假单胞菌Pseudomonas fluorescens Pf0-1中转录调控因子SpfB负调控DNA磷硫酰化修饰

[目的]DNA磷硫酰化修饰是DNA骨架上非桥接的氧原子以序列选择性和R-构型被硫取代的一种新型DNA修饰。目前,磷硫酰化修饰在多种细菌、古生菌以及人类致病菌中多有发现,但其分子调控机制尚不清楚。为了全面解析磷硫酰化修饰的调控机制,本文选择荧光假单胞菌Pf0-1为研究对象,开展了其DNA磷硫酰化修饰的调控机制研究。[方法]首先,构建了spfB基因缺失和回补菌株,使用碘能特异性断裂磷硫酰化修饰DNA的方法,研究了该基因缺失对修饰表型的影响。利用cDNA在相邻同方向的基因间隔区进行PCR,确定了磷硫酰化修饰基因簇spfBCDE内的共转录单元。通过荧光定量RT-PCR,分析了spfB基因缺失突变株中磷硫酰化修饰基因的转录量。利用异源表达并纯化得到的重组蛋白SpfB进行了体外功能研究。通过EMSA实验,验证了SpfB蛋白具有与spfB启动子序列结合活性。通过DNase I footprinting实验,精确定位了SpfB蛋白与DNA结合序列。[结果]spfB基因的缺失加剧了磷硫酰化修饰DNA断裂所致电泳条带弥散的表型,spfB基因的回补能够恢复该表型,证明spfB基因负调控磷硫酰化修饰。鉴定了spf基因簇中只含有1个共转录单元,且该共转录单元在△spfB突变株中转录水平明显上升。通过EMSA和DNase I footprint实验,检测了SpfB蛋白与磷硫酰化修饰基因spfBCDE的启动子区域5''-TGTTTGT-3''相结合。[结论]SpfB作为转录调控因子负调控磷硫酰化修饰基因spfBCDE的表达,为解析磷硫酰化修饰的调控机制和全面理解基因组上的部分修饰特征奠定了基础。     

严重急性呼吸综合征冠状病毒2膜蛋白对宿主细胞pre-mRNA 3"UTR加工的影响

目的 研究严重急性呼吸综合征冠状病毒2（SARS-CoV-2）膜蛋白对宿主细胞mRNA前体（pre-mRNA）3"非翻译区（UTR）加工的影响。方法 本研究以人肺上皮细胞系A549为模型，利用瞬时转染在细胞内过表达SARS-CoV-2膜蛋白；利用RNA-Seq测序技术及生物信息学分析方法，系统性描绘宿主细胞选择性多聚腺苷酸化（alternative polyadenylation，APA）事件；Metascape数据库对发生显著APA变化的基因进行功能富集分析；RT-qPCR验证靶基因3"UTR长度变化；蛋白质免疫印迹（Western blot）检测目的蛋白表达水平。结果 SARS-CoV-2膜蛋白外源表达后宿主细胞内共813个基因发生显著APA变化。GO和KEGG分析显示，差异APA基因广泛参与有丝分裂细胞周期、调节细胞应激等生物过程，涉及病毒感染和蛋白质加工等。从中进一步筛选出AKT1基因，在IGV软件中显示3"UTR延长；RT-qPCR验证AKT1基因的3"UTR长度变化趋势；Western blot结果显示AKT1蛋白磷酸化水平增加。结论 SARS-CoV-2膜蛋白潜在影响宿主pre-mRNA的3"UTR加工，其中参与多种病毒性生物过程的AKT1基因 3"UTR延长，且其编码的蛋白质功能在细胞内被激活。     

人NFE2基因上游增强子lncRNA调控NFE2基因转录和K562细胞增殖

目的 转录因子NFE2的异常表达在许多骨髓增殖性肿瘤患者中被观察到,然而造成这种异常的转录调控机制尚不明确,本研究旨在探究参与NFE2转录调控的元件和分子机制。方法 首先通过公共数据库中ChIP-seq数据和ATAC-seq数据预测NFE2基因的潜在增强子元件,并通过双荧光素酶报告实验进行体外验证。随后,通过PRO-seq和GRO-seq数据结合RACE技术克隆这些增强子RNA转录本,经在线编码潜能预测工具分析认为其为lncRNA,通过RT-qPCR检测该lncRNA在不同白血病细胞系中和这些细胞诱导分化前后的表达变化及其亚细胞定位。最后,通过慢病毒系统在K562细胞中过表达和敲降该lncRNA以探究其功能。结果 鉴定出调控NFE2转录的3个增强子元件,分别位于NFE2转录起始位点-3.6k,-6.2k和+6.3k区域,这些元件插入NFE2启动子上游均能增强下游萤火虫荧光素酶的表达。克隆出-3.6k增强子负链方向的转录本,将其鉴定为-3.6k-lncRNA。本研究发现,该lncRNA在K562、U937和HL-60这3种白血病细胞系中均有一定程度的表达,且均定位于细胞核内。当该lncRNA在K562细胞中过表达,NFE2水平随之提高,细胞增殖和细胞迁移能力受到抑制;当其被敲降时,NFE2水平相应降低而K562细胞增殖能力随之升高。结论 本文鉴定了调控人NFE2基因转录的3个增强子元件和一条增强子lncRNA转录本,并验证了该lncRNA对NFE2转录的正调控作用以及对K562细胞增殖能力具有抑制作用。     

研究报告: 组织蛋白酶B介导NLRP3小体在砷致小胶质细胞炎症激活中的作用

目的 探究组织蛋白酶B（CTSB）介导NLRP3小体在砷致小胶质细胞（BV-2）炎症激活中的作用。方法 取处于对数生长期的BV-2细胞，分别暴露于终浓度为0、2、4、8 μmol/L亚砷酸钠（NaAsO₂）溶液培养24 h，检测细胞活性，测定各组细胞内CTSB和细胞焦亡相关蛋白NLRP3、Caspase-1、IL-18、IL-1β的表达水平。流式细胞仪检测胞内溶酶体膜稳定性。基于实验结果，增设CTSB抑制剂组（5 μmol/L CA074-Me +8 μmol/L NaAsO₂、10 μmol/L CA074-Me+8 μmol/L NaAsO₂），检测两组细胞内炎症相关蛋白NLRP3、Caspase-1和IL-1β、IL-18的表达水平。结果 与对照组比较，各染砷组细胞抑制率增高，呈现剂量效应关系，溶酶体膜稳定性下降，差异有统计学意义（P<0.01），胞内CTSB、NLRP3、IL-1β、IL-18、Caspase-1表达增高，差异有统计学意义（P<0.01）；与对照组（8 μmol/L NaAsO₂）比较，抑制剂组BV-2细胞胞内CTSB、NLRP3、IL-1β、IL-18、Caspase-1水平均降低，差异有统计学差异（P<0.01）。结论 NaAsO₂通过诱导小胶质细胞内CTSB水平的上升，介导NLRP3炎症小体激活小胶质细胞，促其释放炎性因子，致神经系统损伤。     

梨果黑斑病菌AaCaMK基因克隆、生物信息学分析及其在侵染结构分化中的表达分析

[背景] 钙/钙调素依赖型蛋白激酶（Calcium/Calmodulin-Dependent Protein Kinase,CaMK）是真核生物细胞钙信号途径中钙调素下游的一类重要靶蛋白,对病原物生长、胁迫响应及致病性等具有重要的调控作用。[目的] 对梨果黑斑病菌互隔交链孢（Alternaria alternata）AaCaMK基因进行克隆、生物信息学分析,并对其在侵染结构分化过程中的基因表达情况进行分析,为进一步研究梨果黑斑病菌钙离子信号途径中AaCaMK对A.alternata侵染结构分化调控的分子机制提供一定的理论依据。[方法] 采用同源克隆法从A. alternata JT-03中克隆得到3个AaCaMK基因;通过TMHMM、ProtScale、SOPMA等软件对AaCaMK基因进行生物信息学分析;利用实时荧光定量PCR （RT-qPCR）技术分析AaCaMK在梨果黑斑病菌侵染结构分化过程中的表达情况。[结果] 克隆得到片段分别为1 212、1 200、2 349 bp的AaCaMK1、AaCaMK2和AaCaMK3基因;生物信息学分析表明,AaCaMK1、AaCaMK2和AaCaMK3均含有典型的蛋白激酶超家族催化结构域（PKC_Like Superfamily）,并且AaCaMK1和AaCaMK2共同含有CaMK类丝/苏氨酸蛋白激酶催化结构域（STKc_CaMK）,AaCaMK3含有LKB1/CaMKK类丝/苏氨酸蛋白激酶催化结构域（STKc_LKB1_CaMKK）;同源性分析表明,AaCaMK1、AaCaMK2和AaCaMK3分别与玉米大斑病菌CAK1、CAK2和CAK3的相似性高达94.32%、97.49%和86.57%;RT-qPCR分析表明,AaCaMK1、AaCaMK2和AaCaMK3在疏水及果蜡诱导A. alternata侵染结构分化过程中均显著上调表达（P<0.05）,而且果蜡诱导作用更显著。其中AaCaMK1和AaCaMK2在附着胞形成时期（6 h）表达量为对照的1.51倍和3.05倍,而AaCaMK3在侵染菌丝形成阶段（8 h）表达量最高,为对照的2.86倍,并且在果蜡诱导下,这3个基因在芽管伸长阶段（4 h）的上调表达量显著高于疏水界面。[结论] 钙信号中AaCaMK基因在疏水及果蜡诱导A.alternata侵染结构分化过程中发挥重要的调控作用。     

多组学大数据整合分析揭示早期胚胎发育过程中基因表达调控信息的变化规律

摘要 目的：探究哺乳动物早期胚胎发育过程中基因表达调控信息的变化规律。方法：收集小鼠早期胚胎发育各时期的RNA-seq,ATAC-seq,MethylC-Seq和H3K4me3 ChIP-seq数据进行整合分析,观察小鼠早期胚胎发育各时期转录因子表达量的变化,计算各时期基因表达量与转录因子结合位点数量及染色质可及性的相关性,筛选各时期表达量前10%的基因,统计其表达量和转录因子占比,并进行启动子可及性分析。根据前期报道的转录因子三节点调控网络,对早期胚胎各时期转录因子调控网络的富集模式进行分析。根据多组学数据分析结果,推测早期胚胎发育调控过程中转录因子和表观遗传修饰信息的共调控模型。结果：转录因子数量和调控关系变化以及染色质可及性、DNA甲基化修饰、组蛋白修饰等表观遗传修饰共同调控早期胚胎发育各时期的基因表达,这些因素在不同时期发挥不同程度的调控作用。结论：转录因子和表观遗传修饰在早期胚胎发育过程中动态调控基因表达。     

关键酶基因转录水平对重组大肠杆菌合成NAD+的影响

[目的] 烟酰胺腺嘌呤二核苷酸（nicotinamide adenine dinucleotide）是生物体内一种重要的辅因子,其细胞内含量对于NAD⁺依赖型氧化还原反应和有关生化合成代谢具有重要意义。为强化辅因子合成,本文通过不同诱导条件下关键酶基因转录水平与产物合成水平的相关性分析,利用增加正向关键酶基因拷贝数策略提高胞内氧化型辅酶NAD⁺的浓度。[方法] 以实验室前期构建的大肠杆菌NA016为出发菌株,分别从诱导温度、诱导剂浓度、诱导时机三个方面进行了诱导条件的优化,并利用实时荧光定量PCR（RT-qPCR）技术对代谢改造中的有关过表达基因进行了转录水平分析,确定了NAD⁺含量与这些过表达基因转录水平之间的相关性,增加对NAD⁺合成代谢具有正向作用的基因拷贝数以进一步提高胞内NAD⁺水平。[结果] 通过诱导条件优化实验确定菌株NA016的最适诱导温度,在诱导时机为OD₆₀₀达到0.6时加入0.8 mmol/L的IPTG可使胞内NAD⁺含量提高35.37%;转录水平方面分析发现基因nadE和pncB的表达对NAD⁺的合成具有正向调节作用。进一步增加菌株NA016中关键酶基因nadE和pncB的拷贝数可使辅酶含量再次提高22.46%,最高可达41.66μmol/g DCW。[结论] 优化诱导条件和增加关键酶基因拷贝数可以提高氧化型辅酶NAD⁺的含量,这为促进大肠杆菌胞内NAD⁺合成的研究提供借鉴意义。     

纳米二氧化锆对人永生化角质形成细胞组蛋白H3修饰的影响

目的 阐明纳米二氧化锆暴露对人永生化角质形成细胞Ha Ca T组蛋白H3常见修饰位点的影响,探讨组蛋白H3修饰变化的潜在机制,为纳米材料的进一步安全应用提供理论基础。方法 在利用扫描电子显微镜、激光粒度仪、X射线衍射仪等技术对纳米二氧化锆进行详细表征的基础上,通过蛋白质免疫印迹及流式细胞术等方法评价纳米二氧化锆暴露对细胞生存率、细胞内蓄积量以及组蛋白H3修饰等的影响。结果 在分散介质中纳米二氧化锆明显团聚,比表面积减少,二次粒径增大,其短时间内（1 h）即诱导了组蛋白H3第10位丝氨酸的磷酸化、第9及14位赖氨酸的乙酰化、第4及27位赖氨酸的三甲基化修饰水平的升高。进一步分析发现,纳米二氧化锆的细胞内蓄积量及其引起的DNA损伤水平,与纳米二氧化锆诱导的组蛋白H3修饰水平均呈线性相关。结论 纳米二氧化锆暴露后诱导了Ha Ca T细胞组蛋白H3常见修饰位点的变化,其细胞内的蓄积是诱导组蛋白H3修饰变化的关键因素之一,且组蛋白H3修饰的调控机制可能涉及DNA损伤修复途径。     

马源马链球菌兽疫亚种3株新疆分离株基因型的鉴定及MLST分析

[背景] 马链球菌兽疫亚种（Streptococcus equi subsp. zooepidemicus,SeZ）是引起马腺疫的主要病原,还可引起猪链球菌病,加强该菌的地方株分子流行病学监测对有效防控相关疫病十分必要。[目的] 对新疆地区2个马场SeZ分离株进行鉴定和药敏特性分析,并分析3株新疆分离株的分子流行与菌株的遗传进化特征。[方法] 对分离纯化的3株病原菌（ZHZ113、ZHZ211和ZHZ523）进行染色观察、生化及药敏特性检测,对16S rRNA和SeM基因进行遗传进化分析,以链球菌7个管家基因arcC、nrdE、proS、spi、tdk、tpi和yqiL为目的基因对3株分离菌进行多位点序列分型（Multilocus Sequence Typing,MLST）研究。[结果] 3株SeZ的药敏结果显示这3株分离菌对不同抗生素的耐药程度不同,但均对头孢西丁、庆大霉素、链霉素、红霉素、左氧氟沙星、环丙沙星、土霉素等11种药物敏感。16S rRNA基因序列分析显示这3株分离菌均属于Ⅱ群（兽疫链球菌）。3株菌的MLST分型结果分别为ST39、ST419、ST421型,其中ST419和ST421型为SeZ目前尚未见报道的新ST型。SeM基因分析结果显示马源SeZ在不同国家、不同动物和不同时间段上的流行分布存在差异和动态变化的特点。[结论] 3株SeZ分离菌分别与美国犬源及马源菌株亲缘关系较近,反映部分SeZ株在新疆地区的基因型分布及分子流行特点。     

具核梭杆菌脂多糖诱导THP-1细胞M2极化及对低浓度白介素6产生的作用

[背景] 在结直肠肿瘤等多种肿瘤中普遍存在的具核梭杆菌（Fusobacterium nucleatum）与结直肠肿瘤发生、预后不良、复发及化疗耐药等密切相关。其引发炎症、对肿瘤微环境中巨噬细胞等免疫细胞作用与机制尚待阐明。[目的] 对比分析F.nucleatum脂多糖（Lipopolysaccharide,LPS）与嗜黏蛋白阿克曼氏菌（Akkermansia muciniphila）、大肠杆菌（Escherichia coli）的LPS诱导单核细胞极化、炎性细胞因子表达等活性差异,探讨F.nucleatum在诱发慢性炎症、致癌等过程中的作用与机制。[方法] 分别用A.muciniphila、E.coli、F.nucleatum LPS或联合干扰素γ（Interferon-γ,IFN-γ）处理后,观察THP-1、THP-1 M0细胞的细胞形态变化,然后检测M0（CD11B）、M1（CD40、CD86）和M2（CD163、CD206）巨噬细胞标志基因、TLR3、TLR4、IL-6、IL-10等基因转录水平,以及IL-6、IL-10、C反应蛋白（C Reactive Protein,CRP）翻译水平的表达变化。[结果] 聚丙烯酰胺凝胶电泳（Polyacrylamide Gel Electrophoresis,PAGE）分析显示,A.muciniphila、E.coli、F.nucleatum这3种细菌的LPS条带位置、数量存在明显差异。F.nucleatum LPS在具有较强诱导THP-1细胞贴壁的同时,对经佛波肉豆蔻醋酸（Phorbol Myristate Acetate,PMA）处理贴壁的THP-1细胞,无论是单独或是联合IFN-γ处理,诱导形成伪足数、伪足长度及形成梭形细胞比例（M1型巨噬细胞）等均低于A.muciniphila和E.coli LPS。进一步转录水平检测巨噬细胞标志基因表达发现,M1标志基因中,CD40分别上调5 011.0%（P<0.001）、6 048.9%（P<0.001）和1 011.6%（P=0.009 4）,CD86分别上调637.3%（P<0.001）、657.9%（P<0.001）和194.1%（P>0.05）;M2标志基因中,CD163分别下调39.5%（P=0.001 1）、53.7%（P<0.001）和5.9%（P>0.05）,CD206下调18.6%（P>0.05）、88.4%（P=0.005 5）和24.8%（P>0.05）。TLR、白介素家族基因转录水平分析发现,TLR3分别下调32.3%（P=0.044 7）、311.5%（P=0.001 9）、9.6%（P>0.05）;IL-6分别上调17 763.2%（P<0.001）、35 458.2%（P<0.001）、1 123.6%（P>0.05）;IL-10分别上调729.3%（P<0.001）、1 223.3%（P<0.001）、124.4%（P>0.05）。翻译水平上,A.muciniphila、E.coli、F.nucleatum LPS单独或联合IFN-γ处理时,THP-1细胞产生IL-6分别为0.16、6.17、0 pg/mL与410.03、1 334.40、46.20 pg/mL。[结论] F.nucleatum LPS不仅具有较强招募单核细胞并诱导其向M2极化的作用,同时,具有诱导巨噬细胞分泌低浓度IL-6的特性,说明其在引发慢性炎症及肿瘤免疫应答、逃逸等过程中发挥重要作用。综合上述信息,对致癌、免疫激活及肿瘤治疗相关细菌LPS的结构、活性、分子机制等研究将有助于明确革兰氏阴性细菌在慢性炎症、肿瘤发生、免疫调控等中的作用,以期为相关疾病预防与治疗提供新的策略与靶点。     

Uptake of Intact Copper Oxide Nanoparticles Causes Acute Toxicity in Cultured Glial Cells

Copper oxide nanoparticles (CuO-NPs) dispersions are known for their high cell toxic potential but contaminating copper ions in such dispersions are a major hurdle in the investigation of specific nanoparticle-mediated toxicity. In order to distinguish between the adverse effects exhibited by CuO-NPs and/or by contaminating ionic copper, the membrane-impermeable copper chelator bathocuproine disulfonate (BCS) was added in a low molar ratio (20% of the total copper applied) in order to chelate the copper ions that had been released extracellularly from the CuO-NPs before or during the incubation. Physicochemical characterization of synthesized CuO-NPs revealed that the presence of this low concentration of BCS did not alter the size or zeta potential of the CuO-NPs. Application of CuO-NPs to C6 glioma cells and primary astrocytes induced a concentration- and temperature-dependent copper accumulation which was accompanied by a severe loss in cell viability. The adverse consequences of the CuO-NP application were not affected by the presence of 20% BCS, while the copper accumulation and cell toxicity observed after application of ionic copper were significantly lowered in the presence of BCS. These results demonstrate that for the experimental conditions applied the adverse consequences of an exposure of cultured glial cells to dispersions of CuO-NPs are mediated by accumulated NPs and not caused by the uptake of contaminating copper ions.

     

Comparative assessment of the bactericidal effect of nanoparticles of copper oxide,silver, and chitosan-silver against Escherichia coli infection in broilers

Escherichia coli infection is considered one of the most economically important multi-systemic diseases in poultry farms. Several nanoparticles such as silver, chitosan, and copper oxide are known to be highly toxic to several microbes. However, there are no data concerning their success against in vivo experimental E. coli infection in broilers. Therefore, the present study was designed to investigate the bactericidal effect of low doses of CuO-NPs (5 mg/kg bwt), Ag-NPs (0.5 mg/kg bwt), and Ch-Ag NPs (0.5 mg/kg bwt) against E. coli experimental infection in broilers. One hundred chicks were divided into five groups as follows: (1) control; (2) E. coli (4 × 10⁸ CFU/ml) challenged; (3) E. coli +CuO-NPs; (4) E. coli +Ag-NPs; (5) E. coli +Ch-Ag NPs. The challenged untreated group, not NPs treated groups, recorded the lowest weight gain as well as the highest bacterial count and lesion score in all examined organs. The highest liver content of silver was observed in Ag-NPs treated group compared with the Ch-Ag NPs treated group. Our results concluded that Ch-Ag NPs not only had the best antibacterial effects but also acted as a growth promoter in broilers without leaving any residues in edible organs. We recommend using Ch-Ag NPs in broiler farms instead of antibiotics or probiotics.     

Neuropathological and Cognitive Effects Induced by CuO-NPs in Rats and Trials for Prevention Using Pomegranate Juice

Copper oxide nanoparticles (CuO‐NPs) are extensively utilized in several industries and in pharmaceutical production. This excess exposure elevates the concern about its expected poisonous impacts on humans and animals. Pomegranate juice (PJ) is a natural source of polyphenols and exhibits potent antioxidant activities. Our experiment intended to explore the neurobehavioral and toxicopathological impacts of CuO-NPs and to explain the mechanistic role of PJ to reduce their toxicity. Thirty Wistar albino rats received the subsequent materials through oral gavage, every day for 28d: (1) normal saline, (2) 3 mL/kg bwt PJ, (3) 6 mL/kg bwt PJ, (4) 300 mg/kg bwt CuO-NPs, (5) CuO-NPs?+?3 mL/kg bwt PJ, (6) CuO-NPs?+?6 mL/kg bwt PJ. Continuous exposure to CuO-NPs caused a significant elevation of MDA levels and reduction of total antioxidant capacity associated with remarkable pathological alterations in all brain regions including cerebrum, hippocampus and cerebellum. Progressive decline of memory along with cognitive and psychiatric disturbances were observed in rats exposed to CuO-NPs not in PJ co-treated rats. Continuous exposure to CuO-NPs caused over expression of the immunohistochemical markers of caspase-3, iNOS and GFAP altogether with DAN fragmentation and down-regulation of HO-1 and Nrf2 gene in the whole brain tissues. Conversely, rats co-treated with PJ showed dose dependent improvements in the entire toxicological, behavioral, and pathological parameters. We showed that PJ had the ability to reduce the oxidative stress damage via up-regulation of HO-1 and Nrf2 genes in the brain. So that PJ had the ability to protect the brain and DNA from further damage.

     

Assessment of Nanotoxicity (Cadmium Sulphide and Copper Oxide) Using Cytogenetical Parameters in <Emphasis Type="Italic">Coriandrum sativum</Emphasis> L. (Apiaceae)

Present investigation deals with cytogenetical consequences (using attributes namely, seed germination, seedling length, mitotic index, mitotic and meiotic abnormalities and pollen grain sterilities) of cadmium sulphide (CdS) and copper oxide (CuO) nanoparticles (NPs) treatment in Coriandrum sativum L. (Family: Apiaceae, spice of commerce). Ethyl methanesulphonate (EMS), a conventional mutagen is used as positive control. Results suggest that both CdS- and CuO-NPs can induce growth inhibition and cause cytological aberrations in both mitotic and meiotic cells in the studied species. EMS also responds similarly as that of NPs. Study highlights that rooted plant species can be effectively used as model for assessment of nanotoxicity considering cytogenetical parameters.     

Double-Layer Magnetic Nanoparticle-Embedded Silica Particles for Efficient Bio-Separation

Superparamagnetic Fe₃O₄ nanoparticles (NPs) based nanomaterials have been exploited in various biotechnology fields including biomolecule separation. However, slow accumulation of Fe₃O₄ NPs by magnets may limit broad applications of Fe₃O₄ NP-based nanomaterials. In this study, we report fabrication of Fe₃O₄ NPs double-layered silica nanoparticles (DL MNPs) with a silica core and highly packed Fe₃O₄ NPs layers. The DL MNPs had a superparamagnetic property and efficient accumulation kinetics under an external magnetic field. Moreover, the magnetic field-exposed DL MNPs show quantitative accumulation, whereas Fe₃O₄ NPs single-layered silica nanoparticles (SL MNPs) and silica-coated Fe₃O₄ NPs produced a saturated plateau under full recovery of the NPs. DL MNPs are promising nanomaterials with great potential to separate and analyze biomolecules.     

Nanostructured materials for magnetic biosensing

BackgroundMagnetic nanoparticles (MNPs) are at the leading edge of the field of biomedical applications and magnetic biosensing.MethodsMNPs were fabricated by electrophysical methods of the laser target evaporation (LTE) and spark discharge with electrodynamic acceleration of plasma jumpers (SD). Synthesis of polyacrylamide hydrogel was done in the presence of Fe₂O₃ MNPs in different concentrations obtained by LTE. [FeNi/Ti]₃/Cu/[Ti/FeNi]₃/Ti multilayers for giant magnetoimpedance (GMI) based sensitive elements were prepared by rf-sputtering for testing a biosensor prototype.ResultsIron oxide MNPs, ferrofluids, ferrofluids contacting with biological systems, synthetic ferrogels mimicking natural tissues – are the steps of the discussed in this work development of bionanomaterials. Thorough the structural and magnetic studies of a multilayered sensitive element, MNPs and ferrogels insure the complete characterization of biosensor prototype. The GMI responses were carefully evaluated in initial state and in the presence of ferrogel with known concentration of MNPs. SD MNPs had the smallest 5–8 nm size. This nanomaterial was characterized by large internal strains of the order of 25 × 10^− 3, which can play an important role for the interaction with different biosystems.ConclusionsIron oxide MNPs were fabricated by LTE and SD methods. SD MNPs had the smallest 5–8 nm size and large internal strains of the order of 25 × 10^− 3. Designed GMI biosensor prototype allowed precise evaluation of the stray field of the MNPs present in the ferrogel by evaluating the systematic changes of the GMI in a 20–400 MHz frequency range.General significanceThis work summarizes recent developments in the field of nanomaterials potentially applicable in magnetic biosensing.     

Optimization of DNA delivery by three classes of hybrid nanoparticle/DNA complexes

Plasmid DNA encoding a luciferase reporter gene was complexed with each of six different hybrid nanoparticles (NPs) synthesized from mixtures of poly (D, L-lactide-co-glycolide acid) (PLGA 50:50) and the cationic lipids DOTAP (1, 2-Dioleoyl-3-Trimethyammonium-Propane) or DC-Chol {3β-[N-(N', N'-Dimethylaminoethane)-carbamyl] Cholesterol}. Particles were 100-400 nm in diameter and the resulting complexes had DNA adsorbed on the surface (out), encapsulated (in), or DNA adsorbed and encapsulated (both). A luciferase reporter assay was used to quantify DNA expression in 293 cells for the uptake of six different NP/DNA complexes. Optimal DNA delivery occurred for 10⁵ cells over a range of 500 ng - 10 μg of NPs containing 20-30 μg DNA per 1 mg of NPs. Uptake of DNA from NP/DNA complexes was found to be 500-600 times as efficient as unbound DNA. Regression analysis was performed and lines were drawn for DNA uptake over a four week interval. NP/DNA complexes with adsorbed NPs (out) showed a large initial uptake followed by a steep slope of DNA decline and large angle of declination; lines from uptake of adsorbed and encapsulated NPs (both) also exhibited a large initial uptake but was followed by a gradual slope of DNA decline and small angle of declination, indicating longer times of luciferase expression in 293 cells. NPs with encapsulated DNA only (in), gave an intermediate activity. The latter two effects were best seen with DOTAP-NPs while the former was best seen with DC-Chol-NPs. These results provide optimal conditions for using different hybrid NP/DNA complexes in vitro and in the future, will be tested in vivo.     

Compare Analysis for the Nanotoxicity Effects of Different Amounts of Endocytic Iron Oxide Nanoparticles at Single Cell Level

Developing methods that evaluate the cellular uptake of magnetic nanoparticles (MNPs) and nanotoxicity effects at single-cellular level are needed. In this study, magnetophoresis combining fluorescence based cytotoxicity assay was proposed to assess the viability and the single-cellular MNPs uptake simultaneously. Malignant cells (SKHep-1, HepG2, HeLa) were incubated with 10 nm anionic iron oxide nanoparticles. Prussian blue stain was performed to visualize the distribution of magnetic nanoparticles. MTT and fluorescence based assay analyzed the cytotoxicity effects of the bulk cell population and single cell, respectively. DAPI/PI stained was applied to evaluate death mechanism. The number of intracellular MNPs was found to be strongly correlated with the cell death. Significant differences between cellular MNP uptake in living and dead cells were observed. The method could be useful for future study of the nanotoxicity induced by MNPs.     

Synthesis of tumor-targeted folate conjugated fluorescent magnetic albumin nanoparticles for enhanced intracellular dual-modal imaging into human brain tumor cells

Superparamagnetic iron oxide nanoparticles (SPIO NPs), utilized as carriers are attractive materials widely applied in biomedical fields, but target-specific SPIO NPs with lower toxicity and excellent biocompatibility are still lacking for intracellular visualization in human brain tumor diagnosis and therapy. Herein, bovine serum albumin (BSA) coated superparamagnetic iron oxide, i.e. γ-Fe₂O₃ nanoparticles (BSA-SPIO NPs), are synthesized. Tumor-specific ligand folic acid (FA) is then conjugated onto BSA-SPIO NPs to fabricate tumor-targeted NPs, FA-BSA-SPIO NPs as a contrast agent for MRI imaging. The FA-BSA-SPIO NPs are also labeled with fluorescein isothiocyanate (FITC) for intracellular visualization after cellular uptake and internalization by glioma U251 cells. The biological effects of the FA-BSA-SPIO NPs are investigated in human brain tumor U251 cells in detail. These results show that the prepared FA-BSA-SPIO NPs display undetectable cytotoxicity, excellent biocompatibility, and potent cellular uptake. Moreover, the study shows that the made FA-BSA-SPIO NPs are effectively internalized for MRI imaging and intracellular visualization after FITC labeling in the targeted U251 cells. Therefore, the present study demonstrates that the fabricated FITC-FA-BSA-SPIO NPs hold promising perspectives by providing a dual-modal imaging as non-toxic and target-specific vehicles in human brain tumor treatment in future.