The non-conserved integrin cytoplasmic region determines integrin subtype-specific characteristics by modulating talin1 binding kinetics.

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2025-10-06 DOI:10.1016/j.jbc.2025.110793

Naoyuki Kondo,Kenji Fukui,Yuji Kamioka,Yoshihiro Ueda,Yoshiki Ikeda,Taiju Matsushita,Ryo Yazaki,Tatsuo Kinashi

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引用次数: 0

Abstract

Talin governs integrin adhesion by binding to the cytoplasmic tail (CT) of integrin β subunits, but the effects of integrin subtype-specific variations on talin interactions remain unclear. Here, we identify a non-conserved region within the integrin-CT, termed the WN linker, that modulates talin1 binding kinetics and integrin adhesiveness. Single-molecule imaging in live lymphocytes revealed that talin1 bound more strongly to β2 than β7 integrin, with higher off-rates in β7 in vivo. This difference was due to the unique NND sequence in the β2 WN linker compared with KQDS in the β7 WN linker. Structural and biochemical analyses showed that NND established a tighter interaction with talin, whereas KQDS bent, narrowing the interaction area and weakening the interaction. Substituting the NND sequence in β2 with KQDS impaired inside-out signaling- and ligand binding-induced conformational activation of LFA1. Multiple sequence alignment and single-molecule binding analyses revealed that the NND sequence is highly conserved only in mammalian β2 integrins, and that the second asparagine in NND, a residue absent in non-mammalian β2 integrins and other integrins, plays a key role in talin1 binding. Parallel observations in β3 integrins reinforced the pivotal role of the WN linker in modulating integrin-talin affinity. These observations highlight the WN linker as a novel regulator of integrin-talin binding strength and adhesiveness diversity.

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非保守的整合素细胞质区域通过调节talin1结合动力学来决定整合素亚型特异性特征。

Talin通过结合整合素β亚基的细胞质尾部（CT）来控制整合素的粘附，但整合素亚型特异性变异对Talin相互作用的影响尚不清楚。在这里，我们确定了整合素ct中的一个非保守区域，称为WN连接子，它调节talin1结合动力学和整合素粘附性。活体淋巴细胞的单分子成像显示，talin1与β2的结合比β7整合素更强，在体内β7的脱靶率更高。这种差异是由于β2 WN连接子中独特的NND序列与β7 WN连接子中的KQDS序列相比较。结构和生化分析表明，NND与talin的相互作用更紧密，而KQDS则弯曲，缩小了相互作用区域，减弱了相互作用。用KQDS取代β2中的NND序列会破坏由内向外信号传导和配体结合诱导的LFA1构象激活。多序列比对和单分子结合分析表明，NND序列仅在哺乳动物β2整合素中高度保守，并且NND中的第二天冬酰胺是非哺乳动物β2整合素和其他整合素中缺失的残基，在talin1的结合中起关键作用。对β3整合素的平行观察强化了WN连接子在调节整合素-talin亲和力中的关键作用。这些观察结果强调了WN连接子作为整合素-talin结合强度和粘附多样性的新调节器。

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

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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