A hemoglobin expression system in Escherichia coli is described. In order to produce authentic human hemoglobin, we need to co-express both methionine aminopeptidase and globin genes under the control of a strong promoter. We have constructed three plasmids, pHE2, pHE4 and pHE7, for the expression of human normal adult hemoglobin and a plasmid, pHE9, for the expression of human fetal hemoglobin, in high yields. The globin genes can be derived from either synthetic genes or human globin cDNAs. The extra amino-terminal methionine residues of the expressed globins can be removed by the co-expressed methionine aminopeptidase. The heme is inserted correctly into the expressed alpha-globin from our expression plasmids. A fraction (approximately 25%) of the heme is not inserted correctly into the expressed beta- or gamma-globin. However, the incorrectly inserted hemes can be converted into the correct conformation by carrying out a simple oxidation-reduction process on the purified hemoglobin molecule. We have investigated the functional properties of the expressed hemoglobins by measuring their oxygen-binding properties and their structural features by obtaining their 1H-NMR spectra. Our results show that authentic human normal adult and fetal hemoglobins can be produced from our expression plasmids in E. coli and in high yields. Our expression system allows us to design and to produce any recombinant hemoglobins needed for our research on the structure-function relationship in hemoglobin.
We have applied site-directed mutagenesis to our Escherichia coli hemoglobin expression plasmid and constructed five recombinant mutant hemoglobins (r Hbs): r Hb(alpha20His-->Gln or alpha:H20Q); r Hb(alpha:H50Q); r Hb(alpha:H72Q); r Hb(alpha:H89Q); and r Hb(alpha:H112Q). We have constructed these r Hbs to help us assess the contribution of the surface histidyl residues in the alpha-chain to the alkaline Bohr effect of human normal adult hemoglobin (Hb A). In our laboratory, we have monitored the variation of proton nuclear magnetic resonances arising from the C2 protons of the histidyl residues of Hb A as a function of pH and buffer conditions. Several of these resonances have been assigned to the individual histidyl residues on the surface of the hemoglobin molecule using naturally occurring mutant hemoglobins and chemically modified hemoglobins. In the present work, we have identified the C2 proton resonances of five surface histidyl residues of the alpha-chain, alpha20, alpha50, alpha72, alpha89, and alpha112, in both the carbonmonoxy and deoxy forms, by comparing the proton nuclear magnetic resonance spectra of Hb A with those of the r Hbs. For the assignment of the C2 proton resonances of alpha20His and alpha112His, we have used combinations of mutations to compensate for the spectral perturbations resulting from the single mutations, which obscure the resonance assignment. On the basis of the new findings, in solvent containing 0.1 M chloride, the overall contributions from surface histidyl residues of both the alpha- and beta-chain and from other previously identified alkaline Bohr groups account for approximately 75% of the observed Bohr effect at pH 7.3 (the maximum Bohr effect under the prescribed solvent conditions). Our results show that some histidyl residues contribute to the Bohr effect and some oppose the net Bohr effect. In some cases, the addition of anions can diminish or reverse the contributions of specific histidyl residues to the overall Bohr effect. Thus, the Bohr effect, a heterotropic effect, depends on the intricate arrangement and interactions of all hydrogen and anion binding sites in the hemoglobin molecule. It is an excellent example of global electrostatic effects in proteins.
Abnormal human hemoglobins (Hbs) with amino acid substitutions in the al132 interface have very high oxygen affinity and greatly reduced cooperativity in O2 binding compared to normal human Hb. In such abnormal Hbs with mutations at position 1899, the intersubunit hydrogen bonds between Asp-j399 and Tyr-a42 and between Asp-1399 and Asn-a97 are broken, thus destabi the deoxyquaternary structure of these Hbs. A molecular dynamics method has been used to design compensatory amino acid substitutions in these Hbs that can restore their allosteric properties. We have designed a compensatory mutation in a naturally occurring mutant Hb, Hb Kempsey (Asp-I399--Asn), and have produced it using ourEscherichia coli expression plasmid pHE2. We MATERIALS AND METHODSPlasmids, Strains, and Media. The Hb A expression plasmid pHE2 (15) containing synthetic a-and (-globin genes and the E. coli methionine aminopeptidase gene was used to produce mutant Hbs. Phagemid pTZ18U and E. coli JM109 were purchased from Bio-Rad and Promega, respectively. E. coli cells were grown in 2x YT medium (18) supplemented Abbreviations: Hb, hemoglobin; Hb A, human adult Hb; r, recombinant; MD, molecular dynamics; plo, partial pressure at 50%o oxygenation; nmax, Hill coefficient; DSS, 2,2-dimethyl-2-silapentane-5-sulfonate; IHP, inositol hexaphosphate.§To whom reprint requests should be addressed. 11547The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
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