Interaction of Normal and Sickle Hemoglobins for Sodium Dodecylsulphate and Hydrogen Peroxide at pH 5.0 and 7.2.

ISRN Hematology Pub Date : 2013-10-10 eCollection Date: 2013-01-01 DOI:10.1155/2013/629640
Fortunatus C Ezebuo, Sabinus Oscar O Eze, Colin B Lukong, Ferdinand C Chilaka
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引用次数: 1

Abstract

Clinical manifestations of malaria primarily result from proliferation of the parasite within the hosts' erythrocytes. The malaria parasite digests hemoglobin within its digestive vacuole through a sequential metabolic process involving multiple proteases. The activities of these proteases could lead to the production of ROS which could lead to the death of the parasites due to the destruction of their membrane. The action of SDS on hemoglobins can be likened to the way malarial proteases destabilizes host hemoglobin. Hence, the study was designed to determine the binding parameters of SDS and H2O2 for normal, sickle trait carrier and sickle hemoglobins at pH 5.0 and 7.2 using UV-VIS Titration Spectrophotometry. Hb-SDS interactions were significantly different at pH 5.0 but were not at pH 7.2. Also, Hb-H2O2 interactions were statistically different at pH 5.0 and 7.2. The interactions suggest that HbA and HbS are easily destabilized than HbAS and that HbAS has more affinity for H2O2. These suggest a production of more ferryl intermediates or hydroxyl radicals. All these interactions may hinder the development of the malaria parasite at the intraerythrocytic stage and could likely account for a significant proportion of the mechanism that favours the resistance to malaria by individuals with HbAS.

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十二烷基硫酸钠和过氧化氢在pH 5.0和7.2下正常血红蛋白和镰状血红蛋白的相互作用。
疟疾的临床表现主要是由疟原虫在宿主红细胞内增殖引起的。疟原虫通过一系列涉及多种蛋白酶的连续代谢过程在其消化液泡内消化血红蛋白。这些蛋白酶的活性可导致活性氧的产生,活性氧可导致寄生虫因其膜被破坏而死亡。SDS对血红蛋白的作用可以比作疟疾蛋白酶破坏宿主血红蛋白稳定的方式。因此,本研究采用UV-VIS滴定分光光度法测定正常、镰状性状载体和镰状血红蛋白在pH 5.0和7.2条件下SDS与H2O2的结合参数。pH值为5.0时Hb-SDS相互作用差异显著,pH值为7.2时则无差异。pH 5.0和7.2时Hb-H2O2相互作用差异有统计学意义。相互作用表明HbA和HbS比HbAS更容易失稳,HbAS对H2O2更有亲和力。这表明产生了更多的铁基中间体或羟基自由基。所有这些相互作用都可能在红细胞内阶段阻碍疟疾寄生虫的发育,并可能在HbAS个体对疟疾产生抗性的机制中占很大比例。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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