The transport kinetics of lanthanide species in a single erythrocyte probed by confocal laser scanning microscopy

Effective assessment of lanthanide ion delivery into live cells by paramagnetic NMR spectroscopy

We report an effective assessment of lanthanide ion (Ln3+) delivery into live cells by paramagnetic NMR spectroscopy. Free Ln3+ ions are toxic to live cells resulting in a gradual leakage of target proteins to the extracellular media. The citrate-Ln3+ complex is an efficient and mild reagent over the free Ln3+ form for live cell delivery.

Lanthanide-Binding Tags for 3D X-ray Imaging of Proteins in Cells at Nanoscale Resolution

We report the application of lanthanide-binding tags (LBTs) for two- and three-dimensional X-ray imaging of individual proteins in cells with a sub-15 nm beam. The method combines encoded LBTs, which are tags of minimal size (ca. 15-20 amino acids) affording high-affinity lanthanide ion binding, and X-ray fluorescence microscopy (XFM). This approach enables visualization of LBT-tagged proteins while simultaneously measuring the elemental distribution in cells at a spatial resolution necessary for visualizing cell membranes and eukaryotic subcellular organelles.

Lanthanide-based tools for the investigation of cellular environments

Biological probes constructed from lanthanides can provide a variety of readout signals, such as the luminescence of Eu(iii), Tb(iii), Yb(iii), Sm(iii) and Dy(iii), and the proton relaxation enhancement of Gd(iii) and Eu(ii). For numerous applications the intracellular delivery of the lanthanide probe is essential. Here, we review the methods for the intracellular delivery of non-targeted complexes (i.e. where the overall complex structure enhances cellular uptake), as well as complexes attached to a targeting unit (i.e. to a peptide or a small molecule) that facilitates delivery. The cellular applications of lanthanide-based supramolecules (dendrimers, metal organic frameworks) are covered briefly. Throughout, we emphasize the techniques that can confirm the intracellular localization of the lanthanides and those that enable the determination of the fate of the probes once inside the cell. Finally, we highlight methods that have not yet been applied in the context of lanthanide-based probes, but have been successful in the intracellular delivery of other metal-based probes.

Physiological concept for a blood based CFTR test

We tested the hypothesis that the cystic fibrosis transmembrane conductance regulator (CFTR) could be involved in the volume regulation of human red blood cells (RBC). Experiments were based on two gadolinium (Gd(3+)) sensitive mechanisms, i.e. inhibition of ATP release (thetaATP(i)) and membrane destabilization. RBC of either cystic fibrosis (CF) patients or healthy donors (non-CF) were exposed to KCl buffer containing Gd(3+). A significantly larger quantity of non-CF RBC (2.55 %) hemolyzed as compared to CF RBC (0.89 %). It was found that both of the Gd(3+) mechanisms simultaneously are needed to achieve hemolysis, since either overriding thetaATP(i) by exogenous ATP addition prevented Gd(3+) induced hemolysis, or mimicking thetaATP(i) by apyrase in absence of Gd(3+) could not trigger hemolysis. Additionally, ion driven volume uptake was found to be a prerequisite for Gd3+ induced hemolysis as chloride and potassium channel blockers reduced the Gd(3+) response. The results show that in non-CF RBC Gd(3+) exerts its dual effect leading to hemolysis. On the contrary, in CF RBC, lacking CFTR dependent ATP release, the sole Gd(3+) effect of membrane destabilization is not sufficient to induce hemolysis similar to non-CF. This concept could form the basis of a novel method suitable for testing CFTR function in a blood sample.

Binding of La3+ to calmodulin and its effects on the interaction between calmodulin and calmodulin binding peptide, polistes mastoparan

Binding of La(3+) to calmodulin (CaM) and its effects on the complexes of CaM and CaM-binding peptide, polistes mastoparan (Mas), were investigated by nuclear magnetic resonance (NMR) spectroscopy, fluorescence and circular dichroism spectroscopy, and by the fluorescence stopped-flow method. The four binding sites of La(3+) on CaM were identified as the same as the binding sites of Ca(2+) on CaM through NMR titration of La(3+) to uniformly (15)N-labeled CaM. La(3+) showed a slightly higher affinity to the binding sites on the N-terminal domain of CaM than that to the C-terminal. Large differences between the (1)H-(15)N heteronuclear single quantum coherence (HSQC) spectra of Ca(4)CaM and La(4)CaM suggest conformational differences between the two complexes. Fluorescence and CD spectra also exhibited structural differences. In the presence of Ca(2+) and La(3+), a hybrid complex, Ca(2)La(2)CaM, was formed, and the binding of La(3+) to the N-terminal domain of CaM seemed preferable over binding to the C-terminal domain. Through fluorescence titration, it was shown that La(4)CaM and Ca(2)La(2)CaM had similar affinities to Mas as Ca(4)CaM. Fluorescence stopped-flow experiments showed that the dissociation rate of La(3+) from the C-terminal domain of CaM was higher than that from the N-terminal. However, in the presence of Mas, the dissociation rate of La(3+) decreased and the dissociation processes from both global domains were indistinguishable. In addition, compared with the case of Ca(4)CaM-Mas, the slower dissociations of Mas from La(4)CaM-Mas and Ca(2)La(2)CaM-Mas complexes indicate that in the presence of La(3+), the CaM-Mas complex became kinetically inert. A possible role of La(3+) in the Ca(2+)-CaM-dependent pathway is discussed.

Fluorescence analysis of aldolase dissociation from the N-terminal of the cytoplasmic domain of band 3 induced by lanthanide

The cytoplasmic domain of band 3 (CDB3) offers binding sites for several glycolytic enzymes and regulates the glycolysis of erythrocyte. The interaction between recombinant (His)(6)-tagged CDB3 and aldolase, one of the key enzymes that participated in erythrocyte glycolysis, was investigated in the presence of lanthanide. The results indicate that trace lanthanide blocks the inhibition of CDB3-(His)(6) to aldolase and leads to enhancement of aldolase activity. In agreement with activity studies, fluorescence spectra reveal that 4 microM lanthanum ions induce the complete dissociation of aldolase from the N-terminal of CDB3-(His)(6). Interestingly, the synchronous scanning fluorescence spectra of proteins in the presence of various concentrations of lanthanum ions suggest that the conformational change of CDB3-(His)(6) is significantly attributed to the alteration of tryptophan cluster microenvironment, while the aldolase conformation change is mainly derived from tyrosine microenvironment changes. Based on the observation that lanthanide ions induce the dissociation of aldolase from CDB3-(His)(6), it is suggested that the existence of trace lanthanide may affect the glycolysis of erythrocyte.

Complexation of ytterbium to human transferrin and its uptake by K562 cells

There is an increasing interest in the use of lanthanides in medicine. However, the mechanism of their accumulation in cells is not well understood. Lanthanide cations are similar to ferric ions with regard to transferrin binding, suggesting transferrin-receptor mediated transport is possible; however, this has not yet been confirmed. In order to clarify this mechanism, we investigated the binding of Yb3+ to apotransferrin by UV-Vis spectroscopy and stopped-flow spectrophotometry, and found that Yb3+ binds to apotransferrin at the specific iron sites in the presence of bicarbonate. The apparent binding constants of these sites showed that the affinity of Yb3+ is lower than that of Fe3+and binding of Yb3+ in the N-lobe is kinetically favored while the C-lobe is thermodynamically favored. The first Yb3+ bound to the C-lobe quantitatively with a Yb/apotransferrin molar ratio of < 1, whereas the binding to the other site is weaker and approaches completeness by a higher molar ratio only. As demonstrated by 1H NMR spectra, Yb3+ binding disturbed the conformation of apotransferrin in a manner similar to Fe3+. Flow cytometric studies on the uptake of fluorescein isothiocyanate labeled Yb3+-bound transferrin species by K562 cells showed that they bind to the cell receptors. Laser scanning confocal microscopic studies with fluorescein isothiocyanate labeled Yb3+-bound transferrin and propidium iodide labeled DNA and RNA in cells indicated that the Yb3+ entered the cells. The Yb3+-transferrin complex inhibited the uptake of the fluorescein labeled ferric-saturated transferrin (Fe2-transferrin) complex into K562 cells. The results demonstrate that the complex of Yb3+-transferrin complex was recognized by the transferrin receptor and that the transferrin-receptor-mediated mechanism is a possible pathway for Yb3+ accumulation in cells.

Lanthanide ions induce hydrolysis of hemoglobin-bound 2,3-diphosphoglycerate (2,3-DPG), conformational changes of globin and bidirectional changes of 2,3-DPG-hemoglobin's oxygen affinity

The changes in structure and function of 2,3-diphosphoglycerate-hemoglobin (2,3-DPG-Hb) induced by Ln(3+) binding were studied by spectroscopic methods. The binding of lanthanide cations to 2,3-DPG is prior to that to Hb. Ln(3+) binding causes the hydrolysis of either one from the two phosphomonoester bonds in 2,3-DPG non-specifically. The results using the ultrafiltration method indicate that Ln(3+) binding sites for Hb can be classified into three categories: i.e. positive cooperative sites (N(I)), non-cooperative strong sites (N(S)) and non-cooperative weak sites (N(W)) with binding constants in decreasing order: K(I)>K(S)>K(W). The total number of binding sites amounts to about 65 per Hb tetramer. Information on reaction kinetics was obtained from the change of intrinsic fluorescence in Hb monitored by stopped-flow fluorometry. Fluctuation of fluorescence dependent on Ln(3+) concentration and temperature was observed and can be attributed to the successive conformational changes induced by Ln(3+) binding. The results also reveal the bidirectional changes of the oxygen affinity of Hb in the dependence on Ln(3+) concentration. At the range of [Ln(3+)]/[Hb]<2, the marked increase of oxygen affinity (P(50) decrease) with the Ln(3+) concentration can be attributed to the hydrolysis of 2,3-DPG, while the slight rebound of oxygen affinity in higher Ln(3+) concentration can be interpreted by the transition to the T-state of the Hb tetramer induced by Ln(3+) binding. This was indicated by the changes in secondary structure characterized by the decrease of alpha-helix content.

Inhibition of TRP3 channels by lanthanides. Block from the cytosolic side of the plasma membrane

The lanthanide ions La(3+) and Gd(3+) block Ca(2+)-permeable cation channels and have been used as important tools to characterize channels of the transient receptor potential (TRP) family. However, widely different concentrations of La(3+) and Gd(3+) have reportedly been required for block of TRP3 channels in various expression systems. The present study provides a possible explanation for this discrepancy. After overexpression of TRP3 in Chinese hamster ovary cells, whole-cell currents through TRP3 were reversibly inhibited by La(3+) with an EC(50) of 4 microm. For comparison, the organic blocker SKF96365 required an EC(50) of 8 microm. Gd(3+) blocked with an EC(50) of 0.1 microm, but this block was slow in onset and was not reversible after wash-out. When the two lanthanides were added to the cytosolic side of inside-out patches, block was achieved with considerably lower concentrations (EC(50) for La(3+), 0.02 microm; EC(50) for Gd(3+), 0.02 microm). Uptake of La(3+) into the cytosol of Chinese hamster ovary cells was demonstrated with intracellular fura-2. We conclude that lanthanides block TRP3 more potently from the cytosolic than from the extracellular side of the plasma membrane and that uptake of lanthanides will largely affect the apparent EC(50) values after extracellular application.

Orally administrated cerium chloride induces the conformational changes of rat hemoglobin, the hydrolysis of 2,3-DPG and the oxidation of heme-Fe(II), leading to changes of oxygen affinity

The structure and oxygen affinity of hemoglobin from erythrocytes of CeCl(3) fed Wistar rats in the dose range of 0.2-20.0 mg/kg body weight/day were investigated by means of various spectroscopic methods. The changes in oxygen saturation curves of hemoglobin are dependent upon both feeding dose and feeding time. After 40 days feeding with 20 mg CeCl(3)/kg body weight/day, the curve changed to a double sigmoid shape and the oxygen affinity in low oxygen pressure increases. It regained the sigmoid form after 80 days feeding, but the degree of oxygen saturation in higher oxygen pressure became higher than that in the control. These results indicate that CeCl(3) can increase the oxygen affinity of hemoglobin of rat erythrocytes. This effect is further demonstrated by the analysis of Mössbauer spectra of erythrocytes. Increase of hemoglobin content in erythrocytes was found in rats fed with CeCl(3). It might be the offset response to the poor oxygen-releasing capability of the hemoglobin. CD and FT-IR deconvoluted spectra indicate that secondary structures of hemoglobin have remarkable changes, characterized by a gradual decrease of alpha-helix content, in a dose- and feeding time-dependent fashion. Meanwhile, the 31P NMR spectra demonstrate that the level of 2,3-diphosphoglyceric acid (2,3-DPG) in erythrocytes, an allosteric regulator of oxygen release from hemoglobin, decreases due to its hydrolysis. In addition, the Mössbauer and ESR spectra show clearly that a fraction of the heme-iron changes from Fe (II) to Fe (III) in CeCl(3) fed rats. The results indicate that the oral administration of CeCl(3) leads to a microenvironment changes of heme in intracellular hemoglobin. Oxygen affinity changes might be attributed to a series of events triggered by the binding of Ce (III) to hemoglobin and 2,3-DPG, including conformational changes of hemoglobin and 2,3-DPG hydrolysis, respectively and also the partial transformation from heme-Fe (II) to heme-Fe (III).

Gadolinium induces domain and pore formation of human erythrocyte membrane: an atomic force microscopic study

Lanthanide cations bind to human erythrocyte membranes and enhance cell permeability. It was postulated that this effect is due to their likeness with calcium ions, which have been used to induce perforation of cells. However, the nature and mechanism of the perforation are still not clear. In the present work, the change in surface topography of erythrocyte membranes exposed to various gadolinium species was imaged with an atomic force microscope (AFM) in order to get direct evidence of perforation. The images of the whole cell and regions in nanometer scale showed that the normal surface is featured by closely packed nanometer size particles. The AFM images showed that Gd(3+) binding to erythrocytes led to domain structure at low concentration and pore formation at higher concentration. The domain structures that appeared after incubation with 1.0x10(-6)-1.0x10(-5) mol/l Gd(3+) solution for 30 min are featured by the particles aggregated to form ranges and the separations among them enlarged to gorges. With a higher concentration, 2.5x10(-5) mol/l Gd(3+), the further aggregation developed into crater-shaped 'pores'. By washing with EDTA the 'pores' can be resealed but the domain structure remained. The anionic complex of Gd(3+), [Gd(Cit)(2)](3-) of this concentration, can only induce the domain structure formation. The domain and 'pore' structures mediated by Gd(3+) concentrations might be responsible for both enhanced permeability and perforation. The mechanism of Gd-induced domain formation and perforation is discussed on the basis of aggregation of membrane proteins and the coexistence of different phases of membrane lipids resulting from Gd(3+) binding.