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Perturbation of the Intermolecular Contact Regions (Molecular Surface) of Hemoglobin S by Intramolecular, Low-O2-Affinity-Inducing Central Cavity Cross-Bridges (2000)

Malavalli, Ashok ; Manjula, Belur N. ; Friedman, Joel M. ; [et al.]

Springer

The protein journal 19 (2000), S. 255-267

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ISSN: 1573-4943

Keywords: Long-range effects ; site-specific perturbations ; central cavity cross-bridges ; asymmetric hybrids

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology

Notes: Abstract The general assumption among researchers on hemoglobin is that the intramolecular central cavity cross-bridging of Hb does not result in any generalized perturbations at the protein surface. A corollary of this is that central cavity cross-bridges are unlikely to influence the polymerization of deoxy HbS, since polymerization is a protein surface phenomenon involving the participation of multiple protein surface amino acid residues. In an attempt to evaluate this experimentally, we have introduced two low-O2-affinity-inducing central cavity cross-bridges into HbS, ββ-sebacyl [between the two Lys-82(β) residues] and αα-fumaryl [between the two Lys-99(α) residues], and investigated their influence on the polymerization of the deoxy protein. The O2 affinities of the cross-bridged HbS exhibited sensitivity toward the buffer ions and pH in a cross-link-specific fashion. The modulation of the O2 affinity of these cross-bridged HbS in the presence of allosteric effectors, DPG and L-35, is also very distinct, reflecting the differences in the conformational features these two cross-bridges induce within the central cavity at the respective effector-binding domains. In addition, the αα-fumaryl cross bridge inhibited the polymerization, reflecting the perturbation of the microenvironment of one or more intermolecular contact residues, protein surface residues, as a consequence of the central cavity cross-bridge. On the other hand, the ββ-sebacyl cross-bridge exerted a slight potentiating effect on the polymerization of HbS. This reflects the fact that the perturbations at the protein surface are limited and favor polymerization. The results presented demonstrate that the structural changes induced by the central cavity cross-bridges are very specific and not simply restricted to the sites of modification, but are propagated to distant sites/domains, both within and outside the central cavity. It is conceivable that other surface regions that are not involved in the polymerization could also experience similar structural/conformational consequences. These results should be taken into consideration in designing intramolecularly cross-bridged asymmetric hybrid HbS for mapping the contribution of the intermolecular contact residues in the cis and trans dimers of deoxy HbS during polymerization.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1007039111556

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Synthetic potential of Staphylococcus aureus V8-protease: An approach toward semisynthesis of covalent analogs of α-chain of hemoglobin S (1986)

Seetharam, Ramnath ; Acharya, A. Seetharama

New York, N.Y. : Wiley-Blackwell

Journal of Cellular Biochemistry 30 (1986), S. 87-99

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ISSN: 0730-2312

Keywords: semisynthesis ; V8-protease ; gelation ; Life and Medical Sciences ; Cell & Developmental Biology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: Enzyme-catalyzed reformation of peptide bonds in the noncovalent fragment systems of proteins has been emerging as a convenient procedure for the semisynthesis of covalent analogs of the respective proteins. Limited proteolysis of the α-chain of hemoglobin S with Staphylococcus aureus V8-protease converts the chain into a fragment-complementing system by hydrolyzing the peptide bond Glu(30)-Arg(31) of the chain. Therefore, it is conceivable that semisynthesis of covalent analogs of α-chain could be achieved if conditions for the V8-protease catalyzed formation of peptide bonds could be established. The synthetic potential of V8-protease has been now investigated by incubating V8-protease-derived fragments of α-chain, namely α1-30 and α31-47 with the enzyme at pH 6.0 in the presence of n-propanol as the organic cosolvent. RP high performance liquid chromatography analysis showed that a new chromatographically distinct component is generated on incubation, and this has been identified as α1-47 by amino acid analysis, redigestion with V8-protease (in the absence of n-propanol), and tryptic peptide mapping. Optimal conditions for the synthesis of α1-47 is at pH 6.0, 4°C, and 24 hr of incubation with 25% n-propanol as organic cosolvent. This stereospecific condensation of the fragments proceeded to a high level of about 50% in 24 hr. Further incubation up to 72 hr did not increase the yield of α1-47, suggesting that an equilibration of synthesis and hydrolysis reactions has been attained. The demonstration of the synthetic potential of V8-protease and the fact that α1-30 and α31-141 interact to form a native-like complex, opens up an approach for the semisynthesis of covalent analogs of α-chain of hemoglobin S.

Additional Material: 5 Ill.