Ca2+与乳清蛋白结合的亲和毛细管电泳研究

利用亲和毛细管电泳研究了Ca²⁺与α-人乳清蛋白(α-HLA)的结合情况.以恒定浓度α-HLA作为受体,运行缓冲溶液加入不同浓度的Ca²⁺作为配体,可观察到由于Ca²⁺的结合,α-HLA的电泳淌度发生了变化.通过Scatchard方程的淌度比(M)处理数据得到α-HLA与Ca²⁺的表观结合常数(K_app)为2.0×107(mol/L)^-1.同时考察了Ca²⁺对变性剂(尿素)和热诱导所引起的α-HLA去折叠的影响,结果表明,Ca²⁺的结合增强了α-HLA的稳定性,也即提高了α-HLA抗变性剂和热诱导的去折叠性能.     

高效液相色谱法同时测定水体中氧氟沙星及其手性异构体

建立了一种简单快捷的手性配位交换高效液相色谱测定地表水中氧氟沙星及其手性异构体的方法,并研究了常见金属阳离子（Ca²⁺、Mg²⁺、Fe³⁺、Zn²⁺）和腐殖酸（HA）对二者分离的影响。采用C₁₈色谱柱（25 cm×0.46 cm,5 μm）,流动相为pH值4.5的20%（v/v）甲醇水溶液（含4 mmol/L异亮氨酸（配体）和3 mmol/L CuSO₄）,流速为1.0 mL/min,柱温为40℃,检测波长为293 nm。氧氟沙星及其手性异构体左氧氟沙星可在18 min内分离,分离度（R）为2.70。结果表明,不同金属阳离子和腐殖酸对手性分离未见明显影响,但会降低氧氟沙星及其手性异构体的峰面积,其中Fe³⁺和高浓度腐殖酸的影响最大。该法能够快速高效测定地表水中氧氟沙星及其手性异构体,但在测试中需考虑Fe³⁺和高浓度腐殖酸的影响。     

污泥水解液基质微生物燃料电池的研究

研究不同污泥热水解时间下水解液特性及其对微生物燃料电池（MFC）产电的影响.水解时间由2 h增至96 h,水解液pH基本稳定于7.4 ~ 8.0;水解时间增加,其电导率逐渐提高至2.53 mS·cm^-1,COD浓度和碱度也不断增加,水解液的缓冲能力不断得到提高.MFC最大功率密度达到25 W·m^-3,COD去除率呈现先增后降,水解6 h时达到最大（47%）;库仑效率在预水解4 h时达到最高（71%）.阳极室pH下降可归因于NH⁴⁺、Na⁺、Ca²⁺、Mg²⁺等阳离子迁移,其中NH⁴⁺的迁移量最大.     

Ca2+离子掺杂对γ-Ce2S3合成温度及热稳定性的影响

以CeCl₃·7H₂O、CaCl₂·2H₂O和C₂H₂O₄·2H₂O为原料,在制备钙铈氧化物前驱体基础上,再以Ar气为载气、CS₂为硫源对钙铈氧化物前驱体进行硫化合成Ca²⁺掺杂的γ-Ce₂S₃色料。 通过X射线衍射(XRD)、紫外-可见漫反射光谱(UV-Vis)及差热-热重分析(TG-DTA)等技术手段表征了色料的结构和性能。 结果表明,Ca²⁺掺杂能够明显降低γ-Ce₂S₃的合成温度,当n(Ca²⁺):n(Ce³⁺)≥0.16时,在900 ℃硫化150 min即可获得纯相的γ-Ce₂S₃,与不掺杂时合成γ-Ce₂S₃的温度相比降低了300 ℃左右。 同时,Ca²⁺掺杂能够提升γ-Ce₂S₃的抗氧化能力,当n(Ca²⁺):n(Ce³⁺)=0.64时,氧化放热峰的温度由不掺杂时的490.6 ℃提高至541.0 ℃。     

Ca2+诱导的淀粉液化芽孢杆菌α-淀粉酶分子的生物活性和结构变化

在研究Ca²⁺对淀粉液化芽孢杆菌α-淀粉酶分子生物活性影响的基础上, 采用荧光光谱法和傅里叶变换红外光谱法研究了Ca²⁺诱导的酶分子结构变化. 结果表明, 当溶液中Ca²⁺浓度低于25.0 mmol/L时, Ca²⁺对酶分子具有激活作用; 而当Ca²⁺浓度高于25.0 mmol/L时, Ca²⁺对酶分子的生物活性具有抑制作用. 在Ca²⁺诱导的淀粉液化芽孢杆菌α-淀粉酶分子结构变化过程中, 酶分子仅发生二级结构的变化, 并不涉及其三级结构. 当Ca²⁺对酶分子具有激活作用时, 酶分子中的无规卷曲结构及β-折叠结构的含量下降, 而α-螺旋结构及β-转角结构的含量上升; 而当Ca²⁺对酶分子生物活性具有抑制作用时, 酶分子中的α-螺旋结构及β-转角结构的含量下降, 而无规卷曲结构及β-折叠结构的含量上升.     

NaA沸石离子交换过程的介电弛豫谱研究

在40 Hz~110 MHz频率段对不同Ca²⁺交换度的NaA沸石堆积体系进行了介电测量, 并利用Cole-Cole公式及Hanai方法对介电参数和相参数进行拟合与解析. 结果表明, 随着Ca²⁺交换度的不断增高, 堆积体系的介电增量、弛豫频率、弛豫分布系数以及粒子的电导率均有不同程度的降低, 而粒子的介电常数保持不变. 通过综合分析弛豫变化规律与离子交换度的内在联系发现, 离子交换后Ca²⁺选择六元环占位, 同时六元环和八元环位置的相邻2个Na⁺被置换; 占据六元环的Ca²⁺与八元环位置的Na⁺对沸石粒子的极化贡献等价; Ca²⁺的进入导致沸石孔道内微观电场多样化.     

稀土离子跨人血红细胞膜的荧光法研究

采用Fura-2荧光浓度指示剂对红细胞的稀土跨膜作用进行了系列研究.结果表明,稀土离子不能通过完整的红细胞膜进入细胞内.通过与离子载体实验相对照,发现细胞ATP耗竭后,低浓度的稀土离子(5×10^-6mol/L)不能跨膜进入ATP-耗竭红细胞.KCl去极化及加入电压依赖性钙通道刺激剂Bay-K8644对稀土离子的跨膜也没有促进作用.在Ca²⁺内流正常的情况下,低浓度稀土离子(5×10^-6mol/L)对钙离子内流无影响.增大稀土离子浓度到5×10^-4mol/L,用显微镜观察此时红细胞已开始溶血.在模拟胞内离子组分的缓冲液中(pH=7.05),比较了La³⁺,Eu³⁺和Ca²⁺对Fura-2的敏感程度.此条件下Fura-2对La³⁺和Eu³⁺的检测限分别为10-12和10-14mol/L,对Ca²⁺的检测限为10-8mol/L,并测得Fura-2-La³⁺(Eu³⁺)的络合比为1∶1,表观离解常数为1.7×10^-12和4.95×10^-14mol/L,表明用此法检测稀土离子跨膜行为相当灵敏有效.     

金属离子对蛇毒蛋白生物活性及结构效应的影响

从旅顺产白眉蝮蛇(Gloydius blomhoffii brevicaudus, GBB) 蛇毒中纯化得到了3种电泳和质谱纯蛋白活性组分, 其酶解肽段采用高效液相色谱-电喷雾串联质谱(HPLC-nESI-MS/MS)进行序列测定, 与其它同源性蛇毒蛋白氨基酸序列比对发现, 3种蛋白为新的蛇毒磷脂酶A₂、类凝血酶和金属蛋白酶, 分别将其命名为GBB-bPLA₂, GBB-TLE和GBB-MP. 电感耦合等离子体发射光谱法(ICP-AES) 测得每个GBB-bPLA₂和GBB-MP中含有一个Ca²⁺; 每个GBB-TLE中含有2个Zn²⁺. Ca²⁺可分别使GBB-bPLA₂和GBB-MP的荧光发射波长向短波方向移动2.0和1.6 nm, 使二者的荧光发射强度提高14.0%和11.0%; Ca²⁺的存在可显著提高二者的热稳定性, 使GBB-bPLA₂和GBB-MP的热变性温度分别提高1.5和2.0 ℃. Zn²⁺使GBB-TLE的荧光发射强度增高4.3%, 但对GBB-TLE的酯酶水解活性、荧光发射波长和热变性温度无显著影响. 金属离子的存在能够不同程度地影响蛇毒蛋白结构热稳定性, 但对蛇毒蛋白生物活性的作用则不同.     

金属组学在急性心肌梗死早期诊断的应用

为探讨急性心肌梗死(AMI)患者血清中K⁺、Na⁺、Ca²⁺、Fe²⁺、Mg²⁺含量变化，并研究其与心肌梗死患者之间的关系。选取2022年5月至2023年2月收治的AMI患者37例，同时选取健康体检者35例作为对照组。依据入院时或体检时收集的抽血样本进行临床生化分析，比较两组间血清K⁺、Na⁺、Ca²⁺、Fe²⁺、Mg²⁺含量，采用判别方程、主成分分析法(PCA),判断分析哪种金属离子对于心肌梗死的诊断价值大。结果表明，AMI患者的血清中Ca²⁺和Fe²⁺含量低于健康对照组，差异具有统计学意义。基于血钙、铁水平两组具有显著性差异，以它们为基础进行判别分析，获得判别函数式。将血清中K⁺、Na⁺、Ca²⁺、Fe²⁺、Mg²⁺     

冠醚对生物化学影响的研究(Ⅲ)——五种冠醚化合物对小麦幼苗根系吸收与运转42K、24Na、45Ca离子的影响

本文用放射性同位素⁴²K、²⁴Na、⁴⁵Ca作示踪,配以P^K、P^Na离子选择电极测量溶液的电导率和电位变化。研究五种冠醚化合物对南大八号小麦幼苗根系吸收与运转无机离子(K⁺、Na⁺、Ca^艹)的作用。实验结果表明,五种冠醚化合物对小麦幼苗根系具有不同程度的促进吸收和加速运转K⁺、Na⁺、Ca^艹的作用,其中以1号冠醚化合物作用最为明显,在K⁺、Na⁺、Ca⁺艹>中对K⁺的作用最为突出。     

Effect of La on heat production by mitochondria isolated from hybrid rice

The effect of lanthanum on mitochondria isolated from hybrid rice Fengyou 559 (Oryza sativa L.) was investigated. Through in vivo culture, low-dose La³⁺ promoted, but higher dose La³⁺, restrained mitochondrial heat production. However, through in vitro incubation, La³⁺ manifested only inhibitory action on mitochondrial energy turnover, the concentration required for 50% and 100% inhibition being 50.9 and 230.2 μM (57.6 nmol/mg protein), respectively. In addition, La³⁺, like Ca²⁺, induced rice mitochondrial swelling and decreased membrane potential (Δψ), which was inhibited by the specific permeability transition inhibitor cyclosporine A (CsA). The induction approached a constant limitation while mitochondrial metabolism was completely prevented by La³⁺, and microscopy observation showed a high disruption of inner mitochondrial membrane in this state. These results demonstrated that lanthanum influenced rice mitochondria in vivo and in vitro via different action pathways, and the latter involved the opening of rice mitochondrial permeability.     

Calcium oscillations in plant cell cytoplasm induced by red and far-red light irradiation

Light-mediated oscillations of cytoplasmic Ca²⁺ concentration in oat protoplasts were demonstrated using the fluorescence probe quin2 loaded into the cells. The oscillations are not due to an increase in cytoplasmic Ca²⁺ concentration and have no connection with the mitochondrial Ca⁺ pool. A possible association between the Ca⁺ oscillations and phosphoinositide metabolism in plant cell membranes is analysed.     

钙离子和镁离子浓度变化对磷脂酰乙醇胺-磷脂酰甘油双分子层膜的影响

Ca²⁺ and Mg²⁺ ions are the main divalent cations in living cells and play vital roles in the structure and function of biological membranes. To date, the differences in the effects of these two ions on the Escherichia coli (E. coli) inner membrane at various concentrations remain unknown. Here, the effects of Ca²⁺ and Mg²⁺ ions on a mixed lipid bilayer composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine (POPE) and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoglycerol (POPG) in a 3 : 1 ratio (mol/mol), which mimics the E. coli inner membrane, were quantitatively differentiated at different concentrations by dynamic light scattering (DLS), zeta potential measurements and all-atom molecular dynamics (AA-MD) simulations. The DLS results demonstrated that the POPE/POPG liposomes were homogeneous and monodisperse in solutions with Ca²⁺ or Mg²⁺ ion concentrations of 0 and 1 mmol∙L^-1. As the Ca²⁺ or Mg²⁺ ion concentration was increased to 5-100 mmol∙L^-1, lipid aggregation or the fusion of unilamellar liposomes occurred in the ion solutions. The zeta potential measurements showed that both the Ca²⁺ and Mg²⁺ ions had overcharging effects on the negatively charged POPE/POPG liposomes. The AA-MD simulation results indicated that the Ca²⁺ ions irreversibly adsorbed on the membranes when the simulation time was longer than 100 ns, while the Mg²⁺ ions were observed to dynamically adsorb on and desorb from the membranes at various concentrations. These results are consistent with the DLS and zeta potential experiments. The average numbers of Ca²⁺ and Mg²⁺ ions in the first coordination shell of the oxygen atoms of the phosphate, carbonyl and hydroxyl groups of POPE and POPG (i.e., the first coordination numbers) in the pure membrane and membranes containing 5 and 100 mmol∙L^-1 ions were calculated from the radial distribution functions. The results indicated that the primary binding site of these two ions on POPE and POPG at the concentrations studied was the negatively charged phosphate group. Thus, these results might explain the overcharging effects of both the Ca²⁺ and Mg²⁺ ions on the POPE/POPG liposomes. Moreover, as the Ca²⁺ concentration increased, the area per lipid of the lipid bilayers decreased, and the membrane thickness increased, while the Mg²⁺ ions had negligible effects on these membrane parameters. In addition, these ions had different effects on the orientation of the lipid head groups. These simulation results may be used to provide the possible explanations for the differences between Ca²⁺ and Mg²⁺ ions in DLS and zeta potential measurements at the atomic level. The experimental results and MD simulations provide insight into various biological processes regulated by divalent cations, such as membrane fusion.     

Influence of K+, Na+ or Ca2+ Ions on the Interaction Between AmB and Saturated Phospholipids by Langmuir Technique

Interaction between amphotericin B(AmB) and cell membrane is influenced by different metal cations. In the presence of K⁺, Na⁺ or Ca²⁺ ions, the surface pressure-area isotherms and the elastic modulus of an amphotericindipalmitoylphosphatidylcholine(AmB-DPPC) mixed monolayer were discussed. And the excess free energy and entropies of mixing were calculated according to the surface pressure-area isotherms. The phase transition of the mixed monolayer needed a higher concentration of AmB in the sequence Na⁺ > pure buffer > K⁺ > Ca²⁺. When the molar fraction of AmB(x_AmB) was 0.5, the molecular interaction changed from attraction to repulsion and the mixed monolayer turned to ordered state from disorder state under the induction of K⁺ or Ca²⁺ ions at all surface pressure in our experiment. At high surface pressure, the disorder of monolayer enhanced in the presence of Na⁺ ions at x_AmB > 0.1. At different molar ratios of AmB, the influences of these metal cations were discrepant. These cations may influence AmB molecules to form pores on the monolayer. It is helpful to understand the reduction of AmB's toxicity as theoretical reference.     

Surface properties of plasma membrane vesicles isolated from melon (Cucumus melo L.) root cells differing in salinity tolerance

The hypotheses that genotypic differences in salinity tolerance may result from (i) differences in global surface charge density or (ii) from differences in global Ca²⁺ binding were tested. An attempt was made to correlate the differing salinity tolerance of four melon cultivars with surface properties of vesicles extracted from the plasma membrane (PM) of their root cells. Surface characterization involved measurements of electrophoretic mobility and sorption of ⁴⁵Ca²⁺ to the vesicles in the presence of varying concentrations of Ca²⁺, Na⁺ and Mg²⁺. Irrespective of salinity tolerance, vesicles from the four cultivars yielded similar ζ potentials under similar conditions, indicating similar global surface charge densities. Sorption studies with vesicles from two cultivars differing in salinity tolerance predicted independently this result of equal surface charge density. The estimated global binding affinities of Ca²⁺, Na⁺ and Mg²⁺ to the PM of both cultivars were the same with binding coefficients of 50, 0.8 and 9 M⁻¹, respectively. Consequently, the hypotheses enumerated above to interpret genotypic differences in salinity toxicity are rejected. However, vesicles from the salt-resistant strain sorbed 19% more Ca²⁺ per given amount of protein in the membrane, indicating the existence of a larger number of negatively charged surface sites per given amount of protein and a smaller amount of protein per given area of membrane. Genotypic differences in site-specific Ca²⁺-binding affinity (e.g. at ion channels) remain a viable hypothesis for genotypic differences in salinity tolerance.     

基于碳纳米管/Ag/MoS2转导层的全固态钙离子选择电极

构建了一种电势稳定性好的全固态钙离子选择电极(Ca²⁺-ISE),采用碳纳米管(CNT)/Ag/MoS₂为转导层,自制的三脚架化合物作为钙离子载体,制备固体接触式Ca²⁺-ISE。 系统分析了全固态Ca²⁺-ISE的稳定性、能斯特斜率、响应范围、选择性系数等主要性能,发现制备的固体接触式Ca²⁺-ISE在钙离子浓度为1×10^-6~1×10^-1 mol/L范围内呈现线性能斯特响应,响应斜率为28.1 mV/decade。 CNT/Ag/MoS₂的引入有利于提高固体接触式Ca²⁺-ISE的离子浓度线性响应范围,缩短电势平衡时间,降低测试能斯特斜率与理论值差,对于Ca²⁺-ISE的长期在线检测有重要研究意义。     

co-Condensation Synthesis of Salicylaldimine Calcium Complex Containing Mesoporous Silica Nanoparticles as Carriers for Drug Release

A series of functional mesoporous silica nanoparticles（MSNs） was synthesized by a one-step simple synthesis approach involving co-condensation of tetraethoxysilane（TEOS） and salicylaldimine ligand（Sal-Si） in the presence of cetyltrimethylammonium chloride（CTAC） under basic conditions.The target MSNs with different sizes （50,100 and 200 nm,respectively） were obtained.Furthermore,the Ca^2＋ cations were also introduced into MSNs.The prepared nanoparticles were characterized by means of infrared（IR） spectra,thermogravimetric analysis（TGA）,inductively coupled plasma（ICP）,CHN elemental analysis,nitrogen adsorption-desorption,scanning electron microscope（SEM） and transmission electron microscope（TEM）.Ibuprofen（IBU） which contains carboxyl groups was selected as a model drug.The results of drug loading and release reveal that the loading capacities and release behaviors of the model drug are highly dependent on the Ca^2＋ cations in MSNs.The release of IBU from the MSNs functionalized by Ca^2＋ cations is found to be effectively controlled when compared to the release from the MSNs without the functionalization of Ca^2＋ cations,which is due to the ionic interaction between carboxyl groups in IBU and Ca^2＋ cations in MSNs.     

Ion-exchange properties of hypercrosslinked polystyrene impregnated with methyl orange

A novel bipolar stationary phase (HCPS–MO) was prepared by impregnation of hypercrosslinked polystyrene (HCPS) with methyl orange (MO; 4-dimethylamino-4′-sulfoazobenzene) and its ion-exchange properties were studied. Simultaneous separation of cations and anions on HCPS–MO is possible, although it behaves preferentially as a cation-exchanger. Unusual selectivity of HCPS-MO for alkali and alkaline-earth metal cations: Na⁺+K⁺+4⁺+ and Mg²⁺2+2+2+ was observed. The effect of temperature on retention of alkali and alkaline-earth metal cations was studied. Separation of Na⁺, K⁺, Rb⁺, NH₄⁺, Cs⁺, Mg²⁺ and Ca²⁺ on HCPS–MO with diluted cerium(III) nitrate solution as an eluent in single run is presented.