Biochemical,morphological and flow cytometric evaluation of the effects of hexachlorobenzene on rat liver

This study investigated the ability of HCB (0.1% in the diet for 15 days) to cause early changes in the cellular ploidy of rat liver. Treatment caused marked hepatomegaly, increase of microsomal proteins and cytochrome P-450 content and reduction of hepatocyte microviscosity. Microscopic examination showed that the hepatocytes were enlarged, with hyaline cytoplasm and vacuoles. The size distribution of the isolated hepatocytes showed a larger percentage of bigger cells. Flow-cytometric DNA/protein analysis was performed on whole (fixed) cells and on nuclei. From the combined results of both analyses it was possible to exclude significant changes in the percentages of diploid, mononucleated tetraploid, binucleated tetraploid and octoploid hepatocytes. The DNA and protein content of each subpopulation remained unchanged. Our results suggest that HCB does not cause early diploidization of liver cells and that hepatomegaly and cytochrome P-450 induction seem not to be correlated with effects on total DNA and total protein contents.Abbreviations HCB hexachlorobenzene - PI propidium iodide - FITC fluorescein isothiocyanate - DN diploid nuclei - SN 2N-4N nuclei in S-phase - TN tetraploid nuclei - DC diploid cells - SDC 2N-4N diploid cells in S-phase - TC tetraploid cells - STC 4N-8N tetraploid cells in S-phase - OC octoploid cells - MDC mononucleated diploid cells - SMDC mononucleated diploid cells in S-phase - BOC binucleated octoploid cells - SBTC binucleated tetraploid cells in S-phase - BTC binucleated tetraploid cells - MTC mononucleated tetraploid cells.     

p53 localization at centrosomes during mitosis and postmitotic checkpoint are ATM-dependent and require serine 15 phosphorylation

We recently demonstrated that the p53 oncosuppressor associates to centrosomes in mitosis and this association is disrupted by treatments with microtubule-depolymerizing agents. Here, we show that ATM, an upstream activator of p53 after DNA damage, is essential for p53 centrosomal localization and is required for the activation of the postmitotic checkpoint after spindle disruption. In mitosis, p53 failed to associate with centrosomes in two ATM-deficient, ataxiatelangiectasia-derived cell lines. Wild-type ATM gene transfer reestablished the centrosomal localization of p53 in these cells. Furthermore, wild-type p53 protein, but not the p53-S15A mutant, not phosphorylatable by ATM, localized at centrosomes when expressed in p53-null K562 cells. Finally, Ser15 phosphorylation of endogenous p53 was detected at centrosomes upon treatment with phosphatase inhibitors, suggesting that a p53 dephosphorylation step at centrosome contributes to sustain the cell cycle program in cells with normal mitotic spindles. When dissociated from centrosomes by treatments with spindle inhibitors, p53 remained phosphorylated at Ser15. AT cells, which are unable to phosphorylate p53, did not undergo postmitotic proliferation arrest after nocodazole block and release. These data demonstrate that ATM is required for p53 localization at centrosome and support the existence of a surveillance mechanism for inhibiting DNA reduplication downstream of the spindle assembly checkpoint     

Centrosome-independent mitotic spindle formation in vertebrates

BACKGROUND: In cells lacking centrosomes, the microtubule-organizing activity of the centrosome is substituted for by the combined action of chromatin and molecular motors. The question of whether a centrosome-independent pathway for spindle formation exists in vertebrate somatic cells, which always contain centrosomes, remains unanswered, however. By a combination of labeling with green fluorescent protein (GFP) and laser microsurgery we have been able to selectively destroy centrosomes in living mammalian cells as they enter mitosis. RESULTS: We have established a mammalian cell line in which the boundaries of the centrosome are defined by the constitutive expression of gamma-tubulin-GFP. This feature allows us to use laser microsurgery to selectively destroy the centrosomes in living cells. Here we show that this method can be used to reproducibly ablate the centrosome as a functional entity, and that after destruction the microtubules associated with the ablated centrosome disassemble. Depolymerization-repolymerization experiments reveal that microtubules form in acentrosomal cells randomly within the cytoplasm. When both centrosomes are destroyed during prophase these cells form a functional bipolar spindle. Surprisingly, when just one centrosome is destroyed, bipolar spindles are also formed that contain one centrosomal and one acentrosomal pole. Both the polar regions in these spindles are well focused and contain the nuclear structural protein NuMA. The acentrosomal pole lacks pericentrin, gamma-tubulin, and centrioles, however. CONCLUSIONS: These results reveal, for the first time, that somatic cells can use a centrosome-independent pathway for spindle formation that is normally masked by the presence of the centrosome. Furthermore, this mechanism is strong enough to drive bipolar spindle assembly even in the presence of a single functional centrosome.     

Relationship between nuclear DNA synthesis and centrosome reproduction in sea urchin eggs

The importance of nuclear DNA synthesis for the doubling, or reproduction, of centrosomes in cells that are not growth-limited, such as sea urchin eggs, has not been clearly defined. Studies of enucleated, fertilized eggs show that nuclear activities are not required at each cell cycle for the normal reproduction of the complete centrosome. However, other studies report that the inhibition of nuclear DNA synthesis in intact eggs by the drug aphidicolin prevents centrosome reproduction and entry into mitosis as seen by nuclear envelope breakdown. To resolve this paradox, we systematically characterized the effect of aphidicolin on cell division in eggs from three species of sea urchins. Eggs were continuously treated with 5 or 10 micrograms/ml aphidicolin starting 5 min after fertilization. This blocked total incorporation of 3H-thymidine into DNA by at least 90%, as previously reported. We found that the sperm aster always doubles prior to first mitosis. Over a period of several hours, the centrosomes reproduce in the normal 2-4-8-16 fashion, with a period that is longer and more variable than normal. In every culture, a variable percentage of the eggs undergoes nuclear envelope breakdown. Once broken down, the nuclear envelope never visibly reforms even though centrosomes continue to double. Fluorescent labeling of DNA revealed that the chromatin does not condense into discrete chromosomes. Whether or not the nuclear envelope breaks down, the chromatin appears as an amorphous mass of fibers stretched between first two and then four asters. Later, the nuclear envelope/chromatin loses its association with some or all centrosomes. Our results were the same for all eggs at both drug concentrations. Thus, nuclear DNA synthesis is not required for centrosome reproduction in sea urchin eggs.     

Centrosome and Golgi complex during differentiation of hepatocytes in early postnatal development of mice

The structure and functional activity of the centrosome was analyzed in hepatocytes of 5-day old mice, as well as the lengths of Golgi complex cistemae. In the early postnatal development of mice, the liver was represented by two types of hepatocytes: in the first type hepatocytes, the centrosome was active as an organizing center of microtubules, while in the second type hepatocytes, it was inactive. It was proposed that during ontogenesis the centrosome is inactivated as an organizing center of microtubules and activated as an organizing center of intermediate filaments characteristic for differentiated hepatocytes of adult liver. Morphometry of the Golgi complex has shown that Golgi cisternae in the cell center area of early postnatal hepatocytes were longer than in the adult hepatocytes and comparable to those in G1-phase hepatocytes of regenerating liver. The possibility of relations between the differences in the Golgi complex morphology and ontogenetic changes in the functional activity of centrosomes is discussed.     

Centrosome and Golgi complex during differentiation of hepatocytes in early postnatal development of mice

The structure and functional activity of the centrosome was analyzed in hepatocytes of 5-day old mice, as well as the lengths of Golgi complex cisternae. In the early postnatal development of mice, the liver was represented by two types of hepatocytes: in the first type hepatocytes, the centrosome was active as a microtubule organizing center, while in the second type hepatocytes, it was inactive. It was proposed that during ontogenesis the centrosome is inactivated as a microtubule organizing center and activated as an organizing center of intermediate filaments characteristic for differentiated hepatocytes of adult liver. Morphometry of the Golgi complex has shown that Golgi cisternae in the cell center area of early postnatal hepatocytes were longer than in the adult hepatocytes and comparable to those in G ₁-phase hepatocytes of regenerating liver. The possibility of relations between the differences in the Golgi complex morphology and ontogenetic changes in the functional activity of centrosomes is discussed.     

Spermatozoa of the Loach Misgurnus fossilis in the Identification of New Centrosome Proteins

We studied the possibility of using the spermatozoa of the loach Misgurnus fossilis L. in the identification of centrosome proteins. It has been shown that the centrosome of the loach spermatozoa consists of a pair of centrioles of the standard structure and contains the marker protein -tubulin, cytoplasmic microtubules branch out from it, and it does not contain any additional structures characteristic of the centrosomes of spermatozoa of many other fishes. A preparation enriched with intact centrosomes was obtained from the loach spermatozoa. These centrosomes contained -tubulin, although they had lost their ability to induce the polymerization of microtubules. The preparation of loach centrosomes was successfully used to obtain a set of monoclonal antibodies against the mammalian centrosome. A new protein kinase LOSTEK was identified with the help of one of these monoclonal antibodies, SN2-3D2, which was localized in the centrosome and then on microtubules in both loach spermatozoa and cultured mammalian cells. Hence, the loach spermatozoa are a promising means to identify new proteins in the mammalian centrosome.     

Dynein intermediate chain mediated dynein-dynactin interaction is required for interphase microtubule organization and centrosome replication and separation in Dictyostelium

Cytoplasmic dynein intermediate chain (IC) mediates dynein-dynactin interaction in vitro (Karki, S., and E.L. Holzbaur. 1995. J. Biol. Chem. 270:28806-28811; Vaughan, K.T., and R.B. Vallee. 1995. J. Cell Biol. 131:1507-1516). To investigate the physiological role of IC and dynein-dynactin interaction, we expressed IC truncations in wild-type Dictyostelium cells. ICDeltaC associated with dynactin but not with dynein heavy chain, whereas ICDeltaN truncations bound to dynein but bound dynactin poorly. Both mutations resulted in abnormal localization to the Golgi complex, confirming dynein function was disrupted. Striking disorganization of interphase microtubule (MT) networks was observed when mutant expression was induced. In a majority of cells, the MT networks collapsed into large bundles. We also observed cells with multiple cytoplasmic asters and MTs lacking an organizing center. These cells accumulated abnormal DNA content, suggesting a defect in mitosis. Striking defects in centrosome morphology were also observed in IC mutants, mostly larger than normal centrosomes. Ultrastructural analysis of centrosomes in IC mutants showed interphase accumulation of large centrosomes typical of prophase as well as unusually paired centrosomes, suggesting defects in centrosome replication and separation. These results suggest that dynactin-mediated cytoplasmic dynein function is required for the proper organization of interphase MT network as well as centrosome replication and separation in Dictyostelium.     

中心体异常在咖啡因增强顺铂杀伤人肝癌细胞系中的作用

为了探讨咖啡因是否影响细胞周期检验点而增强顺铂杀伤肿瘤细胞及其作用机制 ,选取同步化于S期的肝癌细胞系SMMC 772 1,用顺铂和咖啡因进行不同方式的处理 ,包括顺铂处理、咖啡因处理以及先经顺铂 ,再用咖啡因处理 .利用相关方法对不同处理的细胞进行了分析 ,包括细胞形态 ,细胞生长速率 ,多核细胞的形成与死亡 ,中心体的异常等 .结果显示 ,顺铂与咖啡因联合处理的细胞出现明显的多核化现象 ,多核细胞占总细胞的百分比可以达到 30 %以上 ,高于用顺铂或用咖啡因处理的细胞 .同时观察到多核细胞生存能力较差 ,它们会通过细胞凋亡的形式死亡 .抗中心体人自身免疫血清的免疫荧光结果显示 ,中心体异常与多核细胞的形成直接相关 .在部分多核细胞的核周围有多个不同强度的荧光点 ,在另部分多核细胞中 ,在其中央有一个大的荧光点 ,被多个细胞核围绕 ,荧光较强 .根据结果推测 ,由多个不完整的中心体导致的多极分裂形成多核细胞 ,随后多个中心体聚集到中央形成大的中心体 ,负责间期微管的组装 .结果表明 ,受到顺铂损伤的细胞由于检验点的作用而使细胞周期阻断 ,咖啡因可消除周期的阻断 ,使细胞在中心体未完成正常复制状态下进入有丝分裂 ,产生大量多核细胞 ,这些多核细胞最终发生凋亡 .     

Centrosome abnormalities during a Chlamydia trachomatis infection are caused by dysregulation of the normal duplication pathway

The presence of supernumerary centrosomes in cells infected with Chlamydia trachomatis may provide a mechanism to explain the association of C. trachomatis genital infection with cervical cancer. We show that the amplified centrosomal foci induced during a chlamydial infection contain both centriolar and pericentriolar matrix markers, demonstrating that they are bona fide centrosomes. As there were multiple immature centrioles but approximately one mature centriole per cell, aborted cytokinesis alone cannot account for centrosome amplification during a chlamydial infection. Production of supernumerary centrosomes required the kinase activities of Cdk2 and Plk4, which are known regulators of centrosome duplication, and progression through S-phase, which is the stage in the cell cycle when duplication of the centrosome occurs. These requirements indicate that centrosome amplification during a chlamydial infection depends on the host centrosome duplication pathway, which normally produces a single procentriole from each template centriole. However, C. trachomatis induces a loss of numerical control so that multiple procentrioles are formed per template.     

Spermatozoa of the loach Misgurnus fossilis as a test system for identification of new centromere proteins

We studied the possibility of using the spermatozoa of the loach Misgurnus fossilis L. for identification of centrosome proteins. It has been shown that the centrosome of the loach spermatozoa consists of a pair of centrioles of the standard structure and contains the marker protein gamma-tubulin, cytoplasmic microtubules branch out from it, and it does not contain any additional structures characteristic of the centrosomes of spermatozoa of many other fishes. A preparation enriched with intact centrosomes has been obtained from the loach spermatozoa. These centrosomes contained gamma-tubulin although they lost their ability to induce polymerization of microtubules. The preparation of loach centrosomes was successfully used to obtain a set of monoclonal antibodies against the mammalian centrosome. A new protein kinase LOSTEK was identified with the help of one of these monoclonal antibodies, SN2-3D2, which was localized in the centrosome and on then microtubules in both loach spermatozoa and cultured mammalian cells. Hence, the loach spermatozoa are a promising object for identification of new proteins of the mammalian centrosome.     

Parthenogenesis in Xenopus eggs injected with centrosomes from synchronized human lymphoid cells

In Xenopus eggs, normal development requires the participation of the centrosome provided by the sperm. Injection of foreign centrosomes purified from exponentially growing mammalian cells enables the eggs to undertake parthenogenesis. In order to know whether such a complementation required centrosomes already committed to duplication, we have prepared centrosomes from human cells synchronized at different stages of the cell cycle (G0, G1, G2). We show that the three types of centrosome possess a similar parthenogenetic activity and conclude that duplication of heterologous centrosome can be triggered in Xenopus eggs.     

The C. elegans hook protein, ZYG-12, mediates the essential attachment between the centrosome and nucleus

The centrosome and nucleus are intimately associated in most animal cells, yet the significance of this interaction is unknown. Mutations in the zyg-12 gene of Caenorhabditis elegans perturb the attachment of the centrosome to the nucleus, giving rise to aberrant spindles and ultimately, DNA segregation defects and lethality. These phenotypes indicate that the attachment is essential. ZYG-12 is a member of the Hook family of cytoskeletal linker proteins and localizes to both the nuclear envelope (via SUN-1) and centrosomes. ZYG-12 is able to bind the dynein subunit DLI-1 in a two-hybrid assay and is required for dynein localization to the nuclear envelope. Loss of dynein function causes a low percentage of defective centrosome/nuclei interactions in both Drosophila and Caenorhabditis elegans. We propose that dynein and ZYG-12 move the centrosomes toward the nucleus, followed by a ZYG-12/SUN-1-dependent anchorage.     

Studies on satellite nucleoli in rat hepatocytes and Novikoff hepatoma cells

Summary The present study was undertaken to provide information on the presence and frequency of satellite nucleoli in cells with increased nucleolar biosynthetic activity. The number of hepatocytes containing satellite nucleoli was analyzed in rat liver, regenerating liver 18 h after partial hepatectomy and in Novikoff hepatoma ascites cells. In comparison with hepatocytes of normal liver, the number of both stimulated hepatocytes and malignant hepatoma cells containing satellite nucleoli was significantly reduced. The results also indicated that whereas most satellite nucleoli contain protein C23, a smaller percentage contain protein B23.     

Short term cyclin D1 overexpression induces centrosome amplification, mitotic spindle abnormalities, and aneuploidy

In normal cells, cyclin D1 is induced by growth factors and promotes progression through the G(1) phase of the cell cycle. Cyclin D1 is also an oncogene that is thought to act primarily by bypassing the requirement for mitogens during the G(1) phase. Studies of clinical tumors have found that cyclin D1 overexpression is associated with chromosome abnormalities, although a causal effect has not been established in experimental systems. In this study, we found that transient expression of cyclin D1 in normal hepatocytes in vivo triggered dysplastic mitoses, accumulation of supernumerary centrosomes, abnormalities of the mitotic spindle, and marked chromosome changes within several days. This was associated with up-regulation of checkpoint genes p53 and p21 as well as hepatocyte apoptosis in the liver. Transient transfection of cyclin D1 also induced centrosome and mitotic spindle abnormalities in breast epithelial cells, suggesting that this may be a generalized effect. These results indicate that cyclin D1 can induce deregulation of the mitotic apparatus and aneuploidy, effects that could contribute to the role of this oncogene in malignancy.     

Centrosome alterations induced by formamide cause abnormal spindle pole formations

The formation of the bipolar mitotic apparatus depends on accurate centrosome organization which is crucial for the separation of the genome during cell division. While it has been shown that mutations and overexpression of centrosome proteins (Brinkley and Goepfert, 1998; Pihan et al., 1998) can cause abnormal spindle pole formation, here we report that damages to centrosome structure caused by the chaotropic agent formamide will cause multipolar mitoses upon recovery from the effect when applied at first cell division in sea urchin eggs. Formamide was used as a chemical tool to manipulate centrosome structure and to investigate the effects on microtubule organization. When 1-1.5 m formamide was administered for 30 min at prometaphase of first cell division, microtubules were disassembled and centrosomes compacted into dense spheres around highly condensed chromatin. Upon recovery from formamide, centrosomes decompacted and attempted to form various mitotic organizations. Normal recovery (and attempts of recovery) to bipolarity was possible in five percent of cells treated with 1-1.5 m formamide for 30 min, but abnormal patterns of spindle formation were observed in all other cells, which included mono- (20%), tri (45%), and multipolar (30%) formations organized by mono-, tri-, and multipolar centrosome clusters. When cells were treated with 1.5 m formamide for 90 min, centrosomes became pulverized and fragmented and only monopolar mitotic formations were observed upon recovery. These results are highly reproducible and reveal that abnormalities in centrosome structure can lead to abnormal mitosis which is not caused by mutation or overexpression of centrosome proteins.     

Centrosome number is controlled by a centrosome-intrinsic block to reduplication

The centrosome duplicates once in S phase. To determine whether there is a block in centrosome reduplication, we used a cell fusion assay to compare the duplication potential of unduplicated G1 centrosomes and recently duplicated G2 centrosomes. By fusing cells in different cell cycle stages, we found that G2 centrosomes were unable to reduplicate in a cellular environment that supports centrosome duplication. Furthermore, G2 cytoplasm did not inhibit centrosome duplication in fused cells, indicating that the block to reduplication is intrinsic to the centrosomes rather than the cytoplasm. To test the underlying mechanism, we created mononucleate G1 cells with two centrosomes by fusing cells with enucleated cytoplasts. Both centrosomes duplicated, indicating that the block is not controlled by centrosome:nucleus ratio. We also found that human primary cells have tight control over centrosome number during prolonged S-phase arrest and that this control is partially abrogated in transformed cells. This suggests a link between the control of centrosome duplication and maintenance of genomic stability.     

Cdk2 plays a critical role in hepatocyte cell cycle progression and survival in the setting of cyclin D1 expression in vivo

Cdk2 was once believed to play an essential role in cell cycle progression, but cdk2-/- mice have minimal phenotypic abnormalities. In this study, we examined the role of cdk2 in hepatocyte proliferation, centrosome duplication, and survival. Cdk2-/- hepatocytes underwent mitosis and had normal centrosome content after mitogen stimulation. Unlike wild-type cells, cdk2-/- liver cells failed to undergo centrosome overduplication in response to ectopic cyclin D1 expression. After mitogen stimulation in culture or partial hepatectomy in vivo, cdk2-/- hepatocytes demonstrated diminished proliferation. Cyclin D1 is a key mediator of cell cycle progression in hepatocytes, and transient expression of this protein is sufficient to promote robust proliferation of these cells in vivo. In cdk2-/- mice and animals treated with the cdk2 inhibitor seliciclib, cyclin D1 failed to induce hepatocyte cell cycle progression. Surprisingly, cdk2 ablation or inhibition led to massive hepatocyte and animal death following cyclin D1 transfection. In a transgenic model of chronic hepatic cyclin D1 expression, seliciclib induced hepatocyte injury and animal death, suggesting that cdk2 is required for survival of cyclin D1-expressing cells even in the absence of substantial proliferation. In conclusion, our studies demonstrate that cdk2 plays a role in liver regeneration. Furthermore, it is essential for centrosome overduplication, proliferation, and survival of hepatocytes that aberrantly express cyclin D1 in vivo. These studies suggest that cdk2 may warrant further investigation as a target for therapy of liver tumors with constitutive cyclin D1 expression.