Síndrome hiperhemolítico en gestante con drepanocitosis: desenlace fatal / Hyperhemolytic syndrome in a pregnant woman with sickle cell disease: fatal outcome

La drepanocitosis es una enfermedad caracterizada por la presencia de una hemoglobina anómala. Afecta principalmente a la raza negra. Su diagnóstico y su tratamiento en la gestante son de vital importancia, ya que puede tener repercusiones fatales tanto para la madre como para el feto. Presentamos el caso de una gestante de raza negra con drepanocitosis, el manejo de la patología y desenlace del mismo (AU)

Sickle cell disease is characterized by the presence of abnormal hemoglobin. This entity primarily affects the black population. Diagnosis and treatment of sickle cell disease in pregnant women is essential as outcome can be fatal for both mother and fetus. We report the case of a pregnant black woman with sickle cell disease. The management and outcome are discussed (AU)

alpha-Thalassemia-like globin gene expression by primitive erythrocytes derived from human embryonic stem cells.

Under culture conditions that promote hematopoietic differentiation, human embryonic stem cells (huESC) give rise to primitive erythroid cells that closely resemble the nucleated erythrocytes of early-stage human embryos. The globin chain distribution of these cells is similar to that seen during the embryonic and fetal stages of development. Here we show that huESC-derived erythroid cells produce substantial quantities of homotetrameric hemoglobin (Hb) composed exclusively of gamma-globin-containing subunits. The globin synthesis of these erythroid cells was also significantly unbalanced, with a substantial decrease of alpha-like globin chain synthesis in relation to that of their beta-like globins, a pattern characteristically associated with alpha-thalassemia (alpha-thal). This pattern of unbalanced globin synthesis appears to be an inherent feature of human erythroid cells that synthesize predominantly embryonic-stage globins.

Disorders of the synthesis of human fetal hemoglobin.

Fetal hemoglobin (HbF), the predominant hemoglobin in the fetus, is a mixture of two molecular species (alpha(2)(G)gamma(2) and alpha(2)(A)gamma(2)) that differ only at position 136 reflecting the products of two nonallelic gamma-globin genes. At the time of birth, HbF accounts for approximately 70% of the total Hb. The (G)gamma:(A)gamma globin ratio in the HbF of normal newborn is 70:30 whereas in the trace amounts of HbF that is found in the adult it reverses to 40:60 because of a gamma- to beta-globin gene switch. Alterations of these ratios are indicative of a molecular defect at the level of the HbF synthesis. Qualitative hemoglobinopathies due to (G)gamma and (A)gamma chain structural variants, and quantitative hemoglobinopathies affecting the synthesis of HbF such as gamma-thalassemias, duplications, triplications, and even sextuplications of the gamma-globin genes, which may be detected in newborn blood lysates, have been described. Moreover, several pathological and nonpathological conditions affecting the beta-globin gene cluster, such as beta-thalassemia, sickle cell disease, deltabeta-thalassemia, and hereditary persistence of HbF syndromes, are characterized by the continued synthesis of gamma-globin chains in the adult life. Studies of these natural mutants associated with increased synthesis of HbF in adult life have provided considerable insight into the understanding of the control of globin gene expression and Hb switching.

Missense mutation of the last nucleotide of exon 1 (G->C) of beta globin gene not only leads to undetectable mutant peptide and transcript but also interferes with the expression of wild allele.

Hemoglobin Monroe (beta globin G->C, codon 30) is a missense mutation. We could not detect either the mutant peptide or transcript in reticulocyte-enriched preparation and in expanded erythroid progenitor cells. By quantitative gene expression assay beta globin mRNA was found to be reduced by more than 70% in all heterozygous subjects with different haplotypes. We conclude that this mutation also interferes with expression of wild type allele.

Short insertion in a hemoglobin chain: Hb Esch, an unstable alpha1 variant with duplication of the sequence Ala65-Leu-Thr-Asn68.

Hemoglobin (Hb) Esch, is an alpha1 variant, expressed at less than 5%, resulting from the duplication of the 12 nucleotides corresponding to CD65 through 68. The effect of this insertion is the repetition of the sequence Ala-Leu-Thr-Asn, which corresponds to the last turn of helix E. In this variant the presence of a one-turn elongated helix E causes instability and increased ligand affinity. Hb Esch was characterized by DNA sequencing and confirmed by electrospray mass spectrometry. Functional studies were performed by flash photolysis measurements on a fraction isolated by flatbed isoelectric focusing, which was enriched in the abnormal hemoglobin. Similar to other alpha chain variants due to short insertion (or deletion), Hb Esch probably results from a slipped mispairing mechanism. The stability of such modified proteins depends upon the region which is added or deleted and usually is more stable when involving a flexible loop or complete helix turn(s) near by.

Hb G-San Josè variant levels correlate with alpha-thalassemia genotypes.

Hb G-San Josè or beta7(A4)Glu-->Gly has been reported in Southern Italian or Mexican families. We have studied four families from Sicily and Campania, Southern Italy. In six carriers, the hemoglobin variant level ranged from 32 to 38%. In four double heterozygotes for Hb G-San Josè and alpha-thalassemia the variant level showed a strong correlation with the alpha-thalassemia genotype. In fact, the variant level was 15% when interacting with the - (alpha)20.5/alphaalpha, 19.6% with the alphaalpha/alphaPoly Aalpha, and 24.8% with alphaalpha/alpha(-5) ntalpha genotypes. In two double heterozygotes for Hb G-San Josè and beta+ -IVS-I-6 (T-->C) the hemoglobin variant level was 67%. These data show that the reduced synthesis of alpha chains causes drastic reduction of probability to form Hb G-San Josè in favor of the formation of Hb A. Moreover, this reduction, (i) correlates with the type of alpha-thalassemia genotype and with the degree of the alpha chain deficiency, and (ii) is, most probably, more marked than the degree of alpha chain reduction. The minor affinity of the beta chain variant for the alpha chains associated with the reduced synthesis of the alpha chains is probably the principal cause of the variant hemoglobin reduction. Moreover, the rapid removal of the abnormal chains by proteolytic enzymes must have an essential role in order to reduce the chain variant pool. These conclusions are in agreement with the results obtained in reticulocyte and in vitro recombination experiments.

Expression, purification, and characterization of human hemoglobins Gower-1 (zeta(2)epsilon(2)), Gower-2 (alpha(2)epsilon(2)), and Portland-2 (zeta(2)beta(2)) assembled in complex transgenic-knockout mice.

Embryonic zeta- and epsilon-globin subunits assemble with each other and with adult alpha- and beta-globin subunits into hemoglobin heterotetramers in both primitive and definitive erythrocytes. The properties of these hemoglobins-Hbs Gower-1 (zeta(2)epsilon(2)), Gower-2 (alpha(2)epsilon(2)), and Portland-2 (zeta(2)beta(2))-have been incompletely described as they are difficult to obtain in quantity from either primary human tissue or conventional expression systems. The generation of complex transgenic-knockout mice that express these hemoglobins at levels between 24% and 70% is described, as are efficient methods for their purification from mouse hemolysates. Key physiological characteristics-including P(50), Hill coefficient, Bohr effect, and affinity for 2,3-BPG-were established for each of the 3 human hemoglobins. The stability of each hemoglobin in the face of mechanical, thermal, and chemical stresses was also determined. Analyses indicate that the zeta-for-alpha exchange distinguishing Hb Portland-2 and Hb A alters hemoglobin O(2)-transport capacity by increasing its P(50) and decreasing its Bohr effect. By comparison, the epsilon-for-beta exchange distinguishing Hb Gower-2 and Hb A has little impact on these same functional parameters. Hb Gower-1, assembled entirely from embryonic subunits, displays an elevated P(50) level, a reduced Bohr effect, and increased 2,3-BPG binding compared to Hb A. The data support the hypothesis that Hb Gower-2, assembled from reactivated epsilon globin in individuals with defined hemoglobinopathies and thalassemias, would serve as a physiologically acceptable substitute for deficient or dysfunctional Hb A. In addition, the unexpected properties of Hb Gower-1 call into question a common hypothesis for its primary role in embryonic development.

Hb Lepore-Baltimore (delta 68Leu-beta 84Thr) and Hb Lepore-Washington-Boston (delta 87Gln-beta IVS-II-8) in central Portugal and Spanish Alta Extremadura.

Hb Lepore is one of the most common abnormal haemoglobins in Caucasians in Central Portugal and in the Spanish Alta Extremadura (0.28% in a survey of school children). A group of 19 Portuguese and 14 Spanish Hb Lepore carriers (all unrelated) was characterised at the molecular level by the polymerase chain reaction, sequencing and restriction enzyme analysis. The Portuguese and one Spanish carrier were heterozygous for Hb Lepore-Baltimore, whereas all other Spanish subjects were Hb Lepore-Washington-Boston carriers. Sequencing of the Hb Lepore-Baltimore gene further established the crossover at delta 68-beta 84, a region two codons (CDs) shorter than that previously described and easily confirmed by digestion with MaeI and BanI. Data from haplotype analysis suggest that this crossover occurred as an independent event on the Iberian Peninsula. The haematological data were similar in both groups except for the levels of Hb F and the G gamma chain, which were significantly higher in the Hb Lepore-Baltimore heterozygotes. Quantification of the globin chains and the mRNA transcripts showed that the delta beta gene is transcribed at a higher level than the delta gene with levels of translation giving rise to 10%-15% of Hb Lepore. The different levels of Hb F observed in the two groups are the results of the higher transcription rate of the gamma genes in Hb Lepore-Baltimore heterozygotes and an apparently less efficient translation of G gamma genes in Hb Lepore-Washington-Boston heterozygotes.

Hb Aubenas [beta 62(B8)Glu-->Gly]: a new variant normally synthesized, affecting the same codon as in Hb E.

Hb Aubenas [beta 26(B8)Glu-->Gly] is a mildly unstable variant that was found in a French family without hematological or clinical features. The structural abnormality was determined by protein chemistry methods, including tandem mass spectrometry, and was confirmed by Apa I digestion of a polymerase chain reaction-amplified DNA fragment. Although the substitution involves the same residue as in Hb E, the new nucleotide sequence does not create an additional out-of-frame splice site. The mutated chain is therefore normally synthesized.

Production of human embryonic haemoglobin (Gower II) in a yeast expression system.

The cDNA coding for a human embryonic globin protein has been obtained from an erythroleukaemic cell line. A plasmid expression system for human embryonic haemoglobin Gower II containing cDNA copies of the appropriate pair of globin genes coupled to synthetic galactose-regulated hybrid promoters has been engineered. Transformation of Saccharomyces cerevisiae with this plasmid yields a cellular system capable of high-level production of fully functional tetrameric embryonic haemoglobin. We have developed a purification scheme which gives high yields of pure human embryonic haemoglobin suitable for structural and functional studies. Preliminary characterization studies are reported.

Globin chain synthesis in hemolytic anemia reticulocytes. A case of hemoglobin Burke.

Peripheral red blood cells from an anemic patient were incubated with [14C]Leu and the labeled globin chains were analyzed by CM-cellulose column chromatography in 8M urea. The radioactivity almost equal to that of beta chain emerged between beta and alpha chains. The newly appeared materials were found to be derived from an abnormal hemoglobin (Hb), Hb Burke [beta 107(G9)Gly to Arg], by the sequence analyses of abnormal globin chain and beta globin mRNA from the patient.

Unstable alpha-chain hemoglobin variants with factitious beta-thalassemia biosynthetic ratio: Hb Questembert (alpha 131[H14]Ser-->Pro) and Hb Caen (alpha 132[H15]Val-->Gly).

Hb Questembert [alpha 131(H14)Ser-->Pro] was found in several members of a French family suffering from congenital Heinz body anemia. The unstable hemoglobin was expressed in the peripheral red blood cells at a very low level. Globin biosynthetic studies revealed a high specific activity of the abnormal chain and an alpha-/beta-labeling ratio similar to that of beta-thalassemia trait. Hb Caen [alpha 132(H15) Val-->Gly] is another unstable variant with the same globin biosynthesis abnormality. In both cases the structural modification is localized at the end of the H helix, a region encoded by the third exon. The mechanism for the unbalanced globin synthesis is not yet clear. It may be related 1) to a defect in chain assembly, 2) to an increased rate of degradation of the variant chain followed by the release of unlabeled beta-chains from the abnormal hemoglobin, thus leading to an apparent suppression of beta-chain synthesis, or 3) to a modified stability of the abnormal alpha-globin mRNA.

Further cases of Hb Hirosaki in two Japanese families.

Hb Hirosaki (alpha 43(CE1)Phe----Leu) was recently found anew in two Japanese families. The probands had chronic hemolytic disorders, while two other carriers of the same Hb in one family did not exhibit increased hemolysis. Hb Hirosaki comprised 5 and 2% of the total Hb in the splenectomized and non-splenectomized proband, respectively, while it comprised only 1% in the two clinically silent carriers. The expected nucleotide substitution was found in the alpha 2 (rather than alpha 1) globin gene in 1 proband. The abnormal globin was synthesized (with incorporation of [3H]-leucine) at about 30 and 20% of the total alpha-chain in reticulocytes of the probands and in those of the silent carriers, respectively. The specific radioactivity of the abnormal chain was about 20-times higher than that of the normal counterpart in the non-splenectomized patient and silent carriers (7-times in the splenectomized patient). The total alpha/beta radioactivity ratio was much higher than unity. The newly synthesized Hb Hirosaki had a slightly high isoelectric point and appeared just in front of normal Hb A in anion-exchange chromatography, but the electric charge of aged Hb Hirosaki was indistinguishable from that of Hb A. These results suggest that Hb Hirosaki is quite unstable, and is rapidly denatured and degraded after biosynthesis. The physical number of the alpha globin genes was normal in all subjects.

NMR study of human mutant hemoglobins synthesized in Escherichia coli. Consequences of tyrosine alpha 42 substitutions.

The hydroxyl group of Tyr alpha 42 in human hemoglobin forms a hydrogen bond with the carboxylate of Asp beta 99 which is considered to be one of the most important hydrogen bonds for stabilizing the "T-state." However, no spontaneous mutation at position 42 of the alpha subunit has been reported, and the role of the tyrosine has not been tested experimentally. Two artificial human mutant hemoglobins in which Tyr alpha 42 was replaced by phenylalanine or histidine were synthesized in Escherichia coli, and their proton NMR spectra were studied with particular attention to the hyperfine-shifted and hydrogen-bonded proton resonances. The site-directed mutagenesis of the Tyr alpha 42----Phe removes the hydrogen bond described above and prevents transition to the T-state so that the mutant Hb is rather similar to the "R-state" even when deoxygenated. On the other hand, the mutation from tyrosine to histidine causes less drastic structural changes, and its quaternary and tertiary structures are almost the same as native deoxy-Hb A. This may be attributed to the formation of a new hydrogen bond between His alpha 1(42) and Asp beta 2(99). These observations indicate that the hydrogen bond formed between Tyr alpha 42 and Asp beta 99 is required to convert unliganded Hb to the T-state.

Hyperunstable hemoglobin Toyama [alpha 2 136(H19)Leu----Arg beta 2]: detection and identification by in vitro biosynthesis with radioactive amino acids.

A previously reported case of congenital Heinz body anemia was reinvestigated. Heat denaturation, isopropanol testing, PCMB precipitation, isoelectricfocusing, and reversed phase high performance liquid chromatography on the red cell lysate from the patient gave either negative, or at most, questionable results. In vitro globin biosynthesis using peripheral blood with incorporation of 3H-leucine demonstrated the production of an abnormal alpha chain at the rate of about 1/3 that of the normal alpha chain. A substitution, alpha 136(H19)Leu----Arg, was elucidated by peptide mapping and radiosequencing of an abnormal tryptic peptide. The hemoglobin consisting of the abnormal alpha and normal beta chains eluted between Hb A2 and Hb A0 in anion exchange high performance liquid chromatography. It was barely detectable by this method, comprising less than 1/1000 of the amount of Hb A0, although it was produced at a level of 1/3 of that of HB A0 in terms of radioactivity. The daughter of the propositus was similarly afflicted and produced the same abnormal alpha chain. The son, who also produced the abnormal alpha chain, was essentially free from hemolytic manifestation. His red cells were microcytic and showed an alpha/beta synthetic ratio of over 2.