Graf Dimitri, Schnee Philipp, Pleiss Jürgen, Weirich Sara, Jeltsch Albert
Institute of Biochemistry, University of Stuttgart, Stuttgart, Germany.
Commun Biol. 2025 May 29;8(1):823. doi: 10.1038/s42003-025-08207-4.
The PRDM9 protein lysine methyltransferase is essential in meiotic recombination where it trimethylates H3K4 and H3K36 in chromatin. However, it is not known how this enzyme can specifically methylate these two substrates despite their dissimilar amino acid sequences. Using biochemical and molecular dynamics simulation approaches, we uncover that PRDM's unique dual substrate specificity is based on distinct interaction modes of the enzyme with both substrates. Our data show that PRDM9 interacts with the H3K4 and H3K36 peptides through a bipartite peptide binding cleft, comprising one part specific for H3K4 but tolerating H3K36, and a second part with the opposite properties. Binding of the H3K4 and H3K36 peptide substrates occurs in slightly different conformations which enables the specific recognition of both substrates. While wildtype PRDM9 showed higher activity on H3K4 peptides, site-directed mutagenesis of residues involved in PRDM9-peptide contacts allowed us to strongly modulate the K4/K36 preferences creating mutants with elevated preference for H3K4, mutants with equal methylation of both substrates and even mutants with preference for H3K36. Our data illustrate evolutionary pathways to swap the sequence specificity of PKMTs by few amino acid exchanges, a process that happened several times in the divergent evolution of PKMTs.
PRDM9蛋白赖氨酸甲基转移酶在减数分裂重组过程中至关重要,它能使染色质中的H3K4和H3K36发生三甲基化。然而,尽管这两种底物的氨基酸序列不同,该酶如何特异性地使它们甲基化仍不清楚。我们采用生化和分子动力学模拟方法,发现PRDM独特的双底物特异性基于该酶与两种底物不同的相互作用模式。我们的数据表明,PRDM9通过一个双肽结合裂隙与H3K4和H3K36肽段相互作用,该裂隙一部分对H3K4具有特异性但能容忍H3K36,另一部分则具有相反的特性。H3K4和H3K36肽底物以略有不同的构象结合,从而实现对两种底物的特异性识别。虽然野生型PRDM9对H3K4肽段表现出更高的活性,但对PRDM9与肽段接触所涉及的残基进行定点诱变,使我们能够强烈调节K4/K36偏好性,创造出对H3K4偏好性升高的突变体、对两种底物甲基化程度相同的突变体,甚至对H3K36有偏好的突变体。我们的数据说明了通过少数氨基酸交换来改变PKMTs序列特异性的进化途径,这一过程在PKMTs的分化进化中发生了好几次。
