Observation of immune and stem cells in their native microenvironments requires the development of imaging agents to allow their in vivo tracking. We describe here the synthesis of magnetofluorescent nanoparticles for cell labeling in vitro and for multimodality imaging of administered cells in vivo. MION-47, a prototype monocrystalline iron oxide nanoparticle, was first converted to an intermediate bearing a fluorochrome and amine groups, then reacted with either HIV-Tat peptide or protamine to yield a nanoparticle with membrane-translocating properties. We describe how to assess optimal cell labeling with tests of cell phenotype and function. Synthesis of magnetofluorescent nanoparticles and cell-labeling optimization can be realized in 48 h, whereas nanoparticle uptakes and retention studies may generally take up to 120 h. Labeled cells can be detected by magnetic resonance imaging, fluorescence reflectance imaging, fluorescence-mediated tomography, confocal microscopy and flow cytometry, and can be purified based on their fluorescent or magnetic properties. The present protocol focuses on T-cell labeling but can be used for labeling a variety of circulating cells.
The ability to use magnetic nanoparticles for cell tracking, or for the delivery of nanoparticle-based therapeutic agents, requires a detailed understanding of probe metabolism and transport. Here we report on the development and metabolism of a dual fluorochrome version of our tat-CLIO nanoparticle termed Tat(FITC)-Cy3.5-CLIO. The nanoparticle features an FITC label on the tat peptide and a Cy3.5 dye directly attached to the cross-linked coating of dextran. This nanoparticle was rapidly internalized by HeLa cells, labeling 100% of cells in 45 min, with the amount of label per cell increasing linearly with time up to 3 h. Cells loaded with nanoparticles for 1 h retained 40-60% of their FITC and Cy3.5 labels over a period of 72 h in label-free media. Over a period of 144 h, or approximately 3.5 cell divisions, the T2 spin-spin relaxation time of cells was not significantly changed, indicating retention of the iron oxide among the dividing cell population. Using confocal microscopy and unfixed cells, both dyes were nuclear and perinuclear (broadly cytoplasmic) after Tat(FITC)-Cy3.5-CLIO labeling. Implications of the rapid labeling and slow excretion of the Tat(FITC)-Cy3.5-CLIO nanoparticle are discussed for cell tracking and drug delivery applications.
Monoclonal and polyclonal antibodies recognizing human parathyroid hormone-like protein (PTHLP) have been produced using a series of recombinant and synthetic PTHLP peptides. These antibodies have been used to develop a two-site immunometric enzyme immunoassay which detects PTHLP[1-87] and PTHLP[1-141] but not PTH. The immunoassay detected PTHLP in extracts of squamous carcinomas and normal tissues at concentrations from 7-515 ng PTHLP[1-87]/mg protein. Immunoblotting of the extract which showed the highest immunoreactivity, a squamous carcinoma of the lung from a patient with hypercalcemia, revealed a major band having an apparent mol wt of 26,500 and several other higher mol wt bands. Similar polypeptides were observed by immunoblotting cell extracts from a cell line, SCaBER, which secretes immunoreactive PTHLP into its medium and also from tumors in nude mice derived from this cell line. Chaotropic agents did not alter the immunoblotting pattern, and antibodies to three different epitopes of PTHLP recognized these bands, indicating PTHLP expression in the extracts. Immunohistochemical staining of normal human tissue with these antibodies revealed several PTHLP-containing tissues and confirmed the results of the immunoassay, suggesting a paracrine role for PTHLP. Staining was observed in several neoplastic tissues including squamous cell carcinomas, lung carcinoma, bladder carcinoma, osteogenic sarcoma, and adenocarcinoma of the colon.
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