Comparison of Carboxymethylation Patterns of Harbor Seal and Sperm Whale Myoglobins

The resolved 1H NMR resonances of the aromatic region in the 270-MHz NMR spectrum of sperm whale, horse, and pig metmyoglobin (metMb) have been assigned, including the observable H-2 and H-4 histidine resonances, the tryptophan H-2 resonances, and upfield-shifted resonances from one tyrosine residue. The use of different Mb species, carboxymethylation, and matching of pK values allows the assignment of the H-4 resonances, which agree in only three cases out of seven with scalar-correlated two-dimensional NMR spectroscopy assignments by others. The conversion to hydroxymyoglobin at high pH involves rearrangements throughout the molecule and is observed by many assigned residues. In sperm whale ferric cyanomyoglobin, nine H-2 and eight H-4 histidine resonances have been assigned, including the His-97 H-2 resonance and tyrosine resonances from residues 103 and 146. The hyperfine-shifted resonances from heme and near-heme protons observe a shift with a pK = 5.3 +/- 0.3 (probably due to deprotonation of His-97, pK = 5.6) and another shift at pK = 10.8 +/- 0.3. The spectrum of high-spin ferrous sperm whale deoxymyoglobin is very similar to that of metMb, which allows the assignment of seven surface histidine H-2 and H-4 resonances and also resonances from the two tryptophan residues and one tyrosine. In diamagnetic sperm whale (carbon monoxy)myoglobin (COMb), 10 His H-2 and 11 His H-4 resonances are observed, and 8 H-2 and 9 H-4 resonances are assigned, including His-64 H-4, the distal histidine. This important resonance is not observed in sperm whale oxymyoglobin, which in general shows very similar titration curves to COMb. Histidine-36 shows unusual titration behavior in the paramagnetic derivatives but normal behavior in the diamagnetic derivatives, which is discussed in the accompanying paper [Bradbury, J. H., & Carver, J. A. (1984) Biochemistry (following paper in this issue)].

Section: Methodsmentioning

confidence: 99%

Assignment of proton NMR resonances of histidine and other aromatic residues in met-, cyano-, oxy-, and (carbon monoxy)myoglobins

Carver¹,

Bradbury²

1984

“…-Acid glycoprotein (0.2 g) was treated with bromoacetate at pH 7.0 for a period of 8 days according to the method of Gurd (1972), Nigen and Gurd (1973), and Castellino and Hill (1970). Appropriate aliquots of the reaction mixture were removed at various intervals, separated from the excess reagents by gel filtration, lyophilized, and hydrolyzed with constant boiling HC1 as indicated above.…”

Section: Methodsmentioning

confidence: 99%

Topography of human plasma α1-acid glycoprotein

Schmid¹,

Chen²,

Occhino³

et al. 1976

Human plasma alpha1-acid glycoprotein, whose linear amino acid sequence has recently been elucidated (Schmid et al. (1973), Biochemistry 12, 2711), was further investigated with regard to its topography. Nitration of this protein and subsequent elucidation of the structures of the peptides containing modified tyrosine indicated that residues 27, 37, 78, 115, 127, and 157 are free, 50 and 91 are in an intermediate state, and 65, 74, 110, and 142 are buried. CD measurements between pH 10 and 12 demonstrated that the buried tyrosines are strongly hydrogen bonded and are probably responsible to a considerable extent for the stability of this protein. Of the three tryptophans of this protein, residue 122 proved to be partially reactive with Koshland reagent while the other two (25 and 160) were found to be unreactive. The state of the two disulfide bonds, established by differential reduction and alkylation with specific reagents, was shown to be of an intermediate type. Using carboxymethylation with bromoacetate at pH 7.0 for 8 days, the three histidines (97, 100, and 171) and methionine 111 could be shown to be in intermediate states. All lysines were treated with trinitrobenzenesulfonate and thus were assumed to be free. Of the 40 carboxylic groups, which were amidated with glycine methyl ester, 32 including the 14 sialyl residues were found to be free, six in an intermediate and the remaining two in a buried state. The present study describes the states of almost half of the amino acid residues of alpha1-acid glycoprotein, a knowledge important for the construction of a preliminary three-dimensional model of this conjugated protein.

“…In fact, the proximal His-93 resonance has recently been observed in deoxy-Mb shifted far downfield (LaMar et al, 1977). Second, two of the histidine residues, His-24 and -82, are buried in the X-ray structure (Watson, 1970;Takano, 1977a) and these residues cannot be carboxymethylated (Nigen & Gurd, 1973); consequently their resonances might not be observed due to line broadening as a result of their correlation times being similar to the overall protein correlation time.…”

mentioning

confidence: 99%

NMR titration curves of histidine ring protons. 11. Near-heme histidine residues of deoxy- and oxymyoglobins

Ohms¹,

Hagenmaier²,

Hayes³

et al. 1979

Proton NMR titration curves of the histidine Cepsilon-H resonances of the deoxy and oxy forms of human, horse, and sperm whale myoglobins (Mb) were determined and compared with the results for the met and azide forms. One extra titrating resonance (H-8) was observed for each deoxy-Mb compared with the corresponding met-Mb, and a further extra resonance (H-9) was observed for the oxy-Mb form. These resonances correspond to the two additional resonances previously described for azide-Mb [Hayes, M., Hagenmaier, H., & Cohen, J. S. (1975) J. Biol. Chem. 250, 7461--7472]. This new evidence prompts us to reassign these resonances to the near-heme histidine residues.