OSMOREGULATION IN VERTEBRATES.pptx
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Nov 13, 2022
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About This Presentation
This ppt describes about the how animals regulate the excretary products based on the concentration
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OSMOREGULATION IN VERTEBRATES M.ANGEL HELEN
CONTENTS DEFINITION MECHANISM OF OSMOREGULATION OSMOSIS AND OSMOLALITY OSMOCONFORMERS OSMOREGULATORS OSMOREGULATORY ORGANS IN VERTEBRATES IN MARINE VERTEBRATES IN FRESH WATER VERTEBRATES IN TERRESTRIAL VERTEBRATES
HOMEOSTASIS It is a maintaining of steady state equilibrium in the internal environment of an organism. TWO PROCESS THAT MAINTAIN HOMEOSTASIS OSMOREGULATION – Regulate solute concentration and balances the gain and loss of water. EXCRETION - It is the process of removal of metabolic wastes from the body.
definition The process by which the movement of water takes place. Animals as well as plants contain a large amount of water. In an animal’s body water may enter the result of drinking. The more or less steady state of water contents - maintained - between the amount of water. The term osmoregulation was coined by HOBER in 1902.
Different organisms have different limits of tolerance both for water. Animals whose body fluids and blood have the same concentration as that of surrounding medium is known as isotonic. Animals which live in a medium of a lower salt concentration is known as hypotonic. Animals which live in a medium of high salt concentration is known as hypertonic.
OSMOSIS AND OSMOLALITY A process by which molecules of solvent tend to pass through semi permeable membrane from a less concentrated solution into a more concentrated one.(hypo-osmotic to hyper-osmotic). OSMOTIC CONCENTRATION- Number of osmoles(units) of solutes per litre of solution. i.e., total concentration of all solutes in the organism. OSMOLALITY- Movement of water across a selectively permeable membrane. If two solutions are iso-osmotic, the movement of water is equal in both directions. If two solutions differ in osmolality, the net flow of water is from the hypo-osmotic to the hyper osmotic solution.
OSMOCONFORMERS Osmoconformers are those animals which are osmotically dependent. Those animals are having a high tissue tolerance and can survive such changes as long as their metabolic functions can proceed effectively. Osmotic regulation is practically absent but ionic regulation is essential. Eg ; HAG FISH.
OSMOREGULATORS Osmoregulators are those animals which are osmotically stable (independent) and are able to maintain their internal osmotic concentration. In general osmoconformers can tolerate greater variations in their internal environment than osnoregulators . Osmoregulators can tolerate greater variation in their external environments than osmoconformres . So animals change in volume ( due to alternations of water content ) as the external osmotic concentration changes.
MECHANISM OF OSMOREGULATION To maintain the internal osmotic concentration to an optimum or at a constant level animals have developed various types of adaptations. One of these is a reduction in the area of permeability. Another is the reduction in the permeability of the exposed area. Loss of salts and water may be compensated by their absorption through some part of the excretory system.
OSMOREGULATORY ORGAN IN VERTEBRATES MAIN ORGAN – Kidney through urine production. OTHER ORGANS- Skin, lungs, gills and digestive system.
3 MAJOR ENVIRONMENT Marine environment Freshwater environment Terrestrial environment 1. The nature of osmoregulatory problem is quite different in these environment. 2. Vertebrates live successfully in a wide range of habitats- freshwater, the ocean, tidal regions and on land including desserts. 3. Animals inhibiting their exhibit variety of osmoregulatory adaptations.
OSMOREGULATION IN MARINE ANIMALS Marine animals such as hag fishes, bony fishes, elasmobranch fishes, sea birds, marine reptiles and marine mammals are hypoosmotic to their surrounding environment. In bony fishes the body fluids are hypotonic in relation to the surrounding environment. This is solved by a special gland cells called CHLORIDE SECRETARY CELLS in the gills that excrete excess salt. The water molecules are diffused into the gut.
The marine cartilaginous fishes have solved this problem in a different way. They have same amount of salts in their body fluids. Finally they excrete large amounts of dilute or isotonic urine. Excess salt is also excreted by kidneys. High concentration of urea makes the body fluids slightly hypertonic to sea water.
MARINE CARTILAGENOUS FISH- SHARK
FRESH WATER VERTEBRATES All fresh water animals are hypotonic to the surrounding water. Animals tend to loose water osmotically. They also take in salt. MECHANISM EVOLVED TO MAINTAIN HOMEOSTASIS IN TELEOSTS To compensate the water lose animals drink large quantity of water. Intestinal membrane also absorb water and salts and most of them are passed out with faeces. Some salts are excreted by kidneys. Some absorbed salts such as Nacl , K, Cl are eliminated by active transport through the gill membranes . Chloride secreting cells are present at the base gills and very little urine are excreted by kidneys.
FRESHWATER FISHES
TELEOSTS
In general it has been suggested that the renal system of fresh water - remove sugar, salts and other useful materials. They possess semipermeable areas for respiratory and digestive purposes.
MAIN PROBLEM – Salt concentration of body fluids is higher than environment. So hypertonic to their medium. ADAPTATIONS IN FRESH WATER FISHES Body covered by scales and mucous secretion retard the passage of water into the body. Drink little or no water. Some water leaves the body through gills. Kidneys are adapted to excrete large amount of dilute urine. In Amphibians like Rana and Xenopus they are hypotonic to the watery medium. Rana carnivora – crab eating frog can tolerate sea water. Bufo and Viridis tolerate environmental salinities. Any extra water gained through food can be removed by kidneys. They produce dilute urine so excess water can be eliminated.
Trionyx spinifer (turtle) conserves sodium by active reabsorption. Fresh water birds and mammals – hypertonic. ADAPTATION Integument less permeable to both water and salts. Does not drink water. Active reabsorption of salts in kidneys, tubules and dilute urine is produced. F.W birds - Goose, swamp, Flamingos F.W – Hippopotamus, Otters, River Dolphins.
OSMORECULATION IN FROG
TERRESTRIAL ANIMALS The terrestrial habitat lacks both water and salts in the surrounding medium so they often loss water and salt. Therefore the terrestrial animals usually drink large amount of water. In terrestrial animals such as reptiles, birds, mammals and some crustaceans and annelids - physiological adaptations to meet the osmotic problem.
AMPHIBIANS - Inhabit moist environment. ADAPTATIONS Reduction of permeability of the skin. Seek habitat of high humidity whenever air is dry. High tolerance of dessication . Rapid absorption of water whenever available. Excrete urine and absorb water from urinary bladder. EXAMPLE Urinary bladder acts as a water reservoir in DESERT FROG – Chiroleptes . Urinary bladder volume is large in Bufo congnotus .
TERRESTRIAL REPTILES Water loss from skin is minimised due to heavy keratinisation - impermeable to water. Poikilothermic so characterised by low respiratory and metabolic wastes-evaporation of water through respiration is reduced. Trachysarus (desert lizard) has glomerular surface - reduced so eventually urine formation is reduced. Urinary bladder absent, ureters opens into cloaca and cloacal regions absorbs water from faecal content. Excrete uric acid which requires very little water.
TERRESTRIAL BIRDS AND MAMMALS Maintain constant body temperature and have a high rate of metabolism. Unique capacity to produce urine and have hyperosmotic to blood. ADAPTATION OF TERRESTRIAL BIRDS Conserve water- uric acid. By efficiently reabsorbing water. Has unique capacity of producing hyper osmotic urine. ADAPTATION TO TERRESTRIAL MAMMALS Excrete urea. Produce concentrated urine. Water need is satisfied by drinking it. Utilise metabolic water.
TERRESTRIAL BIRDS AND MAMMALS
DESERT MAMMALS These animals which inhabit in hot dry region. They have adapted to a lack of drinking water as they obtain water entirely from the metabolic reaction. EX: Dipodomys spectabitis . ( kangroo rat)
KANGROO RAT It is found in some of the hottest and driest regions of South western United States. It eats only dry seeds and never drinks water. It has no sweat glands. It produces very dry faeces and excretes a very concentrated urine. CAMELS It can go for a long periods without water in hot, dry deserts. It can lose as much as 40 % of the water in its body fluids and still survive. A dehydrated camel appears very thin as if from starvation - drinks water - body fluids- restored- normal volume.
DESERT MAMMAL CONTENT Food materials vary in their metabolic water potentials. Depend on metabolic water totally. 1g of CHO produces 0.6g of water. 1g of protein produces 0.4g of water. 1g of fat produces 1.07g of water. Fats give maximum output - so desert animals feed on fat rich dry seeds.
VAMPIRE BAT FROM MEXICO Feeds on blood so large quantities of water incorporated in body. In other animals the osmoregulation is performed by sweat glands, mouth, tongue, lungs, kidney.
REFERENCE : Animal physiology by Verma and Agarwal.
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