Protein structure investigations are usually carried out in vitro under conditions far from their native environment in the cell. Differences between in-cell and in vitro structures of proteins can be generated by crowding effects, local pH changes, specific and nonspecific protein and ligand binding events, and chemical modifications. Double electron-electron resonance (DEER), in conjunction with site-directed spin-labeling, has emerged in the past decade as a powerful technique for exploring protein conformations in frozen solutions. The major challenges facing the application of this methodology to in-cell measurements are the instabilities of the standard nitroxide spin labels in the cell environment and the limited sensitivity at conventional X-band frequencies. We present a new approach for in-cell DEER distance measurement in human cells, based on the use of: (i) reduction resistant Gd(3+) chelates as spin labels, (ii) high frequency (94.9 GHz) for sensitivity enhancement, and (iii) hypo-osmotic shock for efficient delivery of the labeled protein into the cell. The proof of concept is demonstrated on doubly labeled ubiquitin in HeLa cells.
Purpose To evaluate the speciation of gadolinium-containing species after multiple administrations of the gadolinium-based contrast agents (GBCAs) gadodiamide and gadoteridol and to quantify the amount of intact gadolinium complexes and insoluble gadolinium-containing species. Materials and Methods A total dose of 13.2 mmol per kilogram of body weight of each GBCA was administered in healthy Wistar rats over a period of 8 weeks. Three days after the final administration, rats were sacrificed, and the brains were excised and divided into three portions. Each portion of brain homogenate was divided into two parts, one for determination of the total gadolinium concentration with inductively coupled plasma mass spectrometry and one for determination of the amount of intact GBCA and gadolinium-containing insoluble species. Relaxometric measurements of gadodiamide and gadolinium trichloride in the presence of polysialic acid were also performed. Results The mean total gadolinium concentrations for gadodiamide and gadoteridol, respectively, were 0.317 μg/g ± 0.060 (standard deviation) and 0.048 μg/g ± 0.004 in the cortex, 0.418 μg/g ± 0.078 and 0.051 μg/g ± 0.009 in the subcortical brain, and 0.781 μg/g ± 0.079 and 0.061 μg/g ± 0.012 in the cerebellum. Gadoteridol comprised 100% of the gadolinium species found in rats treated with gadoteridol. In rats treated with gadodiamide, the largest part of gadolinium retained in brain tissue was insoluble species. In the cerebellum, the amount of intact gadodiamide accounts for 18.2% ± 10.6 of the total gadolinium found therein. The mass balance found for gadolinium implies the occurrence of other soluble gadolinium-containing species (approximately 30%). The relaxivity of the gadolinium polysialic acid species formed in vitro was 97.8 mM/sec at 1.5 T and 298 K. Conclusion Gadoteridol was far less retained, and the entire detected gadolinium was intact soluble GBCA, while gadodiamide yielded both soluble and insoluble gadolinium-containing species, with insoluble species dominating. RSNA, 2017 Online supplemental material is available for this article.
From the early days of CEST agents' disclosure, it was evident that their potential for in vivo applications was strongly hampered by the intrinsic low sensitivity. Therefore, much work has been devoted to seek out suitable routes to achieve strong CEST contrast enhancement. The use of nanosized systems turned out to be a strategic choice, because a very large amount of CEST agents can be delivered at the site of interest. However, the breakthrough innovation in term of increase of sensitivity was found by designing the lipoCEST agents. The naturally inspired, liposomes vesicles, when loaded with paramagnetic lanthanide-based shift reagents, can be transformed into CEST probes. The large number of water molecules entrapped inside the inner cavity of the nanovesicles represents an enormous pool of exchanging protons for the generation of CEST contrast, whereas the presence of the shift reagent increases the separation in chemical shift of their nuclear magnetic resonance signal from that of the bulk water, thus allowing for a proper exchange regime for the activation of CEST contrast. From lipoCEST, it has been rather straightforward to evolve to cellCEST in order to exploit the cytoplasmatic water molecules as source of the CEST effect, once cells have been loaded with the proper shift reagent. The red blood cells were found to be particularly suitable for the development of the cellCEST concept. Finally, an understanding of the main determinants of the CEST effects in nanosized and cellular-sized agents has allowed the design of innovative lipoCEST/RBC aggregates for potential theranostic applications. WIREs Nanomed Nanobiotechnol 2016, 8:602-618. doi: 10.1002/wnan.1385 For further resources related to this article, please visit the WIREs website.
Cells incubated in hypo-osmotic media swell and their membranes become leaky. The flow of water that enters the cells results in the net transport of molecules present in the incubation medium directly into the cell cytoplasm. This phenomenon has been exploited to label cells with MRI Gd-containing contrast agents. It has been found that, in the presence of 100 mM Gd-HPDO3A in an incubation medium characterized by an overall osmolarity of 160 mOsm l⁻¹, each cell is loaded with amounts of paramagnetic complex ranging from 2 × 10⁹ to 2 × 10¹⁰ depending on the cell type. To obtain more insight into the determinants of cellular labeling by the 'hypo-osmotic shock' methodology, a study on cell viability, proliferation rate and cell morphology was carried out on J774A.1 and K562 cells as representative of cells grown in adhesion and suspended ones, respectively. Moreover a comparison of the efficiency of the proposed method with established cell labeling procedures such as pinocytosis and electroporation was carried out. Finally, the effects of the residual electric charge, the size and some structural features of the metal complex were investigated. In summary, the 'hypotonic shock' methodology appears to be an efficient and promising tool to pursue cellular labeling with paramagnetic complexes. Its implementation is straightforward and one may foresee that it will be largely applied in in vitro cellular labeling of many cell types.
Commercial Gd-containing complexes are often used as MRI reporters in cellular labeling procedures as they are internalized into endosomes by pinocytosis. A methodology has been applied to assess the relative stability of three commercial Gd contrast agents following cellular uptake in fibroblasts and macrophages. It has been found that the acyclic series of Gd MRI contrast agents are degraded much more rapidly than their macrocyclic analogues, following endosomal internalization into living cells. This helps to explain their causal role in the development of nephrogenic systemic fibrosis in renally impaired patients. The methodology has also been applied to assess the fate of Gd-DTPA-BMA-loaded liposomes upon their endosomal internalization. Resistant liposomes prevent the degradation of the complex, whereas liposomes designed to release their payload in the acidic environments show a loss of integrity of Gd-DTPA-BMA analogous to the one observed upon internalization of the free complex.
Chemical exchange saturation transfer (CEST) agents are a new class of frequency-encoding MRI contrast agents with a great potential for molecular and cellular imaging. As for other established MRI contrast agents, the main drawback deals with their low sensitivity. The sensitivity issue may be tackled by increasing the number of exchanging protons involved in the transfer of saturated magnetization to the "bulk" water signal. Herein we show that the water molecules in the cytoplasm of red blood cells can be exploited as source of exchangeable protons provided that their chemical shift is properly shifted by the intracellular entrapment of a paramagnetic shift reagent. The sensitivity of this system is the highest displayed so far among CEST agents (less than 1 pM of cells), and the natural origin of this system makes it suitable for in vivo applications. The proposed Ln-loaded RBCs may be proposed as reporters of the blood volume in the tumor region.
Hypoxia is a typical hallmark of many solid tumors and often leads to therapy resistance and the development of a more aggressive cancer phenotype. Oxygen content in tissues has been evaluated using numerous different methods for several imaging modalities, but none has yet reached the required standard of spatial and temporal resolution. Magnetic Resonance Imaging (MRI) appears to be the technique of choice and several pO 2 -responsive probes have been designed for it over the years. In vivo translation is often hampered in Gd-relaxation agents as it is not possible to separate effects that arise from changes in local concentration from those associated with responsive properties. A novel procedure for the MRI based assessment of hypoxia is reported herein. The method relies on the combined use of Gd-DOTP-and Gd-HPDO3A-labeled-Red Blood Cells (RBCs) where the first probe acts as a vascular oxygenation-responsive agent, while the second reports the local labeled RBC concentration in a transplanted breast tumor mouse model. The MRI assessment of oxygenation state has been validated by photoacoustic imaging and ex vivo immunofluorescence. The method refines tumor staging in preclinical models and paves the way for an accurate monitoring of the relationship between oxygenation and tumor growth. 3Hypoxia is one of the main tumor hallmarks and a characteristic feature of advanced solid tumors and results from an imbalance between oxygen supply and consumption.1,2 In fact, tumor growth is often accompanied by heterogeneous vascular system growth leading to insufficient blood supply in some tumor regions, as oxygen's maximum diffusion distance is 70-150 m, so generating chronic hypoxia. Furthermore, intratumoral vascular networks are not well organized in cancers and severe structural and functional abnormalities are found.These include the formation of a chaotic architecture, which is characterized by an increase in vessels with an elongated and tortuous shape, the absence of flow regulation, intermittent stasis, high endothelial permeability and a lack of specific receptors. All these phenomena can lead to acute ischemic hypoxia, which is often transient. 3 The absence of sufficient oxygenation (either chronic or acute) can reduce the effectiveness of medical therapies.Radiotherapy, photodynamic therapy and many chemotherapeutic drugs which act on cell proliferation are active in well oxygenated regions, but have been found to lack efficiency when tissue oxygen pressure (pO 2 ) is low. 4 Furthermore, cancer cells that lack sufficient O 2 show changes in gene expression and gene regulation pathways, leading to an alteration in the tumor cell proteome which permanently modifies cancer cell metabolism and aggressiveness. 5The hostile environment triggers the selection and clonal expansion of more aggressive cancer cells that are able to survive in low or nil oxygen and nutrient supply conditions, thus generating a new cancer phenotype which is more aggressive and resistant to treatment. 6 The ability to assess h...
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