Tony Yeung, Yi Zhang, Bridget Kennedy, Cara Walsh, Tanzy Love, Daniel Xia, Anindro Bhattacharya, Rahul G Krishnan, David Head, Richard Burack
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Abstract
While increased DNA damage is a well-described feature of myelodysplastic syndrome (MDS) and acute myeloid leukemia (AML), it is unclear whether all lineages and all regions of the marrow are homogeneously affected. In this study, we performed immunohistochemistry on formalin-fixed, paraffin-embedded whole-section bone marrow biopsies using a well-established antibody to detect pH2A.X (phosphorylated histone variant H2A.X) that recognizes DNA double-strand breaks. Focusing on TP53 -mutated and complex karyotype MDS/AML, we find a greater pH2A.X+ DNA damage burden compared to TP53 wild-type neoplastic cases and non-neoplastic controls. To understand how double-strand breaks vary between lineages and spatially in TP53- mutated specimens, we applied a low-multiplex immunofluorescence staining and spatial analysis protocol to visualize pH2A.X+ cells with p53 protein staining and lineage markers. pH2A.X marked predominantly mid- to late-stage erythroids, whereas early erythroids and CD34+ blasts were relatively spared. In a prototypical example, these pH2A.X+ erythroids were organized locally as distinct colonies, and each colony displayed pH2A.X+ puncta at a synchronous level. This highly coordinated immunophenotypic expression was also seen for p53 protein staining and among presumed early myeloid colonies. Neighborhood clustering analysis showed distinct marrow regions differentially enriched in pH2A.X+/p53+ erythroid or myeloid colonies, indicating spatial heterogeneity of DNA-damage response and p53 protein expression. The lineage and architectural context within which DNA damage phenotype and oncogenic protein are expressed is relevant to current therapeutic developments that leverage macrophage phagocytosis to remove leukemic cells in part due to irreparable DNA damage. © 2024 The Pathological Society of Great Britain and Ireland.
多重成像技术揭示了 TP53 基因突变骨髓增生异常肿瘤中空间分辨的 DNA 损伤反应邻域。
DNA损伤增加是骨髓增生异常综合征(MDS)和急性髓性白血病(AML)的一个特征,但目前还不清楚是否所有系和骨髓的所有区域都会受到同质性影响。在这项研究中,我们使用一种成熟的抗体对福尔马林固定、石蜡包埋的全切片骨髓活检组织进行了免疫组化,以检测能识别DNA双链断裂的pH2A.X(磷酸化组蛋白变体H2A.X)。我们重点研究了TP53突变和复杂核型的MDS/AML,发现与TP53野生型肿瘤病例和非肿瘤对照组相比,pH2A.X+ DNA损伤负荷更大。为了了解双链断裂在TP53突变标本中是如何在不同系和不同空间发生变化的,我们采用了一种低多重免疫荧光染色和空间分析方案,通过p53蛋白染色和系标记来观察pH2A.X+细胞。在一个典型的例子中,这些 pH2A.X+ 红细胞在局部组织成不同的集落,每个集落同步显示 pH2A.X+ 点。这种高度协调的免疫表型表达也可见于 p53 蛋白染色和推测的早期髓细胞集落中。邻域聚类分析显示,pH2A.X+/p53+红细胞或髓样集落在不同的骨髓区域有不同程度的富集,这表明DNA损伤反应和p53蛋白表达在空间上存在异质性。DNA损伤表型和致癌蛋白表达的系谱和结构背景与当前的治疗发展相关,这些治疗利用巨噬细胞的吞噬作用清除部分因不可修复的DNA损伤而导致的白血病细胞。© 2024 大不列颠及爱尔兰病理学会。
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