参桃软肝颗粒抑制肝癌的分子机制及调控RBPJ的探索

目的肝细胞癌(hepatocellular carcinoma,HCC)是全球第四大常见癌症,严重威胁着国民健康。参桃软肝颗粒(STR)是国医大师周岱翰教授治疗肝癌的临床经验方,在临床实践中取得了良好的疗效,阐明其抑制肝癌生长和转移的机制是亟需解决的问题。方法Transwell侵袭迁移实验检测STR对HepG2细胞侵袭能力的影响,蛋白质印迹法(Western blot,WB)检测STR对Huh7细胞株RBPJ蛋白的表达影响。观察STR对Huh7荷瘤小鼠移植瘤生长的影响。RNA-seq鉴定STR处理的Huh7移植瘤组织中差异表达基因(differentially expressed genes,DEGs)。结果STR可显著抑制HepG2细胞的迁移和侵袭能力,STR可通过蛋白泛素化降解的途径减少RBPJ蛋白的表达;STR给药后,肝癌模型小鼠移植瘤体积以及瘤体重量均下降,肿瘤生长明显受到抑制。在对照组和STR给药组组间共发现2961个DEGs,其中上调和下调基因分别为1884和1077个。基因本体论(gene ontology,GO)、京都基因与基因组百科全书(Kyoto encyclopedia of genes and genomes,KEGG)和疾病本体论(disease ontology,DO)通路富集分析分别展示了STR可能作用的信号通路。结论Notch信号在肝癌中频繁发生异常表达及激活突变,转录因子RBPJ是Notch信号通路主要的下游靶基因,可以增强Notch信号通路中下游基因的表达。STR对肝细胞癌的抑制作用显著,其分子机制可能与抑制RBPJ的蛋白表达相关。

携带siRbpj重组腺病毒载体的构建及其对BMP9诱导骨髓间充质干细胞成骨分化作用影响

目的:构建并筛选特异性干扰Notch信号通路核转录因子Rbpj基因的重组腺病毒,探讨通过Rbpj的经典Notch信号通路在骨形态发生蛋白(bone morphogenetic protein,BMP)9诱导骨髓间充质干细胞(mesenchymal stem cells,MSCs)成骨分化中的作用。方法:设计3对针对小鼠Rbpj的siRNA序列,将其分别亚克隆至pSES-HUS穿梭质粒,再与骨架质粒pAdEasy-1在大肠杆菌BJ5183内同源重组获得重组质粒,经脂质体转染至HEK293细胞中包装扩增腺病毒,利用RT-PCR及Western blot进行筛选、验证有效的干扰腺病毒。该重组腺病毒与AdBMP9处理MSCs细胞株C3H10T1/2,采用组织化学和RT-PCR检测早期成骨指标碱性磷酸酶(alkaline phosphatase,ALP)和晚期成骨指标骨桥蛋白(osteopontin,OPN),骨钙蛋白(osteocalcin,OCN)及BMP下游靶基因Id 1、Runx 2等的表达。结果:成功构建了3个重组腺病毒,并筛选出干扰效率最好的AdsiRbpj-2重组腺病毒,转染C3H10T1/2,AdsiRbpj-2可以明显下调BMP9诱导的早期成骨指标ALP的活性及晚期成骨指标OPN、OCN的表达,成骨相关基因Runx 2等的表达也有下降。结论:成功构建了特异性阻断Notch经典信号通路腺病毒载体AdsiRbpj-2,该重组腺病毒能够抑制BMP9诱导的C3H10T1/2细胞的成骨分化进程,从而进一步证明Notch信号通路在BMP9诱导的MSCs成骨分化过程中有着重要的作用。

RBPJ与KyoT_2真核表达载体的构建与鉴定

目的:构建含有myc-RBPJ(R218H)(recombination binding protein-J)、myc-KyoT2融合基因片段的质粒,并在真核细胞中表达、鉴定。方法:由本科室保存质粒酶切分别得到RBPJ(R218H)和myc-KyoT2基因片段,将RBPJ(R218H)基因插入载体PCMV-myc中,获得融合基因myc-RBP-J(R218H),将myc-RBPJ(R218H)和myc-KyoT2插入真核表达载体pIRES2-EGFP,构建真核表达载体myc-RBPJ(R218H)-IRES2-EGFP、myc-KyoT2-IRES2-EGFP。以其瞬时转染HEK293细胞,应用免疫印迹与流式细胞术检测融合蛋白与绿色荧光蛋白的表达。结果:正确获得myc-RBPJ(R218H)融合基因,DNA序列分析表明所构建的含myc-RBPJ(R218H)、myc-KyoT2融合基因的质粒与设计相同,myc-RBPJ(R218H)、myc-KyoT2融合蛋白与绿色荧光蛋白均正确表达。结论:成功构建了含有myc-RBPJ(R218H)、myc-KyoT2融合基因的真核表达载体,并在真核细胞中正确表达,为进一步研究慢性粒细胞白血病与Notch信号转导通路之间的关系奠定了基础。

miR-223-3p靶向调控Rbpj转录因子对葡萄膜炎大鼠Th1和Th17细胞分化的影响

目的:探讨miR-223-3p对Notch信号通路转录因子Rbpj表达的调控作用以及对实验性自身免疫性葡萄膜炎(EAU)大鼠Th1、Th17细胞分化水平的影响。方法:用双荧光素酶表达报告系统探讨miR-223-3p对Rbpj基因表达的调控作用。将24只雌性Lewis大鼠随机分为EAU模型组、正常对照组(NC组)和空白对照组(BC组),每组8只。EAU模型组注射含光感受器间维生素A结合蛋白(IRBP)、结核菌素和完全弗氏佐剂的乳糜液以诱导葡萄膜炎,BC组注射等体积的不含IRBP多肽的乳糜液,NC组注射等体积的无菌生理盐水。免疫后12d,无菌分离三组大鼠的脾脏、淋巴结和眼组织,实时荧光定量PCR(Q-PCR)检测miR-223-3p和Rbpj基因的表达水平;酶联免疫吸附测定(ELISA)方法检测Rbpj、IFN-γ、IL-17蛋白的表达水平;流式细胞仪检测三组大鼠不同组织中Th1和Th17细胞的表达水平。结果:双荧光素酶检测结果证实Rbpj是miR-223-3p调控的靶基因。免疫后12d,相比于NC组,EAU模型组大鼠脾脏、淋巴结和眼组织中miR-223-3p相对表达水平分别为0.33±0.29、0.11±0.12、0.18±0.11,均呈下调表达(均P<0.05);Rbpj mRNA水平均呈上调表达,分别为3.00±0.06、1.52±0.12、3.01±0.34(均P<0.05);BC组大鼠脾脏、淋巴结和眼组织中miR-223-3p和Rbpj mRNA水平与NC组相比均无差异(P>0.05)。ELISA检测结果发现,免疫后12d的EAU模型组大鼠各组织中Rbpj、IFN-γ、IL-17蛋白表达水平均明显高于NC组(均P<0.05),BC组大鼠各组织中Rbpj、IFN-γ、IL-17蛋白表达水平与NC组相比均无差异(P>0.05)。流式细胞仪检测结果显示,免疫后12d,EAU模型组各组织的Th1和Th17细胞比例均显著高于NC组(均P<0.05)。BC组与NC组各组织Th1和Th17细胞比例无明显变化(均P>0.05)。结论:miR-223-3p可负调控Notch信号通路转录因子Rbpj的表达。EAU大鼠中miR-223-3p的下调表达可升高Rbpj基因和蛋白的表达水平,促进Th1和Th17细胞的分化以及提高相关分子IFN-γ和IL-17的表达水平,进而影响葡萄膜炎的发生发展。

DPPA2/DPPA4在牛着床前胚胎发育过程中的作用及机制

多能发育相关因子2和4(developmental pluripotency-associated 2 and 4,DPPA2/DPPA4)是激活类2细胞期胚胎干细胞(2-cell-like embryonic stem cells,2CL ESCs)基因组的重要调控因子,同时调控胚胎干细胞的增殖。DPPA2/DPPA4在牛早期胚胎发育过程中的功能和机制尚不清楚。本研究利用RNA干扰技术结合胚胎显微注射技术敲低牛胚胎中的DPPA2/DPPA4后发现,与阴性对照组相比,敲低组中牛胚胎的8—16细胞阶段卵裂率和囊胚阶段囊胚率无显著差异,但是囊胚总细胞数、滋养层细胞数和内细胞团细胞数均显著减少(P<0.001、P<0.05、P<0.01)。进一步通过RNA测序(RNA-sequencing,RNA-Seq)分析发现,与阴性对照组相比,敲低组的晚期桑葚胚中,NOTCH信号通路的核心转录因子RBPJ(recombination signal binding protein gene for immunoglobulin kappa J region)的表达量显著下调(P<0.05),而本课题组前期实验证明,RBPJ敲低会导致牛早期胚胎的囊胚质量严重受损。本研究结果揭示了DPPA2/DPPA4在牛着床前胚胎发育中可能通过调节RBPJ的表达来影响细胞增殖。

3D printing of osteocytic Dll4 integrated with PCL for cell fate determination towards osteoblasts in vitro

Since 3D printed hard materials could match the shape of bone,cell survival and fate determination towards osteoblasts in such materials have become a popular research target.In this study,a scaffold of hardmaterial for 3D fabrication was designed to regulate developmental signal(Notch)transduction guiding osteoblast differentiation.We established a polycaprolactone(PCL)and cell-integrated 3D printing system(PCI3D)to reciprocally print the beams of PCL and cell-laden hydrogel for a module.This PCI3D module holds good cell viability of over 87%,whereas cells show about sixfold proliferation in a 7-day culture.The osteocytic MLO-Y4 was engineered to overexpress Notch ligand Dll4,making up 25%after mixing with 75%stromal cells in the PCI3D module.Osteocytic Dll4,unlike other delta-like family members such as Dll1 or Dll3,promotes osteoblast differentiation and themineralization of primary mouse and a cell line of bone marrow stromal cells when cultured in a PCI3D module for up to 28 days.Mechanistically,osteocytic Dll4 could not promote osteogenic differentiation of the primary bone marrow stromal cells(BMSCs)after conditional deletion of the Notch transcription factor RBPjκby Cre recombinase.These data indicate that osteocytic Dll4 activates RBPjκ-dependent canonical Notch signaling in BMSCs for their oriented differentiation towards osteoblasts.Additionally,osteocytic Dll4 holds a great potential for angiogenesis in human umbilical vein endothelial cells within modules.Our study reveals that osteocytic Dll4 could be the osteogenic niche determining cell fate towards osteoblasts.This will open a new avenue to overcome the current limitation of poor cell viability and low bioactivity of traditional orthopedic implants.

Intracellular Notch1 May Induce a Conformational Change in CSL/DNA, without Forming ICN1/CSL/DNA Molecular Complex, <i>in Vitro</i>

Intracellular Notch (ICN) initiates DNA transcription in cooperation with CSL that acts as repressor in the absence of ICN. The ICN mediates recruitment of MAML protein, leading to the formation of minimal transcriptional complex, MAML/ICN/CSL/DNA. Crystal structure reveals that different conformations exist between the free (CSL/DNA) and bound (ICN/MAML/CSL/DNA) forms. The significance of this modulation of the CSL/DNA molecular complex can be better understood by experimental approaches that aim to elucidate the cause and timing of these events. There are four orthologues of human ICN (ICN1-4). We studied interactions between human full-length ICN1 and CSL/DNA without involvement of MAML, in vitro, and found that 1) the EMSA profile of CSL/DNA is altered in the presence of ICN1 as a consequence of an intrinsic change(s) in CSL/DNA, and not due to the formation of an ICN/CSL/DNA molecular complex;2) ICN1 destabilizes CSL/DNA. These findings indicate that human ICN1 functions to modulate the CSL/DNA molecular complex for subsequent recruitment of MAML, and that modulated CSL/DNA cannot accommodate ICN1 in the absence of MAML. The latter in turn, implies that the formation of the MAML/ICN1/CSL/DNA is likely to be a collective event, wherein preassembly of MAML and ICN1 as a binary complex co-localizes at the CSL/DNA promoter site, or the MAML/ICN1/CSL complex is pre-assembled prior to binding to the promoter, rather than ICN1 arriving at CSL/DNA ahead of MAML and/or other associated transcription factors. The novel finding that ICN1 destabilizes the CSL/DNA complex opens new possibilities of transcriptional regulation by Notch.

氟对大鼠骨组织RBPJ及相关基因表达影响

目的观察氟染毒大鼠骨组织中核转录抑制因子(RBPJ)、Jag 1和Hes 5蛋白表达变化,探讨Notch通路与氟骨症关系。方法成年SD大鼠24只,随机分为3组:对照组(饮水含氟<1 mg/L),低、高氟组(饮水含氟50、100 mg/L),每组8只;饲养6个月后,收集尿液和骨组织,测定尿氟和骨氟,观察骨组织学变化并测定骨组织系列形态学指标,免疫组化法检测成骨细胞中RBPJ、Jag 1和Hes 5蛋白表达,免疫印迹法和实时荧光定量法分别检测骨组织RBPJ、Jag 1和Hes 5蛋白与mRNA表达量。结果与对照组比较,低、高氟组大鼠尿氟和骨氟[分别为(11.80±1.08)、(18.08±1.13)mg/L和(5 974.76±2 036.13)、(7 996.51±2 669.93)μg/g)]均升高(均P<0.05);染氟组大鼠骨组织呈骨质硬化病理改变;与对照组比较,低、高氟组大鼠骨组织RBPJ蛋白表达[分别为(4.985±0.913)、(4.279±1.507)]均升高,高氟组Jag 1、Hes 5蛋白表达[分别为(0.112±0.024)、(0.128±0.039)]均降低(均P<0.05);与对照组比较,高氟组大鼠骨组织Jag 1、RBPJ mRNA表达量[分别为(0.005 7±0.005 4)、(0.005 5±0.004 4)]降低(均P<0.05)。结论过量氟抑制Notch通路信号,使该通路下游靶基因表达受到抑制,从而促进成骨作用,参与氟骨症发病过程。

敲除Rbpj降低小鼠子宫蜕膜对孕酮的敏感性

胚胎着床是指处于活化态的囊胚与接受态的子宫内膜相互作用并建立紧密联系的过程,该过程分为定位、黏附和侵入三个时期。胚胎着床后,围绕在囊胚周围的子宫内膜基质细胞广泛增殖并分化为上皮样的蜕膜细胞,这一过程称为蜕膜化。成功的胚胎着床和蜕膜化是妊娠建立的关键,任何一个过程异常都将导致妊娠的失败。孕酮作为调节雌性动物生殖的重要甾类激素,在蜕膜化的维持中扮演着重要角色。Notch信号通路是和细胞命运决定有关的重要信号通路,其作用贯穿于整个胚胎和成体细胞分化的过程。作为Notch信号通路的核心转录因子,Rbpj在调节该信号通路下游基因的表达中扮演着重要角色。本研究旨在通过子宫特异性敲除小鼠研究Rbpj在小鼠人工诱导蜕膜化过程中的作用,探讨Rbpj与孕酮之间的关系。通过在小鼠背部皮下埋植不同长度的装有孕酮的缓释管控制人工诱导蜕膜化模型中孕酮的释放剂量,在诱导蜕膜化72或120 h后收集小鼠血清及子宫。结合HE染色观察蜕膜化中各组子宫的形态差异,利用孕酮试剂盒检测血清中孕酮水平的差异。结果表明,低剂量孕酮条件下敲除Rbpj导致小鼠的蜕膜化受损,无法维持蜕膜化的状态;适当提高孕酮剂量则可以部分挽救Rbpj敲除小鼠的蜕膜受损;在给予相同剂量孕酮的情况下,Rbpj敲除小鼠血清中的孕酮浓度更低。以上结果说明,Notch信号通路的核心转录因子Rbpj的缺失会降低小鼠子宫蜕膜对孕酮的敏感性,高剂量的孕酮可挽救因Rbpj的缺失造成的蜕膜损失。