Hb bali (Macaca) β80 (EF 4) Asn→Lys: The first hemoglobin variant found in the crab-eating monkey (Macaca fascicularis) on Bali Island,Indonesia

A variant hemoglobin due to structural change in the β chain was found in the central part of Bali island, Indonesia, during field studies on the genetic variation of the Indonesian crabeating monkey (Macaca fascicularis), and was named Hb Bali (Macaca). Structural analysis yielded the following results. (1) The amino acid sequence of the normal β chain of the crab-eating monkey coincided with that of the Japanese monkey (M. fuscata) and the pig-tailed monkey (M. nemestrina). (2) Asn at the 80th position from the amino terminal of the β chain was substituted by Lys in Hb Bali. This substitution appeared to have little harmful effect on the carrier, since the hematological characteristics of the heterozygous carriers were not different from those of normal individuals.     

Alteration of an intersubunit contact in hemoglobin variants: comparative study of modifications at position α126 Asp (H9)

Four human hemoglobin variants have already been described at position α 126 (H9), which is normally occupied by an aspartate: Hb Montefiore (→ Tyr), Hb Tarrant (→ Asn), Hb Fukutomi (→ Val), Hb Sassari (→ His). An additional variant, Hb West One (α126 (H9) Asp→ Gly) is herein described. Aspartate α126 (H9) is involved in a set of hydrogen bonds and salt bridges located at the C-terminal portion of the α-chains and of the C-helix of the β-chains, which are broken in the oxy conformer, providing one of the most important sources of the difference in free energy between the T- and R-state in hemoglobin. A comparative study of four of these α126 Hb variants is presented. An identical degree of alteration of the oxygen binding properties (increased oxygen affinity and decreased cooperativity) was found in all cases, when measured under standard experimental conditions (pH 7.2, 0.1 M NaCl). In contrast, the effect of L345 (a derivative of bezafibrate, which is a specific α-chain binding effector) on oxygen binding to Hb differed from one variant to another. When a bulky Tyr or His residue occupied the α126 (H9) position, little effect of L345 was observed. Conversely, when this position was occupied by a residue of smaller size (Gly or Asn), normal heterotropic effects were observed. Molecular graphic modelling indicates that two classes of three-dimensional structure modifications may occur.     

Polymerization of deoxyhemoglobin CHarlem (β6 Glu → Val, β73 Asp → Asn): The effect of β73 asparagine on the gelation and crystallization of hemoglobin

The kinetics of aggregation and the solubility of deoxy Hb2 C_Harlem (α₂β₂ 6 Val, 73 Asn) in concentrated phosphate buffers were studied in comparison with those of deoxy Hb S and deoxy Hb A. Deoxy Hb C_Harlem aggregated with a clear exhibition of a delay time. The length of the delay and aggregation times and the degree of the aggregation depended upon the initial hemoglobin concentration.The initial hemoglobin concentration required for the aggregation of deoxy Hb C_Harlem was approximately 200% of its solubility, a value much higher than that required for the aggregation of deoxy Hb S (120%). With the same hemoglobin concentration, the delay time for the aggregation of deoxy Hb C_Harlem was approximately 100 times longer than that of deoxy Hb S. The logarithmic plotting of the delay time versus hemoglobin concentration in 1.8 m-phosphate buffer (pH 7.4) showed linear lines with a slope (n) of 4.0 for deoxy Hb C_Harlem. In contrast to the results for the aggregation of deoxy Hb S, n values for deoxy Hb C_Harlem were unchanged with phosphate concentrations varying from 1.2 m to 2.0 m. The solubilities of deoxy Hb S and deoxy Hb C_Harlem were increased exponentially by lowering the pH of the medium, with the increase being more conspicuous for Hb C_Harlem. The gels (or aggregates) of Hb C_Harlem were converted to crystals at a rate much faster than were those of Hb A and Hb S. The kinetics for gelation and crystallization of deoxy Hb C_Harlem can be explained by the following scheme, where nuclei G and nuclei C are formed before gelation and crystallization, respectively. Monomenc deoxy Hb

The hemoglobin concentration required for the crystallization of deoxy Hb C_Harlem was about ten times lower than that required for deoxy Hb A. The solubility of deoxy Hb C_Harlem after aggregation was about twice that of deoxy Hb S, suggesting that the substitution of Asn for Asp at the β73 residue inhibits the formation of nuclei G and accelerates the formation of nuclei C.     

Hemoglobin Rothschild (β37(C3)Trp → Arg): A high/low affinity hemoglobin mutant

In hemoglobin Rothschild arginine replaces the normal tryptophan at β37(C3), at α₁β₂ contact. Residue β37 is in close proximity to Argα92 (FG4). Substitution of Trp by Arg at β37 results in two positively charged Arg residues at FG4 and C3 facing each other, a situation that would destabilize the subunit constraints essential for the tetrameric integrity of the molecule and for the reduced ligand affinity of unliganded normal HB³ compared to isolated chains.Our studies show liganded HbR is extensively dissociated into dimers and has a high ligand affinity in phosphate buffer and a low ligand affinity in bis-Tris at alkaline pH. Kinetic studies indicate that in the T state HbR has a higher ligand affinity than HbA. This is explained by reduced subunit constraints in the T state and dissociation of the monoliganded species (Hb₄L) into dimers. Kinetic studies also show that R state Hb Rothschild has lower ligand affinity than R state HbA. These results are explained on the basis of extensive dissociation of R state Hb Rothschild into dimers and lower ligand affinity of dimers as compared to triliganded tetramers (α₂β₂(O₂)₃). Kinetic data indicate that the lower ligand affinity of dimers (Hb Rothschild) as compared to that of triliganded tetramers (HbA) is due to the increased ligand dissociation rates in the case of oxyhemoglobin and reduced ligand combination in the case of carboxyderivatives. Both the CO combination reaction time-course around 425 nm and the O₂ dissociation rates at 437.8 nm indicate the presence of large α,β-chain differences in Hb Rothschild.     

Hb Mobile [α2β2 73(E17)Asp → Val]: A new variant

A new hemoglobin variant found in a mother and her child was characterized by column chromatography of the tryptic hydrolysate of the aminoethylated, glycinamidated -chain, followed by chymotryptic digestion of the abnormal T-9 peptide and amino acid analyses. It was shown to be _{2 2} 73(E17) Asp Val and named Hb Mobile.This work was supported in part by Research Grants AM0780 and AM13173 from the National Institute for Arthritis and Metabolic Disease.     

Hemoglobin tilburg: α2-ß2 73 (E 17) Asp→Gly: A new hemoglobin with reduced oxygen affinity

A new hemoglobin variant has been found in a Dutch Caucasian girl and detected also in members of three generations of her family. This variant is characterized by the substitution of an aspartic acid at position 73 (E 17) of the ß-chain with a glycine residue. Hemoglobin Tilburg makes up to 42% of the total hemoglobin in the blood of the proposita, it is stable at the isopropanol test, and not associated with significant hematological abnormalities in heterozygous carriers. The oxygen dissociation curve of the purified variant, carried out at different pH values, shows a definite reduction of the affinity for oxygen and a normal alkaline Bohr effect. Three more hemoglobins with a single amino acid substitution at the same site have been previously described: Hb Korle-Bu (Asp→Asn), Hb Mobile (Asp→Val) and Hb Vancouver (Asp→Tyr). In all these proteins the affinity for oxygen is lowered to an extent which is variable and characteristic of each mutant. In this paper we discuss the possible mechanism responsible for the abnormal behaviour of hemoglobins substituted at ß 73.     

α-Thalassemia Associated with Hb Instability: A Tale of Two Features. The Case of Hb Rogliano or α1 Cod 108(G15)Thr→Asn and Hb Policoro or α2 Cod 124(H7)Ser→Pro.

We identified two new variants in the third exon of the α-globin gene in families from southern Italy: the Hb Rogliano, α1 cod108 ACC>AAC or α1[α108(G15)Thr→Asn] and the Hb Policoro, α2 cod124 TCC>CCC or α2[α124(H7)Ser→Pro]. The carriers showed mild α-thalassemia phenotype and abnormal hemoglobin stability features. These mutations occurred in the G and H helices of the α-globin both involved in the specific recognition of AHSP and β1 chain. Molecular characterization of mRNA, globin chain analyses and molecular modelling studies were carried out to highlight the mechanisms causing the α-thalassemia phenotype. The results demonstrated that the α-thalassemia defect associated with the two Hb variants originated by different defects. Hb Rogliano showed an intrinsic instability of the tetramer due to anomalous intra- and inter-chain interactions suggesting that the variant chain is normally synthesized and complexed with AHSP but rapidly degraded because it is unable to form the α1β1 dimers. On the contrary in the case of Hb Policoro two different molecular mechanisms were shown: the reduction of the variant mRNA level by an unclear mechanism and the protein instability due to impairment of AHSP interaction. These data highlighted that multiple approaches, including mRNA quantification, are needed to properly identify the mechanisms leading to the α-thalassemia defect. Elucidation of the specific mechanism leads to the definition of a given phenotype providing important guidance for the diagnosis of unstable variants.     

Second-site mutation at M43 (Asn→Asp) compensates for the loss of two acidic residues in the QB site of the reaction center

Two acidic residues, L212Glu and L213Asp, in the Q_B binding sites of the photosynthetic reaction centers of Rhodobacter capsulatus and Rhodobacter sphaeroides are thought to play central roles in the transfer of protons to the quinone anion(s) generated by photoinduced electron transfer. We constructed the site-specific double mutant L212Ala-L213Ala in R. capsulatus, that is incapable of growth under photosynthetic conditions. A photocompetent derivative of that strain has been isolated that carries the original L212Ala-L213Ala double mutation and a second-site suppressor mutation at residue M43 (AsnAsp), outside of the Q_B binding site, that is solely responsible for restoring the photosynthetic phenotype. The Asp,Asn combination of residues at the L213 and M43 positions is conserved in the five species of photosynthetic bacteria whose reaction center sequences are known. In R. capsulatus and R. sphaeroides, the pair is L213Asp-M43Asn. But, the reaction centers of Rhodopseudomonas viridis, Rhodospirillum rubrum and Chloroflexus aurantiacus reverse the combination to L213Asn-M43Asp. In this respect, the Q_B site of the suppressor strain resembles that of the latter three species in that it couples an uncharged residue at L213 with an acidic residue at M43. These reaction centers, in which L213 is an amide, must employ an alternative proton transfer pathway. The observation that the M43AsnAsp mutation in R. capsulatus compensates for the loss of both acidic residues at L212 and L213 suggests that M43Asp is involved in a new proton transfer route in this species that resembles the one normally used in reaction centers of Rps. virddis, Rsp. rubrum and C. aurantiacus.     

Direct evidence of structural changes in reaction centers of Rb. sphaeroides containing suppressor mutations for Asp L213 → Asn: A FTIR study of QB photoreduction

In bacterial reaction centers (RCs), changes of protonation state of carboxylic groups, of quinone-protein interactions as well as backbone rearrangements occuring upon Q_B photoreduction can be revealed by FTIR difference spectroscopy. The influence of compensatory mutations to the detrimental Asp L213 Asn replacement on Q_B ^–/Q_B FTIR spectra of Rb. sphaeroides RCs was studied in three double mutants carrying a Asn M44 Asp, Arg M233 Cys, or Arg H177 His suppressor mutation. The proton uptake by Glu L212 upon Q_B ^– formation, as reflected by the positive band at 1728 cm^–1, is increased in the Asn M44 Asp and Arg H177 His suppressor RCs with respect to native RCs, and remains comparable to that observed in Asp L213 Asn mutant RCs. Only the Arg M233 Cys suppressor mutation affected the 1728 cm^–1 band, reducing its amplitude to near native level. Thus, there is no clear correlation between the apparent extent of proton uptake by Glu L212 and the recovery of the proton transfer RC function. In all of the mutant spectra, several protein (amide I and amide II) and quinone anion (C...O/C...C) modes are perturbed compared to the spectrum of native RCs. These IR data show that all of the compensatory mutations alter the semiquinone-protein interactions and the backbone providing direct evidence of structural changes accompanying the restoration of efficient proton transfer in RCs containing the Asp L213 Asn lesion.     

Four variants of human plasma α2-glycoprotein (ZAG) in the Japanese population

Summary Zn-₂-glycoprotein (ZAG) of plasma from the general Japanese adult population (n=1224) was studied by polyacrylamide gel isoelectric focusing (IEF) followed by immunoblotting with specific antiserum to ZAG. Most of the plasmas showed a common band pattern, while 16 samples showed four other patterns. These ZAG band patterns were easily differentiated by desialyzing the samples prior to IEF. The asialo form of ZAG commonly showed a single band. The 16 plasma samples presenting double bands were classified into four types containing the common single band. The differences in ZAG phenotypes may be suggested to be due to amino acid substitutions of the ZAG molecule. The statistical frequencies of five alleles, which we proposed to designate ZAG^*1, ZAG^*2, ZAG^*3, ZAG^*4, and ZAG^*5, were 0.9935, 0.0025, 0.0016, 0.0004, and 0.0020, respectively. The genetic transmission of the rare alleles ZAG^*3 and ZAG^*4 was confirmed by two family studies.     

The linkage of Hb Valletta [α2β287(F3)Thr→Pro] and Hb F-Malta-I [α2 Gγ2117(G19)His→Arg] in the Maltese population

Summary We have identified a new stable abnormal hemoglobin called Hb Valletta, which is characterized by a ThrPro substitution at position 87 of the chain. This mutation was found to be linked to that of the chain variant Hb F-Malta-I with a HisArg mutation at position 117 of the ^G chain. Both variants were detected in the blood samples of 34 Maltese and two Italian new-born babies with isoelectrofocusing and reversed phase high performance liquid chromatography. Similar analyses of cord blood from 388 additional Maltese newborns failed to identify either one of these two variants. Additional analyses of 353 Maltese adults (including 39 -thalassemia heterozygotes) resulted in the detection of two adult Hb Valletta heterozygotes. Dot-blot hybridization analyses of amplified DNA with a probe specific for the ^G-F-Malta-I variant showed that both also carried that mutation. These results show close linkage of the mutant forms of the ^G- and -globin genes, 27–28 kb apart, and a failure to identify chromosomes with either the Hb F-Malta-I mutation alone or with the Hb Valletta mutation alone, indicating a low recombination frequency.     

Amino acid substitution and chemical characterization of a Japanese variant of carbonic anhydrase I: CA I Hiroshima-1 (86 Asp → Gly)

An electrophoretic variant of red cell carbonic anhydrase I, designated CA I Hiroshima-1, has been observed in 12 apparently unrelated individuals during a survey of 13,019 individuals from the cities of Hiroshima and Nagasaki, Japan. Analyses of tryptic and chymotryptic peptide patterns of this CA I variant purified from 8 of the 12 individuals revealed the same altered peptides in each case. Examination of the amino acid sequence of an altered tryptic peptide purified from one of the variants showed that the aspartic acid residue at position 86 was replaced by a glycine residue. Thermostability studies demonstrated that all samples of CA I Hiroshima-1 were less stable than normal CA I. The specific esterase (p-nitrophenyl acetate) activities of the normal and variant CA I isozymes were essentially the same. The difference spectra of the normal and variant enzymes were essentially the same. The isoelectric focusing patterns of CA I Hiroshima-1 showed a different pattern of minor bands to those produced by normal CA I. The relative amounts of the normal and variant enzymes purified from single heterozygous individuals were similar.This work was supported by U.S. Public Health Service grant GM-24681 and U.S. Department of Energy contract 2828 (to Dr. J. V. Neel).     

Hemoglobin Dallas (α97(G4)Asn→Lys):functional characterization of a high oxygen affinity natural mutant

Hemoglobin Dallas, an α-chain variant with a substitution of lysine for asparagine at position 97(G4), was found to have increased oxygen affinity ($\text{p}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 1}\text{mmHg at pH}\text{7.3}\text{and}\text{20°C), diminished cooperativity (0n,}\text{the Hill coefficient}\text{= 1.7}$) and reduced Bohr effect (about 50%). Addition of allosteric effectors (such as 2,3-diphosphoglycerate, inositol hexakisphosphate and bezafibrate) led to a decrease in oxygen affinity and increase in cooperative energy. Kinetic studies at pH 7.0 and 20°C revealed that (i), the overall rate of oxygen dissociation is 1.4-fold slower than that for HbA and (ii), the carbon monoxide dissociation rate is unaffected. The abnormal properties of this hemoglobin variant can be atttributed to a more ‘relaxed’ T-state.     

PI (α1) polymorphism in the Japanese: Confirmation of PI*M4 and description of new PI variants

PI phenotyping by separator isoelectric focusing (SIEF) was performed on a total of 1000 unrelated Japanese individuals from two different areas of Western Japan. The PI M1M4 subtype was observed together with the six common PI M subtypes. PI*M4 was confirmed to be present but rare in the Japanese. Several new PI variants were identified by comparison runs of each variant with previously reported genetic variants. The significance of treatment of serum with dithiothreitol (DTT) followed by iodacetic acid (IAC) in determination of PI variants is also described.     

Structural and functional studies of hemoglobin Barcelona (α2β2 94 Asp (FG1) → his): Consequences of altering an important intrachain salt bridge involved in the alkaline Bohr effect

Hemoglobin Barcelona was discovered by routine electrophoresis in a Spanish family showing a mild polycythemia. Red blood cells of the propositus which contained 37% of the abnormal hemoglobin had an increased oxygen affinity and a lowered alkaline Bohr effect. After purification, functional studies of Hb² Barcelona (pI = 7.11) demonstrated a twofold increase in oxygen affinity and a moderate reduction in heme-heme interaction compared to normal HbA. Its reaction towards anionic cofactors (Cl^?, DPG or IHP) was similar to that of HbA. Reactivity of the sulphydryl groups (cysteine-β93) was increased in Hb Barcelona both in the deoxy and fully liganded forms, and in the absence as well as in the presence of IHP. By three different methods (the pH-dependence of log P₅₀, the direct proton titration technique and the measurement of the ΔpIdeox-ox) by isoelectric focusing) all in the absence of phosphate ions, Hb Barcelona was found to have a 20 to 30% reduction of the alkaline Bohr effect. This was most pronounced in the alkaline pH range. The reduction was less than expected for the loss of the important intrachain salt-bridge Asp-β94 → His-β146 considered to be responsible for 40 to 60% of the whole T → R Bohr effect (Perutz et al., 1980). This suggested that in Hb Barcelona, His-β146 could be in weak electrostatic interaction with the neighboring Glu-β90 in the deoxy form. It is concluded that the presence of the oxygen-linked Asp-β94 → His-β146 salt-bridge in HbA is a prerequisite for the full expression of the alkaline Bohr effect and heme-heme interaction.     

A comparative study of hematological parameters of α and β thalassemias in a high prevalence zone: Saudi Arabia

BACKGROUND AND AIMS:

Saudi Arabia falls in the high prevalent zone of αα and β thalassemias. Early screening for the type of thalassemia is essential for further investigations and management. The study was carried out to differentiate the type of thalassemia based on red cell indices and other hematological parameters.

MATERIALS AND METHODS:

The study was carried out on 991 clinically suspected cases of thalassemias in Riyadh, Saudi Arabia. The hematological parameters were studied on Coulter STKS. Cellulose acetate hemoglobin electrophoresis and high-performance liquid chromatography (HPLC) were performed on all the blood samples. Gene deletion studies were carried out by restriction fragment length polymorphism (RFLP) technique using the restriction endonucleases Bam HI.

STATISTICAL ANALYSIS:

Statistical analysis was performed on SPSS 11.5 version.

RESULTS:

The hemoglobin electrophoresis and gene studies revealed that there were 406 (40.96%) and 59 (5.95 %) cases of β thalassemia trait and β thalassemia major respectively including adults and children. 426 cases of various deletion forms of α thalassemias were seen. Microcytosis was a common feature in β thalassemias trait and (-α/-α) and (--/αα) types of α thalassemias. MCH was a more significant distinguishing feature among thalassemias. β thalassemia major and α thalassemia (-α/αα) had almost normal hematological parameters.

CONCLUSION:

MCV and RBC counts are not statistically significant features for discriminating between α and β thalassemias. There is need for development of a discrimination index to differentiate between α and β thalassemias traits on the lines of discriminatory Indices available for distinguishing β thalassemias trait from iron deficiency anemia.     

Ultrastructure of the spore in four Japanese species of Ptychomitrium Fürnr. (Musci)

The ultrastructure of the mature spore in four Japanese species of the acrocarpous moss genus Ptychomitrium is presented. In all species the spores have a similar pattern: there is no recognisable aperture nor sporoderm polarity, exine and perine are poorly developed, cytoplasm only occasionally shows polarity, and plastids have a well developed inner membrane system. The presence of frequent intine protrusions is a remarkable feature of this genus. A multilaminar structure of the exine, already observed in Grimmia, occurs also in these species although here it is less pronounced. The significance of these features is discussed within these species, as well as in comparison to other taxa, especially the genus Grimmia.     

Heterozygosity for the IVS-I-5(G→C) mutation with a G→A change at codon 18 (Val→Met; Hb Baden) in cis and a T→G mutation at codon 126 (Val→Gly; Hb Djonburi) in trans resulting in a thalassemia intermedia

We have analyzed the hemoglobins of a young German patient with β-thalassemia intermedia and of his immediate family and included in these studies an evaluation of possible nucleotide changes in the β-globin through sequencing of amplified DNA. One chromosome of the propositus and one of his father's carried the $\text{G}\text{T}\text{G}\text{→}\text{G}\text{G}\text{G}$ mutation at codon 126 leading to the synthesis of Hb Dhoburi or α₂β₂126(H₄)Val→Gly; this variant is slightly unstable and is associated with mild thalassemic features. His second chromosome and one of his mother's had the common IVS-I-5 (G→C) mutation that leads to a rather severe β⁺-thalassemia and the $\text{G}\text{TG}\text{→}\text{A}\text{TG}$ mutation at codon 18, resulting in the replacement of a valine residue by a methionine residue. This newly discovered β-chain variant, named Hb Baden, was present for only 2–3% in both the patient and his mother. This low amount results from a decreased splicing of RNA at the donor splice-site of the first intron that is nearly completely deactivated by the IVS-I-5 (G→C) thalassemic mutation. The chromosome with the codon 18 ($\text{G}\text{TG}\text{→}\text{A}\text{TG}$) and the IVS-I-5 (G→C) mutations has thus far been found only in this German family; analysis of 51 chromosomes from patients with the IVS-I-5 (G→C) mutation living in different countries failed to detect the codon 18 ($\text{G}\text{TG}\text{→}\text{A}\text{TG}$) change.     

Hb Natal or α2(minus Tyr-Arg)β2: A high oxygen affinity α chain variant with a deleted carboxy-terminus resulting from a TAC → TAA (Tyr → terminating codon) mutation in codon α140

The discovery is reported of a fast-moving α chain variant (Hb Natal) which is characterized by a shortened α polypeptide chain because of the deletion of the Tyr-Arg carboxy-terminal residues. Through amplification of appropriate segments of DNA and hybridization with synthetic oligonucleotide probes, it was possible to detect a C → A mutation in codon 140 of the α₂ globin gene, which causes a change in the codon for tyrosine to a terminating codon. Hb Natal or α₂(minus Tyr-Arg)β₂ has a high affinity for oxygen without a Bohr effect and heme-heme interaction. These results provide direct evidence for the importance of the tyrosine residue at α140 in the oxygenation-deoxygenation process.