The sequential phosphorylation of PHF10 subunit of the PBAF chromatin-remodeling complex determines different properties of the PHF10 isoforms.

The mammalian PBAF subfamily of SWI/SNF chromatin remodeling complexes plays a wide role in the regulation of gene expression. PHF10 is a subunit of the signature module of PBAF, responsible for its interaction with chromatin. PHF10 is represented by four different isoforms, which are alternatively incorporated in the complex. Two of PHF10 isoforms lacking C-terminal PHD domains contain a cluster of phosphorylated serine residues, designated as X-cluster. In the present study, we explore the phosphorylation of the X-cluster in detail. We identified additional phosphorylated serine residues and designated them as either frequently or rarely phosphorylated. The X-cluster consists of two independently phosphorylated subclusters. Phosphorylation of the second subcluster depends on phosphorylation of a primary serine 327. These two subclusters surround a sequence, which is predicted to be a nuclear localization sequence (NLS3). The NLS3 does not affect localization of PHF10 isoforms. However, it is essential for X-cluster phosphorylation and increased stability of isoforms that lack PHD. Conversely, the presence of NLS3 signal in isoforms that contain C-terminal PHD domains reduces their stability. Thus, phosphorylation of PHF10 isoforms regulates their cell level, determining the rate of incorporation in PBAF. This may alter the pattern of PBAF regulated genes.

PBAF lacking PHD domains maintains transcription in human neutrophils.

The myeloid precursor cell differentiation requires an extensive chromatin remodeling. We show that the level of the PBAF chromatin remodeling complex decreases following the start of differentiation of myeloid precursors, becoming very low in the terminally differentiated peripheral blood (PB) neutrophils where it co-localizes with Pol II on the transcriptionally active chromatin. Previously, we have shown that the PHF10 subunit of the PBAF signature module has four isoforms, two of them (PHF10-P) contain a tandem of C-terminal PHD domains. We found that out of four PHF10 isoforms present in the myeloid precursor cells, only the PHF10-Ss isoform lacking PHD domains, is actively expressed in the PB neutrophils. In particular, the longest of the PHF10 isoforms (PHF10-Pl), which is essential for proliferation, completely disappears in PB neutrophils. In addition, in the myeloid precursors, promoters of neutrophil-specific genes are associated with the PHD-containing isoforms, together with PBAF and Pol II, when these genes are inactive and only during their activation stage. However, at the later stages of differentiation, when neutrophil-specific genes are actively transcribed, PHF10-P isoforms on their promoters are replaced by the PHF10-S isoforms. Evidently, PHD domains of PHF10 are essential for active chromatin remodeling during transcription activation, but are dispensable for the constantly transcribed genes.