Insensitivity of cerebral oxygen transport to oxygen affinity of hemoglobin-based oxygen carriers

The cerebrovascular effects of exchange transfusion of various cell-free hemoglobins that possess different oxygen affinities are reviewed. Reducing hematocrit by transfusion of a non-oxygen-carrying solution dilates pial arterioles on the brain surface and increases cerebral blood flow to maintain a constant bulk oxygen transport to the brain. In contrast, transfusion of hemoglobins with P50 of 4-34 Torr causes constriction of pial arterioles that offsets the decrease in blood viscosity to maintain cerebral blood flow and oxygen transport. The autoregulatory constriction is dependent on synthesis of 20-HETE from arachidonic acid. This oxygen-dependent reaction is apparently enhanced by facilitated oxygen diffusion from the red cell to the endothelium arising from increased plasma oxygen solubility in the presence of low or high-affinity hemoglobin. Exchange transfusion of recombinant hemoglobin polymers with P50 of 3 and 18 Torr reduces infarct volume from experimental stroke. Cell-free hemoglobins do not require a P50 as high as red blood cell hemoglobin to facilitate oxygen delivery.     

Plant hemoglobins: a molecular fossil record for the evolution of oxygen transport

The evolution of oxygen transport hemoglobins occurred on at least two independent occasions. The earliest event led to myoglobin and red blood cell hemoglobin in animals. In plants, oxygen transport "leghemoglobins" evolved much more recently. In both events, pentacoordinate heme sites capable of inert oxygen transfer evolved from hexacoordinate hemoglobins that have unrelated functions. High sequence homology between hexacoordinate and pentacoordinate hemoglobins in plants has poised them for potential structural analysis leading to a molecular understanding of this important evolutionary event. However, the lack of a plant hexacoordinate hemoglobin structure in the exogenously ligand-bound form has prevented such comparison. Here we report the crystal structure of the cyanide-bound hexacoordinate hemoglobin from barley. This presents the first opportunity to examine conformational changes in plant hexacoordinate hemoglobins upon exogenous ligand binding, and reveals structural mechanisms for stabilizing the high-energy pentacoordinate heme conformation critical to the evolution of reversible oxygen binding hemoglobins.     

Multiple hemoglobins of the cutthroat trout, Salmo clarki

Nine hemoglobins were purified from blood of Salmo clarki by ion-exchange chromatography and preparative isoelectric focusing. The subunit structures of eight of the purified hemoglobins were studied by electrophoresis of globins in the presence of urea. Six are alpha 2 beta 2 tetramers while two appear to be heterotetramers of the type alpha alpha' beta 2 and alpha alpha' beta beta'. The effects of pH, nucleotides, and temperature on the oxygen equilibria of the purified hemoglobins were studied. Five hemoglobins with isoelectric points from 9.1 to 7.1 and one minor hemoglobin with an isoelectric point of 5.9 appear to have essentially identical oxygen binding properties. All have similar oxygen equilibria which are independent of pH and temperature and not affected by saturating amounts of ATP. Another minor hemoglobin with an isoelectric point below 5.9 has similar oxygen equilibria except for a possible pH dependence. Two hemoglobins, with isoelectric points of 6.5 and 6.4, have oxygen binding properties which are strongly pH and temperature dependent. Addition of ATP or GTP causes a large decrease in the oxygen affinity without affecting the cooperativity of oxygen binding. The effect of GTP is slightly greater than that of ATP. No significant differences were observed in the oxygen equilibria of these two hemoglobins. The red blood cells of S. clarki were found to contain large amounts of both ATP and GTP, with an ATP:GTP ratio of 3:1. Both nucleotides may be important modulators of hemoglobin oxygen affinity in S. clarki, in contrast to the situation in S. gairdneri, in which red blood cell GTP concentrations are considerably lower. The presence of six or possibly seven hemoglobins with identical oxygen binding properties in S. clarki suggests that, to a large extent, the physiological role of multiple hemoglobins in this species involves phenomena not directly related to the oxygen binding properties of the hemoglobins.     

Oxygen affinities of maternal and fetal hemoglobins of the viviparous seaperch,Embiotoca lateralis

Summary The striped seaperch,Embiotoca lateralis, is a viviparous teleost. The hemoglobins of adult and fetal seaperch are both tetrameric proteins which in their native state appear to be indistinguishable from one another by electrophoresis. However, differences in the subunit structure of maternal versus fetal seaperch hemoglobins can be detected by electrophoresis in urea with a reducing agent, amino acid analyses and peptide maps of the respective proteins. Furthermore, stripped adult and fetal hemoglobins have different oxygen binding affinities at all pH's tested between pH 6.8 and 8.0. Mid-gestation fetal hemoglobin has a higher oxygen affinity than late-gestation fetal hemoglobin which in turn has a higher affinity than that of the adult hemoglobin. All three stripped hemoglobins show a similar Bohr effect (=–0.9). These data suggest that a difference in oxygen affinities exists in vivo between the adult and fetal blood of the seaperchEmbiotoca lateralis and that it can be explained in part by the presence of a structurally unique fetal hemoglobin. This report is the first to provide evidence for a mechanism of maternal-fetal oxygen transfer in a teleost fish.Abbreviations A adult - LF late-gestation fetal - MF mid-gestation fetal (hemoglobins)     

Single amino acid substitution in important hemoglobinopathies does not disturb molecular function and biological process

Hemoglobin is an important protein found in the red cells of many animals. In humans, the hemoglobin is mainly distributed in the red blood cell. Single amino acid substitution is the main pathogenesis of most hemoglobin disorders. Here, the author used a new gene ontology technology to predict the molecular function and biological process of four important hemoglobin disorders with single substitution. The four studied important abnormal hemoglobins (Hb) with single substitution included Hb S, Hb E, Hb C, and Hb J-Baltimore. Using the GoFigure server, the molecular function and biological process in normal and abnormal hemoglobins was predicted. Compared with normal hemoglobin, all studied abnormal hemoglobins had the same function and biological process. This indicated that the overall function of oxygen transportation is not disturbed in the studied hemoglobin disorders. Clinical findings of oxygen depletion in abnormal hemoglobin should therefore be due to the other processes rather than genomics, proteomics, and expression levels.     

Oxygen-binding properties of hemoglobins from estivating and active African lungfish.

The oxygen-binding characteristics and the multiplicity of the stripped hemoglobiin from active lungfish Protopterus amphibius, are the same as in specimens that have been estivating for about 30 months, showing that alteration in the hemoglobin molecules is not involved in the earlier reported increase in oxygen affinity of whole blood during estivation (Johansen et al., '76). At pH 7.0 and 26 degrees C the hemolysates show a high oxygen affinity (P50 = 3.1 Torr), a Bohr factor (delta log P50/delta pH) of - 0.33, and a cooperativity coefficient (n) of 1.7. Between 15 and 26 degrees C, the apparent heat of oxygenation (delta H) is - 8.6 Kcal-mole-1 at pH 7.0, corresponding with data for other fish. A low sensitivity of oxygen affinity to urea appears to be adaptive to the high urea concentrations in estivating lungfish. The salt sensitivity is, however, similar to human hemoglobin. The hemoglobin consists of two major (electrophoretically anodal) components, which differ slightly in oxygen affinity but are both sensitive to pH and nucleoside triphosphates (NTP). Guanosine triphosphate (GTP), the major erythrocytic organic phosphate, however, depresses the oxygen affinity of the composite and separated hemoglobins more effectively than ATP suggesting that GTP is the primary modulator of oxygen affinity. Comparative measurements reveal only one major hemoglobin component in P. annectens which has a markedly lower oxygen affinity and phosphate sensitivity than P. amphibius hemoglobins and thus seems less pliable to phosphate-mediated variation in oxygen affinity. The data are discussed in relation to the hemoglobin systems of other fish.     

The respiratory proteins of insects

For a long time, respiratory proteins have been considered unnecessary in most insects because the tracheal system was thought to be sufficient for oxygen supply. Only a few species that survive under hypoxic conditions were known exceptions. However, recently it has become evident that (1) intracellular hemoglobins belong to the standard repertoire of insects and (2) that hemocyanin is present in many "lower" insects. Intracellular hemoglobins have been identified in Drosophila, Anopheles, Apis and many other insects. In all investigated species, hemoglobin is mainly expressed in the fat body and the tracheal system. The major Drosophila hemoglobin binds oxygen with high affinity. This hemoglobin type possibly functions as a buffer system for oxygen supply at low partial pressures and/or for the protection from an excess of oxygen. Similar hemoglobins, present in much higher concentrations, store oxygen in specialized tracheal organs of the botfly and some backswimmers. The extracellular hemoglobins in the hemolymph of chironomid midges are evolutionary derivatives of the intracellular insect hemoglobins, which emerged in response to the hypoxic environment of the larvae. In addition, several hemoglobin variants of unknown functions have been discovered in insect genomes. Hemocyanins transport oxygen in the hemolymph of stoneflies, but also in the Entognatha and most hemimetabolan taxa. Apparently, hemocyanin has been lost in Holometabola. At present, no physiological or morphological character is known that could explain the presence or loss of hemocyanins in distinct taxa. Nevertheless, the occurrence of respiratory proteins in insects adds further complexity to our view on insect respiration.     

The phylogeny of polar fishes and the structure,function and molecular evolution of hemoglobin

Fishes thriving in polar habitats offer many opportunities for comparative approaches to understanding protein thermal adaptations. Investigations on the remarkable evolutionary adaptations to these environments of basic proteins such as hemoglobin, the oxygen carrier, can provide new insights into the mechanisms studied in temperate organisms and can shed light on convergent processes evolved in response to thermal adaptations. At the molecular level, hemoglobins are one of the most intriguing systems for studying the relationships between environmental conditions and adaptations. This review summarizes the current knowledge on molecular structure, biological function and phylogeny of hemoglobins of fish species living in both polar habitats but having different evolutionary histories. In benthic, non-migratory, cold-adapted fishes, the stability of thermal conditions may have generated no or few variations in selective pressures on globin sequences through evolutionary time, so that sequences retain the species phylogenetic “signal”. In pelagic, migratory, cold-adapted or temperate fishes, variations in selective pressures on globin sequences caused by variations in temperature accompanying the dynamic life style may have disrupted the phylogenetic “signal” in phenetic trees.     

High-altitude respiration of birds. Structural adaptations in the major and minor hemoglobin components of adult Rüppell's Griffon (Gyps rueppellii, Aegypiinae): a new molecular pattern for hypoxic tolerance

The primary structures of the hemoglobins Hb A, Hb A', Hb D and Hb D' of Rüppell's Griffon (Gyps rueppellii), which can fly as high as 11,300 m, are presented. The globin chains were separated on CM-Cellulose in 8M urea buffers, the four hemoglobin components by FPLC in phosphate buffers. The amino-acid sequences of five globin chains were established by automatic Edman degradation of the globin chains and of the tryptic peptides in liquid-phase and gas-phase sequenators. The sequences are compared with those of other Falconiformes. A new molecular pattern for survival at extreme altitudes is presented. For the first time four hemoglobins are found in blood of a bird; they show identical beta-chains and differ in the alpha A- and alpha D-chains by only one replacement. These four hemoglobins cause a gradient in oxygen affinities. The two main components Hb A and Hb A' differ at position alpha 34 Thr/Ile. In case of Ile as found in Hb A' an alpha 1 beta 1-interface is interrupted raising oxygen affinity compared to Hb A. In addition the hemoglobins of the A- and D-groups differ at position alpha 38 Pro or Gln/Thr (alpha 1 beta 2-interface). Expression of Gln in Hb D/D' raises the oxygen affinity of these components compared to Hb A/A' by destabilization of the deoxy-structure. The physiological advantage lies in the functional interplay of four hemoglobin components. Three levels of affinity are predicted: low affinity Hb A, Hb A' of intermediate affinity, and high affinity Hb D/D'. This cascade tallies exactly with oxygen affinities measured in the isolated components and predicts oxygen transport by the composite hemoglobins over an extended range of oxygen affinities. It is contended that the mechanisms of duplication of the alpha-genome (creating four hemoglobins) and of nucleotide replacements (creating different functional properties) are responsible for this remarkable hypoxic tolerance to 11,300 m. Based on this pattern the hypoxic tolerances of other vultures are predicted.     

Structural and functional properties of hemoglobins from unicellular organisms as revealed by resonance Raman spectroscopy

Hemoglobins have been discovered in organisms from virtually all kingdoms. Their presence in unicellular organisms suggests that the gene for hemoglobin is very ancient and that the hemoglobins must have functions other than oxygen transport, in view of the fact that O2 delivery is a diffusion-controlled process in these organisms. Based on sequence alignment, three groups of hemoglobins have been characterized in unicellular organisms. The group-one hemoglobins, termed truncated hemoglobins, consist of proteins with 110-140 amino acid residues and a novel two-over-two alpha-helical sandwich motif. The group-two hemoglobins, termed flavohemoglobins, consist of a hemoglobin domain, with a classical three-over-three alpha-helical sandwich motif, and a flavin-containing reductase domain that is covalently attached to it. The group-three hemoglobins consist of myoglobin-like proteins that have high sequence homology and structural similarity to the hemoglobin domain of flavohemoglobins. In this review, recent resonance Raman studies of each group of these proteins are presented. Their implications are discussed in the context of the structural and functional properties of these novel hemoglobins.     

The sensitivity of hemoglobin oxygen affinity to diphosphoglycerate and the characteristic pH of methemoglobin.

The sensitivity of the oxygen affinity of a hemoglobin to 2,3-diphosphoglyceric acid concentration has been defined as the change in log1/2O2 (deltalogp1/2O2) which results from saturating the hemoglobin with 2,3-diphosphoglyceric acid. The sensitivity varies from one hemoglobin species to another and is linearly rated to the difference in the logarithm of the binding constants of 2,3-diphosphoglyceric acid to deoxy- and oxyhemoglobin, the characteristic pH (pHch), and inversely proportional to the magnitude of the alkaline Bohr effect measured in a saturating amount of 2,3-diphosphoglyceric acid. Its magnitude is higher in large animals than in small animals and varies linearly with the charged amino acid composition of the hemoglobin. The charged amino acid residues must have been selected for in mammals with high metabolic needs and against in animals with low metabolic needs. Variability in the effect of 2,3-diphosphoglyceric acid on the oxygen transport in the different animal hemoglobins must therefore be the result of a positive Darwinian Selection of the charged amino acid residues in their hemoglobins. Furthermore, all the charged groups and not those at the binding site alone, affect the 2,3-diphosphoglyceric acid binding constant of a hemoglobin.     

Intraerythrocytic organic phosphates of fetal and adult seaperch (Embiotoca lateralis): Their role in maternal-fetal oxygen transport

Summary The viviparous seaperch,Embiotoca lateralis, has unique fetal and adult hemoglobins. Stripped fetal hemoglobin has a higher oxygen affinity than stripped adult hemoglobin at pH 6.5–7.1. The oxygen affinities of both adult and fetal hemoglobins are lowered allosterically by ATP at pH 7.1. Both fetal and adult seaperch erythrocytes include approximately 82% ATP and 18% GTP of the total nucleotide triphosphates (NTP) with a trace of AMP. No 2,3-diphosphoglycerate or inositol polyphosphate was detected. Mid- and late-gestation erythrocytes contain less NTP/mole hemoglobin tetramer than do adult cells. The effective NTP concentration in adult cells is higher than that of the fetal erythrocytes even when the intracellular concentration of Mg²⁺, which complexes with NTP, is accounted for. The difference in adult and fetal intraerythrocytic NTP concentration should enhance transfer of oxygen from maternal to fetal blood. Thus, the teleostEmbiotoca lateralis may employ a dual mechanism in maternal-fetal oxygen transfer. A difference in fetal and maternal hemoglobin structure and oxygen affinities is enhanced by a difference in their respective intraerythrocytic organic phosphate concentrations.     

A ubiquitously expressed human hexacoordinate hemoglobin

We have identified a new human hemoglobin that we call histoglobin because it is expressed in a wide array of tissues. Histoglobin shares less than 30% identity with the other human hemoglobins, and the gene contains an intron in an unprecedented location. Spectroscopic and kinetic experiments with recombinant human histoglobin indicate that it is a hexacoordinate hemoglobin with significantly different ligand binding characteristics than the other human hexacoordinate hemoglobin, neuroglobin. In contrast to the very high oxygen affinities displayed by most hexacoordinate hemoglobins, the biophysical characteristics of histoglobin indicate that it could facilitate oxygen transport. The discovery of histoglobin demonstrates that humans, like plants, differentially express multiple hexacoordinate hemoglobins.     

Gas exchange properties of goat hemoglobins A and C

Hypoxic or anemic goats with the A hemoglobin genotype switch to the production of hemoglobin C, resulting in a reduced blood oxygen affinity. However, the physiologic consequences of this switch are not clear. We therefore studied the gas exchange properties of the two hemoglobin types. We found that purified hemoglobins A and C have very similar oxygen affinities and H+ Bohr effects, but in the presence of CO2, the affinity of hemoglobin C is substantially less than that of hemoglobin A. That this is not a nonspecific ionic effect is suggested by identical effects of NaCl on O2 binding to the two proteins and by a 2-fold higher capacity of hemoglobin C to bind CO2. The data can be explained by a class of CO2 binding sites in the beta C chain whose affinity is much higher than that of either of the primary sites or of those in Hb A. Our results suggest that in hemoglobin C-containing red cells CO2 acts as a potent allosteric effector, analogous to the role played by 2,3-diphosphoglycerate in human red blood cells. Goat hemoglobin C may have advantages over hemoglobins A or B in O2 transport under hypoxic conditions or in anemia.     

The hemoglobin of the sea lamprey,Petromyzon marinus

The blood hemoglobin of the sea lamprey presents a curious mixture of primitive and highly specialized properties. Like muscle hemoglobin, it has a molecular weight of about 17,000, and apparently contains a single heme. Its isoelectric point is like that of a typical invertebrate hemoglobin. Its amino acid composition is partly characteristic of invertebrate) partly of vertebrate hemoglobins (Pedersen; Roche and Fontaine). In the present experiments, the oxygen equilibrium curve of this pigment was measured at several pH's. As expected, it is a rectangular hyperbola, the first such function to be observed in a vertebrate blood hemoglobin. Other hemoglobins known to possess this type of oxygen dissociation curve—those of vertebrate muscle, the worm Nippostrongylus, and the bot-fly larva—appear to serve primarily the function of oxygen storage rather than transport. Lamprey hemoglobin on the contrary is an efficient oxygen-transporting agent. It achieves this status by having, unlike muscle hemoglobin, a relatively low oxygen affinity, and a very large Bohr effect. In these properties it rivals the most effective vertebrate blood hemoglobins.     

A membrane-bound hemoglobin from gills of the green shore crab Carcinus maenas

Most hemoglobins serve for the transport or storage of O(2). Although hemoglobins are widespread in "entomostracan" Crustacea, malacostracans harbor the copper-containing hemocyanin in their hemolymph. Usually, only one type of respiratory protein occurs within a single species. Here, we report the identification of a hemoglobin of the shore crab Carcinus maenas (Malacostraca, Brachyura). In contrast to the dodecameric hemocyanin of this species, C. maenas hemoglobin does not reside in the hemolymph but is restricted to the gills. Immunofluorescence studies and cell fractioning showed that C. maenas hemoglobin resides in the membrane of the chief cells of the gill. To the best of our knowledge, this is the first time that a membrane-bound hemoglobin has been identified in eukaryotes. Bioinformatic evaluation suggests that C. maenas hemoglobin is anchored in the membrane by N-myristoylation. Recombinant C. maenas hemoglobin has a hexacoordinate binding scheme at the Fe(2+) and an oxygen affinity of P(50) = 0.5 Torr. A rapid autoxidation rate precludes a function as oxygen carrier. We rather speculate that, analogous to prokaryotic membrane-globins, C. maenas hemoglobin carries out enzymatic functions to protect the lipids in cell membrane from reactive oxygen species. Sequence comparisons and phylogenetic studies suggested that the ancestral arthropod hemoglobin was most likely an N-myristoylated protein that did not have an O(2) supply function. True respiratory hemoglobins of arthropods, however, evolved independently in chironomid midges and branchiopod crustaceans.     

Hydroxylamine reduction to ammonium by plant and cyanobacterial hemoglobins

Plants often face hypoxic stress as a result of flooding and waterlogged soils. During these periods, they must continue ATP production and nitrogen metabolism if they are to survive. The normal pathway of reductive nitrogen assimilation in non-legumes, nitrate, and nitrite reductase can be inhibited during low oxygen conditions that are associated with the buildup of toxic metabolites such as nitrite and nitric oxide, so the plant must also have a means of detoxifying these molecules. Compared to animal hemoglobins, plant and cyanobacterial hemoglobins are adept at reducing nitrite to nitric oxide under anaerobic conditions. Here we test their abilities to reduce hydroxylamine, a proposed intermediate of nitrite reductase, under anaerobic conditions. We find that class 1 rice nonsymbiotic hemoglobin (rice nsHb1) and the hemoglobin from the cyanobacterium Synechocystis (SynHb) catalyze the reduction of hydroxylamine to ammonium at rates 100-2500 times faster than animal hemoglobins including myoglobin, neuroglobin, cytoglobin, and blood cell hemoglobin. These results support the hypothesis that plant and cyanobacterial hemoglobins contribute to anaerobic nitrogen metabolism in support of anaerobic respiration and survival during hypoxia.     

Structure-function relationships in unusual nonvertebrate globins

Based on the literature and our own results, this review summarizes the most recent state of nonvertebrate myoglobin (Mb) and hemoglobin (Hb) research, not as a general survey of the subject but as a case study. For this purpose, we have selected here four typical globins to discuss their unique structures and properties in detail. These include Aplysia myoglobin, which served as a prototype for the unusual globins lacking the distal histidine residue; midge larval hemoglobin showing a high degree of polymorphism; Tetrahymena hemoglobin evolved with a truncated structure; and yeast flavohemoglobin carrying an enigmatic two-domain structure. These proteins are not grouped by any common features other than the fact they have globin domains and heme groups. As a matter of course, various biochemical functions other than the conventional oxygen transport or storage have been proposed so far to these primitive or ancient hemoglobins or myoglobins, but the precise in vivo activity is still unclear. In this review, special emphasis is placed on the stability properties of the heme-bound O2. Whatever the possible roles of nonvertebrate myoglobins and hemoglobins may be (or might have been), the binding of molecular oxygen to iron(II) must be the primary event to manifest their physiological functions in vivo. However, the reversible and stable binding of O2 to iron(II) is not a simple process, since the oxygenated form of Mb or Hb is oxidized easily to its ferric met-form with the generation of superoxide anion. The metmyoglobin or methemoglobin thus produced cannot bind molecular oxygen and is therefore physiologically inactive. In this respect, protozoan ciliate myoglobin and yeast flavohemoglobin are of particular interest in their very unique structures. Indeed, both proteins have been found to have completely different strategies for overcoming many difficulties in the reversible and stable binding of molecular oxygen, as opposed to the irreversible oxidation of heme iron(II). Such comparative studies of the stability of MbO2 or HbO2 are of primary importance, not only for a full understanding of the globin evolution, but also for planning new molecular designs for synthetic oxygen carriers that may be able to function in aqueous solution and at physiological temperature.