Molecular basis for nuclear accumulation and targeting of the inhibitor of apoptosis BIRC2.

The inhibitor of apoptosis protein BIRC2 regulates fundamental cell death and survival signaling pathways. Here we show that BIRC2 accumulates in the nucleus via binding of its second and third BIR domains, BIRC2 and BIRC2, to the histone H3 tail and report the structure of the BIRC2-H3 complex. RNA-seq analysis reveals that the genes involved in interferon and defense response signaling and cell-cycle regulation are most affected by depletion of BIRC2.

Molecular insight into the PCNA-binding mode of FBH1.

F-box DNA helicase 1 (FBH1) is involved in the regulation of cell responses to replicative stress. FBH1 is recruited to stalled DNA replication fork by PCNA where it inhibits homologous recombination and catalyzes fork regression. Here, we report the structural basis for the molecular recognition of two distinctly different motifs of FBH1, FBH1 and FBH1, by PCNA.

The ZZ domain of HERC2 is a receptor of arginylated substrates.

The E3 ubiquitin ligase HERC2 has been linked to neurological diseases and cancer, however it remains a poorly characterized human protein. Here, we show that the ZZ domain of HERC2 (HERC2) recognizes a mimetic of the Nt-R cargo degradation signal. NMR titration experiments and mutagenesis results reveal that the Nt-R mimetic peptide occupies a well-defined binding site of HERC2 comprising of the negatively charged aspartic acids.

ZZEF1 is a Histone Reader and Transcriptional Coregulator of Krüppel-Like Factors.

The ZZ-type zinc finger and EF-hand domain protein 1 (ZZEF1) is a multidomain-containing protein. Mutations of ZZEF1 has been implicated in several kinds of human diseases such as diabetes and cancers. However, the function of the ZZEF protein remains largely unknown.

Molecular mechanism of the MORC4 ATPase activation.

Human Microrchidia 4 (MORC4) is associated with acute and chronic pancreatitis, inflammatory disorders and cancer but it remains largely uncharacterized. Here, we describe the structure-function relationship of MORC4 and define the molecular mechanism for MORC4 activation. Enzymatic and binding assays reveal that MORC4 has ATPase activity, which is dependent on DNA-binding functions of both the ATPase domain and CW domain of MORC4.