Animal Physiology: Respiratory Pigments

chlorocruorin found in . . .

- 4 families of marine annelids

myoglobin

- a different type of hemoglobin - chemical structure differs - single subunit protein - holds oxygen tighter than hemoglobin - gives muscles their red coloration

chlorocruorins

- always extracellular, dissolved in plasma - iron porphyrin ground bound to protein, different from hemoglobin - bind one oxygen per iron porphyrin group

respiratory pigment

- any molecule that increases the oxygen-carrying capacity of the blood

oxygenated hemocyanin

- blue color

deoxygenated hemerythrin

- colorless

hemoglobin

- comprised of four subunits, each containing one polypeptide chain and one heme group - consists of alpha and beta globin - heme group is the part of hemoglobin that can bind oxygen - each heme contains one iron atom at the center of a porphyrin ring that binds oxygen - each hemoglobin can bind a total of 4 oxygen molecules

oxygenated chlorocruorins

- darker green

characteristics of respiratory pigments

- has a highly specific binding sites - conformation change occurs when pigment binds its ligand - allosteric sites exist for binding molecules other than the primary ligand, thus affecting the binding for the primary ligand - if pigments have multiple subunits, binding sites demonstrate cooperativity

which respiratory pigments contain the metal copper

- hemocyanins

which respiratory pigments contain the metal iron

- hemoglobin - chlorocruorins - hemerythrins

hemoglobin affinity

- hemoglobins that have high oxygen affinities are saturated at low partial pressure of oxygen - hemoglobins with low oxygen affinities are completely saturated only at relatively high partial pressures of oxygen

methemoglobin

- inactive form of hemoglobin - band in high amounts - can be caused by environmental poisons or dugs such as amyl nitrate and nitroglycerin

state of iron in hemoglobin

- iron in ferrous state, oxygen binds to hemoglobin - iron in ferric state, oxygen binds to hemoglobin but it cannot release the oxygen due to its increased in binding affinity *oxidize ferrous to ferric iron

deoxygenated chlorocruorins

- light green

hemerythrin is found in . . .

- marine annelids - sipunculid worms - branchiopods - priapulida

hemocyanin is found in . . .

- molluscs - arthropods

molecules that inactive ferrous hemoglobin to ferric methemoglobin

- nitrates, which greatly increase the rate of oxidation of ferrous to ferric iron (i.e. Blue Baby syndrome) - carbon monoxide inactivates the oxygen carrying ability of hemoglobin

hemerythrins

- no heme group - two iron atoms bound directly to the protein - 8 oxygen binding sites

oxyhemoglobin

- oxygen bound to hemoglobin - bright red

deoxyhemoglobin

- oxygen is not bound to hemoglobin - dark, maroon-red

oxygenated hemerythrin

- reddish violet

methemoglobin reductase

- reduces ferric methemoglobin to the functional ferrous hemoglobin

hemocyanin

- second most common class of respiratory pigments - binds oxygen when the partial pressure of oxygen is high, and releases it when the partial pressure is low - only about 1/4 the efficiency of hemoglobin - copper as metal ion - one oxygen molecule per two copper atoms - it is not contained in cells, but it is dissolved in blood plasma

How does cooperativity work?

- the binding of oxygen by the iron atom causes it to be moved slightly - this causes the histidine attached to it to slightly change position, which causes all other amino acids in the subunits to slightly change position - the change in shape results in the protein gaining affinity for oxygen as more oxygen is bound

deoxygenated hemocyanin

- transparent

types of respiratory pigments

1. hemoglobins 2. chlorocruocins 3. hemerythrins 4. hemocyanins

reason for anucleate RBCs

allow for: - greater flexibility in maneuvering small vessels such as capillaries - more hemoglobin to be contained within the cell, so more oxygen to be transported around the body