Axin localizes to the centrosome and is involved in microtubule nucleation

Axin is known to have an important role in the degradation of β‐catenin in the Wnt pathway. Here, we reveal a new function of Axin at the centrosome. Axin was localized to the centrosome in various cell lines and formed a complex with γ‐tubulin. Knockdown of Axin reduced the localization of γ‐tubulin and γ‐tubulin complex protein 2—components of the γ‐tubulin ring complex—to the centrosome and the centrosomal microtubule nucleation activity after treatment with nocodazole. These phenotypes could not be rescued by the reduction in the levels of β‐catenin. Although the expression of Axin rescued these phenotypes in Axin‐knockdown cells, overexpression of Axin2, which is highly homologous to Axin, could not. Axin2 was also localized to the centrosome, but it did not form a complex with γ‐tubulin. These results suggest that Axin, but not Axin2, is involved in microtubule nucleation by forming a complex with γ‐tubulin at the centrosome.     

FBXL13 directs the proteolysis of CEP192 to regulate centrosome homeostasis and cell migration

Aberrant centrosome organisation with ensuing alterations of microtubule nucleation capacity enables tumour cells to proliferate and invade despite increased genomic instability. CEP192 is a key factor in the initiation process of centrosome duplication and in the control of centrosome microtubule nucleation. However, regulatory means of CEP192 have remained unknown. Here, we report that FBXL13, a binding determinant of SCF (SKP1‐CUL1‐F‐box)‐family E3 ubiquitin ligases, is enriched at centrosomes and interacts with the centrosomal proteins Centrin‐2, Centrin‐3, CEP152 and CEP192. Among these, CEP192 is specifically targeted for proteasomal degradation by FBXL13. Accordingly, induced FBXL13 expression downregulates centrosomal γ‐tubulin and disrupts centrosomal microtubule arrays. In addition, depletion of FBXL13 induces high levels of CEP192 and γ‐tubulin at the centrosomes with the consequence of defects in cell motility. Together, we characterise FBXL13 as a novel regulator of microtubule nucleation activity and highlight a role in promoting cell motility with potential tumour‐promoting implications.     

Possible implication of Golgi-nucleating function for the centrosome

The Golgi apparatus breaks down at mitosis, resulting in the dispersal of Golgi-resident proteins. In NRK cells, however, subsets of both TGN38 and golgin-97, but not ManII and GM130, remained associated with the centrosome throughout the cell cycle. This centrosome association of TGN38 and golgin-97 was not disrupted by treatment with brefeldin A, additional inducers of retrograde trafficking and inhibitors of either kinases or protein phosphatases. Anchoring of the Golgi apparatus within the juxtanuclear region depends on microtubules; the association of TGN38 and golgin-97 subsets with the centrosome, however, was insensitive to nocodazole treatment. Drugs such as PDMP, which block Golgi dispersal both by nocodazole, despite microtubule depolymerization, and by inducers of retrograde trafficking, strengthened the microtubule-nucleating activity of the centrosome. These observations cumulatively suggest the centrosome is implicated in nucleation of the Golgi apparatus through interactions with Golgi-resident proteins, such as TGN38 and golgin-97.     

Nek2 localizes to multiple sites in mitotic cells, suggesting its involvement in multiple cellular functions during the cell cycle.

Nek2 is a mammalian protein kinase that is structurally homologous to NIMA, a mitotic regulator in Aspergillus nidulans. To understand the possible cellular processes in which Nek2 participates during the cell cycle, we investigated the expression and subcellular localization of Nek2 in mitotic cells. The Nek2 protein levels were observed to be regulated in a cell cycle stage-specific manner in cultured cells. The cell cycle stage specificity of Nek2 expression was also confirmed in cells undergoing mitosis in vivo. Nek2 proteins were localized in both the nucleus and cytoplasm throughout the cell cycle, but exhibited dynamic changes in distribution, depending on the cell cycle stage. Nek2 was associated with chromosomes from prophase to metaphase and then was dissociated upon entering into anaphase. Nek2 then appeared at the midbody of the cytoplasmic bridge at telophase. Nek2 was also associated with the centrosome throughout the cell cycle as observed previously by others. Additionally, the nuclear localization of Nek2 was increased during S phase. Such dynamic behavior of Nek2 suggests that Nek2 may be a mitotic regulator that is involved in diverse cell cycle events.     

miR-34a/c induce caprine endometrial epithelial cell apoptosis by regulating circ-8073/CEP55 via the RAS/RAF/MEK/ERK and PI3K/AKT/mTOR pathways

microRNAs (miRNAs) and circular RNAs (circRNAs) are important for endometrial receptivity establishment and embryo implantation in mammals. miR-34a and miR-34c are highly expressed in caprine receptive endometrium (RE). Herein, the functions and mechanisms of miR-34a/c in caprine endometrial epithelial cell (CEEC) apoptosis and RE establishment were investigated. miR-34a/c downregulated the expression level of centrosomal protein 55 (CEP55) and were sponged by circRNA8073 (circ-8073), thereby exhibiting a negative interaction in CEEC. miR-34a/c induced CEEC apoptosis by targeting circ-8073/CEP55 through the regulation of the RAS/RAF/MEK/ERK and phosphoitide 3-kinase (PI3K)/protein kinase B (AKT)/mammalian target of rapamycin (mTOR) pathways. Positive and negative feedback loops and cross-talk were documented between the RAS/RAF/MEK/ERK and PI3K/AKT/mTOR pathways. miR-34a/c regulated the levels of RE marker genes, including forkhead box M1, vascular endothelial growth factor, and osteopontin (OPN). These results suggest that miR-34a/c not only induce CEEC apoptosis by binding to circ-8073 and CEP55 via the RAS/RAF/MEK/ERK and PI3K/AKT/mTOR pathways, but may also regulate RE establishment in dairy goats.     

Novel clades of the HU/IHF superfamily point to unexpected roles in the eukaryotic centrosome,chromosome partitioning,and biologic conflicts

The HU superfamily of proteins, with a unique DNA-binding mode, has been extensively studied as the primary chromosome-packaging protein of the bacterial superkingdom. Representatives also play a role in DNA-structuring during recombination events and in eukaryotic organellar genome maintenance. However, beyond these well-studied roles, little is understood of the functional diversification of this large superfamily. Using sensitive sequence and structure analysis methods we identify multiple novel clades of the HU superfamily. We present evidence that a novel eukaryotic clade prototyped by the human CCDC81 protein acquired roles beyond DNA-binding, likely in protein-protein interaction in centrosome organization and as a potential cargo-binding protein in conjunction with Dynein-VII. We also show that these eukaryotic versions were acquired via an early lateral transfer from bacteroidetes, where we predict a role in chromosome partition. This likely happened before the last eukaryotic common ancestor, pointing to potential endosymbiont contributions beyond that of the mitochondrial progenitor. Further, we show that the dramatic lineage-specific expansion of this domain in the bacteroidetes lineage primarily is linked to a functional shift related to potential recognition and preemption of genome invasive entities such as mobile elements. Remarkably, the CCDC81 clade has undergone a similar massive lineage-specific expansion within the archosaurian lineage in birds, suggesting a possible use of the HU superfamily in a similar capacity in recognition of non-self molecules even in this case.     

CK2 beta, which inhibits Mos function, binds to a discrete domain in the N-terminus of Mos

Progesterone stimulates G2-arrested Xenopus oocytes to synthesize Mos, a MAPK kinase kinase required for the coordinated activation of cdc2 and the G2/Meiosis I (MI) transition. Mos leads to activation of MAPK, Rsk, and the inhibition of the cdc2 inhibitor Myt1. Previous work identified CK2 beta as a Mos-interacting protein, and suggested that CK2 beta acts as a negative regulator by setting a threshold above which newly made Mos must accumulate to activate MAPK. However, it had not been demonstrated that CK2 beta directly inhibits Mos. We report here that Mos (52-115) is required for CK2 beta binding and can serve as a portable binding domain. To test whether CK2 beta acts at the level of Mos or on a downstream component, we took advantage of previous work that showed injection of Mos arrests rapidly dividing embryonic cells. We find that coinjection of CK2 beta and Mos into embryonic cells inhibits the ability of Mos to arrest cell division. In contrast, CK2 beta does not inhibit the mitotic arrest induced by injection of active Rsk. These results argue that CK2 beta directly binds and inhibits Mos rather than a downstream component, and support that CK2 beta functions as a molecular buffer that prevents premature MAPK activation and oocyte maturation.     

与细胞周期G2/M期进程相关的H2AX磷酸化

γH2AX焦点(foci)被普遍当做DNA双链断裂（DSB）损伤的分子标志物.为探 讨细胞周期进程相关的H2AX磷酸化规律特征,采用胸腺嘧啶双阻滞结合噻氨酯哒唑(nocodazole)的后续处理,将HeLa细胞同步于有丝分裂的前中期．然后,用流式细胞仪检测细胞周期、Western印迹和免疫荧光法,观察γH2AX表达和γH2AX焦点的形成．结果显示,细胞进入G2/M期和有丝分裂过程中,γH2AX水平显著增加 ;在无DNA DSB发生的情况下,部分M期细胞中也存在大量的γH2AX焦点．随着细 胞完成有丝分裂从M期退出再进入G1期,γH2AX的表达水平逐渐降低．这种 γH2AX表达变化特征与G2/M期密切关联的PLK1和Cyclin B1的表达规律相类似． 在4 Gy大剂量照射下,HeLa细胞于照后8 到12 h出现明显的G2/M期阻滞．γH2AX 焦点数在照后1 h达高峰,随后降低,照后8 h又上升,出现了第2个峰值．与之不同的是,在1 Gy低剂量照射下,细胞的G2/M期阻滞微弱,γH2AX焦点数在照后 0.5 h最高,随后下降,且无反弹,符合DNA DSB的修复动力学特征．因此,将γ H2AX当做DNA DSB分子标志物时,还需要考虑细胞周期变化的影响．γH2AX适合 作为1 Gy以下照射的DNA双链断裂损伤的分子标志．     

Hsp70 family member, mot-2/mthsp70/GRP75, binds to the cytoplasmic sequestration domain of the p53 protein

Hsp70 family member mot-2/mthsp70/GRP75/PBP74 was shown to bind to the tumor suppressor protein p53. In this study, by in vivo coimmunoprecipitation of mot-2 with p53 and its deletion mutants, the mot-2 binding site of p53 was mapped to its C-terminal amino acid residues 312-352, a region of p53 that includes its cytoplasmic sequestration domain. These data demonstrate that cytoplasmic sequestration and inactivation of p53 by mot-2 occurs by its binding to the cytoplasmic sequestration domain. Therefore, perturbation of mot-p53 interactions can be employed to abrogate cytoplasmic retention of wild-type p53 in tumors.     

M-CSF上调cyclinD1/D3和CDK2/6的表达促进HeLa细胞增殖

非分泌型巨噬细胞集落刺激因子(M-CSF)的表达在肿瘤的发生发展过程中发挥重要作用,为探讨胞质M-CSF对细胞增殖的影响,采用基因重组技术构建胞内稳定表达M-CSF的HeLa细胞系,以空载体(pCMV/myc/cyto)转染HeLa细胞和未转染HeLa细胞作为对照,MTT法及反义寡核苷酸抑制实验分析M-CSF对细胞增殖的影响,并计算细胞倍增时间,RT-PCR观察胞内M-CSF对G1期细胞周期相关蛋白的影响．结果显示,与对照组比较,转染M-CSF的HeLa细胞倍增时间明显缩短、增殖能力显著增强,M-CSF的特异性反义寡核苷酸能抑制转染M-CSF的HeLa细胞的增殖,且抑制率随着反义寡核苷酸浓度的增高而增强,转染M-CSF 的HeLa细胞的cyclinD1/D3和CDK2/6 mRNA表达显著升高(P < 0.05)．提示：M-CSF可上调cyclinD1/D3和CDK2/6的mRNA表达,促进HeLa细胞的增殖．     

Filamin A, the Arp2/3 complex, and the morphology and function of cortical actin filaments in human melanoma cells.

The Arp2/3 complex and filamin A (FLNa) branch actin filaments. To define the role of these actin-binding proteins in cellular actin architecture, we compared the morphology of FLNa-deficient human melanoma (M2) cells and three stable derivatives of these cells expressing normal FLNa concentrations. All the cell lines contain similar amounts of the Arp2/3 complex. Serum addition causes serum-starved M2 cells to extend flat protrusions transiently; thereafter, the protrusions turn into spherical blebs and the cells do not crawl. The short-lived lamellae of M2 cells contain a dense mat of long actin filaments in contrast to a more three-dimensional orthogonal network of shorter actin filaments in lamellae of identically treated FLNa-expressing cells capable of translational locomotion. FLNa-specific antibodies localize throughout the leading lamellae of these cells at junctions between orthogonally intersecting actin filaments. Arp2/3 complex-specific antibodies stain diffusely and label a few, although not the same, actin filament overlap sites as FLNa antibody. We conclude that FLNa is essential in cells that express it for stabilizing orthogonal actin networks suitable for locomotion. Contrary to some proposals, Arp2/3 complex-mediated branching of actin alone is insufficient for establishing an orthogonal actin organization or maintaining mechanical stability at the leading edge.     

The N-terminal domain of DDA3 regulates the spindle-association of the microtubule depolymerase Kif2a and controls the mitotic function of DDA3

DDA3 is a microtubule-associated protein that controls chromosome congression and segregation by regulating the dynamics of the mitotic spindle. Depletion of DDA3 alters spindle structure, generates unaligned chromosomes at metaphase, and delays the mitotic progression. DDA3 interacts with the microtubule depolymerase Kif2a and controls the association of Kif2a to the mitotic spindle and the dynamic turnover of microtubules in the spindle. To understand the function and regulation of DDA3, we analyzed its domain structure and found that the C-terminal domain of DDA3 directly binds to microtubules in vitro and associates with the mitotic spindle in vivo. The N-terminal domain of DDA3 does not interact with microtubules, but acts dominant negatively over the wild-type protein. Ectopic expression of this domain prevents the endogenous DDA3 from association with the spindle and results in a high frequency of unaligned chromosomes in metaphase cells, a phenotype similar to that in metaphase cells depleted of DDA3. Mechanistically, expression of N-terminal DDA3 reduces the amount of spindle-associated Kif2a and increases the spindle microtubule density, pheno-copying those in DDA3-depleted cells. We conclude that DDA3 has a distinct domain structure. The C-terminal domain confers its ability to associate with the mitotic spindle, while the regulatory N-terminal domain controls the microtubule-binding by the C-terminal domain and determines the cellular activity of the DDA3 protein.     

Redox biology in normal cells and cancer: Restoring function of the redox/Fyn/c-Cbl pathway in cancer cells offers new approaches to cancer treatment

This review discusses a unique discovery path starting with novel findings on redox regulation of precursor cell and signaling pathway function and identification of a new mechanism by which relatively small changes in redox status can control entire signaling networks that regulate self-renewal, differentiation, and survival. The pathway central to this work, the redox/Fyn/c-Cbl (RFC) pathway, converts small increases in oxidative status to pan-activation of the c-Cbl ubiquitin ligase, which controls multiple receptors and other proteins of central importance in precursor cell and cancer cell function. Integration of work on the RFC pathway with attempts to understand how treatment with systemic chemotherapy causes neurological problems led to the discovery that glioblastomas (GBMs) and basal-like breast cancers (BLBCs) inhibit c-Cbl function through altered utilization of the cytoskeletal regulators Cool-1/βpix and Cdc42, respectively. Inhibition of these proteins to restore normal c-Cbl function suppresses cancer cell division, increases sensitivity to chemotherapy, disrupts tumor-initiating cell (TIC) activity in GBMs and BLBCs, controls multiple critical TIC regulators, and also allows targeting of non-TICs. Moreover, these manipulations do not increase chemosensitivity or suppress division of nontransformed cells. Restoration of normal c-Cbl function also allows more effective harnessing of estrogen receptor-α (ERα)-independent activities of tamoxifen to activate the RFC pathway and target ERα-negative cancer cells. Our work thus provides a discovery strategy that reveals mechanisms and therapeutic targets that cannot be deduced by standard genetics analyses, which fail to reveal the metabolic information, isoform shifts, protein activation, protein complexes, and protein degradation critical to our discoveries.