Osmoregulation - The Kidney (1) PDF

Summary

This document explains how kidneys maintain fluid balance in terrestrial vertebrates. It details the chemical composition of urine, the three processes involved in urine formation, and the kidney's countercurrent mechanism. It also discusses the renin-angiotensin-aldosterone system and ADH's influence on urine volume and concentration.

Full Transcript

Osmoregulation
The Kidney
A.K. Daemicke
 š Explain how kidneys function to maintain
fluid balance in terrestrial vertebrates
š Describe the chemical composition of
urine
š Recognize the three processes that are
involved in creating urine forms and
identify ways in which urine composition
Learning can be altered
š Explain how the kidney’s countercurrent
Objectives mechanism works
š Discuss the renin angiotensin aldosterone
system and understand how it influences
blood pressure
š Understand how ADH levels influence the
volume and concentration of urine
excreted by animals
 Animals live in varying
environments that each pose
unique challenges to osmotic
balance
Saltwater Freshwater Land
 What is the difference
between an osmoconformer
and an osmoregulator?
Osmoconformers
š Most marine invertebrate organisms that maintain an internal environment which is
isotonic to their external environment (saltwater)
š Saltwater = 1,000 mOsm/L
š NO net movement of water
Osmoregulators

šMarine, freshwater and terrestrial vertebrates that maintain an internal environment which is
hypertonic/hypotonic to their external environment
Tonicity Review

Isotonic Hypertonic Hypotonic
 Passive Transport – Osmosis
100 mOsm/L 200 mOsm/L 150 mOsm/L 150 mOsm/L
Dilute Glucose Concentrated Movement of water
Plasma membranes are
Solution Glucose Solution
permeable to water, but
frequently not to solutes
When two solutions
exchange water by osmosis,
water always moves from the
one with lower osmotic
pressure into the one with
higher osmotic pressure

Semipermeable Membrane

Glucose molecule
How do
osmoregulators
make sure their
fluids stay within
a narrow range?
For blood and other body
fluids to be maintained at
a normal composition,
animals require organs
that serve to counteract
any deviation away from
normal
 The kidneys are the
primary organ that
serves to maintain
fluid homeostasis in
terrestrial
vertebrates.

This work was supported and approved by the Human Anatomical Sciences Graduate Program
at Northern Illinois University. All Human Bodies donated to the Department of Biological Sciences
Body Donation Program are treated humanely, and with the highest ethical standards
Urinary System
Organs
š Kidneys are our major
excretory organs.
š Ureters transport urine from
kidneys to urinary bladder.
š Urinary bladder is temporary
storage reservoir for urine.
š Urethra transports urine out
of body.
Qualities of the Kidney

š Consist of tubular elements
š Produce and void aqueous solutions derived
from blood
š Do so to regulate the composition and volume
of blood
 o A complex solution of various organic and inorganic solutes, as well as
water that are drawn from the blood
o Therefore, the composition of urine impacts the composition of an animal’s
blood.
o 95% water and 5% solute
o Water in urine consists of two parts
Amount that is require to accompany excreted solutes
Amount that is additional that may or may not be excreted à this is
regulated
o Wastes
Urea: from amino acid breakdown
Creatinine: metabolite of creatine phosphate
o Other normal solutes
Na+, K+, PO43–, and SO42–, Ca2+, Mg2+ and HCO3–
o Abnormally high concentrations of any constituent, or abnormal
components, e.g., blood proteins, WBCs, bile pigments, may indicate
pathology

Chemical Composition of Urine
 š Osmolarity of body fluids
Regulation of Expressed in milliosmols (mOsm)

Urine Kidneys maintain osmolarity of
plasma at ~275-325 mOsm by
Concentration regulating urine concentration and
volume.
and Volume Kidneys function with a
countercurrent mechanism.
Renal cortex
Kidney have a
rich blood supply
Renal medulla in order to filter
blood
 Nephrons

š Structural and functional
units that form urine
š > 1 million per kidney
š Two main parts
Renal corpuscle
Renal tubule
Urine Formation

Primary urine becomes definitive urine by way of three events…
(1)Glomerular filtration
(2)Tubular reabsorption
(3)Tubular secretion

While all three occur for some substances, that is not true for all substances.
Renal cortex

Let’s make
Renal medulla
some urine!
Fun fact! Our total blood volume filters
into the renal tubules about every 22
minutes
Glomerular Filtration

š Passive process
š No metabolic energy required
š Hydrostatic pressure higher in glomerulus (55 mm
Hg) forces fluids and solutes through filtration
membrane
Opposed by osmotic pressure of blood and
hydrostatic pressure of glomerular capsule
Net filtration pressure (NFP)
š No reabsorption into capillaries of glomerulus
š Large molecules (e.g. plasma proteins and blood
cells) cannot get filtered
š Glucose, ions and amino acids can pass
Glomerular Disease

š Caused by an infection or a drug
that is harmful to your kidneys
In other cases, it may be
caused by a disease that
affects the entire body, like
diabetes or lupus.
Many different diseases can
cause swelling
(inflammation) or scarring
(sclerosis) of the glomerulus
š Symptoms
Albuminuria
Hematuria
Where does the filtrate
enter next?
 š Most of tubular contents reabsorbed to
blood

Proximal š Includes active and passive tubular
reabsorption
Convoluted š Two routes:

Tubule (PCT) 1. Transcellular
2. Paracellular
 Tubular
Reabsorption
š Transcellular route
Apical membrane of tubule
cells à
Cytosol of tubule cells à
Basolateral membranes of
tubule cells à
Endothelium of peritubular
capillaries
š Paracellular route
Between tubule cells limited by
tight junctions, but leaky in
proximal nephron
Reabsorption in PCT

š Na+ uptake is driven by electrochemical
gradient established by Na+/K+ pump.
š Aquaporins cause PCT to be highly
permeable to water.
š Glucose and amino acid uptake driven by
secondary active transport.
Reabsorption
3 1
in PCT
4
2
These
aquaporins
are always
open à
obligatory
water
reabsorption
 Glucose reabsorption in the proximal tubule …

When
transporters are
saturated, the
Transport excess in
maximum (Tm ) for excreted in
every substance urine.
reabsorbed by a
transport protein
and is
proportional to
the number of
proteins available
for transport.
Diabetes
Where does the filtrate
enter next?
Loop of Henle

š Provides capacity to make hyperosmotic
urine
š An important adaptation to have in order
to live on land
š In the ascending limb, ions are passively
and actively transported out of filtrate.
š The descending limb is only permeable to
water and not NaCl.
Hyperosmotic interstitial fluid created by
NaCl active transport in the ascending limb
drives water reabsorption in the descending
limb.
 The
Countercurrent
Multiplier
š Expends energy to create a
concentration gradient
š The only way to move water is
to move Na+ first.
Hyperosmotic region
created in by ascending
limb, drives water
movement out of
descending limb.
š Limbs are close enough to
influence each other’s
exchange with the interstitial
fluid they share.
The Countercurrent Multiplier
 PCT DCT

The Countercurrent
Exchanger
The steady influx of 300 mOsm
filtrate at the beginning of the
descending limb, coupled with
Descending Ascending
the dilution of filtrate moving
Limb Limb
up the ascending limb, serve
to keep the osmotic pressure
of at the outer cortical end of
the loop near 300 mOsm.
 The
Countercurrent
Exchanger
š Vasa recta runs alongside the
loop.
š Function: preserve medullary
gradient
Prevent rapid removal of
salt from interstitial space
Remove reabsorbed
water
š Water entering ascending
vasa recta either from
descending vasa recta or
reabsorbed from nephron
loop and collecting duct.
Volume of blood at end of
vasa recta greater than at
beginning
 Role of countercurrent mechanisms
Countercurrent o All the loops and their combined action establish and maintain
Mechanism osmotic gradient. (~300 mOsm to ~1200 mOsm) from renal cortex
through medulla
o Helps with drives concentration of urine in collecting duct which aids
land animals conserve water.
What sorts
of animals
do we
expect to
have long
loops of
Henle?
Species with a
high relative
medullary
thickness tend to
produce
especially
concentrated
urine as it is a
gauge long loop
concentration.

29.10

Relative medullary thickness also decreases allometrically with body size
Longer loop of Henle = greater concentration
gradient

Expect desert mammals to have longer
loops of Henle and to produce more
concentrated urine
https://ib.bioninja.com.au/higher-level/topic-11-animal-physiology/113-the-kidney-and-osmoregu/water-balance.html
Distal Convoluted Tubule (DCT)

š Movement of many substances depends on the body’s
needs
š Regulated by hormones
Aldosterone: Increases active transport Na+ out and in K+ to
filtrate when blood volume/ concentration of Na+ is low or K+ is
high
š pH regulation
Can absorb bicarbonate and secrete H+, raising pH of
bloodstream.
Can release bicarbonate and absorb H+, lowering pH of
bloodstream
In order to fully appreciate what
occurs in the collecting duct,
let’s consider how the kidney
helps maintain blood pressure.
Juxtaglomerular
Complex (JGC)
o Three cell populations
o Macula densa
Tall, closely packed cells of
ascending limb
Chemoreceptors; sense NaCl
content of filtrate
o Granular cells (juxtaglomerular, or
JG cells)
Enlarged, smooth muscle cells
of arteriole
Secretory granules contain
enzyme renin
Mechanoreceptor sense
blood pressure in afferent
arteriole
o Extraglomerular mesangial cells
Between arteriole and tubule
cells
Passes signals between
macula densa and granular
cells
 Main mechanism for
Extrinsic increasing blood pressure

Controls: Three pathways to renin
Renin- release by granular cells
Angiotensin- Direct stimulation of granular cells by
sympathetic nervous system
Aldosterone Stimulation by activated macula
densa cells when filtrate NaCl
Mechanism concentration low
Reduced stretch of granular cells
Renin-
Angiotensin
Aldosterone
System
 DCT and collecting duct: reabsorption hormonally
regulated
o Antidiuretic hormone (ADH): released when an
increase in blood osmolarity or a decrease in blood
volume is detected
Released by posterior pituitary gland

Reabsorption Causes principal cells of collecting ducts to
insert aquaporins in apical membranes à water

Capabilities of
reabsorption
As ADH levels increase, water reabsorption
Renal Tubules
increases.
Function: decrease blood osmolarity; increase
and o
blood volume
Aldosterone: released when decreased blood
Collecting pressure is detected
Released by adrenal glands
Ducts Targets principal cells of collecting ducts and
distal DCT and promotes synthesis of luminal Na+
and K+ channels, and basolateral Na+-K+
ATPases for Na+ reabsorption à water follows
Functions: increase blood volume/
concentration of Na+ is or decrease K+
Let’s draw it
out!
ADH
NaCl concentration in
medullary interstitial ADH high ADH low
fluids increases with
increasing depth of
the medulla because
blood supply removes
water from medullary
interstitial fluids

29.14
Diabetes insipidus

š A rare condition caused by a lack of ADH or
a failure of the kidneys to respond to ADH
š Treatment includes a medication called
desmopressin acetate
š What are some symptom one would have
with diabetes insipidus?
Frequent urination
Dehydration
Excessive thirst
 Takeaway
Animals can control the excretion of
water independently of the
excretion of solutes.
Have you ever noticed
that in the morning your
urine is very dark?
Color of urine is Since an animal hasn’t had
water all night, it must
evidence of reabsorb osmotically free
osmoregulation! water and only excretes
water that is required to be
excreted with solutes
The RAAS is
not the only
way ADH
secretion is
stimulated!
 Stimulus

Receptors

Afferent pathway

Control center
Negative
Ta
Feedback awa kes
Efferent pathway stim y the
ulus
!
Effector
Response
Stimuli

Animals monitor various measures of water
1. Blood volume
2. Extracellular ion concentration
 What happens to these
variables as we lose water
to the environment?

Decrease Increase extracellular
Lose water
blood volume ion concentration
Receptors
sensing
extracellular ion o Osmoreceptors are sensory receptors in the thirst
concentration center in the hypothalamus that monitor the
concentration of solutes (osmolality) of the blood.
(Osmoreceptors) o If blood osmolality increases above its ideal value, the
hypothalamus transmits signals that result in a
conscious awareness of thirst.
Control
Center
 Stimulus: Dehydration

Receptors: Osmoreceptors in hypothalamus

Control center: Hypothalamus initiates… thirst

Negative
Feedback Release of ADH from posterior pituitary Response: drink

ADH travels through blood to…

Effector: CT cells à insert aquaporins

es
Tak the
y
awa ulus!
stim Response: Reabsorb water
into blood
Formation of
Dilute and
Concentrated
Urine
 Great summary video!
https://www.youtube.com/watch?time_continue=3&v=XbI8eY-BeXY&feature=emb_title
The Real Thing!