Figure 1
Figure 1. Schematic diagram of the EKLF protein. Shown are N-terminal proline-rich and C-terminal (C2H2 zinc fingers; ZnF) DNA-binding domains. EKLF activity is modulated by posttranslational modifications that promote protein-protein interactions. The transactivation activity of EKLF (top) is associated with the phosphorylation status of threonine 41 and acetylation of lysine 288.16–18 Acetylated K288 is involved in interactions with the chromatin-remodeling SWI/SNF-related complex (E-RC1) through the BRG1 subunit.19–21 The repression activity of EKLF (bottom) relies on an acetylation of K302, enabling its interaction with corepressors Sin3a and HDAC1.91,92 Sumoylation of K74 serves to tether components of NuRD repression complex via interaction with Mi2β and HDAC1.23 EKLF is also a substrate for ubiquitination; however, this modification is not specific to any particular internal lysine.93

Schematic diagram of the EKLF protein. Shown are N-terminal proline-rich and C-terminal (C2H2 zinc fingers; ZnF) DNA-binding domains. EKLF activity is modulated by posttranslational modifications that promote protein-protein interactions. The transactivation activity of EKLF (top) is associated with the phosphorylation status of threonine 41 and acetylation of lysine 288.16-18  Acetylated K288 is involved in interactions with the chromatin-remodeling SWI/SNF-related complex (E-RC1) through the BRG1 subunit.19-21  The repression activity of EKLF (bottom) relies on an acetylation of K302, enabling its interaction with corepressors Sin3a and HDAC1.91,92  Sumoylation of K74 serves to tether components of NuRD repression complex via interaction with Mi2β and HDAC1.23  EKLF is also a substrate for ubiquitination; however, this modification is not specific to any particular internal lysine.93 

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