:
1. threshold
2. Tm
3. splay

Be sure to keep the concepts of
threshold and Tm separate.
Everyone tends to confuse them!

Threshold - the plasma concentration below which the substance (in this case, glucose)
is not found in the urine.
On the diagram below, the threshold is ~3 mg/ml, or 300 mg/dl, which is 3x the normal
plasma concentration of 100 mg/dl.
E.g., , if the threshold for glucose is 3 mg/ml and GFR is 125 ml/min then
Tm for glucose is 375 mg/min (125 ml/min * 3 mg/ml = 375 mg/min)
Tm for reabsorption - the maximum reabsorptive rate of a substance and is constant
(exception is Tm for phosphate).
Tm is constant, but threshold may vary and depends on both GFR and Tm. Example: If GFR
doubles (from 100 to 200 ml/min) and the Tm is constant, then the
threshold would be halved (from 300 to 150 mg/dl). This actually
happens in pregnancy where GFR can increase by 50-100% and
the threshold for glucose decreases accordingly. So pregnant
women with normal serum glucose can have glucose in the urine.
Splay – Not all nephrons are identical. Thus, the threshold is
not a definitive point for the kidney as a whole, there is
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Proximal Tubule Tm Mechanisms

variation among individual nephrons, so that some non-linearity, or splay, in the
reabsorption and excretion curves occurs near threshold.
Tm Reabsorption – Glucose, an example
Colors are helpful here...see slide show on video if it helps you...or bring colored pencils
to class.
As glucose gets filtered, the amount
in the tubular fluid rises (blue
dashed line). Note that the rate of
rise is identical to the GFR which is
the slope of the red line.
When the amount of glucose filtered
is lower than the Tm (dot-dash line),
all of the glucose gets reabsorbed
and none appears in the urine. Once
the amount of glucose filtered
exceeds the Tm, that is, the
maximum reabsorptive rate is
reached, the glucose in the filtrate exceeds the amount that can be reabsorbed and
glucose begins to appear in the urine (solid black line) and is excreted.
The maximum PLASMA concentration at which the amount filtered can be fully
reabsorbed is the THRESHOLD. In other words, the PLASMA concentration above which
glucose begins to first appear in the urine is the THRESHOLD. There are many ways of
phrasing this.
You may also wish to follow the animated sections of the lecture presentation…so as
not to make the notes even longer.
Uglucose * V = (GFR * Aglucose) - Rglucose
Tm = maximum Rglucose

Effect of Change in GFR on Threshold
Note the solid line for filtered load (= GFR x Aglu).
Also, recall that reabsorption reaches max when
FR the line denoting “filtration rate” crosses the line
FR

wG
Lo for Tm. Dropping a vector to the glucose
hG

concentration when this line crosses the line for
Hig

Tm gives the threshold.
When the GFR increases the amount of glucose
filtered per unit time also increases. The “filtration
rate” line becomes steeper (dash-dot).
Notice how this line crosses the Tm line at a lower concentration of blood glucose, that is,
the threshold for glucose decreases. Pregnancy is an example of this.
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Likewise, when GFR decreases, the slope of the filtration rate line is less steep, the line
(dashed) crosses the Tm line later and the threshold increases. Chronic kidney disease
is an example of this.

Tm: characteristics of 2º Active Transport
Saturability
analogous to the Vmax in enzyme reactions
transporter (carrier); substrate (glucose)
[glucose] ® ­ Rglu until carrier is “saturated”
carrier always saturated with respect to Na+ (150 mM) vs glucose (5.6 mM),
so Na+ is never rate limiting
Specificity
e.g., transport of the “D” not the “L” optical isomer
Competitiveness
affinities: also transports fructose, galactose, xylose
Note that inulin (5-carbon sugar) or mannose (6-carbon sugar) do NOT
compete

All Tm mechanisms exhibit three characteristics of secondary (or tertiary) active transport,
listed above.
1. Saturability - (analogous to enzymatic reactions) At a constant transporter number in
the membrane, and increase in substrate concentration will increase the transport rate
until all the carriers (transporters) for that substance are saturated. When the carriers are
saturated and transporting at the maximum rate, the Tm is achieved.
In the case of glucose (and amino acids, phosphate, metabolites) reabsorbed by the
proximal tubule, Na+ is also a substrate and is co-transported with glucose. Since the Na+
concentration is so high (150 mM) relative to glucose (100 mg/dl = 0.56 mM), the Na+-
glucose co-transporter is always saturated with Na+, so that the Na+ concentration is
never rate limiting.
2. Specificity - carriers are specific for the molecules they transport. e.g., “D” but not “L”
glucose is transported glucose and galactose but not mannose are transported.
3. Competitiveness - The carrier has affinities for glucose, fructose, galactose and
xylose. These four carbohydrates compete for the same carrier. E.g., If the plasma
concentration of fructose increases, it will decrease the apparent maximum reabsorptive
rate (Tm) for glucose.
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Cellular Transport: Glucose

Cell characteristics
Na,K-ATPase on basolateral mmb
luminal and basolateral mmb permeability to K >> Na
PD of ICF is negative vs TF
NaICF [K]ISF. The membranes are more permeable to K+ than
Na+, so the PD (potential difference) across both apical and basolateral membranes
approximates the Nernst potential for K+ (-80mV inside neg). Thus, there are large
electrical and chemical gradients for Na+ to move from TF into ICF (intracellular fluid).
The Na-glucose co-transporter, therefore, moves Na+ downhill coupled to glucose
movement uphill into the cell. Glucose then moves, via GLUT2, from ICF to ISF (interstitial
fluid) and then into the plasma.
SGLT1 and GLUT1 are present in the later part of the proximal tubule.
Glucose is reabsorbed by secondary active transport. Energy is derived from coupled
movement of a solute (Na+) down its electro-chemical gradient and permits glucose to be
reabsorbed against its electrochemical gradient.
Secondary active transport can transport solute against enormous gradients! Under
normal conditions, filtered glucose is completely reabsorbed, so that TF glucose
concentration decreases to zero, whereas ISF glucose concentration is approximately
that of plasma. Indeed, nearly an infinite gradient!!!
Primary active transport (eg., Na,K-ATPase) depends directly on ATP hydrolysis to
provide the energy for transport a solute against its electrochemical gradient.
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The Na,K-ATPase in the basolateral membrane is KEY in maintaining [Na+] in the ICF
low. If the Na,K-ATPase is poisoned, ICF [Na+] will increase and the driving force for
secondary active transport (the downward movement of Na+ from TF into the cell) will be
dissipated and Na coupled transport will stop.
Diabetes mellitus - Normally the plasma concentration, Aglucose is much lower than
threshold for glucose; therefore, all the filtered glucose is reabsorbed. In untreated
diabetes mellitus, Aglucose may be as high as 500 to 1000 mg/dl, >> threshold. Under these
conditions, more glucose is filtered than can be reabsorbed. The maximum reabsorptive
capacity for glucose (Tm) is exceeded. Consequently, glucose is excreted in the urine.
SGLT2 is the target of the NEW diabetes medications that you are hearing about in all
the TV commercials: the gliflozins. (These are exciting new drugs that have been found
to decrease cardiovascular risk and deterioration of diabetic kidney disease!)
SGLT2 is a high capacity/low affinity transporter that transports Na+ and glucose at ratio
1:1 and can establish a cell to TF glucose ratio of 70.
SGLT1 is a low capacity/high affinity transporter that transports Na+ and glucose at ratio
2:1 and can establish a cell to TF glucose ratio of 4,900.
NEW INFORMATION
Textbooks and my notes
SGLT2 inhibitor used to say that the Tm
for glucose does not
change and that it is
largely the same in all
humans. No one
bothered to check until
the new SGLT2
SGLT2 inhibitor inhibitors came out.

Note in the figure that the
Tm for type 2 diabetics is
higher than that for
healthy controls.
Inhibition of the SGLT2
transporter decreases
the Tm for glucose in both healthy and type 2 diabetic subjects. Diabetes Care 36:3169–3176, 2013

Question: What would you expect urinary excretion of glucose to do if a person is
given a dose of a gliflozin drug? (increase/decrease)

What would you expect Na excretion to do after the person is given the SGLT2
inhibitor? (increase/decrease)
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FACTS about Tm Mechanisms
ALL are at least secondary active transport (some may be tertiary)
ALL exhibit
saturation
specificity
competition
ALL derive energy from downhill movement of Na into the cell
For many years, it has been generally accepted that ALL Tm mechanisms are in the
proximal tubule. New findings in the distal nephron may alter this concept, but remain
controversial at this time.

Other Substances with Tm Reabsorption
Amino acids:
3 types (at least) apical transporters: basic, acidic, other
specificity for “L” isomer
saturable but concentration