Model mice for Presbyterian hemoglobinopathy (Asn(beta108)-->Lys) confer hemolytic anemia with altered oxygen affinity and instability of Hb

Hb Presbyterian (HBB: c.327C>G) in a Nicaraguan Family

Hemoglobin (Hb) is the protein responsible for oxygen transportation. It is a tetrameric protein comprising two α- and two β-globin subunits. In the literature, a large number of mutations in the α- and β-globin genes have been documented. Among these mutations, Hb Presbyterian (HBB: c.327 C>G), is a naturally occurring mutant exerting low oxygen affinity. The C to G exchange (AAC>AAG) at codon 108 of the β-globin gene results in the substitution of asparagine by lysine. Here, we document the identification of HBB: c.327 C>G in a 6-year-old female patient and her father from Nicaragua and Cuba, respectively. The presence of the abnormal Hb was confirmed by cellulose acetate electrophoresis, high performance liquid chromatography (HPLC) and genomic DNA sequencing. The β-globin gene sequences for both, father and daughter, disclosed the heterozygous mutation at codon 108 to be Hb Presbyterian or HBB: c.327 C>G. The mutant Hb was previously reported in four families from North America, Germany, Japan and Spain, respectively. This is the fifth family carrying HBB: c.327 C>G described to date and the first report from Latin America.

Pregnancy-secreted Acid phosphatase, uteroferrin, enhances fetal erythropoiesis

Uteroferrin (UF) is a progesterone-induced acid phosphatase produced by uterine glandular epithelia in mammals during pregnancy and targeted to sites of hematopoiesis throughout pregnancy. The expression pattern of UF is coordinated with early fetal hematopoietic development in the yolk sac and then liver, spleen, and bone to prevent anemia in fetuses. Our previous studies suggested that UF exerts stimulatory impacts on hematopoietic progenitor cells. However, the precise role and thereby the mechanism of action of UF on hematopoiesis have not been investigated previously. Here, we report that UF is a potent regulator that can greatly enhance fetal erythropoiesis. Using primary fetal liver hematopoietic cells, we observed a synergistic stimulatory effect of UF with erythropoietin and other growth factors on both burst-forming unit-erythroid and colony-forming unit-erythroid formation. Further, we demonstrated that UF enhanced erythropoiesis at terminal stages using an in vitro culture system. Surveying genes that are crucial for erythrocyte formation at various stages revealed that UF, along with erythropoietin, up-regulated transcription factors required for terminal erythrocyte differentiation and genes required for synthesis of hemoglobin. Collectively, our results demonstrate that UF is a cytokine secreted by uterine glands in response to progesterone that promotes fetal erythropoiesis at various stages of pregnancy, including burst-forming unit-erythroid and colony-forming unit-erythroid progenitor cells and terminal stages of differentiation of hematopoietic cells in the erythroid lineage.

Chemosensory ventilatory responses in the mutant mice with Presbyterian hemoglobinopathy

The working hypothesis of this study was that chronically increased tissue oxygenation would facilitate respiratory endurance to chemical stimuli. We investigated the ventilatory responses to hypoxia and hypercapnia before and after carotid chemodenervation in the anesthetized, spontaneously breathing Presbyterian, which carry a low affinity variant of hemoglobin, and in wild-type mice. We found a dampening of all chemosensory responses in Presbyterian hemoglobinopathy. Particularly, the Presbyterian mouse with intact carotid body innervation was more vulnerable to hypoxia than the wild-type mouse, showing an accelerated decline in breathing frequency which was not counterbalanced by tidal respiration. We further found that chemodenervation in the Presbyterian mouse, performed in normoxia, led to respiratory arrest. The study shows enhanced susceptibility of respiration to hypoxia and indispensability of neural input from the carotid body for upholding the central respiratory controller's function in Presbyterian hemoglobinopathy. The study also suggests a relationship between hemoglobin-oxygen dissociation and respiration, which points to a metabolic, tissue oxygenation-linked component of respiratory regulation.

Erythrocytes induce proinflammatory endothelial activation in hypoxia

Although exposure to ambient hypoxia is known to cause proinflammatory vascular responses, the mechanisms initiating these responses are not understood. We tested the hypothesis that in systemic hypoxia, erythrocyte-derived H(2)O(2) induces proinflammatory gene transcription in vascular endothelium. We exposed mice or isolated, perfused murine lungs to 4 hours of hypoxia (8% O(2)). Leukocyte counts increased in the bronchoalveolar lavage. The expression of leukocyte adhesion receptors, reactive oxygen species, and protein tyrosine phosphorylation increased in freshly recovered lung endothelial cells (FLECs). These effects were inhibited by extracellular catalase and by the removal of erythrocytes, indicating that the responses were attributable to erythrocyte-derived H(2)O(2). Concomitant nuclear translocation of the p65 subunit of NF-κB and hypoxia-inducible factor-1α stabilization in FLECs occurred only in the presence of erythrocytes. Hemoglobin binding to the erythrocyte membrane protein, band 3, induced the release of H(2)O(2) from erythrocytes and the p65 translocation in FLECs. These data indicate for the first time, to our knowledge, that erythrocytes are responsible for endothelial transcriptional responses in hypoxia.

Thrombocytopenia and erythrocytosis in mice with a mutation in the gene encoding the hemoglobin β minor chain

Diverse mutations in the genes encoding hemoglobin (Hb) have been characterized in human disease. We describe here a mutation in the mouse Hbb-b2 gene, denoted Plt12, that precisely mimics the human hemoglobin Hotel Dieu variant. The mutation results in increased affinity of Hb for oxygen and Plt12 mutant mice exhibited reduced partial pressure of O(2) in the blood, accompanied by erythrocytosis characterized by elevated erythropoietin levels and splenomegaly with excess erythropoiesis. Most homozygous Hbb-b2(Plt12/Plt12) mice succumbed to early lethality associated with emphysema, cardiac abnormalities, and liver degeneration. Survivors displayed a marked thrombocytopenia without significant deficiencies in the numbers of megakaryocytes or megakaryocyte progenitor cells. The lifespan of platelets in the circulation of Hbb-b2(Plt12/Plt12) mice was normal, and splenectomy did not correct the thrombocytopenia, suggesting that increased sequestration was unlikely to be a major contributor. These data, together with the observation that megakaryocytes in Hbb-b2(Plt12/Plt12) mice appeared smaller and deficient in cytoplasm, support a model in which hypoxia causes thrombocytopenia as a consequence of an inability of megakaryocytes, once formed, to properly mature and produce sufficient platelets. The Plt12 mouse is a model of high O(2)-affinity hemoglobinopathy and provides insights into hematopoiesis under conditions of chronic hypoxia.

Reduction in hemoglobin-oxygen affinity results in the improvement of exercise capacity in mice with chronic heart failure

OBJECTIVES

This study examined whether a reduction in hemoglobin-oxygen affinity improves exercise capacity in mice with heart failure.

BACKGROUND

Exercise intolerance is a major determinant of quality of life in patients with chronic heart failure. One of the major goals of the treatment for chronic heart failure is to improve quality of life.

METHODS

Four weeks after left coronary ligation, we transplanted bone marrow cells isolated from the transgenic mice expressing a hemoglobin variant with low oxygen affinity, Presbyterian, into the lethally irradiated mice with heart failure or administered a synthetic allosteric modifier of hemoglobin. The mice were then exercised on a treadmill.

RESULTS

Four weeks after the left coronary artery ligation, mice showed cardiac dysfunction and chamber dilation, which were characteristics of heart failure. The transplantation led to a reduction in hemoglobin-oxygen affinity and an increase in oxygen supply for skeletal muscle without changes in muscle properties. The transplanted mice showed improved running performance on a treadmill despite impaired cardiac contractility. Furthermore, administration of the synthetic allosteric modifier of hemoglobin showed a similar effect.

CONCLUSIONS

Allosteric modification of hemoglobin represents a therapeutic option for improving exercise capacity in patients with chronic heart failure. One mechanism of improvement in exercise capacity is enhanced oxygen delivery in the skeletal muscle.

Comprehensive analysis of gene expression in testes producing haploid germ cells using DNA microarray analysis

The comprehensive changes in testicular gene expression before and after haploid germ cell differentiation were examined using microarray analysis. Approximately 14,000 expressed sequence tag (EST) clones of Mouse FANTOM Array ver.1 were hybridized with probes generated from mRNA of adult and juvenile (17 days postpartum) testes before the onset of spermiogenesis. Of 1315 genes that exhibited reproducible changes in expression (p < 0.05), 46% exhibited an increase of twofold or more in adults compared to juveniles, and 22% a decrease of twofold or more. The analysis not only confirmed the reported haploid-specific expression of several known genes, but also provided new information on the differential expression of various other genes, including upregulated genes such as Allc and Skd3 and downregulated genes such as hbb b1, before or after the onset of spermiogenesis. Based on the fundamental difference in expression profiles, and molecular functions of the encoded products, the genes were classified into several groups: postmeiotically upregulated genes encoding various enzymes, structural and regulatory proteins, and chaperones, and downregulated genes encoding haemoglobins and oxidation/reduction-related proteins or the machinery associated with protein synthesis, such as ribosomal proteins.

Beneficial effect of transfusion with low-affinity red blood cells in endotoxemia

BACKGROUND

Sepsis caused by endotoxins such as lipopolysaccharide (LPS) impairs the microcirculation, diminishing tissue blood supply and aggravates systemic hypoxia. A novel lower-affinity hemoglobin (Hb) variant, Hb Presbyterian, enhances oxygen release to peripheral tissues and may improve tissue oxygen supply during sepsis.

STUDY DESIGN AND METHODS

This study investigated the effectiveness of Presbyterian Hb in transfusion therapy with LPS-challenged sepsis mouse model. Septic wild-type mice were transfused with RBCs from Presbyterian Hb-carrying mutant mice and wild-type mice. Their survival rates were assessed, and apoptosis of hepatocytes was evaluated. Survival rates of septic Presbyterian mutant mice and the wild-type littermates were also studied.

RESULTS

The Presbyterian mutant RBC-transfused septic group survived longer than the wild-type RBC-transfused group. Apoptosis was reduced in the hepatocytes of the former group. Presbyterian mutant mice themselves, however, did not have stronger resistance to LPS-induced sepsis.

CONCLUSION

Transfusion of low-affinity Hb-containing RBCs has beneficial effects in septic mice.

Tissue hyperoxygenation promotes oxidative metabolism in motor unit

Some mutant hemoglobin (Hb) variants are found with lowered O2 affinity. Low oxygen affinity is reported to increase the O2 availability in peripheral tissues (Kunert et al. [1996] Microvasc. Res. 52:58-68). In the present study, we used a mouse model carrying two low-affinity Hb variants, Titusville and Presbyterian, to evaluate the chronic in vivo influence of lowered oxygen affinity on the neuromuscular system. Our model mice showed an increased voluntary running ability compared with wild-type littermates. In the tibialis anterior (TA) muscle of mutant mice, the glycolytic fibers were converted to oxidative ones in where the activity of the mitochondrial marker enzyme succinate dehydrogenase (SDH) was up-regulated. We report that the spinal ventral horn motoneurons innervating TA skeletal fibers also showed higher mitochondrial oxidative enzyme activity. This phenomenon was evidenced by increased SDH activity and electron microscopic (EM) mitochondrial electronic density in these motoneurons. Our data suggest that, as the result of adaptation to the tissue hyperoxygenation, energy metabolism in the neuron-muscle motor unit is augmented and thus function of the motor unit is promoted.

Oxygen sensing: applications in humans

Our concepts of oxygen sensing have been transformed over the years. We now appreciate that oxygen sensing is not a unique property limited to “chemoreceptors” but is a common property of tissues and that responses to changes in oxygen levels are not static but can change over time. Respiratory responses initiated at the carotid body are modified by the excitatory and depressant effects of hypoxia at the brain and on the pathways connecting the carotid body to the brain. Equally important is that we are beginning to use our understanding of the cellular and molecular pathways triggered by hypoxia and hyperoxia to identify therapeutic targets to treat diseases such as cancer. We also have a better understanding of the complexities of the human respiratory responses to hypoxia; however, major deficiencies remain in our ability to alter or even measure human ventilatory responses to oxygen deficiency.

The affinity of hemoglobin for oxygen affects ventilatory responses in mutant mice with Presbyterian hemoglobinopathy

The purpose of this study was to test whether chronically enhanced O2 delivery to tissues, without arterial hyperoxia, can change acute ventilatory responses to hypercapnia and hypoxia. The effects of decreased hemoglobin (Hb)-O2 affinity on ventilatory responses during hypercapnia (0, 5, 7, and 9% CO2 in O2) and hypoxia (10 and 15% O2 in N2) were assessed in mutant mice expressing Hb Presbyterian (mutation in the beta-globin gene, beta108 Asn --> Lys). O2 consumption during normoxia, measured via open-circuit methods, was significantly higher in the mutant mice than in wild-type mice. Respiratory measurements were conducted with a whole body, unrestrained, single-chamber plethysmograph under conscious conditions. During hypercapnia, there was no difference between the slopes of the hypercapnic ventilatory responses, whereas minute ventilation at the same levels of arterial PCO2 was lower in the Presbyterian mice than in the wild-type mice. During both hypoxic exposures, ventilatory responses were blunted in the mutant mice compared with responses in the wild-type mice. The effects of brief hyperoxia exposure (100% O2) after 10% hypoxia on ventilation were examined in anesthetized, spontaneously breathing mice with a double-chamber plethysmograph. No significant difference was found in ventilatory responses to brief hypoxia between both groups of mice, indicating possible involvement of central mechanisms in blunted ventilatory responses to hypoxia in Presbyterian mice. We conclude that chronically enhanced O2 delivery to peripheral tissues can reduce ventilation during acute hypercapnic and hypoxic exposures.

Oxygen affinity of hemoglobin regulates O2 consumption, metabolism, and physical activity

The oxygen affinity of hemoglobin is critical for gas exchange in the lung and O(2) delivery in peripheral tissues. In the present study, we generated model mice that carry low affinity hemoglobin with the Titusville mutation in the alpha-globin gene or Presbyterian mutation in the beta-globin gene. The mutant mice showed increased O(2) consumption and CO(2) production in tissue metabolism, suggesting enhanced O(2) delivery by mutant Hbs. The histology of muscle showed a phenotypical conversion from a fast glycolytic to fast oxidative type. Surprisingly, mutant mice spontaneously ran twice as far as controls despite mild anemia. The oxygen affinity of hemoglobin may control the basal level of erythropoiesis, tissue O(2) consumption, physical activity, and behavior in mice.