Anastassiia Vertii

Analysis of Properties of Small Heat Shock Protein Hsp25 in MAPK-activated Protein Kinase 2 (MK2)-deficient Cells MK2-DEPENDENT INSOLUBILIZATION OF Hsp25 OLIGOMERS CORRELATES WITH SUSCEPTIBILITY TO STRESS

Small heat shock proteins (sHsps) exist in dynamic oligomeric complexes and display diverse biological functions ranging from chaperone properties to modulator of apoptosis. So far, the role of stress-dependent phosphorylation of mammalian sHsps for its structure and function has been analyzed by using various phosphorylation site mutants overexpressed in different cell types as well as by non-exclusive inhibitors of the p38 MAPK cascade. Here we investigate the role of phosphorylation of endogenous sHsp in a genetic model lacking the major Hsp25 kinase, the MAP kinase-activated protein kinase MK2. We demonstrate that in MK2-deficient fibroblasts, where no stress-dependent phosphorylation of Hsp25 at Ser86 and no in vitro binding to 14-3-3 was detectable, stress-dependent disaggregation of endogenous Hsp25 complexes is impared and kinetics of arsenite-dependent, H2O2-dependent, and sublethal heat shock-induced insolubilization of Hsp25 is delayed. Similarly, green fluorescent protein-tagged Hsp25 shows retarded subcellular accumulation into stress granules in MK2-deficient cells after arsenite treatment. Decreased insolubilization of Hsp25 in MK2-deficient cells correlates with increased resistance against arsenite, H2O2, and sublethal heat shock treatment and with decreased apoptosis. In contrast, after severe, lethal heat shock MK2-deficient embryonic fibroblasts cells show fast and complete insolubilization of Hsp25 independent of MK2 and no increased stress resistance. Hence, MK2-dependent formation of insoluble stress granules and irreversible cell damage by oxidative stresses and sublethal heat shock correlate and only upon severe, lethal heat shock MK2-independent processes could determine insolubilization of Hsp25 and are more relevant for cellular stress damage.

The Centrosome, a Multitalented Renaissance Organelle

The centrosome acts as a microtubule-organizing center (MTOC) from the G1 to G2 phases of the cell cycle; it can mature into a spindle pole during mitosis and/or transition into a cilium by elongating microtubules (MTs) from the basal body on cell differentiation or cell cycle arrest. New studies hint that the centrosome functions in more than MT organization. For instance, it has recently been shown that a specific substructure of the centrosome-the mother centriole appendages-are required for the recycling of endosomes back to the plasma membrane. This alone could have important implications for a renaissance in our understanding of the development of primary cilia, endosome recycling, and the immune response. Here, we review newly identified roles for the centrosome in directing membrane traffic, the immunological synapse, and the stress response.

New frontiers: discovering cilia‐independent functions of cilia proteins

In most vertebrates, mitotic spindles and primary cilia arise from a common origin, the centrosome. In non‐cycling cells, the centrosome is the template for primary cilia assembly and, thus, is crucial for their associated sensory and signaling functions. During mitosis, the duplicated centrosomes mature into spindle poles, which orchestrate mitotic spindle assembly, chromosome segregation, and orientation of the cell division axis. Intriguingly, both cilia and spindle poles are centrosome‐based, functionally distinct structures that require the action of microtubule‐mediated, motor‐driven transport for their assembly. Cilia proteins have been found at non‐cilia sites, where they have distinct functions, illustrating a diverse and growing list of cellular processes and structures that utilize cilia proteins for crucial functions. In this review, we discuss cilia‐independent functions of cilia proteins and re‐evaluate their potential contributions to “cilia” disorders.

The Centrosome Undergoes Plk1-Independent Interphase Maturation during Inflammation and Mediates Cytokine Release

Cytokine production is a necessary event in the immune response during inflammation and is associated with mortality during sepsis, autoimmune disorders, cancer, and diabetes. Stress-activated MAP kinase signaling cascades that mediate cytokine synthesis are well established. However, the downstream fate of cytokines before they are secreted remains elusive. We report that pro-inflammatory stimuli lead to recruitment of pericentriolar material, specifically pericentrin and γ-tubulin, to the centrosome. This is accompanied by enhanced microtubule nucleation and enrichment of the recycling endosome component FIP3, all of which are hallmarks of centrosome maturation during mitosis. Intriguingly, centrosome maturation occurs during interphase in an MLK-dependent manner, independent of the classic mitotic kinase, Plk1. Centrosome disruption by chemical prevention of centriole assembly or genetic ablation of pericentrin attenuated interleukin-6, interleukin-10, and MCP1 secretion, suggesting that the centrosome is critical for cytokine production. Our results reveal a function of the centrosome in innate immunity.

Centrosome-intrinsic mechanisms modulate centrosome integrity during fever.

The centrosome is critical for cell division. Heat stress (HS) causes degradation of all centrosome substructures by centrosome-bound proteasomes. HS-activated degradation is centrosome specific and can be rescued by targeting Hsp70 to the centrosome. Centrosome inactivation is a physiological event, as centrosomes in leukocytes of febrile patients are disrupted.

CPEB Regulation of TAK1 Synthesis Mediates Cytokine Production and the Inflammatory Immune Response

ABSTRACT The cytoplasmic-element-binding (CPEB) protein is a sequence-specific RNA-binding protein that regulates cytoplasmic polyadenylation-induced translation. In mouse embryo fibroblasts (MEFs) lacking CPEB, many mRNAs encoding proteins involved in inflammation are misregulated. Correlated with this aberrant translation in MEFs, a macrophage cell line depleted of CPEB and treated with lipopolysaccharide (LPS) to stimulate the inflammatory immune response expresses high levels of interleukin-6 (IL-6), which is due to prolonged nuclear retention of NF-κB. Two proteins involved in NF-κB nuclear localization and IL-6 expression, IκBα and transforming growth factor beta-activated kinase 1 (TAK1), are present at excessively low and high steady-state levels, respectively, in LPS-treated CPEB-depleted macrophages. However, only TAK1 has an altered synthesis rate that is CPEB dependent and CPEB/TAK1 double depletion alleviates high IL-6 production. Peritoneal macrophages isolated from CPEB knockout (KO) mice treated with LPS in vitro also have prolonged NF-κB nuclear retention and produce high IL-6 levels. LPS-injected CPEB KO mice secrete prodigious amounts of IL-6 and other proinflammatory cytokines and exhibit hypersensitivity to endotoxic shock; these effects are mitigated when the animals are also injected with (5Z)-7-oxozeaenol, a potent and specific inhibitor of TAK1. These data show that CPEB control of TAK1 mRNA translation mediates the inflammatory immune response.

Human basal body basics

In human cells, the basal body (BB) core comprises a ninefold microtubule-triplet cylindrical structure. Distal and subdistal appendages are located at the distal end of BB, where they play indispensable roles in cilium formation and function. Most cells that arrest in the G0 stage of the cell cycle initiate BB docking at the plasma membrane followed by BB-mediated growth of a solitary primary cilium, a structure required for sensing the extracellular environment and cell signaling. In addition to the primary cilium, motile cilia are present in specialized cells, such as sperm and airway epithelium. Mutations that affect BB function result in cilia dysfunction. This can generate syndromic disorders, collectively called ciliopathies, for which there are no effective treatments. In this review, we focus on the features and functions of BBs and centrosomes in Homo sapiens.

New dimensions of asymmetric division in vertebrates

Traditionally, we imagine that cell division gives rise to two identical daughter cells. Nevertheless, all cell divisions, to some degree, display asymmetry. Asymmetric cell division is defined as the generation of two daughter cells with different physical content and/or developmental potential. Several organelles and cellular components including the centrosome, non‐coding RNA, chromatin, and recycling endosomes are involved in the process of asymmetric cell division. Disruption of this important process is known to induce profound defects in development, the immune response, regeneration of tissues, aging, and cancer. Here, we discuss recent advances that expand our understanding of the mechanisms and consequences of asymmetric cell division in vertebrate organisms.

The Centrosome: A Phoenix Organelle of the Immune Response

Stress exposure influences the function, quality and duration of an organism’s life. Stresses such as infection can induce inflammation and activate the immune response, which, in turn, protects the organism by eliminating the pathogen. While many aspects of immune system functionality are well established, the molecular, structural and physiological events contributed by the centrosome remain enigmatic. Here we discuss recent advances in the role of the centrosome in the stress response during inflammation and the possible benefits of the centrosome as a stress sensor for the organism.