中药复方BBYNG对乳腺癌骨转移小鼠的作用观察

目的透过对中药复方BBYNG与西药双磷酸盐OSTAC的动物实验研究,观察中药治疗骨转移的疗效。方法参照文献建立高发骨转移的小鼠乳腺癌动物模型后,分别对不同组别的荷瘤小鼠灌喂相当于临床病人服用剂量的BBYNG或OSTAC,对比观察荷瘤小鼠的肿瘤生长、活动状态、生存时间、骨转移及骨破坏的程度等。结果BBYNG可减慢荷瘤小鼠的肿瘤生长,但不能显著缩小肿瘤的体积;可减轻肿瘤骨转移引起的活动障碍和骨破坏,延长生存时间。此结果与作者已进行的临床观察结果相似。结论BBYNG有减轻动物模型肿瘤引起的骨转移和骨破坏、延长荷瘤小鼠生存时间的作用;值得推广应用及开展用于预防肿瘤骨转移的探讨,并深化对其作用机理的研究。     

乳腺癌实验动物模型的制备与应用

乳腺癌实验动物模型在研究人类乳腺癌的生物学行为及治疗等方面起着非常重要的作用。根据制备方法及研究目的的不同,乳腺癌实验动物模型可分为自发性、诱发性、移植性、转基因性及乳腺癌骨转移等动物模型,每种动物模型都有各自的特点和应用条件。     

肿瘤细胞和骨微环境在骨转移中的作用

随着肿瘤治疗水平的提高,肿瘤患者的生存期显著延长,转移性骨肿瘤的发生率呈增长趋势.骨转移引起的剧烈的临床症状和其较长的潜伏期,以及缺乏有效的治疗方法,极大降低了患者的生活质量.本文主要综述了骨转移相关的细胞特征及骨微环境在骨转移中的作用,并分析了影响骨转移形成的相关分子因素,为骨转移的定向分子治疗提供进一步的理论依据.     

CA19-9、CA125、CEA及Ferritin联合检测诊断非小细胞肺癌脑、骨转移的临床价值研究

目的:研究CA19-9、CA125、癌胚抗原(CEA)以及铁蛋白(Ferritin)四种肿瘤标志物联合检测用于诊断非小细胞肺癌(NSCLC)脑或(和)骨转移的临床价值。方法:选取2011年5月至2012年5月于我院就诊的NSCLC患者184例。将发现脑或(和)骨转移者归为转移组,共96例;将未发现脑、骨转移者归为无转移组,共88例,采用电化学发光免疫分析法测定各组患者血清中CA19-9、CA125、CEA以及Ferritin的水平,探讨其在NSCLC患者脑或(和)骨转移中的诊断效能。结果:在发生脑或(和)骨转移的NSCLC患者中,CA19-9、CA125、CEA及Ferritin四种肿瘤标志物的水平和阳性率均显著高于未发生骨、脑转移的患者。ROC曲线分析显示,以上四种肿瘤标志物对诊断NSCLC骨或(和)脑转移的敏感度分别为73.48%、69.13%、66.35%和61.34%;特异度分别为80.02%、32.51%、65.11%和62.58%;将四种肿瘤标志物联合进行诊断的敏感度和特异度分别为91.21%和88.64%,显著高于单一标志物诊断。结论:发生脑或(和)骨转移的NSCLC患者血清中CA19-9、CA125、CEA以及Ferritin四种肿瘤标志物水平均显著升高,以上标志物联合检测可提高NSCLC患者脑或(和)骨转移的诊断效能,可作为早期诊断NSCLC患者脑或(和)骨转移的辅助检测指标。     

人乳腺癌MCF-7细胞在放射线处理的SCID小鼠中转移的实验研究

目的建立人乳腺癌MCF-7细胞SCID(Severe combined immunodeficiency,SCID)小鼠转移动物模型。方法采用人乳腺癌细胞株MCF-7细胞悬液,分别接种于5只经放射线处理的SCID小鼠腋背部皮下。记录肿瘤生长情况,处死荷瘤鼠并做病理切片,观察各脏器转移情况。结果接种SCID小鼠后6～10d成瘤,成瘤率为5/5只,潜伏期平均(7.4±1.3)d。接种后5只鼠分别于第60～68天拉颈处死,检测荷瘤,平均直径为(26.6±2.2)mm,平均重量为5.28g。病理学检查,转移脏器有3个部位,出现肺转移的为4/5只、骨转移的为3/5只和淋巴结转移的为1/5只。结论建立了人乳腺癌SCID小鼠转移动物模型,该模型可为肿瘤转移研究提供重要的实验工具。     

DLC1在肿瘤进程中的新角色

原发肿瘤向重要器官,如骨、肺、脑、肝等的转移是恶性肿瘤患者死亡的主要原因。对于女性而言,乳腺癌是发病率较高的一类恶性肿瘤。早期乳腺癌通过合理治疗可实现根治,但晚期会发生原位癌向多器官的转移。其中,大约70%的晚期乳腺癌会发生骨转移。在乳腺癌骨转移过程中,转化生长因子β(TGFβ)-甲状旁腺激素样激素(PTHLH)通路发挥着关键性的调控作用,但对这一通路活性本身受哪些因子的影响方面现在知之甚少。因此,中国科学院上海生命科学研究院健康科学研究所胡国宏课题组利用多种肿瘤转移模型,探索影响TGFβ-PTHLH通路活性的因素,最终发现DLC1在乳腺癌骨转移过程中起关键性的负调控作用。DLC1功能的行使依赖于它失活RHO-ROCK通路,继而抑制TGFβ诱导的SMAD3连接区磷酸化。DLC1对后者的抑制降低了TGFβ诱导的PTHLH的转录和分泌,从而减少了骨转移微环境中的成熟破骨细胞,最终阻碍了乳腺癌的破骨性转移。该项研究首次证明DLC1-RHO信号通路在调控乳腺癌骨转移微环境中具有重要作用,也为临床上治疗乳腺癌骨转移提供了新思路。     

Noggin抑制乳腺癌溶骨性骨转移的作用研究

该文主要研究头蛋白(Noggin)抑制乳腺癌溶骨性骨转移的可能作用机制。通过体外慢病毒感染的方法,将Noggin慢病毒感染乳腺癌MDA-MB-231细胞, Western blot检测Noggin表达情况,利用CCK8和流式细胞术检测细胞增殖和周期改变, Western blot检测BMPs/SMAD信号通路变化和PI3K/Akt/mTOR关键分子Akt和m TOR总的蛋白和磷酸化蛋白的改变,裸鼠胫骨贴骨注射乳腺癌细胞复制骨转移动物模型,通过X片检测Noggin对乳腺癌溶骨性骨缺损的影响,免疫组化检测乳腺癌骨转移组织中Akt总的蛋白、磷酸化蛋白以及细胞核增殖抗原PCNA的改变。Noggin组的Noggin蛋白表达明显升高, Noggin慢病毒感染MDA-MB-231细胞第3天, CCK8检测其吸光度值为(0.452±0.059),显著低于RFP组(0.683±0.064),并且将细胞周期阻滞在G1期; Western blot显示Akt和mTOR总的蛋白未发生改变、磷酸化蛋白表达明显降低;乳腺癌溶骨性骨转移动物模型中Noggin组的溶骨性缺损明显低于RFP组,免疫组化结果显示PI3K/Akt/mTOR中关键分子Akt磷酸化蛋白、PCNA表达明显降低。Noggin可能通过抑制PI3K/Akt/mTOR通路的激活来抑制乳腺癌的溶骨性骨转移。     

亲骨转移乳腺癌细胞MDA-MB-231BO成瘤性的初步研究

目的通过比较亲骨转移乳腺癌细胞（MDA-MB-231BO）和亲代乳腺癌细胞（MDA-MB-231）的生长曲线和致瘤性,初步探讨MDA-MB-231BO细胞的生物学特性。方法MTT法测定两种细胞的生长曲线,并将两种乳腺癌细胞接种于裸鼠腋窝处皮下,建立乳腺癌细胞异种移植瘤动物模型,30 d后处死裸鼠,肿瘤组织及相关脏器官做病理检查。结果MTT法测得MDA-MB-231BO细胞生长速率高于MDA-MB-231细胞。接种两种乳腺癌细胞的裸鼠均长出肿瘤,成瘤率为100%。病理检查符合人乳腺癌细胞特征,MDA-MB-231BO组瘤体体积明显大于MDA-MB-231组（P〈0.05）。结论MDA-MB-231BO细胞生长速率高于MDA-MB-231细胞,而且MDA-MB-231BO在裸鼠体内的致瘤性强于MDA-MB-231。     

SD大鼠与Wistar大鼠脑胶质瘤动物模型的建立及比较

目的比较利用SD大鼠、Wistar大鼠建立脑胶质瘤动物模型的不同,为研究脑胶质瘤的发病机制及治疗方法提供操作平台。方法利用立体定向仪建立SD大鼠、Wistar大鼠大脑皮层接种C6细胞（2.5×105个细胞/只）,建立脑胶质瘤动物模型,利用组织病理学、免疫组织化学以及核磁共振成像等技术,比较两种动物模型在成瘤率、肿瘤生长状况、死亡率以及动物一般情况等方面的异同。结果SD大鼠组、Wistar大鼠组的成瘤率均为100%,两组均未见转移;但SD大鼠组肿瘤成瘤时间较长,且部分肿瘤有自愈倾向,而Wistar大鼠组则未出现类似情况。结论Wistar大鼠大脑皮层脑胶质瘤动物模型的肿瘤性状更接近于人的脑胶质瘤,因此更适合探索和研究脑胶质瘤的发病机制和治疗方法;而SD大鼠的肿瘤由于性状类似转移瘤,且有自愈倾向,不适合作为上述相关研究的动物模型。     

唑来膦酸联合99Tc-MDP治疗肿瘤多发骨转移的临床价值

目的:探讨唑来膦酸联合99Tc-MDP(云克)治疗多发骨转移瘤的临床价值.方法:将40例确诊为肿瘤伴骨转移的病人,随机分为两组.观察组22例,使用唑来膦酸联合99Tc-MDP治疗;对照组18例,单独使用99Tc-MDP治疗,均治疗3周后比较两组治疗前后骨痛的变化情况、骨转移灶的治疗情况及不良反应的发生情况.结果:观察组和对照组的止痛总有效率分另为95.5％和66.7％,差异有统计学意义(P＜0.05).观察组和对照组骨转移灶的治疗总有效率分别为36.3％和27.7％,差异有统计学意义(P＜0.05).此外,两组治疗过程中均偶见不同程度的发热,但不良反应的发生率并无统计学差异(P＞0.05).结论:唑来膦酸联合99Tc-MDP治疗多发骨转移瘤的止痛效果及骨转移灶的疗效显著优于单纯99Tc-MDP治疗,且毒副作用无明显增加.     

微流控芯片在乳腺癌骨转移研究中的应用

乳腺癌骨转移患者死亡率高达70%～80%,目前缺乏有效的治疗药物.微流控芯片技术能够有效模拟骨组织的生化和生物物理微环境,便捷地实现模拟骨微环境中乳腺癌骨转移的研究,这将为探索乳腺癌骨转移的细胞和分子机制、进而进行抗乳腺癌骨转移药物高通量筛选提供有价值的技术方法和平台.本综述简要介绍了乳腺癌骨转移的分子机制和治疗药物研究现状,详细阐述了乳腺癌骨转移的微流控芯片模型,分析了基于微流控芯片技术进行抗乳腺癌骨转移药物高通量筛选的优势和挑战,旨在为乳腺癌骨转移机制研究和药物筛选提供参考.     

Enpp1: A Potential Facilitator of Breast Cancer Bone Metastasis

Bone is the most common site of breast cancer metastasis and once established, it is frequently incurable. Critical to our ability to prevent and treat bone metastasis is the identification of the key factors mediating its establishment and understanding their biological function. To address this issue we previously carried out an in vivo selection process to isolate murine mammary tumor sublines possessing an enhanced ability to colonize the bone. A comparison of gene expression between parental cells and sublines by genome-wide cDNA microarray analysis revealed several potential mediators of bone metastasis, including the pyrophosphate-generating ectoenzyme Enpp1. By qRT-PCR and Western analysis we found that expression of Enpp1 was elevated in human breast cancer cell lines known to produce bone metastasis in animal models compared to non-metastatic and normal mammary epithelial cell lines. Further, in clinical specimens, levels of Enpp1 were significantly elevated in human primary breast tumors relative to normal mammary epithelium, with highest levels observed in breast-bone metastasis as determined by qRT-PCR and immunohistochemical analysis. To examine the potential role of Enpp1 in the development of bone metastasis, Enpp1 expression was stably increased in the breast cancer cell line MDA-MB-231 and the ability to colonize the bone following intracardiac and direct intratibial injection of athymic nude mice was determined. By both routes of administration, increased expression of Enpp1 enhanced the ability of MDA-MB-231 cells to form tumors in the bone relative to cells expressing vector alone, as determined by digital radiography and histological analysis. Taken together, these data suggest a potential role for Enpp1 in the development of breast cancer bone metastasis.     

Small molecules inhibit ex vivo tumor growth in bone

Bone is a common site of metastasis for breast, prostate, lung, kidney and other cancers. Bone metastases are incurable, and substantially reduce patient quality of life. To date, there exists no small-molecule therapeutic agent that can reduce tumor burden in bone. This is partly attributed to the lack of suitable in vitro assays that are good models of tumor growth in bone. Here, we take advantage of a novel ex vivo model of bone colonization to report a series of pyrrolopyrazolone small molecules that inhibit cancer cell invasion and ex vivo tumor growth in bone at single-digit micromolar concentration. We find that the compounds modulated the expression levels of genes associated with bone-forming osteoblasts, bone-destroying osteoclasts, cancer cell viability and metastasis. Our compounds provide chemical tools to uncover novel targets and pathways associated with bone metastasis, as well as for the development of compounds to prevent and reverse bone tumor growth in vivo.     

Cancer Cell Expression of Autotaxin Controls Bone Metastasis Formation in Mouse through Lysophosphatidic Acid-Dependent Activation of Osteoclasts

Background

Bone metastases are highly frequent complications of breast cancers. Current bone metastasis treatments using powerful anti-resorbtive agents are only palliative indicating that factors independent of bone resorption control bone metastasis progression. Autotaxin (ATX/NPP2) is a secreted protein with both oncogenic and pro-metastatic properties. Through its lysosphospholipase D (lysoPLD) activity, ATX controls the level of lysophosphatidic acid (LPA) in the blood. Platelet-derived LPA promotes the progression of osteolytic bone metastases of breast cancer cells. We asked whether ATX was involved in the bone metastasis process. We characterized the role of ATX in osteolytic bone metastasis formation by using genetically modified breast cancer cells exploited on different osteolytic bone metastasis mouse models.

Methodology/Principal Findings

Intravenous injection of human breast cancer MDA-B02 cells with forced expression of ATX (MDA-B02/ATX) to inmmunodeficiency BALB/C nude mice enhanced osteolytic bone metastasis formation, as judged by increased bone loss, tumor burden, and a higher number of active osteoclasts at the metastatic site. Mouse breast cancer 4T1 cells induced the formation of osteolytic bone metastases after intracardiac injection in immunocompetent BALB/C mice. These cells expressed active ATX and silencing ATX expression inhibited the extent of osteolytic bone lesions and decreased the number of active osteoclasts at the bone metastatic site. In vitro, osteoclast differentiation was enhanced in presence of MDA-B02/ATX cell conditioned media or recombinant autotaxin that was blocked by the autotaxin inhibitor vpc8a202. In vitro, addition of LPA to active charcoal-treated serum restored the capacity of the serum to support RANK-L/MCSF-induced osteoclastogenesis.

Conclusion/Significance

Expression of autotaxin by cancer cells controls osteolytic bone metastasis formation. This work demonstrates a new role for LPA as a factor that stimulates directly cancer growth and metastasis, and osteoclast differentiation. Therefore, targeting the autotaxin/LPA track emerges as a potential new therapeutic approach to improve the outcome of patients with bone metastases.     

Autophagy provides a conceptual therapeutic framework for bone metastasis from prostate cancer

Prostate cancer is a common malignant tumor, which can spread to multiple organs in the body. Metastatic disease is the dominant reason of death for patients with prostate cancer. Prostate cancer usually transfers to bone. Bone metastases are related to pathologic fracture, pain, and reduced survival. There are many known targets for prostate cancer treatment, including androgen receptor (AR) axis, but drug resistance and metastasis eventually develop in advanced disease, suggesting the necessity to better understand the resistance mechanisms and consider multi-target medical treatment. Because of the limitations of approved treatments, further research into other potential targets is necessary. Metastasis is an important marker of cancer development, involving numerous factors, such as AKT, EMT, ECM, tumor angiogenesis, the development of inflammatory tumor microenvironment, and defect in programmed cell death. In tumor metastasis, programmed cell death (autophagy, apoptosis, and necroptosis) plays a key role. Malignant cancer cells have to overcome the different forms of cell death to transfer. The article sums up the recent studies on the mechanism of bone metastasis involving key regulatory factors such as macrophages and AKT and further discusses as to how regulating autophagy is crucial in relieving prostate cancer bone metastasis.Subject terms: Cancer models, Prostate cancer     

NF-kappaB in breast cancer cells promotes osteolytic bone metastasis by inducing osteoclastogenesis via GM-CSF

Advanced breast cancers frequently metastasize to bone, resulting in osteolytic lesions, yet the underlying mechanisms are poorly understood. Here we report that nuclear factor-kappaB (NF-kappaB) plays a crucial role in the osteolytic bone metastasis of breast cancer by stimulating osteoclastogenesis. Using an in vivo bone metastasis model, we found that constitutive NF-kappaB activity in breast cancer cells is crucial for the bone resorption characteristic of osteolytic bone metastasis. We identified the gene encoding granulocyte macrophage-colony stimulating factor (GM-CSF) as a key target of NF-kappaB and found that it mediates osteolytic bone metastasis of breast cancer by stimulating osteoclast development. Moreover, we observed that the expression of GM-CSF correlated with NF-kappaB activation in bone-metastatic tumor tissues from individuals with breast cancer. These results uncover a new and specific role of NF-kappaB in osteolytic bone metastasis through GM-CSF induction, suggesting that NF-kappaB is a potential target for the treatment of breast cancer and the prevention of skeletal metastasis.     

Anti-transforming growth factor ß antibody treatment rescues bone loss and prevents breast cancer metastasis to bone

Breast cancer often metastasizes to bone causing osteolytic bone resorption which releases active TGFβ. Because TGFβ favors progression of breast cancer metastasis to bone, we hypothesized that treatment using anti-TGFβ antibody may reduce tumor burden and rescue tumor-associated bone loss in metastatic breast cancer. In this study we have tested the efficacy of an anti-TGFβ antibody 1D11 preventing breast cancer bone metastasis. We have used two preclinical breast cancer bone metastasis models, in which either human breast cancer cells or murine mammary tumor cells were injected in host mice via left cardiac ventricle. Using several in vivo, in vitro and ex vivo assays, we have demonstrated that anti-TGFβ antibody treatment have significantly reduced tumor burden in the bone along with a statistically significant threefold reduction in osteolytic lesion number and tenfold reduction in osteolytic lesion area. A decrease in osteoclast numbers (p?=?0.027) in vivo and osteoclastogenesis ex vivo were also observed. Most importantly, in tumor-bearing mice, anti-TGFβ treatment resulted in a twofold increase in bone volume (p<0.01). In addition, treatment with anti-TGFβ antibody increased the mineral-to-collagen ratio in vivo, a reflection of improved tissue level properties. Moreover, anti-TGFβ antibody directly increased mineralized matrix formation in calverial osteoblast (p?=?0.005), suggesting a direct beneficial role of anti-TGFβ antibody treatment on osteoblasts. Data presented here demonstrate that anti-TGFβ treatment may offer a novel therapeutic option for tumor-induced bone disease and has the dual potential for simultaneously decreasing tumor burden and rescue bone loss in breast cancer to bone metastases. This approach of intervention has the potential to reduce skeletal related events (SREs) in breast cancer survivors.     

Anti-tumor effect in human breast cancer by TAE226, a dual inhibitor for FAK and IGF-IR in vitro and in vivo

Focal adhesion kinase (FAK) is a 125-kDa non-receptor type tyrosine kinase that localizes to focal adhesions. FAK overexpression is frequently found in invasive and metastatic cancers of the breast, colon, thyroid, and prostate, but its role in osteolytic metastasis is not well understood. In this study, we have analyzed anti-tumor effects of the novel FAK Tyr³⁹⁷ inhibitor TAE226 against bone metastasis in breast cancer by using TAE226. Oral administration of TAE226 in mice significantly decreased bone metastasis and osteoclasts involved which were induced by MDA-MB-231 breast cancer cells and increased the survival rate of the mouse models of bone metastasis. TAE226 also suppressed the growth of subcutaneous tumors in vivo and the proliferation and migration of MDA-MB-231 cells in vitro. Significantly, TAE226 inhibited the osteoclast formation in murine pre-osteoclastic RAW264.7 cells, and actin ring and pit formation in mature osteoclasts. Moreover, TAE226 inhibited the receptor activator for nuclear factor κ B Ligand (RANKL) gene expression induced by parathyroid hormone-related protein (PTHrP) in bone stromal ST2 cells and blood free calcium concentration induced by PTHrP administration in vivo. These findings suggest that FAK was critically involved in osteolytic metastasis and activated in tumors, pre-osteoclasts, mature osteoclasts, and bone stromal cells and TAE226 can be effectively used for the treatment of cancer induced bone metastasis and other bone diseases.     

Interactions between human osteoblasts and prostate cancer cells in a novel 3D in vitro model

Cell-cell and cell-matrix interactions play a major role in tumor morphogenesis and cancer metastasis. Therefore, it is crucial to create a model with a biomimetic microenvironment that allows such interactions to fully represent the pathophysiology of a disease for an in vitro study. This is achievable by using three-dimensional (3D) models instead of conventional two-dimensional (2D) cultures with the aid of tissue engineering technology. We are now able to better address the complex intercellular interactions underlying prostate cancer (CaP) bone metastasis through such models. In this study, we assessed the interaction of CaP cells and human osteoblasts (hOBs) within a tissue engineered bone (TEB) construct. Consistent with other in vivo studies, our findings show that intercellular and CaP cell-bone matrix interactions lead to elevated levels of matrix metalloproteinases, steroidogenic enzymes and the CaP biomarker, prostate specific antigen (PSA); all associated with CaP metastasis. Hence, it highlights the physiological relevance of this model. We believe that this model will provide new insights for understanding of the previously poorly understood molecular mechanisms of bone metastasis, which will foster further translational studies, and ultimately offer a potential tool for drug screening.