Lactate detection in inducible and orthotopic Her2/neu mammary gland tumours in mouse models.

This study compared the steady state concentration of lactate in an inducible Her2/nue transgenic breast cancer mouse model and in tumours from the same Her2/neu model grown orthotopically. In vivo lactate was detected by MRS using the Hadamard encoded selective multiple quantum coherence pulse sequence (HadSelMQC) recently developed by our laboratory. A lower lactate signal was observed in the inducible tumours compared to orthotopic tumours in vivo, while ex vivo analysis of perchloric acid extracts revealed similar amounts of this metabolite in both models. Histological staining of mammary tumour specimens showed a much higher level of fat tissue in inducible tumours compared to the orthotopic model. Phantom studies with [3-(13) C] lactate indicated that a lipid environment could significantly reduce the T2 of lactate and impede its detection. The transgenic inducible model for breast cancer not only better recapitulated the biological aspects of the human disease but also provided additional characteristics related to in vivo detection of lactate that are not available in orthotopic or xenograft models. This study suggests that the level of lactate measured by the HadSelMQC pulse sequence may be underestimated in human patients in the presence of high lipid levels that are typically encountered in the breast.

Metabolic network analysis of DB1 melanoma cells: how much energy is derived from aerobic glycolysis?

A network model has been developed for analysis of tumor glucose metabolism from (13)C MRS isotope exchange kinetic data. Data were obtained from DB1 melanoma cells grown on polystyrene microcarrier beads contained in a 20-mm diameter perfusion chamber in a 9.4 T Varian NMR spectrometer; the cells were perfused with 26 mM [1,6-(13)C(2)]glucose under normoxic conditions and 37°C and monitored by (13)C NMR spectroscopy for 6 h. The model consists of ∼150 differential equations in the cumomer formalism describing glucose and lactate transport, glycolysis, TCA cycle, pyruvate cycling, the pentose shunt, lactate dehydrogenase, the malate-aspartate and glycerophosphate shuttles, and various anaplerotic pathways. The rate of oxygen consumption (CMRO(2)) was measured polarographically by monitoring differences in pO(2). The model was validated by excellent agreement between model predicted and experimentally measured values of CMRO(2) and glutamate pool size. Assuming a P/O ratio of 2.5 for NADH and 1.5 for FADH2, ATP production was estimated as 46% glycolytic and 54% mitochondrial based on average values of CMRO(2) and glycolytic flux (two experiments).

In vivo and ex vivo MR imaging of slowly cycling melanoma cells.

Slowly cycling cells are believed to play a critical role in tumor progression and metastatic dissemination. The goal of this study was to develop a method for in vivo detection of slowly cycling cells. To distinguish these cells from more rapidly proliferating cells that constitute the vast majority of cells in tumors, we used the well-known effect of label dilution due to division of cells with normal cycle and retention of contrast agent in slowly dividing cells. To detect slowly cycling cells, melanoma cells were labeled with iron oxide particles. After labeling, we observed dilution of contrast agent in parallel with cell proliferation in the vast majority of normally cycling cells. A small and distinct subpopulation of iron-retaining cells was detected by flow cytometry after 20 days of in vitro proliferation. These iron-retaining cells exhibited high expression of a biological marker of slowly cycling cells, JARID1B. After implantation of labeled cells as xenografts into immunocompromised mice, iron-retaining cells were detected in vivo and ex vivo by magnetic resonance imaging that was confirmed by Prussian Blue staining. Magnetic resonance imaging detects not only iron retaining melanoma cells but also iron positive macrophages. Proposed method opens up opportunities to image subpopulation of melanoma cells, which is critical for continuous tumor growth.

In vivo 14N nuclear magnetic resonance spectroscopy of tumors: detection of ammonium and trimethylamine metabolites in the murine radiation induced fibrosarcoma 1.

The in vivo 14N nuclear magnetic resonance spectra of s.c. implanted murine radiation induced fibrosarcomas (RIF-1) display narrow resonances assignable to betaine and other trimethylamines and broad resonances due to amino acids and peptides. In 19 of the 41 tumors studied a distinct resonance from the ammonium ion is detectable. The accumulation of ammonium in the tumor to nuclear magnetic resonance detectable levels may result from glutaminolysis (a possible pathway for energy production in the tumor), from the degradation of peptides and proteins, or from the deamination of adenine nucleotides. Estimates of the tissue ammonium concentration were obtained from the in vivo tumor spectrum and the spectrum of the nonlabile trimethylamines in the perchloric acid extract. In the extract, the 14N resonances of betaine, carnitine, choline, phosphorylcholine, and glycerophosphorylcholine were resolved, and a relatively high level of tissue urea was observed. Spin-lattice relaxation times were obtained for the 14N nucleus of each of these metabolites in phosphate buffer.

Serum inhibition of in vitro 67Ga binding by L1210 leukemic cells.

The influence of human serum on in vitro 67Ga uptake by L1210 leukemic lymphoblasts has been investigated. Both high- and low-molecular-weight serum components inhibit cellular uptake of the isotope. Inhibition by the high-molecular-weight serum fraction correlates closely with the extent of binding of the radionuclide. Although transferring participates in high-molecular-weight inhibition, it accounts for 10 percent or less of the inhibitory and binding capacity. Similarly, various low-molecular-weight serum components, including citrate, phosphate, glutamate, and others, contribute to inhibition. This inhibition of 67Ca uptake by serum results from the presence of several, perhaps many, inhibitory components.

Intracellular acidification of human melanoma xenografts by the respiratory inhibitor m-iodobenzylguanidine plus hyperglycemia: a 31P magnetic resonance spectroscopy study.

In vivo 31P magnetic resonance spectroscopy demonstrates that human melanoma xenografts can be significantly acidified by induction of hyperglycemia combined with administration of m-iodobenzylguanidine (MIBG), an inhibitor of mitochondrial respiration. In melanoma xenografts (< or =8 mm diameter), intracellular pH (pHi, measured by the chemical shift of the Pi resonance) and extracellular pH (pHe, measured with 3-aminopropylphosphonate) was reduced by less than 0.2 unit during i.v. infusion of glucose for 40 min. Administration of MIBG (30 mg/kg) under hyperglycemic conditions (26 mM) reduced tumor pHi and pHe by approximately 0.4 (P < 0.001) and approximately 0.6 (P < 0.001) unit, respectively; coincidentally, the nucleoside triphosphates:Pi ratio decreased approximately 60% (P < 0.004) relative to the baseline level. Minimal changes in pHi and pHe and a small decrease in nucleoside triphosphates:Pi ratio (26%, P = 0.2) were observed in liver in response to MIBG plus hyperglycemia. These results suggest that under normoglycemic and hyperglycemic conditions, small human melanoma xenografts (< or =8 mm) may exhibit a relatively high level of oxidative phosphorylation that may be blocked by MIBG. The acidification may result from increased lactate production as a direct effect of MIBG inhibition of respiration in mitochondria of tumor cells, or through indirect systemic effects, which remain to be identified. The synergetic effects of MIBG and hyperglycemia result in significant acidification of the tumor and a decrease in tumor bioenergetic status, and the effects are largely selective for tumors in comparison with normal tissues.

Detection of tumor response to chemotherapy by 1H nuclear magnetic resonance spectroscopy: effect of 5-fluorouracil on lactate levels in radiation-induced fibrosarcoma 1 tumors.

The aim of this study was to evaluate the ability of noninvasive 1H magnetic resonance spectroscopic imaging to detect the response of radiation-induced fibrosarcoma 1 tumors to treatment with 5-fluorouracil (5-FU). Parallel magnetic resonance studies of tumor extracts and assays of apoptosis and necrosis in tumor sections were performed to elucidate the mechanism underlying the changes detected in spectra in vivo. Cell death in tumors after a single dose of 5-FU (165 mg/kg, i.p.) was characterized by increased apoptosis, decreased necrotic fraction, and tumor shrinkage within 48 h. No significant change in normalized trimethylamine and lactate levels was observed during 3 days of untreated tumor growth. Following treatment with 5-FU, normalized intensities of both trimethylamine and lactate decreased significantly from pretreatment levels within 24 h and continued to decline at 48 h. The decrease in lactate levels determined by spectroscopic imaging in vivo was also observed in perchloric acid extracts of radiation-induced fibrosarcoma 1 tumors. Possible mechanisms for the decrease of tumor lactate levels include increased blood flow and decreased glycolytic rate. Unlike lactate, changes in normalized trimethylamine levels observed in vivo were not observed in tumor extracts. The mechanism underlying the anomalous decrease in the in vivo trimethylamine level is under investigation. These findings demonstrate that lactate is a reliable and sensitive indirect indicator of response to 5-FU in at least one tumor model and point to the possible clinical utility of this resonance as an index of clinical tumor response to chemotherapy.

Response of radiation-induced fibrosarcoma-1 in mice to cyclophosphamide monitored by in vivo 31P nuclear magnetic resonance spectroscopy.

In vivo 31P nuclear magnetic resonance spectroscopy has been used to examine the RIF-1 fibrosarcoma in mice during untreated growth and following chemotherapy with cyclophosphamide. Levels of inorganic phosphate increase relative to phosphocreatine or nucleoside triphosphates during early untreated growth. After the tumor reaches a volume of approximately 1 g, no further decrease in energy level is observed. Following treatment with cyclophosphamide, tumor phosphorus metabolite ratios and pH are significantly altered, compared to untreated age-matched controls. During the growth delay period following chemotherapy there is a significant reduction in the ratio of inorganic phosphate to other phosphate metabolites, compared to age-matched controls. In addition, a more alkaline pH is observed in the tumors of treated animals. When the growth delay period ends, nuclear magnetic resonance spectra return to pretreatment patterns. The magnitude of the differences in 31P nuclear magnetic resonance spectral parameters between treated animals and untreated controls is dose dependent. However, doses of cyclophosphamide above 200 mg/kg do not result in earlier spectroscopic alterations, nor in larger effects by Day 3 after treatment, even though clonogenic cell killing and growth delay are greater at these higher doses.

In vivo 31P nuclear magnetic resonance spectroscopy of subcutaneous 9L gliosarcoma: effects of tumor growth and treatment with 1,3-bis(2-chloroethyl)-1-nitrosourea on tumor bioenergetics and histology.

In vivo 31P nuclear magnetic resonance spectroscopy was used to examine the bioenergetics of the rat 9L gliosarcoma during untreated growth and in response to chemotherapy with 1,3-bis(2-chloroethyl)-1-nitrosourea. Tumor growth was associated with a decline in the phosphocreatine and nucleoside triphosphate resonances, consistent with an increase in tumor hypoxia during untreated growth. Following chemotherapy with 1,3-bis(2-chloroethyl)-1-nitrosourea (10 mg/kg), tumor levels of phosphocreatine and nucleoside triphosphate rebounded while the level of inorganic phosphate in the tumor declined. Histological comparison of treated and untreated tumor sections 4 days posttreatment showed that the treated tumor had a lower proportion of necrotic cells, a higher proportion of viable cells, and a 5-fold higher level of interstitial space than the control tumor.

Potentiation of interleukin 1 alpha mediated antitumor effects by ketoconazole.

In the present studies, the regulatory role of adrenal hormones on the antitumor activity of recombinant human interleukin 1 alpha (IL-1 alpha) was investigated. Ketoconazole, a potent but transient inhibitor of adrenal steroid hormone biosynthesis, inhibited IL-1 alpha induced increases in plasma corticosterone. In s.c. RIF-1 tumors (C3H/HeJ mice) ketoconazole potentiated IL-1 alpha induced hemorrhagic necrosis (59Fe labeled RBC uptake) and prolonged intervals of low tumor perfusion (86Rb+ uptake) and attendant depletion of tumor high energy phosphate reserves as determined by in vivo 31P nuclear magnetic resonance spectroscopy. In normal muscle and skin the ketoconazole-IL-1 alpha combination had no effect on RBC content and little or no effect on tissue perfusion. Ketoconazole potentiation of IL-1 alpha induced tumor pathophysiologies was accompanied by time and ketoconazole dose dependent potentiation of RIF-1 tumor clonogenic cell killing. Although ketoconazole at 40 mg/kg and IL-1 alpha at 25 micrograms/kg alone each produced approximately 50% clonogenic cell kill, a combined treatment (IL-1 alpha 1 h after ketoconazole) resulted in surviving fractions of approximately 1.5%. In vitro, ketoconazole and IL-1 alpha induced only additive clonogenic cell kill in primary RIF-1 explant cultures. The effect of elevated plasma corticosterone levels, induced by ketamine-acepromazine anesthesia, on IL-1 alpha responsiveness was also studied in the RIF-1 tumor model. In C3H/HeJ mice, anesthesia increased plasma corticosterone levels within 30 min, abrogated the IL-1 alpha effect on tumor perfusion, and prevented depletion of tumor high energy phosphate metabolite reserves. Our results are consistent with the hypothesis that IL-1 alpha mediated adrenal hormone responses exert a profound negative feedback on IL-1 alpha antitumor activities. Our data also indicate that adrenal steroid hormone biosynthetic pathways could provide a focus for modulation strategies to increase the efficacy of cytokine based therapeutic interventions.

Quantitative T1rho magnetic resonance imaging of RIF-1 tumors in vivo: detection of early response to cyclophosphamide therapy.

This study compares two potential magnetic resonance imaging (MRI) indices for noninvasive early detection of tumor response to chemotherapy: the spin-lattice relaxation in the rotating frame (T1rho) and the transverse relaxation time (T2). Measurements of these relaxation parameters were performed on a s.c. murine radiation-induced fibrosarcoma (RIF-1) model before and after cyclophosphamide treatment. The number of pixels exhibiting T1rho values longer than controls in viable regions of the tumor increased significantly as early as 18 h after drug administration and remained elevated up to 36 h after treatment (P < 0.005). Although a trend of increasing T2s relative to controls was noted in viable regions of the tumor 36 h after treatment, the changes were not statistically significant. Histological examination indicated a decrease in mitotic index that paralleled the changes in T1rho. We conclude that T1rho measurements may be useful for noninvasive monitoring of early response of tumors to chemotherapy.

31P-nuclear magnetic resonance studies of the effect of recombinant human interleukin 1 alpha on the bioenergetics of RIF-1 tumors.

The effect of a single injection of human recombinant interleukin 1 alpha (IL-1 alpha) on s.c. RIF-1 tumors in mice was studied by in vivo 31P nuclear magnetic resonance spectroscopy. Spectra were obtained before and up to 24 h after IL-1 alpha. At 2, 4, 6, and 8 h after IL-1 alpha injection, RIF-1 tumors exhibited a reduction in bioenergetic status compared to untreated controls. The Pi to beta-nucleoside triphosphate and the phosphomonoester to beta-nucleoside triphosphate ratios increased, while the phosphocreatine to Pi and phosphodiester to phosphomonoester ratios decreased. Tumor blood flow, estimated by 86RbCl uptake, decreased within 30 min after IL-1 alpha treatment. Minimum perfusion was detected at 4 h, with recovery between 6 and 12 h after IL-1 alpha treatment. Histological sections of the RIF-1 tumors revealed intravascular congestion by 2 h, extravascular hemorrhage by 4 h, and necrosis by 12 h after treatment with IL-1 alpha. The time course of bioenergetic changes in RIF-1 tumors determined by 31P-NMR spectroscopy was found to parallel the reduction and subsequent recovery of tumor blood flow.

Loss of high-energy phosphate following hyperthermia demonstrated by in vivo 31P-nuclear magnetic resonance spectroscopy.

We have used in vivo 31P-nuclear magnetic resonance spectroscopy to study the changes in high-energy phosphates following hyperthermia. Immediately after heating, there is a fall in adenosine triphosphate and apparent intracellular pH and an increase in inorganic phosphate. Following sublethal heating (40 degrees for 15 min), these changes were partial, and they resolved over the subsequent 45 hr. With tumors given severe hyperthermia (47 degrees for 15 min), there was complete disappearance of adenosine triphosphate, with no recovery by 24 hr posttreatment. Qualitatively similar effects were seen after heating of normal leg muscle. The degree of fall of the adenosine triphosphate/inorganic phosphate concentration ratio was directly proportional to the heat dose and to thermal cell kill. 31P-Nuclear magnetic resonance spectroscopy may be useful in thermal dosimetry and treatment evaluation following hyperthermia.

Altered glucose metabolism in adriamycin-induced heart failure.

Spontaneously hypertensive rats received 1 mg/kg of Adriamycin intravenously once a week for up to 12 weeks; their hearts were excised and perfused with buffer containing 5 mM [1-13C]glucose. Histological evidence of Adriamycin cardiotoxicity was evident after 8 and 12 weeks of treatment and was accompanied by a significant decrease in cardiac function. There were only minor changes in the 31P-NMR spectra in hearts following treatment; however, 13C-NMR spectra revealed decreased incorporation of label into the lactate, alanine and glutamate pools in hearts with severe tissue damage compared to hearts from untreated animals.

Nuclear magnetic resonance studies of the denaturation of ubiquitin.

The effects of pH, temperature and guanidine hydrochloride concentration on the structure of ubiquitin, a polypeptide which can activate adenylate cyclase and can mimic thymopoietin induced differentiation of prothymocytes, were monitored using nuclear magnetic resonance spectroscopy. This relatively small polypeptide (molecular weight of 8541) exhibits a remarkable stability towards pH and temperature changes. At 7 M guanidine hydrochloride concentration, the structure of ubiquitin is essentially a random coil.

Bleomycin interactions with DNA. Studies on the role of the C-terminal cationic group of bleomycin A2 in association with and degradation of DNA.

The role of the cationic dimethylsulfonium group of bleomycin A2 in the binding of the drug to poly(dA-dT) has been investigated by proton NMR studies on the S-demethylated derivative. In contrast to the parent drug, the demethyl congener shows no intercalation of the aromatic bithiazole group which is adjacent to the former cationic group. However, chemical studies show that the demethyl derivative retains the capability to degrade DNA in the presence of iron(II), albeit at a reduced rate and to a lesser extent than the intact bleomycin A2. Thus, the cationic group is necessary for the intercalation of the bithiazole portion of the drug molecule; however, intercalation is not essential for the degradation of DNA.

Inhibition of lysozyme by polyvalent metal ions.

The rate of hen egg-white lysozyme (mucopeptide N-acetylmuramoylhydrolase, EC 3.2.1.17), catalysis was determined in the presence of various metal ions (Co2+, Zn2+ and eight of the trivalent lanthanide ions). In the assay system employed, the lanthanides were found to inhibit more strongly than either Zn2+ or Co2+. The inhibition data was fitted to several models of the interactions of the metal ion with the enzyme. These models ranged in complexity from a single inhibitory metal binding site on the enzyme (two-parameter fit) to the presence of two non-independent and non-equivalent inhibitory metal binding sites (five-parameter fit). The more complicated models did not fit the data more precisely than the simplest one-site model, suggesting that the adoption of the simpler model is warranted. The fact that the association constants obtained from the simplest analysis for Co2+ (1.3 +/- 1.9 . 10(2) M-1) and Gd3+ (7.0 +/- 2.6 . 10(3) M-1) are consistent with literature values determined from spectroscopic measurements further supports the validity of the simplest model.

Proton nuclear magnetic resonance methyl and methylene linewidths from plasma decrease during postprandial lipemia.

Narrow proton nuclear magnetic resonance (1H-NMR) linewidths from plasma have been associated with the presence of malignancy (Fossel et al., New Engl. J. Med. (1986) 315, 1369-1376). In that study, subjects and controls were not fasted. In the present study, 1H-NMR methyl and methylene linewidths were measured in plasma from normolipemic individuals without cancer both during fasting and every 90 min after eating a fat meal. Plasma lipoprotein levels were measured in order to relate results to postprandial lipemia. Methyl, methylene, and average 1H-NMR linewidths were strongly positively correlated with high-density lipoprotein levels and inversely correlated with triacylglycerol-rich lipoprotein levels in both the fasting and postprandial states. Linewidths decreased postprandially, reaching a nadir at the peak of plasma triacylglycerol levels. This study demonstrated that postprandial lipemia can lead to narrowing of plasma methyl and methylene resonances comparable to that reported for subjects with cancer.

Mössbauer, EPR and NMR studies of the acid-induced reduction and changes in spin state of ferric bleomycin.

Iron-57 Mössbauer, electron paramagnetic resonance (EPR) and H-1 nuclear magnetic resonance (NMR) studies of iron-bleomycin complexes in the pH range from 1.0 to 6.0 are reported. Sequential protonation of the ligands produces a variety of high-spin and low-spin complexes of the metal. Of particular interest is the reversible equilibrium between Fe(III)- and oxygen-stable Fe(II)-bleomycin. Below pH 3.5 Fe(II) complexes form, with maximal reduction occurring at approximately pH 2. At still lower pH, Fe(III) complexes unassociated with bleomycin become dominant. The observed reduction in the absence of exogenous reducing agents suggests the possible involvement of intramolecular autoreduction in bleomycin-mediated DNA degradation.

Monitoring pharmacokinetics of anticancer drugs: non-invasive investigation using magnetic resonance spectroscopy.

Magnetic resonance spectroscopy (MRS) offers the unique advantage of detecting, identifying and quantifying chemicals deep within the living body in a totally non-invasive manner. In studies on pharmacology and toxicology of anticancer drugs, MRS and the closely related technique magnetic resonance imaging (MRI) have many uses. MRS in particular, despite its low sensitivity, offers unique insights into pharmacokinetics (the changing concentration of the drug at its site of action) which can be monitored, and metabolism (both activation and detoxification) can be detected in real time. This review considers some recent work on (19)F, (31)P, (1)H and (13)C MRS of anticancer drugs. Future possibilities for (13)C MRS and (1)H MRS studies of drugs and their metabolites are considered in detail.