LZ—410盼生安对肝癌细胞细胞周期时相的影响及对DNA损伤效应…

ＬＺ－４１０盼生安是一种广谱抗肿瘤药物。本文以５－Ｆｕ作为阳性对照药物从对ＢＥＬ－７４０２肝癌细胞周期时相的影响及对ＤＮＡ损伤效应两个方面进行了初步探讨。结果表明,ＬＺ－４１０能将细胞阻滞在Ｇ０／Ｇ１期,抑制了细胞的生长增殖作用。并且在本实验条件下,ＬＺ－４１０并不引起ＤＮＡ的损伤。这表明ＬＺ－４１０抑制肝癌细胞生长增殖不是通过对ＤＮＡ损伤引起的,而主要是通过阻滞肿瘤细胞于Ｇ０／Ｇ１期实现的。     

芫菁体内结合斑蝥素对胃癌SGC-7901细胞增殖的抑制作用

本文考察了芫菁体内结合斑蝥素和人工合成的斑蝥素盐类衍生物斑蝥素酸镁的体外抗肿瘤活性。采用WST-1法检测两者在体外对人胃腺癌SGC-7901细胞增殖的抑制作用。实验结果显示两者对SGC-7901细胞均表现出明显的抑制效果,且随药物浓度升高其抑制作用增强,呈剂量效应关系;其半数抑制浓度(IC50)分别为10.86和8.65μmol/L。此外,通过流式细胞术检测表明,结合斑蝥素能引起SGC-7901细胞G0～G1期阻滞;斑蝥素酸镁则引起SGC-7901细胞S期阻滞,两者均能通过干预SGC-7901细胞的周期来抑制其增殖。     

合欢皮总皂苷对人微血管内皮细胞体外增殖的影响

研究合欢皮总皂苷对人微血管内皮细胞增殖的药效学影响。采用人脐静脉微血管内皮细胞HMEC-1作为研究模型,经不同剂量合欢皮总皂苷作用48、72 h后,应用SRB法、光学显微镜观察合欢皮总皂苷对HMEC-1细胞增殖、形态的影响;应用台盼蓝染色法、DNA梯形条带法、流式细胞仪PI单染方法分析合欢皮总皂苷对HMEC-1细胞生长的影响。实验结果发现合欢皮总皂苷提取物具有抑制血管内皮细胞增殖的作用,其与时间、剂量均存在依赖关系,作用48 h的IC50为1.5μg/mL;合欢皮总皂苷使HMEC-1细胞周期阻滞在亚G0/G1期,高剂量作用48 h后可能引起细胞产生坏死。因此,合欢皮总皂苷可能通过改变细胞周期,部分引起细胞坏死,从而抑制人微血管内皮细胞的增殖。     

HMBA诱导人肝癌SMMC-7721细胞分化的观察

本文研究HMBA对人肝癌SMMC-7721细胞的诱导分化作用.细胞生长曲线测定和细胞分裂指数观察显示HMBA可明显抑制细胞增殖,细胞生长抑制率达64.14%,分裂指数抑制率为53.88%.光镜和透射电镜观察可见HMBA能诱导人肝癌SMMG-7721细胞形态和超微结构发生恢复性改变.生化检测或免疫细胞化学方法观察显示,HM-BA处理后细胞γ.谷氨酸转肽酶(γ-GT)活性和甲胎蛋白(AFP)、增殖细胞核抗原(PCNA)表达均降低,而酪氨酸.酮戊二酸转氨酶(TAT)活性增强.流式细胞仪分析表明HMBA引起细胞发生G0/G1期阻滞.以上结果表明HMBA能有效抑制人肝癌细胞恶性增殖活性,逆转肝癌细胞恶性形态与超微结构特征,改变肝癌细胞相关酶活性和抗原表达,引发G0/G1期阻滞,从而对肝癌细胞具有明显的诱导分化作用.     

苜蓿素对人直肠癌SW1116细胞增殖和凋亡的作用及其机制

本文探讨苜蓿素对人直肠癌SW1116细胞增殖和凋亡的作用及其机制.采用MTr法检测苜蓿素对SW1116细胞生长的抑制作用;AO/EB染色后观察凋亡细胞形态;流式细胞术检测对细胞周期的影响;DNA片段化分析对细胞凋亡的作用;Westem blot检测对Bcl-2和Bax蛋白表达的影响.结果显示,苜蓿素可明显抑制SW1116细胞的增殖,呈剂量依赖性;AO/EB染色观察到给药组出现细胞凋亡特征;苜蓿素可阻滞细胞于G1/G1期和增加SW1116细胞凋亡率;凝胶成像分析仪检测到典型的DNA阶梯状条带;苜蓿素可呈剂量依赖地减弱Bcl-2和增强Bax蛋白表达.上述结果表明,苜蓿素可显著抑制人直肠癌SW1116细胞的增殖,使细胞阻滞于G1/G1期,并可诱导细胞凋亡,其机制可能与下调Bcl-2和上调Bax蛋白有关.     

沙利度胺通过诱导G1阻滞和凋亡抑制血管内皮细胞增殖

沙利度胺是一种抗血管生成药物,临床上用于治疗多种肿瘤,但其抗肿瘤血管生成机制尚不十分清楚. 本文采用MTT法观察沙利度胺对体外培养的血管内皮细胞增殖的影响. 结果发现,沙利度胺能够抑制血管内皮细胞的增殖,其IC50为16.47 μg/mL;然后采用Hoechst染色和流式细胞仪检测细胞凋亡和细胞周期,发现沙利度胺能够诱导内皮细胞凋亡,并干扰细胞的周期,出现G0/G1期阻滞. 最后,通过Western印迹方法分析沙利度胺对血管内皮细胞Bcl-2蛋白表达的影响,发现抗凋亡的Bcl-2蛋白表达水平随沙利度胺浓度增大而降低. 初步结果提示,沙利度胺可能通过阻遏抗凋亡分子Bcl-2表达,激活诱导G1期阻滞的信号通路而抑制内皮细胞新生,从而抑制肿瘤生长. 诱导内皮细胞凋亡及G1期阻滞的具体分子机制正在研究中.     

D609 对Neuro-2a 脑神经瘤细胞增殖和细胞周期的影响

目的:探讨小分子化合物D609对脑神经瘤细胞Neuro-2a的生长抑制及诱导细胞周期阻滞的效应,并初步研究其机制。方法:采用CCK-8法检测D609对Neuro-2a细胞的生长抑制作用;利用流式细胞术(FACS)检测D609处理对细胞周期进程的影响;利用免疫印迹实验(Western blot)检测不同浓度的D609处理后,细胞裂解液中细胞周期蛋白抑制因子p27的表达水平。结果:CCK-8的实验结果显示,加入150μmol/L D609处理72小时后,细胞生长受到明显地抑制,且伴有剂量依赖效应;流式细胞术的结果表明,D609处理使细胞周期阻滞在G0/G1期;免疫印迹的结果表明药物处理提升了p27的表达,且随药物浓度升高其表达亦增强。结论:D609可以有效地抑制Neuro-2a细胞的生长;进一步研究表明药物处理可以提升p27的表达水平并可以诱导将细胞阻滞在G0/G1期。因此,此研究将为脑神经瘤的治疗提供借鉴。     

过表达Nogo-C对PC12细胞存活及增殖的影响

以PC12细胞为神经元细胞模型,研究Nogo-C对神经元细胞存活及增殖的作用。在PC12细胞中转染过表达Nogo-C,使用G418药物筛选以获得稳定表达的细胞克隆,利用Hoechst33342染色、细胞计数、MTT以及流式细胞仪等技术检测Nogo-C对细胞增殖以及细胞周期的影响。结果表明:(1)Hoechst33342染色未观察到表达Nogo-C的细胞发生明显凋亡;(2)细胞计数及MTT实验观察到转染Nogo-C后的PC12细胞生长增殖活性明显降低;(3)流式细胞仪检测细胞生长周期,正常PC12细胞G1期的百分数为(37.8±7.9)%,S期为(50.4±8.5)%,而转染Nogo-C的PC12细胞G1期为(76.8±4.1)%,S期为(14.7±1.7)%,提示转染Nogo-C的PC12细胞的细胞周期被阻滞在G1期;(4)没有获得稳定表达Nogo-C的PC12细胞模型。实验证明,过表达Nogo-C通过使PC12细胞周期被阻滞在G1期而明显抑制细胞的增殖,但是并不引起细胞的凋亡。     

CEACAM1异常表达对白血病BALL-1细胞增殖的影响

通过si RNA技术抑制癌胚抗原相关粘附分子CEACAM1在人急性B淋巴细胞白血病细胞系BALL-1中的表达,体外实验研究异常表达于白血病B细胞的CEACAM1对细胞增殖的影响。应用CCK-8法测定细胞增殖发现CEACAM1表达下调后BALL-1细胞的增殖能力明显下降。细胞周期分析结果显示CEACAM1被抑制后细胞增殖状态表现为S期细胞百分比降低,G0/G1期细胞比例升高,提示CEACAM1表达下调是通过引起细胞周期停滞在G0/G1期来降低细胞增殖的,表明CEACAM1本身对白血病B细胞具有促进增殖的作用。     

丙戊酸钠抑制A549细胞生长

目的研究丙戊酸钠对肺癌A549细胞增殖和细胞周期的影响。方法MTT检测生长抑制,流式细胞仪检测细胞周期和凋亡,Western blot检测p21WAF1/CIP1蛋白表达。结果丙戊酸钠以剂量依赖性方式抑制A549细胞生长;丙戊酸钠上调G0/G1期比例,下调S期和G2/M期,不影响细胞凋亡;丙戊酸钠上调p21WAF1/CIP1蛋白表达。结论丙戊酸钠上调p21WAF1/CIP1表达,使细胞阻滞于G0/G1期,抑制A549细胞生长。     

Interaction between radiation and drug damage in mammalian cells. VI. Radiation and doxorubicin age-response function of doxorubicin-sensitive and -resistant Chinese hamster cells.

A comparative study of the radiation and/or doxorubicin (DOX) survival response for synchronous populations of Chinese hamster V79 cells and two DOX-resistant variants (77A and LZ-8) was performed. The greatest cellular radiation sensitivity was observed in mitosis, while the greatest resistance was observed during late S phase for the three cell lines. The variation in radiation response throughout the cell cycle was expressed as a change in the width of the shoulder of the survival curves (Dq) with little change in D0. This suggests that each phase of the cell cycle has a different capacity for accumulation of radiation injury. The radiation age-response function for the three cell lines revealed that 77A and LZ-8 cells were more radiosensitive than V79 cells throughout the cell cycle. Exposure of synchronous populations to DOX (1.84 microM for V79, 9.21 microM for 77A, and 921 microM for LZ-8) for 1 h as a function of cell cycle phase revealed that V79, 77A, and LZ-8 cells exhibited the greatest sensitivity to DOX in mitosis and the most resistance to DOX during S phase, as indicated by the differences in the slope of the initial component of the survival curve. Levels of P-glyco-protein (P-gp) are probably not a factor contributing to DOX age-response function since P-gp levels remain constant throughout the cell cycle in all three cell lines. Synchronous populations of V79, 77A, and LZ-8 cells sequentially treated with DOX and radiation at various cell cycle phases were also analyzed. The results showed that the interaction between radiation and DOX damage resulted in a reduced cellular capacity for the accumulation of radiation damage throughout the cell cycle, as indicated by a decrease in the width of the shoulder of the survival curve. Overall, both DOX-sensitive V79 cells and DOX-resistant 77A and LZ-8 cells exhibited (1) a similar age-response function for radiation or DOX, and (2) no differences in the effects of DOX on radiation-induced damage throughout the cell cycle. These results indicate that acquired resistance to DOX associated with increased levels of P-gp in the cell membrane did not appear to affect the age-response function for radiation or DOX, and the nature of the interaction between damage caused by radiation and DOX was also not affected.     

The relationship of DNA and chromosome damage to survival of synchronized X-irradiated L5178Y cells. I. Initial damage

We investigated the role of initial DNA and chromosome damage in determining the radiosensitivity difference between the variant murine leukemic lymphoblast cell lines L5178Y-S (sensitive) and L5178Y-R (resistant) and the difference in cell cycle-dependent variations in radiosensitivity of L5178Y-S cells. We measured initial DNA damage (by the neutral filter elution method) and chromosome damage (by the premature chromosome condensation method) and compared them with survival (measured by cloning) for both cell lines synchronized in G1 or G2 phase of the cell cycle (by centrifugal elutriation) and irradiated with low doses of X rays (up to 10 Gy). The initial yield of DNA and chromosome damage in G2 L5178Y-S cells was almost twice that in G1 L5178Y-S cells and G1 or G2 L5178Y-R cells. In all cases DNA damage expressed as relative elution corresponded with chromosome damage (breaks in G1 chromosomes, breaks and gaps in G2 chromosomes). Also we found that the initial DNA and chromosome damage did not determine cell age-dependent radiosensitivity variations in L5178Y-S cells, as there was less initial damage in the more sensitive G1 phase than in the G2 phase. L5178Y-R cells showed only small changes in survival or initial yield of DNA and chromosome damage throughout the cell cycle. Because survival and initial damage in sensitive and resistant cells irradiated in G2 phase correlated, the difference in radiosensitivity between L5178Y-S and L5178Y-R cells might be determined by initial damage in G2 phase only.     

A role for homologous recombination proteins in cell cycle regulation

Eukaryotic cells respond to DNA breaks, especially double-stranded breaks (DSBs), by activating the DNA damage response (DDR), which encompasses DNA repair and cell cycle checkpoint signaling. The DNA damage signal is transmitted to the checkpoint machinery by a network of specialized DNA damage-recognizing and signal-transducing molecules. However, recent evidence suggests that DNA repair proteins themselves may also directly contribute to the checkpoint control. Here, we investigated the role of homologous recombination (HR) proteins in normal cell cycle regulation in the absence of exogenous DNA damage. For this purpose, we used Chinese Hamster Ovary (CHO) cells expressing the Fluorescent ubiquitination-based cell cycle indicators (Fucci). Systematic siRNA-mediated knockdown of HR genes in these cells demonstrated that the lack of several of these factors alters cell cycle distribution, albeit differentially. The knock-down of MDC1, Rad51 and Brca1 caused the cells to arrest in the G2 phase, suggesting that they may be required for the G2/M transition. In contrast, inhibition of the other HR factors, including several Rad51 paralogs and Rad50, led to the arrest in the G1/G0 phase. Moreover, reduced expression of Rad51B, Rad51C, CtIP and Rad50 induced entry into a quiescent G0-like phase. In conclusion, the lack of many HR factors may lead to cell cycle checkpoint activation, even in the absence of exogenous DNA damage, indicating that these proteins may play an essential role both in DNA repair and checkpoint signaling.     

Analysis of DNA oxidative damage related to cell proliferation

In vivo and in vitro cell populations exhibit a different sensitivity and a heterogeneous response to many genotoxic agents. Several studies have been carried out to evaluate the possibility that the different sensitivity of the cells is related to their proliferative status. In this study, the sensitivity of proliferating (P) and quiescent (Q) C3H10T1/2 cells to oxidative damage and their repair capability has been investigated by single cell gel electrophoresis (SCGE) and micronucleus test. Furthermore the possibility to simultaneously detect DNA damage and cell cycle position has been evaluated. Our results showed a dose-related increase of DNA damage in exponential and plateau phase cells treated with hydrogen peroxide (doses ranging between 2.5 and 100 microM). DNA damage was almost completely repaired within 2 h after treatment in both culture conditions. The percentage of cells in the various phases of the cell cycle has been determined by comet assay and by flow cytometry, and a good agreement between the results of the two techniques was found. Untreated exponentially growing cells in G1 phase showed a lower tail moment than S and G2/M cells. The same cell cycle dependence was evidenced in cells treated with low doses of H(2)O(2), while, at the higher doses, all cells showed a similar level of damage. These results confirm the sensitivity of the Comet Assay in assessing DNA damage, and support its usefulness in evaluating cell cycle-related differential sensitivity to genotoxic agents.     

Cyclin D1 expression and cell cycle response in DNA mismatch repair-deficient cells upon methylation and UV-C damage

We have evaluated cell survival, apoptosis, and cell cycle responses in a panel of DNA mismatch repair (MMR)-deficient colon and prostate cancer cell lines after alkylation and UV-C damage. We show that although these MMR-deficient cells tolerate alkylation damage, they are as sensitive to UV-C-induced damage as are the MMR-proficient cells. MMR-proficient cells arrest in the S-G2 phase of the cell cycle and initiate apoptosis following alkylation damage, whereas MMR-deficient cells continue proliferation. However, two prostate cancer cell lines that are MMR-deficient surprisingly arrest transiently in S-G2 after alkylation damage. Progression through G1 phase initially depends on the expression of one or more of the D-type cyclins (D1, D2, and/or D3). Analysis of cyclin D1 expression shows an initial MMR-independent decrease in the protein level after alkylation as well as UV-C damage. At later time points, however, only DNA damage-arrested cells showed decreased cyclin D1 levels irrespective of MMR status, indicating that reduced cyclin D1 could be a result of a smaller fraction of cells being in G1 phase rather than a result of an intact MMR system. Finally, we show that cyclin D1 is degraded by the proteasome in response to alkylation damage.     

Polo-like kinase 1 inactivation following mitotic DNA damaging treatments is independent of ataxia telangiectasia mutated kinase

Polo-like kinase 1 (Plk1) is an important regulator of several events during mitosis. Recent reports show that Plk1 is involved in both G2 and mitotic DNA damage checkpoints. Ataxia telangiectasia mutated kinase (ATM) is an important enzyme involved in G2 phase cell cycle arrest following interphase DNA damage, and inhibition of Plk1 by DNA damage during G2 occurs in an ATM-/ATM-Rad3-related kinase (ATR)-dependent fashion. However, it is unclear how Plk1 is regulated in response to M phase DNA damage. We found that treatment of mitotic cells with DNA damaging agents inhibits Plk1 activity primarily through dephosphorylation of Plk1, which occurred in both p53 wild-type and mutant cells. Inhibition of Plk1 is not prevented by caffeine pretreatment that inhibits ATM activity and also occurs in ATM mutant cell lines. Furthermore, ATM mutant cell lines, unlike wild-type cells, fail to arrest after mitotic DNA damaging treatments. The phosphatidylinositol 3-kinase (PI3K) inhibitor, LY294002, reduces Plk1 dephosphorylation following mitotic DNA damaging treatments, suggesting that the PI3K pathway may be involved in regulating Plk1 activity. Earlier studies showed that inhibition of Plk1 by G2 DNA damage occurs in an ATM-dependent fashion. Our results extend the previous studies by showing that ATM is not required for dephosphorylation and inhibition of Plk1 activity following mitotic DNA damage, and also suggest that Plk1 is not a principal regulator or mediator of the mitotic DNA damage response.     

Flow cytometric analysis of unbalanced control of protein accumulation and DNA synthesis in differentiating mouse myeloid leukemia cells

The protein and DNA contents of mouse myeloid leukemia M1 (clone B24) cells were determined by flow cytometry (FCM) after double fluorescent staining of the cells with fluorescein isothiocyanate and propidium iodide. FCM analysis showed that there was a linear relationship between the DNA and protein contents in logarithmically growing cells, although the protein content showed some variation. B24 cells can be induced to differentiate into macrophage-like cells by treatment with a protein inducer(s) in conditioned medium (CM) of hamster embryo cells. When the cells were treated with various concentrations of CM, cells with a 2C DNA content, G1/0 cells, increased and protein accumulated in these G1/0 cells. The increases in the number of G1/0 cells and in their protein content per cell were proportional to the concentration of CM. Serial analysis of changes in the contents of DNA and protein in differentiating B24 cells showed that DNA synthesis was suppressed by differentiation-induced block of the cell cycle at the G1/0 phase, whereas increase in the protein content was not completely suppressed by block of the cell cycle. These results suggest that unbalanced control of the DNA and protein contents of B24 cells is involved in the mechanisms of the morphological changes during differentiation into macrophages.     

The presence of G1 and G2 populations in normal epithelium of rat urinary bladder

The cell population kinetics of transitional epithelium of the rat urinary bladder was analysed by (3H) thymidine autoradiography and pararosanilin Feulgen DNA cytofluorometry. By flash and 72 h continuous DNA labelling, the generative cells of the transitional epithelium were found to be well localized in the basal layer, and it was postulated that che cells produced by cell proliferation in the basal layer would migrate towards the surface, maintaining direct attachment to the basement membrane by anchorage of a cellular process. Analyses of normal and wounded transitional epithelium revealed that 58.8% of all basal cells are G0 cells in G1 phase (G1-population), and 59.0% of the remaining basal cells reside in prolonged (75.1-108.0 h) G2 phase, preserving the ability to divide (G2-population). The cell cycle time of the generative basal cells including the long G2 phase was calculated as 129.1-162 h. All the cells existing in upper layers were found to be also G0 cells in G1 phase, with the DNA amounts of 2C class. No polyploid cells could be detected except for 2C-2C binucleated cells in the superficial layer. The existence of a G2-population may serve for the urgent need of cell incrementation to repair cell loss as the cells in G2 phase can divide without the time-delay needed for DNA synthesis. The rat transitional epithelium, which is composed exclusively of proliferating and potentially proliferative cells, will have much greater capability to repair damage than stratified squamous epithelia.     

Effects of p21 Gene Down-Regulation through RNAi on Antler Stem Cells In Vitro

Cell cycle is an integral part of cell proliferation, and consists mainly of four phases, G1, S, G2 and M. The p21 protein, a cyclin dependent kinase inhibitor, plays a key role in regulating cell cyclevia G1 phase control. Cells capable of epimorphic regeneration have G2/M accumulation as their distinctive feature, whilst the majority of somatic cells rest at G1 phase. To investigate the role played byp21 in antler regeneration, we studied the cell cycle distribution of antler stem cells (ASCs), via down-regulation of p21 in vitro using RNAi. The results showed that ASCs had high levels of p21 mRNA expression and rested at G1 phase, which was comparable to the control somatic cells. Down-regulation of p21 did not result in ASC cell cycle re-distribution toward G2/M accumulation, but DNA damage and apoptosis of the ASCs significantly increased and the process of cell aging was slowed. These findings suggest that the ASCs may have evolved to use an alternative, p21-independent cell cycle regulation mechanism. Also a unique p21-dependent inhibitory effect may control DNA damage as a protective mechanism to ensure the fast proliferating ASCs do not become dysplastic/cancerous. Understanding of the mechanism underlying the role played by p21 in the ASCs could give insight into a mammalian system where epimorphic regeneration is initiated whilst the genome stability is effectively maintained.     

Cell-cycle-dependent turnover of P-glycoprotein in multidrug-resistant cells

Regulation of P-glycoprotein (Pgp) expression occurs not only at the DNA and mRNA level but also at the protein level. We showed previously that Pgp was stabilized when multidrug-resistant CH(R)C5 and SKVCR 2.0 ovarian cell lines were subjected to serum-starved or high-cell-density growth conditions, whereas Pgp turnover in a leukemic multidrug-resistant cell line, CEMVLB0.1, was not affected by serum starvation (Muller et al., 1995). On further analysis, we have observed that the majority of the CH(R)C5 and SKVCR 2.0 cells under these conditions were in the G1/G0 phase of the cell cycle, whereas the cell cycle of CEMVLB0.1 cells was not affected. Pgp in CEMVLB0.1 cells was stabilized only when the cell cycle was delayed in the G1/G0 phase by using amino acid-deficient growth medium. In CH(R)C5 cells, Pgp half-life was also considerably increased when the cell cycle of these ovary-derived cells was delayed in the G1/G0 phase by using high concentrations of progesterone under normal serum growth conditions. In contrast, Pgp stability was not greatly affected if these cells were delayed in the S or G2/M phase of the cell cycle with Ara-C, cisplatin, or colchicine under the same conditions. Insulin-like growth factors could release the serum-starved CH(R)C5 and SKVCR2.0 cells from the G1/G0 phase and destabilized Pgp. These results indicate that Pgp turnover is a cell-cycle-related process in MDR cells.