鉴定 XIIIβ因子介导谷氨酰胺底物结合和激活肽切割的β-三明治结构残基。

Department of Chemistry, University of Louisville, Louisville, Kentucky, United States.

Department of Biochemistry and Molecular Genetics, University of Louisville School of Medicine, Louisville, Kentucky, United States.

Thromb Haemost. 2024 May;124(5):408-422. doi: 10.1055/a-2220-7544. Epub 2023 Dec 1.

BACKGROUND

Factor XIII (FXIII) forms covalent crosslinks across plasma and cellular substrates and has roles in hemostasis, wound healing, and bone metabolism. FXIII activity is implicated in venous thromboembolism (VTE) and is a target for developing pharmaceuticals, which requires understanding FXIII - substrate interactions. Previous studies proposed the β-sandwich domain of the FXIII A subunit (FXIII-A) exhibits substrate recognition sites.

MATERIAL AND METHODS

Recombinant FXIII-A proteins (WT, K156E, F157L, R158Q/E, R171Q, and R174E) were generated to identify FXIII-A residues mediating substrate recognition. Proteolytic (FXIII-A*) and non-proteolytic (FXIII-A°) forms were analyzed for activation and crosslinking activities toward physiological substrates using SDS-PAGE and MALDI-TOF MS.

RESULTS

All FXIII-A* variants displayed reduced crosslinking abilities compared to WT for Fbg αC (233 - 425), fibrin, and actin. FXIII-A* WT activity was greater than A°, suggesting the binding site is more exposed in FXIII-A*. With Fbg αC (233 - 425), FXIII-A* variants R158Q/E, R171Q, and R174E exhibited decreased activities approaching those of FXIII-A°. However, with a peptide substrate, FXIII-A* WT and variants showed similar crosslinking suggesting the recognition site is distant from the catalytic site. Surprisingly, FXIII-A R158E and R171Q displayed slower thrombin activation than WT, potentially due to loss of crucial H-bonding with neighboring activation peptide (AP) residues.

CONCLUSION

In conclusion, FXIII-A residues K156, F157, R158, R171, and R174 are part of a binding site for physiological substrates [fibrin (α and γ) and actin]. Moreover, R158 and R171 control AP cleavage during thrombin activation. These investigations provide new molecular details on FXIII - substrate interactions that control crosslinking abilities.

背景

因子 XIII (FXIII) 在血浆和细胞底物上形成共价交联，在止血、伤口愈合和骨代谢中发挥作用。FXIII 活性与静脉血栓栓塞症 (VTE) 有关，是开发药物的靶点，这需要了解 FXIII-底物相互作用。先前的研究提出 FXIII A 亚基 (FXIII-A) 的 β-夹层结构域表现出底物识别位点。

材料和方法

生成重组 FXIII-A 蛋白 (WT、K156E、F157L、R158Q/E、R171Q 和 R174E) 以鉴定介导底物识别的 FXIII-A 残基。使用 SDS-PAGE 和 MALDI-TOF MS 分析蛋白水解 (FXIII-A*) 和非蛋白水解 (FXIII-A°) 形式对生理底物的激活和交联活性。

结果

与 WT 相比，所有 FXIII-A* 变体的 Fbg αC (233-425)、纤维蛋白和肌动蛋白的交联能力均降低。FXIII-A* WT 活性大于 A°，表明结合位点在 FXIII-A中更暴露。对于 Fbg αC (233-425)，FXIII-A 变体 R158Q/E、R171Q 和 R174E 的活性降低，接近 FXIII-A°。然而，对于肽底物，FXIII-A* WT 和变体显示出相似的交联，表明识别位点远离催化位点。令人惊讶的是，FXIII-A R158E 和 R171Q 的凝血酶激活速度比 WT 慢，这可能是由于与邻近的激活肽 (AP) 残基失去了关键氢键。

结论

总之，FXIII-A 残基 K156、F157、R158、R171 和 R174 是生理底物 [纤维蛋白 (α 和 γ) 和肌动蛋白] 结合位点的一部分。此外，R158 和 R171 控制凝血酶激活过程中的 AP 切割。这些研究为控制交联能力的 FXIII-底物相互作用提供了新的分子细节。

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BACKGROUND

MATERIAL AND METHODS

RESULTS

CONCLUSION

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材料和方法

结果

结论

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