Resveratrol, a natural dietary phytoalexin, possesses similar properties to hydroxyurea towards erythroid differentiation.

Resveratrol, a natural dietary polyphenol, has been postulated to be implicated in the cardioprotective effect of red wine and the low incidence of breast and prostate cancers among vegetarians and Orientals respectively. This compound inhibits ribonucleotide reductase as does hydroxyurea, the first therapeutic agent used in the treatment of sickle cell disease. Using the human erythroleukaemic K562 cell line as an in vitro model, we show here that 50 micromol/l of resveratrol induced a higher haemoglobin production (sevenfold) in K562 cells than 500 micromol/l of hydroxyurea (3.5-fold). This erythroid differentiation was linked to a dose- and time-dependent inhibition of cell proliferation associated with an equivalent increased expression of p21 mRNA, but with a higher increased level of p21 protein (sixfold) for cells treated with resveratrol than for those treated with hydroxyurea (1.5-fold). We also show that 50 micromol/l of resveratrol and 25 micromol/l of hydroxyurea induced variable but similar enhancements of fetal haemoglobin synthesis in cultured erythroid progenitors for the majority of the sickle cell patients studied. These inductions were linked to, but not correlated with, a variable decrease in erythroid burst-forming unit clone number. Taken together, these results show that resveratrol merits further investigations in sickle cell disease therapy.

Two mild cystic fibrosis-associated mutations result in severe cystic fibrosis when combined in cis and reveal a residue important for cystic fibrosis transmembrane conductance regulator processing and function.

The number of complex cystic fibrosis transmembrane conductance regulator (CFTR) genotypes identified as having double-mutant alleles with two mutations inherited in cis has been growing. We investigated the structure-function relationships of a severe cystic fibrosis (CF)-associated double mutant (R347H-D979A) to evaluate the contribution of each mild mutation to the phenotype. CFTR mutants expressed in HeLa cells were analyzed for protein biosynthesis and Cl(-) channel activity. Our data show that R347H is associated with mild defective Cl(-) channel activity and that the D979A defect leads to misprocessing. The mutant R347H-D979A combines both defects for a dramatic decrease in Cl(-) current. To decipher the molecular mechanism of this phenotype, single and double mutants with different charge combinations at residues 347 and 979 were constructed as charged residues were involved in this complex genotype. These studies revealed that residue 979, located in the third cytoplasmic loop, is critical for CFTR processing and Cl(-) channel activity highlighting the role of charged residues. These results have also important implications for CF, as they show that two mutations in cis can act in concert to alter dramatically CFTR function contributing to the wide phenotypic variability of CF disease.

Haemoglobin J-Biskra: a new mildly unstable alpha1 gene variant with a deletion of eight residues (alpha50-57, alpha51-58 or alpha52-59) including the distal histidine.

Single point mutation, which accounts for 92% of the 700 known variants, is the most frequent genetic defect responsible for abnormal haemoglobins. Small deletions (or insertions) involving from one to five residues are also observed, but in only approximately 5% of cases. The remaining variants produce fusion or extended haemoglobins. A deletion of eight residues, which included the distal histidine and its neighbours (alpha50-57, alpha51-58 or alpha52-59), was found in Hb J-Biskra. This new alpha-chain variant was mildly unstable in vitro only and there was no haematological or biochemical evidence of haemolysis in the affected family members. 24 nucleotides were missing in a region of the alpha1 gene showing an identical sequence of eight nucleotides at both ends. Several starting points could therefore lead to the same nucleotide and aminoacid remaining sequence. This deletion is the largest up to now reported in a haemoglobin molecule which is expressed at an almost normal level in the red blood cell. Comparison of the DNA sequences near to the deleted (or inserted) regions in the various haemoglobins carrying this type of abnormality almost always revealed the presence of a sequence that was hypothesized to slow down progression of the replication fork, and of repeats that may lead to possible secondary structures favouring slipped mispairing.

Critical role of human bisphosphoglycerate mutase Cys22 in the phosphatase activator-binding site.

The enzymatic activities catalyzed by bisphosphoglycerate mutase (BPGM, EC 5.4.2.4) have been shown to occur at a unique active site, with distinct binding sites for diphosphoglycerates and monophosphoglycerates. The physiological phosphatase activator (2-phosphoglycolate) binds to BPGM at an undetermined site. BPGM variants were constructed by site-directed mutagenesis of three amino acid residues in the active site to identify residues specifically involved in the binding of the monophosphoglycerates and 2-phosphoglycolate. Substitution of Cys22 by functionally conservative residues, Thr or Ser, caused a great decrease in 2-phosphoglycolate-stimulated phosphatase activity and in the Ka value of the activator, whereas it caused no change in other catalytic activities or in the Km values of 2,3-diphosphoglycerate (2,3-DPG) and glycerate 3-phosphate (3-PG, EC 1.1.1.12), indicating that Cys22 is specifically involved either directly or indirectly in 2-phosphoglycolate binding. Kinetic experiments showed that the Ka of the cofactor and the Km of 3-PG were affected by the substitution of Ser23 indicating that this residue is necessary for the fixation of both 3-PG and 2-phosphoglycolate. The R89K variant has previously been shown to have a modified Km value for monophosphoglycerates, however, its affinity for 2-phosphoglycolate is unaltered, suggesting that Arg89 is specifically involved in monophosphoglycerates binding. CD spectroscopic studies of substrates and cofactor binding showed that 2,3-DPG induced structural modifications of normal and mutated enzymes which could be due to protein phosphorylation. Addition of 2-phosphoglycolate to phosphorylated proteins with normal affinity for the cofactor produced spectra with the same characteristics as unphosphorylated species. In summary, monophosphoglycerates and 2-phosphoglycolate have partially distinct binding sites in human BPGM. The specific implication of the Cys22 residue in 2-phosphoglycolate binding is of great significance in the design of analogs of therapeutic benefit.

A recombinant bisphosphoglycerate mutase variant with acid phosphatase homology degrades 2,3-diphosphoglycerate.

To date no definite and undisputed treatment has been found for sickle cell anemia, which is characterized by polymerization of a deoxygenated hemoglobin mutant (HbS) giving rise to deformed erythrocytes and vasoocclusive complications. Since the erythrocyte glycerate 2,3-bisphosphate (2,3-DPG) has been shown to facilitate this polymerization, one therapeutic approach would be to decrease the intraerythrocytic level of 2,3-DPG by increasing the phosphatase activity of the bisphosphoglycerate mutase (BPGM; 3-phospho-D-glycerate 1,2-phosphomutase, EC 5.4.2.4). For this purpose, we have investigated the role of Gly-13, which is located in the active site sequence Arg9-His10-Gly11-Glu12-Gly13 in human BPGM. This sequence is similar to the Arg-His-Gly-Xaa-Arg* sequence of the distantly related acid phosphatases, which catalyze as BPGM similar phosphoryl transfers but to a greater extent. We hypothesized that the conserved Arg* residue in acid phosphatase sequences facilitates the phosphoryl transfer. Consequently, in human BPGM, we replaced by site-directed mutagenesis the corresponding amino acid residue Gly13 with an Arg or a Lys. In another experiment, we replaced Gly13 with Ser, the amino acid present at the corresponding position of the homologous yeast phosphoglycerate mutase (D-phosphoglycerate 2,3-phosphomutase, EC 5.4.2.1). Mutation of Gly13 to Ser did not modify the synthase activity, whereas the mutase and the phosphatase were 2-fold increased or decreased, respectively. However, replacing Gly13 with Arg enhanced phosphatase activity 28.6-fold, whereas synthase and mutase activities were 10-fold decreased. The presence of a Lys in position 13 gave rise to a smaller increase in phosphatase activity (6.5-fold) but an identical decrease in synthase and mutase activities. Taken together these results support the hypothesis that a positively charged amino acid residue in position 13, especially Arg, greatly activates the phosphoryl transfer to water. These results also provide elements for locating the conserved Arg* residue in the active site of acid phosphatases and facilitating the phosphoryl transfer. The implications for genetic therapy of sickle cell disease are discussed.

Amino acid residues involved in the catalytic site of human erythrocyte bisphosphoglycerate mutase. Functional consequences of substitutions of His10, His187 and Arg89.

Human bisphosphoglycerate mutase (GriP2 mutase) is a trifunctional enzyme which synthesizes and degrades GriP2 in red cells. Among the amino acid residues involved in its active site there are two conserved histidine residues, His10 which is phosphorylated during the catalytic process and His187 for which only speculative data have been made about the potential role during the reactions. Another amino acid residue, Arg89, had not been described as part of this active site but we have recently shown that a natural mutant Arg89-->Cys was highly thermolabile and showed severe perturbations of its enzymatic properties. To understand better the exact role of these residues, replacements of His10 by Gly (H10G) or Asp (H10D), His187 by Asn (H187N), Tyr (H187Y) or Asp (H187D) and Arg89 by Cys (R89C), Ser (R89S), Gly (R89G) or Lys (R89K) were performed by site-directed mutagenesis. The results obtained in this report show that replacement of the His10 residue completely abolished the enzymatic activities. Concerning the His187 residue, our results afford arguments that it plays an essential role in the three catalytic activities. Indeed all these activities are abolished in the two H187Y and H187D variants, whereas they are detectable though strongly diminished, for the H187N variant. In addition mutations at His187 could be distinguishable from those at His10 since the former resulted in a thermolabile enzyme, whereas no significant change in heat stability was observed for the latter. It is noteworthy that the H187N variant is protected against thermal instability by glycerate 2,3-bisphosphate (GriP2). Concerning the Arg89 mutants, R89C, R89S and R89G, the three variants showed characteristics identical to those found in the natural R89C mutant, i.e. loss of 99% of synthase activity, consistent decrease of mutase and 2-phosphoglycolate-stimulated phosphatase activities whereas the unstimulated phosphatase activity was normal. Moreover these mutants were unstable at 55 degrees C but GriP2 was able to protect them against thermal instability. In contrast, the R89K mutant was stable at 55 degrees C. Its synthase and unstimulated phosphatase activities were normal but its mutase and 2-phosphoglycolate-stimulated phosphatase activities were decreased. In addition, Km values for monophosphoglycerates were increased (3.2-fold) in the synthase but normal in mutase activities, whereas Km values for GriP2 were normal in mutase and phosphatase activities.(ABSTRACT TRUNCATED AT 400 WORDS)

Hemoglobin Saint Mandé [beta 102 (G4) Asn----Tyr]. Functional studies and structural modeling reveal an altered T state.

Oxygen equilibrium studies of purified hemoglobin Saint Mandé (Hb SM) [beta 102 (G4) Asn----Tyr] reveal a decreased oxygen affinity and cooperativity but to a lesser extent than found for Hb Kansas (beta 102 Thr). The low affinity of Hb SM depends on environmental conditions: eliminating chloride or raising the pH greatly elevated the ratio of p50 of Hb SM to that of Hb A. The alkaline Bohr effect is reduced by about 40%. The effects of anions (chloride, organophosphates) binding to deoxy Hb SM are also reduced. These data indicate that the functional properties of Hb SM are intermediary between Hb A and Hb Kansas. In addition, molecular graphics modeling of Hb SM in the oxy and deoxy structures indicate the possibility of a new hydrogen bond in the T state between beta(1)102 Tyr and alpha(2)42 Tyr. Stabilisation of the T state in this manner is a plausible explanation for several of the effects observed.

New results of hemoglobin variant structure determinations by fast atom bombardment mass spectrometry.

Fast atom bombardment mass spectrometry has already been used for the identification of mutations in abnormal human hemoglobin chains. This paper presents new results obtained with this technique. The methodology used here is compared with more conventional biochemical techniques and automated microsequencing. In every case, a well-chosen combination of peptide-high performance liquid chromatography, mass spectrometry, amino acid analysis, and sequence analysis led rapidly to the identification of the mutant. The high sensitivity of these techniques holds great promise for the analysis of molecular abnormalities in various genetic disorders presently detectable only by the application of a molecular biological approach.

Natural and artificial mutants of the human 2,3-bisphosphoglycerate as a tool for the evaluation of structure-function relationships.

2,3-bisphosphoglycerate mutase is a multifunctional enzyme which catalyses in red blood cells the synthesis and the degradation of 2,3-bisphosphoglycerate, the allosteric effector of hemoglobin. In order to study the structure-function relationships in BPGM, an expression vector was constructed which yielded an active protein, but with a modified electrophoretic mobility, due to a non-blocked N-terminal residue. Using site directed mutagenesis, mutants were produced with shortened chains. Results indicated the importance of residues 252-256 for the function. A natural deficient mutant with the substitution 89 Arg----Cys was described. Artificial mutant with the same substitution reproduced the same defect, as well as mutants Arg----Gly and Arg----Ser, indicating the key role of Arg 89 in the enzymatic mechanism.

Human bisphosphoglycerate mutase. Expression in Escherichia coli and use of site-directed mutagenesis in the evaluation of the role of the carboxyl-terminal region in the enzymatic mechanism.

Bisphosphoglycerate mutase is an erythrocyte-specific enzyme whose main function is to synthesize 2,3-diphosphoglycerate, the allosteric effector of hemoglobin. In addition to its main 2,3-diphosphoglycerate synthase activity, the enzyme displays phosphatase and mutase activities both involving 2,3-diphosphoglycerate in their reaction. The three activities have been demonstrated to be catalysed at a unique active site. To study the structure of such an active site we have developed a recombinant system producing mutants of human bisphosphoglycerate mutase in Escherichia coli, by site-directed mutagenesis. For this purpose the human bisphosphoglycerate mutase cDNA that we had previously cloned has been used to construct a procaryotic high level expression vector bearing the "tac" promoter. Human bisphosphoglycerate mutase produced in E. coli, a species which does not normally synthesize this enzyme, represented 8% of the total soluble bacterial protein and displayed the three catalytic activities (synthase, mutase, and phosphatase) characteristic of the enzyme. Since it has been suggested that the carboxyl-terminal region may be implicated in the catalytic activity of the enzyme, three variants deleted in this part of the protein were produced. Our results indicate that a minimal deletion of 7 amino acid residues in the carboxyl-terminal portion of the human bisphosphoglycerate mutase completely abolished the three catalytic activities of the enzyme. In contrast, the effects of the deletion of the last two lysine residues were limited to a 38% reduction in the synthase activity. These results show that the carboxyl-terminal amino acid residues are either directly or indirectly implicated in the three catalytic functions of the human bisphosphoglycerate mutase, and that the two terminal lysine residues are not essential for the major part of the enzymatic mechanism of the enzyme.

Hemoglobin Köln occurring in association with a beta zero thalassemia: hematologic and functional consequences.

Hemoglobin (Hb) Köln-beta zero thalassemia compound heterozygosity was discovered in a young Greek patient. This gave us the unique opportunity for studying the functional properties of this unstable high-oxygen affinity hemoglobin variant in red cells containing almost pure Hb Köln. The red cells of the proposita exhibit morphological alterations and hematologic indices corresponding to the presence of an unstable Hb and beta thalassemia. Globin chain synthesis confirmed the association with a beta zero thalassemia gene. Oxygen-binding curves for these cells were biphasic, indicating the presence of both heme-saturated and of approximately 20% of non-cooperative Hb Köln. The major component exhibits an increased oxygen affinity, reduced cooperativeness, and normal alkaline Bohr effect. The 35-year-old proposita is active, has not been splenectomized, and has not been transfused in several years.

Hb Bruxelles: alpha 2A beta (2)41 or 42(C7 or CD1)Phe deleted.

Hb Bruxelles is a new beta-globin variant producing severe congenital Heinz body anemia. It results from the deletion of one of the two adjacent phenylalanines, beta 41 or beta 42, presumably by frameshift mutagenesis. Its whole blood oxygen affinity is significantly lowered.

Hb J-Cordoba [alpha 2A beta 2(95)(FG2)Lys----Met]. A new Hb variant found in Argentina.

Hb J-Cordoba [alpha 2A beta 2(95)(FG2)Lys----Met], is one of the few hemoglobin variants discovered in Argentina. The structure and functional abnormalities are described. Hb J-Cordoba exhibits a slightly increased oxygen affinity, low cooperativity, and normal interaction with heterotropic cofactors.

Hb Tunis [alpha 2 beta 2 124 (H2)Pro----Ser], a new beta chain variant identified by HPLC.

During a routine hematological investigation of a child from Tunis, a silent hemoglobin variant was discovered by isoelectric-focusing. This variant was not detectable by conventional electrophoretic methods, had normal stability, expression, and oxygen affinity, and did not produce any clinical symptoms. This new variant beta 124(H2)Pro----Ser was named Hb Tunis.

Hemoglobin Brest [beta 127 (H5)Gln----Lys] a new unstable human hemoglobin variant located at the alpha 1 beta 1 interface with specific electrophoretic behavior.

Hb Brest [beta 127 (H5)Gln----Lys] is a new unstable variant located at the alpha 1 beta 1 interface at the same position as Hb Complutense [beta 127(H5)Gln----Glu]. In each of these, the substitution produces a distinct alteration in charge, yet both variants move with Hb A in conventional electrophoresis. This peculiar electrophoretical behavior may be due to the molecular position of the modified residue, which is deeply buried inside the tetramer.

Hemoglobin Saverne: a new variant with elongated beta chains: structural and functional properties.

A 26-year-old French woman born in Saverne (France) was found to have Heinz body hemolytic anemia. Isoelectrofocusing showed the presence of an abnormal band amounting to 35% of the total hemoglobin concentration, suggesting a beta variant. Structural analysis of the abnormal beta chain showed an elongated C-terminal segment. Histidine 143 is replaced by a proline and the C-terminal sequence is identical to the corresponding segment of Hb Cranston. This new variant, named Hb Saverne, has beta chains composed of 156 amino acid residues. Studies of its functional properties showed that Hb Saverne is an unstable, high affinity variant with low cooperativity.

Further characterization of Hb Henri Mondor or alpha 2 beta 2(26)(B8)Glu----Val.

A second case of Hb Henri Mondor is reported. The subject, homozygous for Hb Henri Mondor, is of Algerian origin. The electrophoretical behavior and structural characterization are given and discussed. Hb Henri Mondor, which is characterized by the replacement of the lysine residue in position beta 26, as is the case for Hb E, has normal functional properties and is normally expressed.

A new case of Hb Little Rock [beta 143(H21)His----Gln], a high affinity variant. Study during pregnancy.

A new case of Hb Little Rock [beta 143(H21)His----Gln] is described. This high affinity variant (P50 = 15 mm Hg in whole cells) has a nearly normal cooperativity. The abnormal beta chain is readily detectable using urea-Triton X-100 electrophoresis. The altered beta T-14 peptide was separated by high performance liquid chromatography. The proposita was followed during a pregnancy. Oxygen unloading was reduced, but normal oxygen loading was maintained in the fetus. There were neither placental abnormalities, nor intrauterine growth retardation.