![Distribution of molecular size Hb cross-links and polymers after H2O2 treatment. (A) Silver-stained SDS-PAGE analysis of nonoxidized and H2O2-treated Hb/Hb-Hp (5 μg Hb per lane). Hb was mixed with different concentrations of Hp (phenotype 1-1) to get Hp/Hb ratios between 2:1 and 0.25:1. The concentration of Hb was equal in all samples (250 μM in heme). Oxidation was performed with a 10-fold excess concentration of H2O2 over heme where indicated (H2O2+) for 60 minutes. (B) Western blot analysis of nonoxidized and H2O2-treated Hb and Hb-Hp with an anti–α-globin–specific monoclonal antibody (α-globin) and with a polyclonal anti-Hp antibody (Hp). Nonoxidized αα DBBF cross-linked Hb was used as a control to prove α-globin specificity of the anti-Hb antibody. With αα cross-linked Hb there appears a strong signal at approximately 30 kDa that represents αα dimers, but no signal can be observed at 15 kDa where fully dissociated α-globin chains (monomer) appear in HbA0. (C) In contrast to HbA0, α-α cross-linked Hb that does not bind to Hp is not protected from polymerization when exposed to H2O2 (left panel: [1] marker, [2] HbA0 + H2O2, [3] HbA0-Hp + H2O2; right panel: [1] α-α Hb + H2O2 [2/3] α-α Hb-Hp + H2O2 [2 independent reactions]). (D) MALDI-MS analysis of H2O2-treated Hb and Hb-Hp. As observed in the α-globin Western blot, α-chains at m/z approximately 15 290 disappear during H2O2 treatment of Hb but do not disappear if Hb is oxidized in the presence of equimolar concentrations of Hp.](https://ash.silverchair-cdn.com/ash/content_public/journal/blood/113/11/10.1182_blood-2008-08-174466/5/zh80130932720004.jpeg?Expires=1720796588&Signature=eWBsYEFW0B5D0h8AKuH39M7RPmKVkuj~bgacDhY3BsRdnI5LizcBLK3VbOQxrd7J2lGW7jWPXy4GND0zdKCS7Ym0AfjayNjXg5xTgDWjXChFZb47HFtDH7-sSafVd3u6so3EjKJQLPGfM9FFEVBbZvmeou5OH42he3PGMqJS5xtaZPUNDSbe94WfO2nO52aqxMMR6xWoMEt6PAkmZGiqeer8pLnijIv91a7ewJYF~TbxN5XpqZqq5oxpbXjJtRLcSAnRorgzP9~2-zRrDBqy1nnEsaIkOhDBjggQEs1yy5fAs61RJw9gtYNnoS8W17OT1X-YQXKtnZfgOXR0gvvw3A__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
Distribution of molecular size Hb cross-links and polymers after H2O2 treatment. (A) Silver-stained SDS-PAGE analysis of nonoxidized and H2O2-treated Hb/Hb-Hp (5 μg Hb per lane). Hb was mixed with different concentrations of Hp (phenotype 1-1) to get Hp/Hb ratios between 2:1 and 0.25:1. The concentration of Hb was equal in all samples (250 μM in heme). Oxidation was performed with a 10-fold excess concentration of H2O2 over heme where indicated (H2O2+) for 60 minutes. (B) Western blot analysis of nonoxidized and H2O2-treated Hb and Hb-Hp with an anti–α-globin–specific monoclonal antibody (α-globin) and with a polyclonal anti-Hp antibody (Hp). Nonoxidized αα DBBF cross-linked Hb was used as a control to prove α-globin specificity of the anti-Hb antibody. With αα cross-linked Hb there appears a strong signal at approximately 30 kDa that represents αα dimers, but no signal can be observed at 15 kDa where fully dissociated α-globin chains (monomer) appear in HbA0. (C) In contrast to HbA0, α-α cross-linked Hb that does not bind to Hp is not protected from polymerization when exposed to H2O2 (left panel: [1] marker, [2] HbA0 + H2O2, [3] HbA0-Hp + H2O2; right panel: [1] α-α Hb + H2O2 [2/3] α-α Hb-Hp + H2O2 [2 independent reactions]). (D) MALDI-MS analysis of H2O2-treated Hb and Hb-Hp. As observed in the α-globin Western blot, α-chains at m/z approximately 15 290 disappear during H2O2 treatment of Hb but do not disappear if Hb is oxidized in the presence of equimolar concentrations of Hp.
