Photodegraded nifedipine promotes transferrin-independent gallium uptake by cultured tumor cells.

UNLABELLED: It was reported previously that normal soft tissues accumulate 67Ga by a transferrin-dependent route, but uptake by tumors can be transferrin independent. It was also reported that, although overexpression of the transferrin receptor can promote Ga avidity, the transferrin-independent uptake of 67Ga is significant and can be augmented to exceed transferrin-mediated levels by increasing extracellular calcium. In assessing the effect of calcium channel blockers on uptake of 67Ga, it was observed that, after exposure to light (either visible or ultraviolet [UV]), nifedipine strongly potentiates the cellular uptake of 67Ga by a transferrin-independent process. METHODS: The effect of nifedipine on 67Ga uptake as a function of time, concentration, duration and type of preexposure to light was determined in two cultured Chinese hamster ovary cell lines. One cell line lacks the transferrin receptor. In the other, the human transferrin receptor has been restored by transfection and is overexpressed constitutively. RESULTS: Although there are some differences in pattern of stimulation of uptake, nifedipine subjected to either UV or fluorescent light strongly promotes the uptake of 67Ga in the cultured cells in a time-dependent and concentration-dependent manner. Maximal uptake of 67Ga occurs when the cells are incubated for 30 min with 25 micromol/L nifedipine preexposed to either 4h of fluorescent or 1h of UV light. Under these conditions, uptake of 67Ga is 1000-fold greater than basal levels and 50-fold greater than can be achieved by the transferrin-dependent route. Light-shielded nifedipine has no effect on 67Ga uptake. CONCLUSION: The effect of photodegraded nifedipine on the uptake of 67Ga is independent of expression of the transferrin receptor. The potential for photodegraded nifedipine to improve oncologic imaging with 67Ga warrants further investigation.

Uptake of gallium-67 in transfected cells and tumors absent or enriched in the transferrin receptor.

UNLABELLED: Gallium-67 has been a controversial tumor-imaging agent in nuclear medicine for decades. This controversy centers on why tumors are variable in gallium-avidity, whether 67Ga uptake is a transferrin-independent or dependent process, and whether tumors and normal tissues differ in mechanism of uptake. If the factors that control uptake of 67Ga were understood better, then efforts to improve oncologic imaging with 67Ga by increasing the tumor activity, or by decreasing the background, may be warranted. METHODS: Conventional systems for evaluating the mechanism and control of 67Ga uptake have significant limitations. We have endeavored to circumvent these by developing a pair of transfected cell lines. One cell line has no transferrin receptor. In the other, the human transferrin receptor has been restored by transfection and is over-expressed constitutively, without the necessity to manipulate factors such as cell growth or iron content. The uptake of 67Ga, both as a citrate salt and as a gallium-transferrin complex, was examined in these pairs of cells in vitro. The effect of calcium and of soluble (ionic) iron concentration on 67Ga uptake also was determined. Tumors were grown as explants of these cells in nude mice and comparisons of uptake of 67Ga by these tumors in vivo were made. RESULTS: The in vivo uptake of 67Ga is significantly increased in tumors in which the transferrin receptor is overexpressed, compared to those without a functional transferrin receptor. However, a notable amount of accumulation of 67Ga also occurs, both in vitro and in vivo, by a transferrin-independent route. In vitro experiments demonstrate that the uptake of 67Ga by the transferrin-independent route can be enhanced further to levels that equal or exceed those achieved by the transferrin-dependent route by increasing the content of calcium or iron salts in the incubation medium. CONCLUSION: Significant transferrin-independent uptake of 67Ga occurs both in vitro and in vivo. This uptake can be stimulated further in vitro, suggesting that in vivo enhancement might also be possible to enhance the utility of the radiometal for tumor imaging.

Identification of an EGF/TGF-alpha receptor in primary cultures of guinea pig gastric mucous epithelial cells.

Binding and localization of transforming growth factor-alpha (TGF-alpha) and epidermal growth factor (EGF) were assessed using in vitro primary cultures of guinea pig gastric mucous epithelial cells (GMEC). GMEC were isolated and cultured in six-well plates with Dulbecco's modified Eagle's medium + 10% serum and then changed to serum-free medium for 24 h for binding studies. The binding time course of 125I-labeled EGF and 125I-TGF-alpha in GMEC cultures at 4 degrees C was saturable, reaching a plateau within 4-6 h. Competition-binding curves revealed that the amount of unlabeled EGF and TGF-alpha to reduce 125I-EGF binding by 50% was 0.35 and 0.23 nM, respectively. The amount of unlabeled EGF and TGF-alpha to decrease 125I-TGF-alpha binding by 50% was 0.30 and 0.21 nM, respectively. A Scatchard analysis of the data disclosed that a single class of high-affinity binding sites (dissociation constant = 0.24 nM) was present. The maximal binding capacity was approximately 20 fmol/10(6) cells or approximately 12,000 receptors per cell. The binding of 125I-EGF and 125I-TFG-alpha to GMEC cultures was maximal between pH 7.0 and 8.5. No specific binding of EGF or TGF-alpha could be detected below pH 5.0. The half-maximal pH dissociation value for EGF and TGF-alpha was pH 5.89 and pH 6.83, respectively. We found no difference in the final amounts of membrane-bound or internalized 125I-EGF and 125I-TGF-alpha. However, there was a significant difference (P < 0.05) at 5-30 min in the rate of dissociated and internalized 125I-EGF- and 125I-TGF-alpha. Immunofluorescence microscopy of GMEC cultures for EGF/TGF-alpha receptors showed increased fluorescence at the leading edges and around the perimeter of cells. Detection of an EGF/TGF-alpha receptor was also confirmed by Western blotting. Our findings demonstrate that guinea pig GMEC possess a specific EGF/TGF-alpha receptor, which further supports a physiological role for EFG and TFG-alpha as mitogens in these cells.

Establishment of human colonic epithelial cells in long-term culture.

Study of normal colonic function is important in understanding the cellular mechanisms of carcinogenesis and other diseases of the colon. However, colonic pathophysiological studies have been limited due to the lack of long-term cultures of normal human colonic epithelial cells. The purpose of the present study was to develop methods of isolating viable human colonic epithelial cells for the establishment of nontransformed colonic epithelial cell lines. Human colonic epithelial cells were isolated from surgically resected normal human colons. We found that the use of a short enzymatic digestion gave a consistently higher number (>90%) of viable human colonic epithelial cells. These isolated colonocytes were grown on plastic, collagen-coated filters, or feeder layers using different media formulations. Those colonocytes from the initial primary cultures that were most "epithelial" in appearance were cloned and passaged to establish long-term cultures of nontransformed human colonic epithelial cells. The epithelial nature and secretory function of these established cell lines were confirmed by morphological criteria (light microscopy,, phase contrast microscopy, and electron microscopy). We found that the long-term cultures remained immunopositive to anti-cytokeratin antibodies and immunonegative to anti-vimentin antibodies. Using a soft agar assay we found that the colonocytes did not form colonies, suggesting that the long-term culturing did not cause these cells to become transformed. Under serum-free conditions, we found that epidermal growth factor and transforming growth factor-alpha were equally potent in their mitogenic effects for these colonocytes. Some of the subcultured cells could be maintained for at least 8 months and still retain their epithelial characteristics. We believe that this methodology will serve as a valuable tool for the isolation and culturing of human colonic epithelial cells for studies of normal and malignant colonic disease processes.