Hb Monza: A novel extensive HBB duplication with preserved α-β subunit interaction and unstable hemoglobin phenotype.

IF 12.8 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Med Pub Date : 2025-04-11 Epub Date: 2024-12-18 DOI:10.1016/j.medj.2024.11.007

Ivan Civettini, Arianna Zappaterra, Paola Corti, Amedeo Messina, Andrea Aroldi, Andrea Biondi, Fabrizio Cavalca, Valentina Crippa, Francesca Crosti, Giulia Maria Ferrari, Federica Malighetti, Luca Mologni, Alberto Piperno, Daniele Ramazzotti, Chiara Scollo, Alfonso Zambon, Fabio Rossi, Carlo Gambacorti-Passerini

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引用次数: 0

Abstract

Background: Unstable hemoglobins are caused by single amino acid substitutions in the HBB gene, often affecting key histidine residues, leading to protein destabilization and hemolytic crises. In contrast, long HBB variants, exceeding 20 bp, are rare and associated with a β-thalassemia phenotype due to disrupted α-β chain interactions. We describe a family wherein four of six members carry a novel 23-amino-acid in-frame duplication of HBB (c.176_244dup), named hemoglobin (Hb) Monza. Despite its length, this duplication manifests as an unstable hemoglobin variant rather than a β-thalassemia phenotype.

Methods: A static 3D model of the Hb Monza β chain was generated using AlphaFold and SWISS-MODEL. Molecular dynamics (MD) simulations were performed with the Generalized Born implicit solvent model. After energy minimization and heating to 311 K (38°C), a 40 ns production run was conducted.

Findings: 3D modeling of Hb Monza revealed minimal structural changes in the Hb β chain, particularly in the key histidine residues and their interaction with the iron atom. Additionally, the static 3D model showed a preserved α-β interaction, explaining the absence of a β-thalassemia clinical phenotype. MD simulations under thermal stress revealed a notable increase in root-mean-square deviation compared to the wild-type β subunit, along with a loss of contacts with the heme, explaining the hemolytic crises during febrile episodes.

Conclusion: Despite the long duplication in HBB, Hb Monza retains functional α-β interaction while demonstrating instability under stressful conditions. This unique variant presents with an unstable Hb phenotype rather than a β-thalassemia phenotype.

Funding: No financial funding was received.

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Hb Monza：一种新型的广泛 HBB 重复，具有保留的 α-β 亚基相互作用和不稳定的血红蛋白表型。

背景：不稳定的血红蛋白是由HBB基因中的单个氨基酸取代引起的，通常会影响关键的组氨酸残基，导致蛋白质不稳定和溶血危机。相比之下，超过20 bp的长HBB变异是罕见的，并且由于α-β链相互作用的破坏而与β-地中海贫血表型相关。我们描述了一个家族，其中6个成员中有4个携带一种新的23个氨基酸的帧内重复HBB (c.176_244dup)，命名为血红蛋白（Hb） Monza。尽管它的长度，这种重复表现为不稳定的血红蛋白变异，而不是β-地中海贫血表型。方法：利用AlphaFold和SWISS-MODEL软件建立Hb Monza β链的静态三维模型。采用广义Born隐式溶剂模型进行了分子动力学（MD）模拟。在能量最小化并加热到311 K（38°C）后，进行了40 ns的生产运行。结果：Hb Monza的3D建模显示Hb β链的微小结构变化，特别是关键组氨酸残基及其与铁原子的相互作用。此外，静态3D模型显示保留α-β相互作用，解释了β-地中海贫血临床表型的缺失。热应激下的MD模拟显示，与野生型β亚基相比，根均方差显著增加，同时与血红素失去接触，这解释了发热期溶血危机。结论：尽管HBB中存在长重复，但Hb Monza在应激条件下表现出不稳定性，同时保留了功能性α-β相互作用。这种独特的变异表现为不稳定的Hb表型，而不是β-地中海贫血表型。经费：未收到财政经费。

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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来源期刊

Med MEDICINE, RESEARCH & EXPERIMENTAL-

CiteScore

17.70

自引率

0.60%

发文量

102

期刊介绍： Med is a flagship medical journal published monthly by Cell Press, the global publisher of trusted and authoritative science journals including Cell, Cancer Cell, and Cell Reports Medicine. Our mission is to advance clinical research and practice by providing a communication forum for the publication of clinical trial results, innovative observations from longitudinal cohorts, and pioneering discoveries about disease mechanisms. The journal also encourages thought-leadership discussions among biomedical researchers, physicians, and other health scientists and stakeholders. Our goal is to improve health worldwide sustainably and ethically. Med publishes rigorously vetted original research and cutting-edge review and perspective articles on critical health issues globally and regionally. Our research section covers clinical case reports, first-in-human studies, large-scale clinical trials, population-based studies, as well as translational research work with the potential to change the course of medical research and improve clinical practice.