Oxygen affinity and allosteric effects of embryonic mouse haemolglobins

Functional diversification of sea lamprey globins in evolution and development

Agnathans have a globin repertoire that markedly differs from that of jawed (gnathostome) vertebrates. The sea lamprey (Petromyzon marinus) harbors at least 18 hemoglobin, two myoglobin, two globin X, and one cytoglobin genes. However, agnathan hemoglobins and myoglobins are not orthologous to their cognates in jawed vertebrates. Thus, blood-based O₂ transport and muscle-based O₂ storage proteins emerged twice in vertebrates from a tissue-globin ancestor. Notably, the sea lamprey displays three switches in hemoglobin expression in its life cycle, analogous to hemoglobin switching in vertebrates. To study the functional changes associated with the evolution and ontogenesis of distinct globin types, we determined O₂ binding equilibria, type of quaternary assembly, and nitrite reductase enzymatic activities of one adult (aHb5a) and one embryonic/larval hemoglobin (aHb6), myoglobin (aMb1) and cytoglobin (Cygb) of the sea lamprey. We found clear functional differentiation among globin types expressed at different developmental stages and in different tissues. Cygb and aMb1 have high O₂ affinity and nitrite reductase activity, while the two hemoglobins display low O₂ affinity and nitrite reductase activity. Cygb and aHb6 but not aHb5a show cooperative O₂ binding, correlating with increased stability of dimers, as shown by gel filtration and molecular modeling. The high O₂-affinity and the lack of cooperativity confirm the identity of the sea lamprey aMb1 as O₂ storage protein of the muscle. The dimeric structure and O₂-binding properties of sea lamprey and mammalian Cygb were very similar, suggesting a conservation of function since their divergence around 500million years ago.

Convergent evolution of hemoglobin switching in jawed and jawless vertebrates

Background

During development, humans and other jawed vertebrates (Gnathostomata) express distinct hemoglobin genes, resulting in different hemoglobin tetramers. Embryonic and fetal hemoglobin have higher oxygen affinities than the adult hemoglobin, sustaining the oxygen demand of the developing organism. Little is known about the expression of hemoglobins during development of jawless vertebrates (Agnatha).

Results

We identified three hemoglobin switches in the life cycle of the sea lamprey. Three hemoglobin genes are specifically expressed in the embryo, four genes in the filter feeding larva (ammocoete), and nine genes correspond to the adult hemoglobin chains. During the development from the parasitic to the reproductive adult, the composition of hemoglobin changes again, with a massive increase of chain aHb1. A single hemoglobin chain is expressed constitutively in all stages. We further showed the differential expression of other globin genes: Myoglobin 1 is most highly expressed in the reproductive adult, myoglobin 2 expression peaks in the larva. Globin X1 is restricted to the embryo; globin X2 was only found in the reproductive adult. Cytoglobin is expressed at low levels throughout the life cycle.

Conclusion

Because the hemoglobins of jawed and jawless vertebrates evolved independently from a common globin ancestor, hemoglobin switching must also have evolved convergently in these taxa. Notably, the ontogeny of sea lamprey hemoglobins essentially recapitulates their phylogeny, with the embryonic hemoglobins emerging first, followed by the evolution of larval and adult hemoglobins.

Electronic supplementary material

The online version of this article (doi:10.1186/s12862-016-0597-0) contains supplementary material, which is available to authorized users.

Erythropoietin induces sustained phosphorylation of STAT5 in primitive but not definitive erythrocytes generated from mouse embryonic stem cells

OBJECTIVE

During embryonic development murine erythropoiesis occurs in two waves by producing first primitive erythroid cells (EryPs) and then definitive erythroid cells (EryDs). Erythropoietin (EPO) signaling is compared between EryPs and EryDs.

METHODS

We studied the EPO signaling in EryPs and EryDs using an embryonic stem-derived culture system, which can recapitulate this in vivo development process and has thus been used as a convenient in vitro model system of erythropoiesis.

RESULTS

We found that EPO induced sustained phosphorylation and nuclear translocation of signal transducer and activator of transcription 5 (STAT5) in EryPs but not EryDs. EryPs expressed dramatically higher amounts of EPO receptor compared with EryDs, indicating there was excessive signaling from the receptor upon EPO stimulation. In addition, reduced expression of tyrosine phosphatase, Src homology region 2 domain-containing phosphatase-1, and decreased total phosphatase activity in EryPs partly explain the persistent activation of STAT5. Nevertheless, Janus kinase 2 (JAK2) phosphorylation, which is essential for transduction of EPO signaling from the EPO receptor to STAT5, was observed in a transient but not a persistent manner. Inhibition of JAK activity resulted in partial suppression of transient phosphorylation of STAT5 and no suppression of sustained phosphorylation of STAT5.

CONCLUSION

This study presents a unique feature of EryPs, as this is the first known example of sustained activation of STAT5 in normal cells. Our results also imply the existence of a JAK2-independent pathway of EPO signaling to induce STAT5 activation.

Origins of mammalian hematopoiesis: in vivo paradigms and in vitro models

Though a topic of medical interest for centuries, our understanding of vertebrate hematopoietic or "blood-forming" tissue development has improved greatly only in recent years and given a series of scientific and technical milestones. Key among these observations was the description of procedures that allowed the transplantation of blood-forming activity. Beyond this, other advances include the creation of a variety of knock-out animals (mice and more recently zebrafish), microdissection of embryonic and fetal blood-forming tissues, hematopoietic stem (HSC) and progenitor cell (HPC) colony-forming assays, the discovery of cytokines with defined hematopoietic activities, gene transfer technologies, and the description of lineage-specific surface antigens for the identification and purification of pluripotent and differentiated blood cells. The availability of both murine and human embryonic stem cells (ESC) and the delineation of in vitro systems to direct their differentiation have now been added to this analytical arsenal. Such tools have allowed researchers to interrogate the complex developmental processes behind both primitive (yolk sac or extraembryonic) and definitive (intraembryonic) hematopoietic tissue formation. Using ES cells, we hope to not only gain additional basic insights into hematopoietic development but also to develop platforms for therapeutic use in patients suffering from hematological disease. In this review, we will focus on points of convergence and divergence between murine and human hematopoiesis in vivo and in vitro, and use these observations to evaluate the literature regarding attempts to create hematopoietic tissue from embryonic stem cells, the pitfalls encountered therein, and what challenges remain.

Oxygen transport by rabbit embryonic blood: high cooperativity of hemoglobin-oxygen binding

Oxygen equilibrium curves (OECs) have been determined in blood of embryonic and adult rabbits (Oryctolagus cuniculus) using a thin film method (modified Hemoscan). The gestational age of the rabbits was from 12 days to 14 days, the end of the embryonic period. Measurements were made at 37 degrees C and a PCO2 of 21, 42, or 71 mmHg. The most striking finding was an embryonic OEC which was steep above 50% saturation. The Hill plot in this upper region gave a mean nH value of 5.3 in the embryos, the first finding of nH significantly greater than 4 in any normal eutherian mammal. On hemolysis, nH dropped below 4. Oxygen affinity of 14 day embryonic blood was higher than that of adult blood: respective P50 values at PCO2 = 42 mmHg were 29.6 mmHg and 32.5 mmHg. The P50s were somewhat lower at earlier stages. The Bohr effect was measured (as delta log P50/delta log PCO2) in 14 day embryos. Its value was 0.26, about 10% lower than in adults. The results show an apparent aggregation of Hb tetramers, as found in marsupials, but no right shifting of the embryonic OEC compared to the adult OEC.

Blood O2 transport in newborn and adult of a very small marsupial (Sminthopsis crassicaudata)

Blood O2 transport and hemoglobin types have been studied in a Dasyurid marsupial (Sminthopsis crassicaudata) at the neonatal (10-20 mg) and adult (16 g) stages, and in part of the transition period. In neonates the blood was embryonic in type with erythrocytes nucleated and containing two Hb types both different from adult Hb. The oxygen equilibrium curves (OECs) at day 1 had a P50 of 38 mmHg at 36 degrees C and PCO2 = 43 mmHg. This is lower than in other neonatal marsupials, but higher than in fetal or neonatal eutherian mammals. Adult P50 under the same conditions were higher (59 mmHg), the normal relationship in viviparous animals. Hill plots of neonatal OECs showed a sharp upward bend at about 50% saturation. As in other embryonic and neonatal marsupials, in the upper part of the plot nH was greater than 4. This indicates aggregation of Hb tetramers. The Bohr effect of neonatal blood at higher PCO2 values (43-71 mmHg PCO2) was zero. The special features of neonatal blood had largely disappeared by day 6.

Blood oxygen carriage in the marsupial, tammar wallaby (Macropus eugenii), at prenatal and neonatal stages

The measurements reported here are the first to be made on oxygen carriage of a prenatal marsupial. The oxygen equilibrium curves (OECs) of tammar wallaby blood 1-2 days before the due date of birth showed a high P50 (mean = 44 Torr at 36 degrees C at a PCO2 of 34 Torr), more than 1.5 times that of the mother. This was confirmed by measurements in red cell suspensions at controlled pH. The finding of a higher P50 than in adult is in contrast to the general finding in eutherian (placental) mammals. Also they showed interaction between O2 and CO2 carriage (expressed as delta log P50/delta log PCO2 between 34 and 64 Torr PCO2) about half the magnitude of that in adults. At high PCO2 this effect reversed in the lower part but not in the upper part of the OEC. The Hill plot of the OECs showed a bend in the middle range of saturation: in nearly all cases the Hill coefficient (nH) was greater than 4.0 above about 50% saturation suggesting aggregation of haemoglobin tetramers. These results are similar to those previously reported for neonatal tammars and confirmed by further measurements in this study. The prenatals all had four haemoglobin types, identical with those found in the neonates.

How do avian embryos breathe? Oxygen transport in the blood of early chick embryos

1. Chick embryos with primary circulation, up to about 3 days of development, show no hemoglobin-mediated transport of oxygen. 2. In embryos with secondary circulation, between 3 and 6 days of incubation, the vascular area acts as the respiratory organ. Its efficiency in the oxygen uptake is less than that of the chorioallantois of later embryos. On the contrary, oxygen release to the tissues is highly efficient. 3. A full efficient hematic uptake of oxygen is reached at about the 6th incubation day, when chorioallantois acts as the embryonic respiratory organ. 4. The different respiratory mechanisms of developing chick embryo are closely related to the functional properties of the various hemoglobins which are produced during the embryonic life.

Oxygen carriage and carbonic anhydrase activity in the blood of a marsupial, the Tammar wallaby (Macropus eugenii), during early development

Blood O2 transport and Hb type have been studied in pouch young and adult of a marsupial, the Tammar Wallaby. The O2-Hb equilibrium curves (at 35.5 degrees C and PCO2 = 34 Torr) had a high P50 in the first few days of life, up to 49 Torr. This fell to 32 Torr by 2 weeks of age. Also (delta log P50/delta PCO2) was low but it rose to adult levels by 2 weeks of age. The curves in these early pouch young showed a change in Hill coefficient (nH) at between 32 and 62% saturation, nH rising to more than 4.0 at higher O2 saturations. This indicates interaction between more than 4 Hb subunits. Model calculations showed that such curves could be produced by a mixture of 2 Hb components; one with a low P50 and low nH, and one with a high P50 and high nH. In this model the nH values were different from the nH values of either component. The temperature effect on P50 in early pouch young was higher than in adult Tammars and similar to that reported for adult eutherians. In the first 4 days all red cells were nucleated and four Hb types were present. Carbonic anhydrase activity in the blood before birth was about 30% of the adult levels. These levels remained until 2 days after birth, when a rapid rise in activity began, near-adult levels being reached at 5 days despite the animals being still very immature.

Embryonic pig hemoglobins Gower I (zeta 2 epsilon 2), Gower II (alpha 2 epsilon 2), Heide I (zeta 2 theta 2) and Heide II (alpha 2 theta 2): oxygen-binding functions related to structure and embryonic oxygen supply

The common pig lacks a fetal hemoglobin but has four embryonic hemoglobins: Gower I (zeta 2 epsilon 2), Gower II (alpha 2 epsilon 2), Heide I (zeta 2 theta 2) and Heide II (alpha 2 theta 2) as well as adult Hb A (alpha 2 beta 2) and the amino acid sequence for each of the five constituent polypeptide chains has been established. The oxygenation characteristics of the five components, measured in relation to pH, temperature and the erythrocytic ligand 2,3-diphosphoglycerate (DPG), together with the changes in their relative concentrations during early embryonic life, are given. The findings indicate a progressive decrease in maternal-fetal oxygen affinity difference and thus in oxygen transfer efficacy at a given diffusion gradient that correlates with the development of the gas exchange structures. The functional properties of the individual hemoglobins are additionally discussed in relation to molecular structure.

Molecular aspects of embryonic mouse haemoglobin ontogeny

Embryos from C57BL/6J mice between the gestational ages of 9 and 16 days possess three embryonic haemoglobins EI, EII and EIII, the proportions of which change as a function of gestational age. Component EI, originally present at approx. 65% at day 9, decreases to approx. 20% by day 16, while component EII increases in an inverse manner to that of component EI. During this period component EIII remains essentially constant at approx. 25%. Separation of these species by ion-exchange chromatography has allowed the characterization of the Hill coefficient, Bohr effect, heat of oxygenation and binding of allosterically active organic phosphates for each component. The three components show marked functional heterogeneity and also differ from maternal haemoglobin. Oxygenation curves for whole embryonic blood show distinct deviations from simple binding behaviour. The presence of a high-affinity component within the blood samples may be accounted for by the presence of haemoglobin EI. By using parameters obtained from the study of the isolated components it has been possible to synthesize mathematically the O2-binding curves, obtained experimentally, throughout the gestational period. The characteristics of the isolated haemoglobin components of embryonic mouse blood are discussed in terms of the changing demands for O2 likely to be encountered by the developing embryo.

Sequence and linkage of the goat epsilon I and epsilon II beta-globin genes

Overlapping clones containing beta-globin genes have been isolated from a goat genomic library which establish the linkage arrangement 5'-epsilon I-epsilon II-psi beta X-beta C-3'. The complete nucleotide sequence of the epsilon I and epsilon II genes was determined. The sequences of these two genes, along with those previously reported for psi beta X and beta C, complete the sequence of the genes of this linkage set. The first gene in the quadruplet, epsilon I, shows unexpectedly high homology with the human epsilon globin gene both in coding and non-coding regions, and encodes a globin protein that is 90% homologous to human epsilon. The only major difference between the goat epsilon I gene and the human epsilon gene is the presence of an insertion element in the second intron of epsilon I. This element is repetitive in nature and is similar to those found in the second intron of the gamma, beta C and beta A globin genes of the goat. epsilon II also shows high nucleotide homology to the human epsilon globin gene in coding regions and encodes a protein 79% homologous to human epsilon. Notably, however, epsilon II has equivalent nucleotide homology in coding regions to the gamma and epsilon genes of the human locus. The insertion element present in epsilon I is not present in epsilon II. A comparison of the goat beta globin set described here, based on linkage arrangement, nucleotide homology and divergence analysis indicates that this subset of goat beta globin genes is analogous to the entire beta globin loci of other mammalian species. These analyses further indicate that the embryonic genes in these clusters are evolving more slowly than the adult beta globin genes. Comparison of the 5' flanking sequences of epsilon I and epsilon II with those of the beta-embryonic globin genes of other mammals reveals a conserved sequence, C-A-C-C-C-C-T-G, located 28 to 29 bases upstream from the C-C-A-A-T consensus sequence, which appears at this position in the embryonic genes, but in none of the non-embryonic genes. Significantly, this sequence is selectively conserved in the human alpha embryonic globin gene, zeta, which diverged from the beta embryonic genes 500 million years ago, and it may therefore represent an embryonic recognition or signal sequence.

Structure of the zeta chain of human embryonic hemoglobin

The complete amino acid sequence of the zeta chain of human embryonic hemoglobin has been determined. It differs from human alpha globin at 57 of the 141 residues and several of the replacements are at positions of structural or functional importance, particularly in relationship to the Bohr effect and high intrinsic oxygen affinity which are characteristic of embryonic hemoglobins. The zeta-globin sequence is more closely related to other mammalian embryonic alpha-like globins than to human alpha, suggesting that there have been strong selective pressures to maintain these embryo-specific globins since their emergence several hundred million years ago.

Adaptation of hemoglobin function to subterranean life in the mole, Talpa europaea

In order to understand the mechanism responsible for the high oxygen affinity of mole blood, we investigated in the mole. Talpa europaea, red cell parameters that determine hemoglobin function. We have found that the oxygen half saturation pressure (P50) of mole blood is 2.85 kPa (21.4 Torr) at pCO2 4.7 kPa, pH 7.4 and 37 degree C. The concentration of 2,3-diphosphoglycerate (2,3-DPG) averaged 5.3 mmol/l in red cells. In addition, we have determined P50 in hemoglobin solutions at various concentrations of 2,3-DPG at an assumed intraerythrocytic pH of 7.2 and 37 degree C. These data were used to calculate the association constants of 2,3-DPG to mole hemoglobin. P50 was 1,89 kPa (14.2 Torr) in hemoglobin solutions without 2,3-DPG. The response to 2,3-DPG was relatively low. Noteworthy, CO2 did not affect the oxygen affinity at constant pH in the presence of 2,3-DPG. Our results suggest that the high blood oxygen affinity of the mole can be attributed to a weak interaction of its hemoglobin with 2,3-DPG.

Rat embryonic and foetal erythrocytes. High 2,3-bisphosphoglycerate and ATP and low oxygen affinity in vitro for nucleated embryonic cells

Embryonic nucleated red cells of the rat have high ATP and 2,3-bisphosphoglycerate and relatively low oxygen affinity. During foetal life they are replaced by large non-nucleated red cells with high ATP, low bisphosphoglycerate and high oxygen affinity. After birth, small non-nucleated red cells with high bisphosphoglycerate and low oxygen affinity rapidly predominate.

Regulation of oxygen affinity in blood of fetal, newborn and adult mouse

Oxygen half saturation pressure (P50) of blood and the role of 2,3 diphosphoglycerate (DPG), adenosine-triphosphate and red cell pH regulating oxygen affinity were examined in fetuses (16,5-18,5 days of gestational age), neonatal (1-22 days post partum) and adult mice (Balb/c). The high oxygen affinity of fetal blood (P50 = 29 Torr at 37 degrees C, pH 7.4 and Pco2 = 40 Torr) decreases to an average adult value of 41 Torr within two weeks after birth, accompanied by an increase of DPG-concentration from 0.2 M/MHb4 to the average of 1.5 M/MHb4. At a constant pHe of 7.4 red cell pH decreases from pH 7.3 to 7.18 from 18.5 days of gestational age to ten days post partum. Electrophoretic mobility and functional characteristics of purified fetal and adult hemoglobin were identical. Changes in oxygen affinity occur only due to organic phosphate concentration variations. A rapid replacement of large size fetal red cells by smaller adult cells after birth fairly coincides with the increase of the 2,3-DPG concentration.