Production of unmodified human adult hemoglobin in Escherichia coli.

Shen, Tong-Jian; Ho, Nancy T.; Simplăceanu, Virgil; Zou, Ming; Green, Brian N.; Tam, Ming F.; Ho, Chien

doi:10.1073/pnas.90.17.8108

Cited by 160 publications

(241 citation statements)

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“…Cells were grown in DM-4 medium (25) at 30°C in a 20-liter fermenter (B. Braun Biotech International, model Biostat C). The induction and purification of rHb were carried out as described previously (26). Hb A and Hb S from whole blood were purified according to established methods in our laboratory (27,28).…”

Section: Methodsmentioning

confidence: 99%

Sickle Cell Hemoglobin with Mutation at αHis-50 Has Improved Solubility

Tam

Simplăceanu

et al. 2015

Journal of Biological Chemistry

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Section: Methodsmentioning

confidence: 99%

Sickle Cell Hemoglobin with Mutation at αHis-50 Has Improved Solubility

Tam

Simplăceanu

et al. 2015

Journal of Biological Chemistry

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“…Plasmids were transfected into E. coli (JM 109) (Promega Co.), bacteria were grown at 30°C, and soluble ␤-globin chain variants were isolated as described (5,8). Expression and purification of ␤-globin variants were basically as described previously (5,8). However, cationexchange chromatography on a Source 15 S column (Amersham Pharmacia Biotech) instead of Superose 12 gel filtration was used for purification of the ␤ chain variants.…”

Section: Expression Of Soluble Recombinant Human ␤-Globin Chain Variantsmentioning

confidence: 99%

“…␤112 Ser, ␤112 Val, ␤112 Thr, and ␤112 Asp) were constructed and expressed using the pHE2␤ plasmid vector that contains cDNAs coding for each ␤ chain variant and methionine aminopeptidase which was originally developed to express ␣ and ␤ chains at the same time (8,9). The basic strategy for generation of these variants by site-specific mutagenesis of the normal ␤ chain involves recombination/polymerase chain reaction as described previously (10).…”

Section: Expression Of Soluble Recombinant Human ␤-Globin Chain Variantsmentioning

confidence: 99%

“…Clones were subjected to DNA sequence analysis of the entire ␤-globin cDNA region using site-specific primers and fluorescently tagged terminators in a cycle sequencing reaction in which extension products were analyzed on an automated DNA sequencer. Plasmids were transfected into E. coli (JM 109) (Promega Co.), bacteria were grown at 30°C, and soluble ␤-globin chain variants were isolated as described (5,8). Expression and purification of ␤-globin variants were basically as described previously (5,8).…”

Section: Expression Of Soluble Recombinant Human ␤-Globin Chain Variantsmentioning

confidence: 99%

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Role of β112 Cys (G14) in Homo- (β4) and Hetero- (α2β2) Tetramer Hemoglobin Formation

Yamaguchi¹,

Pang²,

Reddy³

et al. 1998

Journal of Biological Chemistry

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In order to assess the role of ␤112 Cys in homo-and hetero-tetrameric hemoglobin formation, we expressed four ␤112 variants (␤ 112Cys3 Asp , ␤ 112Cys3 Ser , ␤ 112Cys3 Thr , and ␤ 112Cys3 Val ) and studied assembly with ␣ chains in vitro. ␤112 Cys is normally present at ␤ 1 ␤ 2 and ␣ 1 ␤ 1 interaction sites in homo-(␤ 4 ) and hetero-tetramers (␣ 2 ␤ 2 ). ␤ 4 formation in vitro was influenced by the amino acid at ␤112. ␤112 Asp completely inhibited formation of homo-tetramers, whereas ␤112 Ser showed only slight inhibition. In contrast, ␤112 Thr or Val enhanced homotetramer formation compared with ␤ A chains. Association constants for homo-tetramer formation increased in the order of ␤ 112Cys3 Ser , ␤ A , ␤ 112Cys3 Thr , and ␤ 112Cys3 Val , whereas the value for ␤ 112Cys3 Asp was zero under the same conditions. These ␤112 changes also affected in vitro ␣ 2 ␤ 2 hetero-tetramer formation. Order of ␣ 2 ␤ 2 formation under limiting ␣-globin chain conditions showed Hb ␤C112S > Hb A > Hb S ‫؍‬ Hb ␤C112T ‫؍‬ Hb ␤C112V > > > Hb ␤C112D. Hb ␤112D can form tetrameric hemoglobin, but this ␤112 change promotes dissociation into ␣ and ␤ chains instead of ␣␤ dimer formation upon dilution. These results indicate that amino acids at ␣ 1 ␤ 1 interaction sites such as ␤112 on the G helix play a key role in stable ␣␤ dimer formation. Our findings suggest, in addition to electrostatic interaction between ␣ and ␤ chains, that dissociation of ␤ 4 homo-tetramers to monomers and hydrophobic interactions of the ␤112 amino acid with ␣ chains governs stable ␣ 1 ␤ 1 interactions, which then results in formation of functional hemoglobin tetramers. Information gained from these studies should increase our understanding of the mechanism of assembly of multi-subunit proteins.Equimolar amounts of ␣-and ␤-globin chains of human hemoglobin self assemble to form ␣ 2 ␤ 2 tetramer. In addition, isolated ␤ chains also assemble to form ␤ 4 homo-tetramers (1). Extensive previous studies using naturally occurring variants and our recent studies using recombinant ␤ chain variants showed that affinity between ␣ and ␤ chains is promoted by negatively charged ␤ chains and is independent of charge location on the surface except at the ␣ 1 ␤ 1 interaction site (2-5). Our previous studies showed that affinity is promoted by negatively charged ␤ chains up to a maximum of two additional net negative charges (5). In addition, we showed that ␤112 Cys located at an ␣ 1 ␤ 1 interaction site on the G helix is critical for facilitating formation of stable ␣␤ dimers which then form functional hemoglobin tetramers. We also demonstrated that ␤ 112Cys3 Asp inhibits formation of stable ␣ 1 ␤ 1 and ␤ 1 ␤ 2 interactions in ␣ 2 ␤ 2 and ␤ 4 tetramers, respectively (5).X-ray diffraction analysis of ␤ 4 and ␣ 2 ␤ 2 showed that ␤112 Cys on the G helix is involved in ␤ 1 ␤ 2 and ␣ 1 ␤ 1 subunit interactions, respectively, and that there is similarity between the quaternary structure of carbonmonoxy ␤ 4 and carbonmonoxy ␣ 2 ␤ 2 tetramers (6). The detailed role of ␣ 1 ␤ 1 interaction s...

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“…It has been reported that the assembly of myosin heavy and light chains occurs in E. coli, but the protein has not been fully characterized (McNally et al, 1988). The two subunits of hemoglobin have been coexpressed in E. coli and shown to renature into a functional tetrameric complex (Hoffman et al, 1990;Shen et al, 1993). The overexpression of the chaperones in E. coli cells expressing human procollagenase results in an increase in the accumulation and solubility of this protein in the cytoplasm, but it is not clear if the resulting protein is functional (Lee and Olins, 1992).…”

mentioning

confidence: 99%

Assembly of functional skeletal muscle troponin complex in Escherichia coli

Malnic

Reinach

1994

European Journal of Biochemistry

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The production of multi-subunit proteins of eukaryotic origin in Escherichia coli usually relies on the different subunits being expressed individually and the protein being reassembled in vitro. Here we describe the construction and characterization of plasmids capable of coexpressing the three subunits of chicken skeletal muscle troponin complex in E. coli. We demonstrate that the troponin subunits assembled in the cytoplasm of E. coli cell are fully functional. The troponin complex was purified to homogeneity in high yields. When reconstituted into actin filaments, the complex assembled in vivo was capable of regulating the myosin ATPase with a calcium dependence that was identical to the complex reconstituted in vitro. These results demonstrate that the coexpression of the subunits of a protein complex can prevent the accumulation of denatured proteins in inclusion granules.

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Production of unmodified human adult hemoglobin in Escherichia coli.

Cited by 160 publications

References 36 publications

Sickle Cell Hemoglobin with Mutation at αHis-50 Has Improved Solubility

Sickle Cell Hemoglobin with Mutation at αHis-50 Has Improved Solubility

Role of β112 Cys (G14) in Homo- (β4) and Hetero- (α2β2) Tetramer Hemoglobin Formation

Assembly of functional skeletal muscle troponin complex in Escherichia coli

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