UHMK1 is a novel splicing regulatory kinase.

The U2AF Homology Motif Kinase 1 (UHMK1) is the only kinase that contains the U2AF homology motif, a common protein interaction domain among splicing factors. Through this motif, UHMK1 interacts with the splicing factors SF1 and SF3B1, known to participate in the 3' splice site recognition during the early steps of spliceosome assembly. Although UHMK1 phosphorylates these splicing factors in vitro, the involvement of UHMK1 in RNA processing has not previously been demonstrated. Here, we identify novel putative substrates of this kinase and evaluate UHMK1 contribution to overall gene expression and splicing, by integrating global phosphoproteomics, RNA-seq, and bioinformatics approaches. Upon UHMK1 modulation, 163 unique phosphosites were differentially phosphorylated in 117 proteins, of which 106 are novel potential substrates of this kinase. Gene Ontology analysis showed enrichment of terms previously associated with UHMK1 function, such as mRNA splicing, cell cycle, cell division, and microtubule organization. The majority of the annotated RNA-related proteins are components of the spliceosome but are also involved in several steps of gene expression. Comprehensive analysis of splicing showed that UHMK1 affected over 270 alternative splicing events. Moreover, splicing reporter assay further supported UHMK1 function on splicing. Overall, RNA-seq data demonstrated that UHMK1 knockdown had a minor impact on transcript expression and pointed to UHMK1 function in epithelial-mesenchymal transition. Functional assays demonstrated that UHMK1 modulation affects proliferation, colony formation, and migration. Taken together, our data implicate UHMK1 as a splicing regulatory kinase, connecting protein regulation through phosphorylation and gene expression in key cellular processes.

Relation Between Stress Granules and Cytoplasmic Protein Aggregates Linked to Neurodegenerative Diseases.

ᅟ: A hallmark of neurodegenerative diseases is the accumulation of cytoplasmic protein aggregates in neurons of affected subjects. Among recently identified elements of these aggregates are RNA-binding proteins (RBPs) involved in RNA metabolism and alternative splicing and have in common the presence of low complexity domains (LCD) that are prone to self-assemble and form aggregates. The mechanism of cytoplasmic protein aggregation remains elusive. Stress granules (SGs) that are micrometric RNA-protein assemblies located in the cytoplasm of cells exposed to environmental stress are suspected to play the role of seeds. The review sheds light on the recent experimental results that suggest a link between SGs and cytoplasmic protein aggregates but also propose other routes for the formation of these aggregates. PURPOSE OF REVIEW: To analyze the potential relationship between cytoplasmic protein aggregates in neurons of affected subjects and stress granules. RECENT FINDINGS: Liquid phase separation explains how protein and RNA could assemble in membraneless compartments, notably SGs. These results highlight the importance of RBPs with LCD in the SG assembly. Maturation of SGs and in particular the dense core is a potential source of insoluble protein aggregates. Several lines of evidence linked stress granule dynamics to pathogenic protein aggregates. (i) Proteins that accumulate in cytoplasmic aggregates are also SG components. (ii) Neurons are specifically exposed to stress events due to their high metabolism and long lifespan. (iii) Diseases linked protein mutations affect the SG dynamics. (iv) SG dense core could be a breeding ground for protein aggregates. However, we should also keep in mind that SGs are not the only RNA-protein assembly in the cytoplasm; the RNA transport granules could also play a role in the formation of insoluble protein aggregates.

Evolutionary Changes on the Way to Clathrin-Mediated Endocytosis in Animals.

Endocytic pathways constitute an evolutionarily ancient system that significantly contributed to the eukaryotic cell architecture and to the diversity of cell type-specific functions and signaling cascades, in particular of metazoans. Here we used comparative proteomic studies to analyze the universal internalization route in eukaryotes, clathrin-mediated endocytosis (CME), to address the issues of how this system evolved and what are its specific features. Among 35 proteins crucially required for animal CME, we identified a subset of 22 proteins common to major eukaryotic branches and 13 gradually acquired during evolution. Based on exploration of structure-function relationship between conserved homologs in sister, distantly related and early diverged branches, we identified novel features acquired during evolution of endocytic proteins on the way to animals: Elaborated way of cargo recruitment by multiple sorting proteins, structural changes in the core endocytic complex AP2, the emergence of the Fer/Cip4 homology domain-only protein/epidermal growth factor receptor substrate 15/intersectin functional complex as an additional interaction hub and activator of AP2, as well as changes in late endocytic stages due to recruitment of dynamin/sorting nexin 9 complex and involvement of the actin polymerization machinery. The evolutionary reconstruction showed the basis of the CME process and its subsequent step-by-step development. Documented changes imply more precise regulation of the pathway, as well as CME specialization for the uptake of specific cargoes and cell type-specific functions.