溴氰菊酯对兔红细胞内Na+浓度影响的 23Na NMR研究

细胞内Na~+浓度[Na_(in)~+]的大小具有重要的生理意义。位移试剂Dy(PPP)_2~(7-)[二(三聚磷酸)合镝(Ⅲ)离子]能使细胞外Na~+(Na_(out)~+)共振频率向高场位移,使得~(23)Na NMR在不破坏细胞结构的条件下直接观察Na_(in)~+成为可能,国内这方面的研究甚少。有研究指出,     

活细胞 23Na-NMR研究进展；水溶性位移试剂的应用

钠离子(N⁺)是生物体内最重要的无机阳离子之一。引入适当的水溶性位移试剂(SR),应用 ²³Na核磁共振波谱( ²³Na-NMR)技术,是研究活细胞中N⁺代谢的二条新途径。本文综述了活细胞中 ²³Na-SR-NMR研究的实验方法及其研究进展。     

大鼠红细胞作为SOD新型载体的细胞水平上的研究

用低渗透析 -等渗重封的方法制备了包埋超氧化物歧化酶 ( SOD)的大鼠载体红细胞 ,并从细胞水平上研究了透析条件对大鼠红细胞包埋 SOD的影响与载体红细胞的部分性质 .流式细胞计( FCM)研究表明 ,随透析时间延长和透析液渗透压降低 ,包埋 SOD的载体红细胞百分率升高 ,但载体细胞平均包埋 SOD的量无明显变化 ;SOD浓度对载体细胞百分率无明显影响 ,但与载体细胞平均包埋 SOD的量成线性关系 ;载体红细胞前向角散射 ( FLS)明显下降 ,但显微镜下观察到的载体细胞的大小无明显变化 ,当载体细胞反注射到大鼠体内后 FLS能迅速恢复 ;载体红细胞密度下降 ,其原因是低渗透析时红细胞膨胀未能完全恢复 ;载体红细胞未暴露与自身 Ig G结合的抗原位点 .激光扫描共聚焦显微镜 ( LSCM)分析表明 ,SOD在细胞内呈从细胞中心到细胞膜浓度逐步下降的辐射分布特征 .     

阳离子对豚鼠Ⅱ型前庭毛细胞ACh-敏感性电流的调制

本文旨在探讨哺乳动物前庭胆碱能传出神经系统的作用机制,应用全细胞膜片钳技术研究新鲜分离的豚鼠Ⅱ型前庭毛细胞ACh-敏感性电流的特性以及细胞内外的阳离子对ACh-敏感性电流的调制作用。结果显示,Ⅱ型前庭毛细胞对细胞外ACh敏感,ACh激活缓慢持久的外向性电流,室温下此电流的再次完全激活时间约为(60±10)s。ACh-敏感性电流的反转电位为(-66±8)mV,提示此电流主要由K+参与形成,其直接作用是使毛细胞超极化。ACh-敏感性电流对较高浓度的四乙胺(tetraethylammonium chloride,TEA)敏感,提示细胞外ACh激活钙依赖性钾电流。进一步检测细胞内外阳离子对 ACh-敏感性电流的调制作用发现,细胞外Na+和细胞内Ca2+释放不参与此电流的激活过程,而细胞外K+、细胞外Ca2+和细胞内Mg2+对ACh-敏感性电流具有重要的调制作用。进一步提示,ACh是哺乳动物前庭传出神经系统重要的神经递质。 Na+不参与ACh-敏感性电流的激活过程提示,ACh-敏感性电流可能由非α9-N型胆碱能受体(α9-nAChR)介导。ACh诱导的Ⅱ型前庭毛细胞超极化作用受细胞外Ca2+浓度和细胞内Mg2+浓度调制。     

三齿草藤(Vicia bungei Ohwi)凝集素的细胞表面受体研究

应用亲和层析法从三齿草藤(Vicia bungei Ohwi)种子中纯化的三齿草藤凝集素(VBL),可以凝集兔和豚鼠的红细胞,也可凝集人、牛和羊的精细胞,说明这些细胞表面存在有VBL的受体。用FITC和~(125)I进行标记,可得到FITC-VBL和~(125)I-VBL,其生物学活性不受影响。氯胺T法的标记率可达55％;应用FITC-VBL研究牛精细胞和兔红细胞膜上VBL受体的分布,发现二者由胞膜上受体分布据不一致。VBL与牛精细胞结合条件的正交试验表明细胞浓度的影响最大。用不同量的未标记的VBL对~(125)I-VBL与兔红细胞和人精细胞的结合实验,以Scatchard法作图,兔红细胞得一类似于双曲线的凹形曲线,提示该细胞膜上受体的性质有所不同,而人精细胞却有很大差异。若以兔红细胞膜上存在有高低亲和力两种受体进行计算,可求得结合常数和每个细胞上的受体数。应用几种单糖和外源凝集素影响~(125)I-VBL与兔红细胞的结合,当单糖(D-Man,D-Glc)浓度为0.01M时,相对结合率开始急剧下降,单糖浓度若增至0.1M时,其相对结合率仅为40％,而PHA-P和SML浓度为1mg/ml时,相对结合率开始下降,当浓度达10mg/ml时,相对结合率下降至30％左右。     

瞬时受体电位通道研究进展

瞬时受体电位通道(TRP channels)是位于细胞膜上的一类重要的阳离子通道超家族.根据氨基酸序列的同源性,将已发现的28种哺乳动物,TRP通道分为:TRPC、TRPV、TRPM、TRPA、TRPP和TRPML 6个亚家族.所有的TRP通道都具有6次跨膜结构域.不同的TRP通道对钙离子和钠离子选择性不同.TRP通道分布广泛,调节机制各异,通过感受细胞内外环境的各种刺激,参与痛温觉、机械感觉、味觉的发生和维持细胞内外环境的离子稳态等众多生命活动.     

维生素D3对三角帆蚌外套膜细胞内Ca2+浓度的影响

采用胰酶消化法获得三角帆蚌(Hyriopsis cumingii)外套膜细胞,用Fluo-3/AM荧光标记技术和激光共聚焦扫描显微镜(confocal laser scanning microscope,CLSM)检测外套膜内外表皮细胞在静息状态下细胞的游离ca2+浓度及不同浓度维生素D.(VD.)孵育后的外套膜细胞的...     

阳离子聚丙烯酰胺的合成及其表征

合成了阳离子功能单体甲基丙烯酰氧乙基二甲基丁基溴化铵(DMB),并将DMB与丙烯酰胺(AM)共聚制备了阳离子聚丙烯酰胺,并用IR,NMR对其结构进行了表征。     

阳离子脂质体对HepG2.2.15细胞病毒分泌、毒性及凋亡的影响

目的:探讨阳离子脂质体作为基因治疗药物载体对HepG2.2.15细胞的病毒分泌、毒性及凋亡的研究.方法:以2.5、5.0、7.510.0 μL/mL浓度的阳离子脂质体转染HepG2.2.15细胞,共温育10 d,ELISA法检测细胞上清中HBsAg和HBeAg含量的变化.转染48 h后,MTT法检测阳离子脂质体对细胞的毒性、荧光显微镜检测细胞凋亡情况.结果:各个剂量组阳离子脂质体对HepG2.2.15细胞均有抑制作用,其中10 μL/mL组在第10 d对HBsAg、HBeAg抑制率分别达31.5%、29.9%,表现出较高的毒性作用.2.5、5.0、7.5 10.0 μL/mL阳离子脂质体转染HepG2.2.15细胞后,MTT检测结果显示其细胞存活率分别为82.14%、77.62%、77.4%、61.9%.荧光显微镜下可见各浓度组均有凋亡,且随脂质体剂量增加细胞凋亡数增加.结论:阳离子脂质体能抑制HepG2.2.15细胞分泌HBsAg和HBeAg,其毒性及诱导凋亡作用呈剂量和时间依赖性.作为基因治疗药物载体时,剂量宜小于7.5 μL/mL.     

海藻糖载入红细胞及其冷冻干燥的实验研究

冷冻干燥保存是长期保存人体红细胞的理想方案之一。冻干保护剂海藻糖渗入细胞内后,对细胞膜和细胞内物质有保护作用,其中的一个作用是增加细胞质的浓度,使冻干过程容易形成稳定的玻璃态。应用高渗法处理红细胞,通过考察胞内海藻糖含量、红细胞冻干后的存活率、腺苷三磷酸酶(ATPase)、超氧化物歧化酶(SOD)活力以及细胞形态变化,研究胞内海藻糖含量对红细胞冻干后活性的影响。结果显示:海藻糖对红细胞冻干具有明显的保护作用,随胞内海藻糖浓度升高,其保护性能逐渐增强;43.8mmol/L的胞内海藻糖浓度对红细胞保护最好,细胞存活率达到53.6%,形态保持良好,ATP和SOD活力均在正常的范围内。     

Nuclear magnetic resonance monitoring of sodium in biological tissues

In recent year, the 23Na nuclear magnetic resonance (NMR) technique has been applied to the study of biological tissues. The advantages of this method are noninvasiveness and good sensitivity. The resonances of the intra- and extra-cellular sodium can be separated by the addition of shift reagents to the extracellular compartment. The method has been mostly applied to cell suspensions, kidney tubules, glands, and small organs. Owing to line-broadening effects, the NMR visibility of the intracellular sodium is reduced to 40% in most cases but can be lower or higher. Time-dependent measurements are possible with adequate life-supporting equipment, allowing the determination of transport parameters. 23Na relaxation times are short in tissues (below 50 ms) and highly dependent on the medium composition. The application of the 23Na NMR technique to intact organs can be hampered by the difficulty of getting a good distribution of the shift reagent in the extracellular milieu. A summary of the studies performed is presented with specific examples to illustrate typical applications.     

双量子滤波（DQF）核磁共振研究细胞内钠

双量子滤波（ＤＱＦ）核磁共振研究细胞内钠屠萍官,张日清,赵南明（清华大学生物科学与技术系生物膜与膜生物工程国家重点实验室北京１０００８４）用核磁共振位移试剂实现了细胞内销的动态研究［１］。但由稀土元素组成的位移试剂是否具有毒性至今仍有争议［２－４］。...     

23Na NMR study of intracellular sodium ions in Dictyostelium discoideum amoeba

The intracellular sodium concentration in the amoebae from the slime mold Dictyostelium discoideum has been studied using 23Na NMR. The 23Na resonances from intracellular and extracellular compartments could be observed separately in the presence of the anionic shift reagent Dy(PPPi)7-2 which does not enter into the amoebae and thus selectively affects Na+ in the extracellular space. 31P NMR was used to control the absence of cellular toxicity of the shift reagent. The intracellular Na+ content was calculated by comparison of the intensities of the two distinct peaks arising from the intra- and extracellular spaces. It remained low (0.6 to 3 mM) in the presence of external Na+ (20 to 70 mM), and a large Na+ gradient (20- to 40-fold) was maintained. A rapid reloading of cells previously depleted of Na+ was readily measured by 23Na NMR. Nystatin, an antibiotic known to perturb the ion permeability of membranes, increased the intracellular Na+ concentration. The time dependence of the 23Na and 31P NMR spectra showed a rapid degradation of Dy(PPPi)7-2 which may be catalyzed by an acid phosphatase.     

In vivo measurements of intra- and extracellular Na+ and water in the brain and muscle by nuclear magnetic resonance spectroscopy with shift reagent.

The introduction of new paramagnetic shift reagents in the nuclear magnetic resonance (NMR) method has made it possible to distinguish intra- and extracellular ions in tissues or organs in vitro. We measured the intra- and extracellular 23Na and 1H in vivo in the gerbil brain and skeletal muscle by NMR spectroscopy employing the shift reagent, dysprosium triethylenetetraminehexaacetate (Dy[TTHA]3-). Without Dy(TTHA)3-, the 23Na and 1H signals were seen only as single peaks, but gradual intravenous infusion of Dy(TTHA)3- separated these signals into two peaks, respectively. The unshifted peaks reflected the intracellular 23Na and 1H signals, while the shifted peaks reflected the extracellular signals. In the brain spectra, an additional small peak, which represented intravascular signals, was detected and its intensity increased after injection of papaverine hydrochloride. The present method is advantageous over the microelectrode technique because of its nondestructiveness and its capability for obtaining intra- and extracellular volume information from measurements of the 1H spectra, the peaks of which reflect the intra- and extracellular water amounts. The intracellular Na+ increase associating with increased cellular volume after ouabain in the muscle was clearly visualized by this method. The technique is clearly of use for physiological and pathophysiological studies of organs.     

Measurement of a wide range of intracellular sodium concentrations in erythrocytes by 23Na nuclear magnetic resonance.

The accuracy of the 23Na nuclear magnetic resonance (NMR) method for measuring the sodium concentration in erythrocytes was tested by comparing the NMR results to those obtained by emission-flame photometry. Comparisons were made on aqueous solutions, hemolysates, gels, ghosts, and intact erythrocytes. The intra- and extracellular 23Na NMR signals were distinguished by addition of the dysprosium tripolyphosphate [Dy(PPP)7-2] shift reagent to the extracellular fluid. The intra- and extracellular volumes of ghosts and cells were determined by the isotope dilution method. Our results indicate that greater than 20% of the intracellular signal remains undetected by NMR in ghosts and cells. When the cells are hemolyzed, the amount of NMR-detectable sodium varies depending on the importance of gel formation. In hemolysates prepared by water addition, the NMR and flame photometry results are identical. The loss of signal in ghosts, cells, and undiluted hemolysates is attributed to partial binding of the Na+ ion to intracellular components, this binding being operative only when these components exist in a gel state. In a second part, 31P NMR was used to monitor the penetration of the shift reagent into the cells during incubation. Our data demonstrate that free Dy3+ can slowly accumulate inside the red cell.     

A micromethod for the stereochemical analysis of fatty acid desaturase-mediated sulfoxidation reactions

The stereochemistry of fatty acid desaturase-mediated sulfoxidation can be evaluated at micromolar concentrations of analyte using (19)F NMR in combination with a chiral shift reagent: (S)-(+)-MPAA.     

NMR studies of intracellular sodium ions in mammalian cardiac myocytes

The unambiguous measurement of intracellular sodium ion [Na+]i by the noninvasive NMR technique offers a new opportunity to monitor precisely the maintenance and fluctuations of [Na+]i levels in intact cells and tissues. The anionic frequency shift reagent, dysprosium (III) tripolyphosphate, which does not permeate intact cells, when added to suspensions of intact adult rat cardiac myocytes, alters the NMR frequency of extracellular sodium ions, [Na+]o, leaving that of intracellular ions, [Na+]i, unaffected. Using 23Na NMR in conjunction with this shift reagent, we have determined NMR-visible intracellular Na+ ion concentration in a suspension of isolated cardiac myocytes under standard conditions with insulin and Ca2+ in the extracellular medium to be 8.8 +/- 1.2 mmol/liter of cells (n = 4). This value is comparable to that measured by intracellular ion-selective microelectrodes in heart tissue. Cardiac myocytes incubated for several hours in insulin-deficient, Ca2+-containing medium prior to NMR measurement exhibited a somewhat lower [Na+]i value of 6.9 +/- 0.5 mmol/liter of cells (n = 3). Reversible Na+ loading of the cells by manipulation of extracellular calcium levels is readily measured by the NMR technique. Incubation of myocytes in a Ca2+-free, insulin-containing medium causes a 3-fold increase in [Na+]i to a level of 22.8 +/- 2.6 mmol/liter of cells (n = 10). In contrast to cells with insulin, insulin-deficient myocytes exhibit a markedly lower level of [Na+]i of only 14.6 +/- 2.0 mmol/liter of cells (n = 4) in Ca2+-free medium. These observations suggest that insulin may stimulate a pathway for Na+ influx in heart cells.     

Multinuclear NMR studies of the Langendorff perfused rat heart

The quantitation of intracellular sodium ion concentration [Na+]in perfused organs using NMR spectroscopy requires a knowledge of the extent of visibility of the 23Na resonance and of the intracellular volume of the organ. We have used a multinuclear NMR approach, in combination with the extracellular shift reagent dysprosium (III) tripolyphosphate, to determine the NMR visibility of intra- and extracellular 23Na and 35Cl ions, intracellular volume, and [Na+]in in the isolated Langendorff perfused rat heart. Based on a comparison of the extracellular volumes calculated using 2H and 23Na, 35Cl, or 59Co NMR of the perfused heart we conclude that resonances of extracellular sodium and chloride ions (including ions in interstitial spaces) are fully visible, contrary to assumptions in the literature. Furthermore, prolonged hypoxia or ischemia caused a dramatic increase in intracellular Na+ and [Na+] in rose to approach that in the external medium indicating full visibility of the intracellular 23Na resonance. Resonance intensities of intra- and extracellular 23Na ions, along with a knowledge of the extracellular space as a fraction of the total organ water space, yielded an average [Na+] in of about 10 mM (10 +/- 1.5 mM) for the rat heart at 37 degrees C. Double-quantum filtered 23Na NMR of the perfused rat heart in the absence and presence of paramagnetic reagents revealed, contrary to assumptions in the literature, that both intra- and extracellular sodium ions contribute to the detected signal.     

Lanthanide complexes of aminophosphonates as shift reagents for 7Li and 23Na NMR studies in biological systems.

A systematic NMR characterization of various Dy(III) complexes of linear and macrocyclic aminophosphonates as 7Li and 23Na NMR shift reagents for biological systems was undertaken. Their efficacy as shift reagents (SR) was tested under constant aqueous solution ionic strength conditions at pH 7.5 as a function of rho = [SR]/[M+]. Further characterization of the two best SRs, Dy(PcPcP)2(7-) and Dy(DOTP)5-, led to the conclusion that, although quite sensitive to solution pH and the presence of alkali metal ions and Mg2+ and Ca2+, these complexes were stable towards hydrolysis by phosphatases. The lack of precipitation of its solutions in the presence of Ca2+, allowed the choice of Dy(DOTP)5- as the best overall SR for biological studies. Other SRs, like Dy(TTHA)3-, although less sensitive to pH and to divalent ions, require significantly higher concentrations to yield the same shifts, leading to large bulk susceptibility artifacts in perfused tissues and organs.     

Direct High-resolution Nuclear Magnetic Resonance Studies of Cation Transport in Vivo: Na+ Transport in Yeast Cells

A new nuclear magnetic resonance (NMR) method for monitoring transmembrane metal cation transport is reported. It is illustrated with a study of Na⁺ efflux from Na⁺-rich yeast cells. The technique involves the use of an anionic paramagnetic shift reagent, present only outside the cells, to induce a splitting of the sodium-23 NMR peak, in this case, into components representing intra- and extracellular Na⁺. The time course of the efflux is in good agreement with the literature and can be well fitted with a double exponential decay expression. Splitting of the lithium-7 NMR signal from a suspension of Li⁺-rich respiratory-deficient, petite yeasts is also reported.