Flagellar elongation and shortening in Chlamydomonas. The use of cycloheximide and colchicine to study the synthesis and assembly of flagellar proteins.

Flagella can be removed from the biflagellate Chlamydomonas and the cells begin to regenerate flagella almost immediately by deceleratory kinetics. Under usual conditions of deflagellation, more than 98% of all flagella are removed. Under less drastic conditions, cells can be selected in which one flagellum is removed and the other left intact. When only one of the two flagella is amputated, the intact flagellum shortens by linear kinetics while the amputated one regenerates. The two flagella attain an equal intermediate length and then approach their initial length at the same rate. A concentration of cycloheximide which inhibits protein synthesis permits less than one-third of each flagellum to form when both flagella are amputated. When only one is amputated in cycloheximide, shortening proceeds normally and the degree of elongation in the amputated flagellum is greater than if both were amputated in the presence of cycloheximide. The shortening process is therefore independent of protein synthesis, and the protein from the shortening flagellum probably enters the pool of precursors available for flagellar formation. Partial regeneration of flagella occurs in concentrations of cycloheximide inhibitory to protein synthesis suggesting that some flagellar precursors are present. Cycloheximide and flagellar pulse-labeling studies indicate that precursor is used during the first part of elongation, is resynthesized at mid-elongation, and approaches its original level as the flagella reach their initial length. Colchicine completely blocks regeneration without affecting protein synthesis, and extended exposure of deflagellated cells to colchicine increases the amount of flagellar growth upon transfer to cycloheximide. When colchicine is applied to cells with only one flagellum removed, shortening continues normally but regeneration is blocked. Therefore, colchicine can be used to separate the processes of shortening and elongation. Radioautographic studies of the growth zone of Chlamydomonas flagella corroborate previous findings that assembly is occurring at the distal end (tip growth) of the organelle.

Flagellar elongation and shortening in Chlamydomonas. IV. Effects of flagellar detachment, regeneration, and resorption on the induction of flagellar protein synthesis.

Synthesis of new proteins is required to regenerate full length Chlamydomonas flagella after deflagellation. Using gametes, which have a low basal level of protein synthesis, it has been possible to label and detect the synthesis of many flagellar proteins in whole cells. The deflagellation-induced synthesis of the tubulins, dyneins, the flagellar membrane protein, and at least 20 other proteins which co-migrate with proteins in isolated axonemes, can be detected in gamete cytoplasm, and the times of initiation and termination of synthesis for each of the proteins can be studied. The nature of the signal that stimulates the cell to initiate flagellar protein synthesis is unknown. Flagellar regeneration and accompanying pool depletion are not necessary for either the onset or termination of flagellar protein synthesis, because colchicine, which blocks flagellar regeneration, does not change the pattern of proteins synthesized in the cytoplasm after deflagellation or the timing of their synthesis. Moreover, flagellar protein synthesis is stimulated after cells are chemically induced to resorb their flagella, indicating that the act of deflagellation itself is not necessary to stimulate synthesis. Methods were defined for inducing the cells to resorb their flagella by removing Ca++ from the medium and raising the concentration of K+ or Na+. The resorption was reversible and the flagellar components that were resorbed could be re-utilized to assemble flagella in the absence of protein synthesis. This new technique is used in this report to study the control of synthesis and assembly of flagella.

Mitigating effect of EUK-207 on radiation-induced cognitive impairments.

The brain could be exposed to irradiation as part of a nuclear accident, radiological terrorism (dirty bomb scenario) or a medical radiological procedure. In the context of accidents or terrorism, there is considerable interest in compounds that can mitigate radiation-induced injury when treatment is initiated a day or more after the radiation exposure. As it will be challenging to determine the radiation exposure an individual has received within a relatively short time frame, it is also critical that the mitigating agent does not negatively affect individuals, including emergency workers, who might be treated, but who were not exposed. Alterations in hippocampus-dependent cognition often characterize radiation-induced cognitive injury. The catalytic ROS scavenger EUK-207 is a member of the class of metal-containing salen manganese (Mn) complexes that suppress oxidative stress, including in the mitochondria, and have been shown to mitigate radiation dermatitis, promote wound healing in irradiated skin, and mitigate vascular injuries in irradiated lungs. As the effects of EUK-207 against radiation injury in the brain are not known, we assessed the effects of EUK-207 on sham-irradiated animals and the ability of EUK-207 to mitigate radiation-induced cognitive injury. The day following irradiation or sham-irradiation, the mice started to receive EUK-207 and were cognitively tested 3 months following exposure. Mice irradiated at a dose of 15Gy showed cognitive impairments in the water maze probe trial. EUK-207 mitigated these impairments while not affecting cognitive performance of sham-irradiated mice in the water maze probe trial. Thus, EUK-207 has attractive properties and should be considered an ideal candidate to mitigate radiation-induced cognitive injury.

Effects of single-dose and fractionated cranial irradiation on rat brain accumulation of methotrexate.

The effects of single-dose and fractionated whole-brain irradiation on brain methotrexate (MTX) has been studied in a rat model. The amount of MTX present in the brain 24 hr after a single i.p. dose (100 mg/kg) was the same wether animals were sham irradiated or given a single dose of 2000 rads 6 or 48 hr prior to the drug (6.9, 8.3, and 6.8 pmol MTX/g, wet weight, respectively). Animals sham irradiated or given 2000 rads in 10 fractions over 11 days and treated with an average dose of 1.2 mg MTX/kg i.p. twice a week for 24 weeks did not differ significantly in their brain MTX concentration (7.9 and 8.3 pmol MTX/g, wet weight, respectively). Chronically MTX-treated animals became folate deficient whether they were irradiated or not (450 and 670 pmol folate/g, wet weight, brain in MTX-treated and control animals). Thus, MTX accumulates in the brain with acute or chronic administration, and this accumulation is not altered by this amount of brain irradiation.

Neutrophil cathepsin G is specifically decreased under vitamin A deficiency.

Vitamin A deficiency leads to an increased susceptibility to infections, increased severity of infections and increased mortality. Because the neutrophil is the first cell to respond to infection, this study explores the effect of vitamin A deficiency on neutrophil proteinases. We found that neutrophils from vitamin A-deficient rats had lower levels of two cathepsin G-like enzymes (28 and 24 kDa) when compared to neutrophils from weight-matched pair-fed rats, vitamin A-deficient rats which were repleted with retinyl palmitate and nonrestricted vitamin A complete diet rats. The 28 kDa cathepsin G-like enzyme, which migrated with the same mobility as elastase on SDS-polyacrylamide gels, was quantified using Western blots. The 24 kDa cathepsin G-like enzyme was quantified using zymogram gels. This activity was inhibited by chymostatin. Other neutrophil proteinases, elastase, plasminogen activators and gelatinase, were not altered significantly by vitamin A deficiency. The low levels of cathepsin G may contribute to differences in the inflammatory process observed under vitamin A deficiency.

Mobile phones, mobile phone base stations and cancer: a review.

There have been reports in the media and claims in the courts that radiofrequency (RF) emissions from mobile phones are a cause of cancer, and there have been numerous public objections to the siting of mobile phone base antennas because of a fear of cancer. This review summarizes the current state of evidence concerning whether the RF energy used for wireless communication might be carcinogenic. Relevant studies were identified by searching MedLine with a combination of exposure and endpoint terms. This was supplemented by a review of the over 1700 citations assembled by the Institute of Electrical and Electronics Engineers (IEEE) International Committee on Electromagnetic Safety as part of their updating of the IEEE C95.1 RF energy safety guidelines. Where there were multiple studies, preference was given to recent reports, to positive reports of effects and to attempts to confirm such positive reports. Biophysical considerations indicate that there is little theoretical basis for anticipating that RF energy would have significant biological effects at the power levels used by modern mobile phones and their base station antennas. The epidemiological evidence for a causal association between cancer and RF energy is weak and limited. Animal studies have provided no consistent evidence that exposure to RF energy at non-thermal intensities causes or promotes cancer. Extensive in vitro studies have found no consistent evidence of genotoxic potential, but in vitro studies assessing the epigenetic potential of RF energy are limited. Overall, a weight-of-evidence evaluation shows that the current evidence for a causal association between cancer and exposure to RF energy is weak and unconvincing. However, the existing epidemiology is limited and the possibility of epigenetic effects has not been thoroughly evaluated, so that additional research in those areas will be required for a more thorough assessment of the possibility of a causal connection between cancer and the RF energy from mobile telecommunications.

ACE inhibitors and AII receptor antagonists in the treatment and prevention of bone marrow transplant nephropathy.

Radiation nephropathy has emerged as a major complication of bone marrow transplantation (BMT) when total body irradiation (TBI) is used as part of the regimen. Classically, radiation nephropathy has been assumed to be inevitable, progressive, and untreatable. However, in the early 1990's, it was demonstrated that experimental radiation nephropathy could be treated with a thiol-containing ACE inhibitor, captopril. Further studies showed that enalapril (a non-thiol ACE inhibitor) was also effective in the treatment of experimental radiation nephropathy, as was an AII receptor antagonist. Studies also showed that ACE inhibitors and AII receptor antagonists were effective in the prophylaxis of radiation nephropathy. Interestingly, other types of antihypertensive drugs were ineffective in prophylaxis, but brief use of a high-salt diet in the immediate post-irradiation period decreased renal injury. A placebo-controlled trial of captopril to prevent BMT nephropathy in adults is now underway. Since excess activity of the renin-angiotensin system (RAS) causes hypertension, and hypertension is a major feature of radiation nephropathy; an explanation for the efficacy of RAS antagonism in the prophylaxis of radiation nephropathy would be that radiation leads to RAS activation. However, current studies favor an alternative explanation, namely that the normal activity of the RAS is deleterious in the presence of radiation injury. On-going studies suggest that efficacy of RAS antagonists may involve interactions with a radiation-induced decrease in renal nitric oxide activity or with radiation-induced tubular cell proliferation. We hypothesize that while prevention (prophylaxis) of radiation nephropathy with ACE inhibitors, AII receptor antagonists, or a high-salt diet work by suppression of the RAS, the efficacy of ACE inhibitors and AII receptor antagonists in treatment of established radiation nephropathy depends on blood pressure control.

Hypoxic fractions of human tumors xenografted into mice: a review.

Transplanted tumors in rats and mice have been used extensively in radiobiology studies examining the biological basis and therapeutic implications of hypoxia in solid tumors, and in studies evaluating new agents and regimens which may circumvent the radioprotective effects of hypoxic cells. This use of rodent tumors assumes that data obtained using rapidly-growing transplanted tumors arising in inbred rodents can be extrapolated meaningfully to the treatment of primary and/or metastatic lesions in heterozygous humans. The studies reported here examine one facet of this critical assumption by comparing the hypoxic fractions of transplanted rodent tumors with those of human tumor cell lines xenografted into immune deficient mice. No significant differences were found between the hypoxic fractions of the xenografts and those of mouse tumors. This finding eliminates several possible bases for predicting that the oxygenation of human tumors might be systematically different from that of the rodent tumors often used in preclinical radiobiology studies, and supports the hypothesis that human tumors contain hypoxic cells which may be critical in determining their response to therapy.

Intermittent use of a perfluorochemical emulsion (Fluosol-DA 20%) and carbogen breathing with fractionated irradiation.

Oxygen carrying perfluorochemical emulsions have been shown to enhance the response of animal tumors to large single doses of radiation. Clinically, however, perfluorochemical emulsions are being used with only some fractions in multiple fraction radiation courses. To test the efficacy of a perfluorochemical emulsion under conditions that are closer to those used in current clinical trials, BA1112 rat sarcomas were treated with three fractions per week of 6 Gy per fraction. Once a week, animals were infused i.v. with a perfluorochemical emulsion at 15 ml/kg, and allowed to breathe carbogen (95% O2:5% CO2) for 30 minutes prior to and during irradiation. The 50% tumor control dose was 93.1 (87.9-103.1) Gy in the control arm compared to 74.3 (64.9-83.9) Gy for the animals given the perfluorochemical infusion plus carbogen breathing. The dose modification factor for intermittent perfluorochemical infusion and carbogen breathing was 1.26 (1.15-1.40). In a similar fractionated schedule, the hypoxic cell radiosensitizer, misonidazole, given once per week at 600 mg/kg, gave a dose modification factor of 1.22 (1.14-1.32).

Late toxicity of total body irradiation with bone marrow transplantation in a rat model.

In defined-flora, barrier-maintained rats, radiation nephritis is the principle late toxicity seen after high dose-rate total body irradiation (TBI), when hematologic toxicity is prevented by bone marrow transplantation (BMT). Pneumonitis develops only if rats are placed in a conventional microbiological environment during and after BMT. Low dose-rate TBI gives qualitatively similar late toxicity, but at radiation doses twice as large. Fractionation of the TBI has little effect on the bone marrow ablation doses, but results in increased gastrointestinal and renal tolerance. The addition of immunosuppressive or cytotoxic drugs (cyclosporine-A, methotrexate, cis-platinum) after TBI and BMT greatly decreases the dose of TBI that can be tolerated. The use of a cyclophosphamide plus cytosine arabinoside conditioning regimen prior to TBI and BMT increases the bone marrow ablation dose, but has no effect on acute gastrointestinal toxicity or on renal toxicity. These results indicate that substantial late toxicity may be associated with the TBI conditioning regimens used for BMT even in the absence of cytotoxic and antibiotic drugs, immunosuppressive agents, infection and graft-versus-host disease; and that radiation may be a contributing factor in the nephritis sometimes observed after TBI and BMT.

Influence of nephrotoxic drugs on the late renal toxicity associated with bone marrow transplant conditioning regimens.

The total body irradiation that is given as part of bone marrow transplant conditioning regimens is a factor in the renal toxicity that is observed after bone marrow transplant, but it may not be the only factor. We hypothesize that nephrotoxic drugs used in prior chemotherapy can precipitate renal radiation damage. Studies were designed to determine if nephrotoxic antineoplastic drugs could shorten the latent period for the development of radiation nephritis. Rats were given bilateral renal irradiation using a radiation schedule that produced moderate nephritis. Cisplatinum, BCNU, or mitomycin were given before, during, or after irradiation at doses that produced only mild nephrotoxicity. All cisplatinum-radiation sequences resulted in decreased renal function, with radiation prior to cisplatinum producing the greatest dysfunction. BCNU increased renal dysfunction equally in all schedules, but mitomycin had only minimal effects. Most drug schedules, including those with mitomycin, produced earlier development of morbidity after fractionated renal irradiation. In a second set of studies, rats were given single doses of the same nephrotoxic drugs, followed 3 months later by total body irradiation plus bone marrow transplant. The drugs had no effect on the marrow ablation dose, but BCNU and cisplatinum decreased gastrointestinal tolerance. Four months after total body irradiation, rats which received drugs alone or total body irradiation alone have essentially normal renal function, but rats which received cisplatinum plus total body irradiation or BCNU plus total body irradiation show a dose-dependent decrease in renal function. These studies show that radiation nephritis can be precipitated by low doses of nephrotoxic drugs, and may help to explain the incidence of early radiation nephritis in bone marrow transplant patients conditioned with total body irradiation.

Hypoxic fractions of solid tumors: experimental techniques, methods of analysis, and a survey of existing data.

Hypoxic fractions are measured by indirect techniques, which compare the response of tumors to large single doses of radiation given under normal aeration and artificial hypoxia. This paper reviews hypoxic fraction measurements and measurement techniques, giving particular attention to the biological, technical, and statistical aspects of the assays; the implicit assumptions underlying the analyses; and the dependence of the determinations on the assay conditions and the tumor and host characteristics. The three major hypoxic fraction assay techniques (paired survival curve, clamped tumor control, and clamped growth delay) share common biological assumptions. They require that the survival curves of naturally and artificially hypoxic cells have the same slope and intercept. They assume that the majority of the cells are either fully oxic or fully hypoxic. They assume that the methods used to induce artificial hypoxia leave no oxygenated regions and that tumor cells rendered artificially hypoxic are no less viable than cells in normally-aerated tumors. The universal validity of these assumptions is questionable. Each technique uses additional special assumptions and each may measure a different population of hypoxic cells. This paper reviews 92 hypoxic fraction determinations in 42 tumor systems. Radiobiologically hypoxic cells appear to be present in the majority of macroscopic solid rodent tumors. The hypoxic fraction was found to increase as the tumor size increased from microscopic to macroscopic; the dependence of hypoxic fraction on tumor size at macroscopic sizes was less clear. The site of tumor implantation, the use of anesthesia, and certain host characteristics may influence the hypoxic fraction. The hypoxic fraction generally did not depend on the tumor growth rate, transplantation history, or histology. These findings indicate that hypoxic cells are a common feature of solid tumors in rodents and provide no evidence that hypoxic cells should not be present in human tumors.

Drug resistance following irradiation of RIF-1 tumors: influence of the interval between irradiation and drug treatment.

RIF-1 tumors contain a small number of cells (1 to 100 per 10(6) cells) that are resistant to 5-fluorouracil, methotrexate, or adriamycin. The frequency of drug-resistant cells among individual untreated tumors is highly variable. Radiation, delivered in vivo at doses of 3 to 12 Gy, increases the frequency of methotrexate- and 5-fluorouracil-resistant cells, but not the frequency of adriamycin-resistant cells. The magnitude of induction of 5-fluorouracil and methotrexate resistance shows a complex dependence on the radiation dose and on the interval between irradiation and assessment of drug resistance. For a dose of 3 Gy, induced 5-fluorouracil and methotrexate resistance is seen only after an interval of 5 to 7 days, whereas for a dose of 12 Gy, high levels of induced resistance are observed 1 to 3 days after irradiation. The maximum absolute risk for induction of resistance is 4 per 10(4) cells per Gy for methotrexate, and 3 per 10(6) cells per Gy for 5-fluorouracil. These results indicate that tumor hypoxia may play a role in the increased levels of drug resistance seen after irradiation, and that both genetic and environmental factors may influence radiation-induction of drug resistance. These studies provide essential data for models of the development of tumor drug resistance, and imply that some of the drug resistance seen when chemotherapy follows radiotherapy may be caused by radiation-induced drug resistance.

Applicability of animal tumor data to cancer therapy in humans.

The problem of applying experimental tumor studies to clinical cancer therapy is a complex one. The radiotherapy literature contains many examples of premature efforts to apply laboratory observations to the clinic, and many examples of failures to adequately consider animal tumor observations in the design of clinical studies. This review covers three areas: tumor hypoxia, where clinical trials based on animal tumor data have been conducted with radiosensitizers, hyperbaric oxygen, and systemic oxygen carriers; dose fractionation, where current trials of hyperfractionation are based in part on animal tumor studies; and chemo-radiotherapy, where clinical trials are only beginning to exploit concepts developed in animal tumor systems. The use of animal tumor systems extends past the screening of new agents. Animal tumor models can be used in biological, physiological, and pharmacological studies to elucidate the biological factors influencing the efficacy of therapeutic agents. Tumor studies can be combined with studies of normal tissues to predict the toxicities to be anticipated in clinical trials, and to assess the potential for therapeutic gain. Animal studies can also provide data which are useful in designing optimal clinical trials of new agents and maximizing the potential for successful clinical application of new approaches. In general, it is not possible to apply specific laboratory data directly to man. To translate, rather than transpose, information from the laboratory to the clinic, the model studies must be directed at evaluating principles, rather than merely quantifying results. Only through studies of mechanisms, by designing experiments to test or refute a hypothesis, will it be possible to apply model studies to man.

Treatment of radiation nephropathy with ACE inhibitors.

PURPOSE: A previous study showed that radiation nephritis could be treated with captopril, an angiotensin-converting-enzyme inhibitor. These studies were designed to determine whether other angiotensin-converting-enzyme inhibitors would be effective, whether captopril would inhibit the development of the histopathologic lesions typical of radiation nephritis, and whether captopril could be used to treat the nephropathy observed in bone marrow transplant recipients conditioned with total body irradiation. METHODS AND MATERIALS: In radiation nephritis studies, rats were given 17-27 Gy bilateral renal irradiation in 5 fractions. Six months after irradiation animals were stratified by blood urea nitrogen and assigned to no treatment, or treatment with captopril (500 mg/l) or enalapril (50 mg/l) in the drinking water. A subset of animals was sacrificed for histopathology after 3 months; the remaining animals continued on drugs for 7 months. In the bone marrow transplant nephropathy study, rats received 14-17 Gy total body irradiation in 6 fractions over 3 days followed by syngeneic bone marrow transplant. Six months after irradiation, animals were stratified by blood urea nitrogen and assigned to no treatment, or treatment with captopril (500 mg/l). Animals remained on drugs for 6 months. In all studies animals were followed with periodic renal function tests. RESULTS: In the radiation nephritis study, survival and renal function were significantly enhanced by both captopril and enalapril, but there were no significant differences between the drugs. The histopathologic severity of the lesions of radiation nephritis correlated with the degree of renal dysfunction; and in irradiated animals with equal initial azotemia, captopril-treated rats developed less severe renal lesions. Finally, captopril also prolonged survival and preserved renal function in this rat bone marrow transplant nephropathy model. CONCLUSION: Angiotensin-converting-enzyme inhibitors are an effective treatment for both radiation nephritis and bone marrow transplant nephropathy.

Tumor and normal tissue tolerance for fractionated low-dose-rate radiotherapy.

Radiobiological evidence suggests that an improved therapeutic ratio might be achieved through the use of smaller than conventional dose fractions. The ultimate in small dose fractions for external beam radiotherapy would be fractionated low-dose-rate (LDR) irradiation, and clinical trials of fractionated external beam LDR therapy are already in progress. Using the BA1112 rat sarcoma, we have determined the 50% tumor control dose for LDR and for conventional-dose-rate (CDR) fractionated radiotherapy. These tumor control doses were compared to normal tissue tolerance doses for hemi-body irradiation in similar CDR and LDR schedules. Animals were treated 3 times per week without anesthesia using 10-19 fractions. LDR radiotherapy was done with 60Co at dose rates of 0.028-0.033 Gy/min; CDR radiotherapy was done with 250 kVp X rays at dose rates of 0.54-2.1 Gy/min. The tumor control dose modification factor (DMF) for LDR compared to CDR irradiation was 1.3 (1.0-1.5). For LDR and CDR hemi-body irradiation, the dose modification factor for 7 day lethality (gastrointestinal damage) was 1.7 (1.5-1.9), for 100 day morbidity was 1.8 (1.6-2.2), and for radiation nephritis at 90 days was 1.9 (1.7-2.3). The therapeutic gain factor for fractionated low-dose-rate irradiation compared to conventional-dose-rate fractionated radiotherapy was therefore 1.8/1.3 = 1.4 (1.2-1.8). The study shows that there is an experimental as well as a theoretical basis for anticipating a therapeutic benefit from the use of external beam fractionated LDR radiotherapy, and implies that the recognized therapeutic efficacy of brachytherapy is not due solely to the high localized dose.

Effect of nephrotoxic drugs on the development of radiation nephropathy after bone marrow transplantation.

PURPOSE: Chronic renal failure is a significant cause of late morbidity in bone marrow transplant patients whose conditioning regimen includes total body irradiation (TBI). Radiation is a major cause of this syndrome (bone marrow transplant nephropathy), but it may not be the only cause. These studies use a rat syngeneic bone marrow transplant model to determine whether nephrotoxic agents used in conjunction with bone marrow transplantation (BMT) could be enhancing or accelerating the development of radiation nephropathy. METHODS AND MATERIALS: Rats received 11-17 Gy TBI in six fractions over 3 days followed by syngeneic bone marrow transplant. In conjunction with the bone marrow transplants, animals received either no drugs, cyclosporine, amphotericin, gentamicin, or busulfan. Drugs were given in schedules analogous to their use in clinical bone marrow transplantation. Drug doses were chosen so that the drug regimen alone caused detectable acute nephrotoxicity. Animals were followed for 6 months with periodic renal function tests. RESULTS: Gentamicin had no apparent interactions with TBI. Amphotericin increased the incidence of engraftment failure, but did not enhance radiation nephropathy. Cyclosporin with TBI caused late morbidity that appeared to be due to neurological problems, but did not enhance radiation nephropathy. Busulfan resulted in a significant enhancement of radiation nephropathy. CONCLUSION: Of the nephrotoxins used in conjunction with bone marrow transplantation only radiation and busulfan were found to be risk factors for bone marrow transplant nephropathy.

Radiation induction of drug resistance in RIF-1: correlation of tumor and cell culture results.

The RIF-1 tumor line contains cells that are resistant to various anti-neoplastic drugs, including 5-fluorouracil (5FU), methotrexate (MTX), adriamycin (ADR), and etoposide (VP16). The frequency of these drug-resistant cells is increased after irradiation. The frequency of drug-resistant cells and the magnitude of radiation-induced drug resistance are different in cell culture than in tumors. The dose-response and expression time relationships for radiation induction of drug resistance observed in RIF-1 tumors are unusual. We hypothesize that at high radiation doses in vivo, we are selecting for cells that are both drug resistant and radiation resistant due to microenvironmental factors, whereas at low radiation doses in vivo and all radiation doses in vitro, we are observing true mutants. These studies indicate that there can be significant differences in drug-resistance frequencies between tumors and their cell lines of origin, and that radiation induction of drug resistance depends significantly on whether the induction is done in tumors or in cell culture. These results imply that theories about the induction of drug resistance that are based on cell culture studies may be inapplicable to the induction of drug resistance in tumors.

Hepatic function and drug pharmacokinetics after total body irradiation plus bone marrow transplant.

Radiation nephritis is the principle late toxicity seen after total body irradiation in barrier-maintained rats when hematologic toxicity is prevented by bone marrow transplantation. Renal dysfunction is observed for single doses as low as 7.5 Gy. Hepatic blood flow, as measured by indocyanine green clearance, is decreased after 8.5-9.5 Gy single-dose total body irradiation. Serum albumin levels are decreased after 9.5 Gy single-dose total body irradiation. Hypoalbuminemia is a symptom of hepatic damage, but can also be caused by renal damage or edema. No decrease in total serum protein is observed, indicating that proteinuria resulting from renal damage is not the cause of hypoalbuminemia. No edema and some dehydration are observed. These data indicate that hepatic damage as well as renal damage may be occurring after total body irradiation plus bone marrow transplantation. Animals given total body irradiation plus bone marrow transplantation show decreased tolerance to a wide variety of immunosuppressive and cytotoxic drugs, even when these drugs are given months after total body irradiation. Altered drug clearance after total body irradiation plus bone marrow transplantation is observed for cis-platinum, vincristine, and adriamycin. The increase in cis-platinum toxicity after total body irradiation plus bone marrow transplantation is caused by decreased renal drug clearance. The decrease in vincristine tolerance and the alterations in adriamycin and vincristine pharmacokinetics are caused by altered drug distribution after total body irradiation plus bone marrow transplantation. These results indicate that bone marrow transplant survivors may show altered clearance of, and decreased tolerance to, a wide variety of drugs that are used after bone marrow transplantation.

Renal irradiation and the pharmacology and toxicity of methotrexate and cisplatinum.

We used a rat model to study the effects of renal irradiation on the pharmacology of methotrexate (MTX) and cisplatinum (cis-Pt). Unanesthetized rats were given bilateral kidney irradiation (20 Gy in 9 fractions). At 9 months after irradiation, 3% of the animals had died and survivors showed moderately impaired renal function. At 15 months, 30% of the animals had died and survivors showed severely impaired renal function. Some animals were given i.v. MTX 1 week to 15 months after irradiation. In irradiated rats, the area under the MTX plasma clearance curve equaled that of controls through 6 months, and was significantly above controls from 9 months on. Other animals were given i.p. cis-Pt 1 week to 9 months after irradiation. The acute toxicity of cis-Pt was the same in control and irradiated rats when cis-Pt was given immediately before or after irradiation. Beginning 3 months after irradiation there was a progressive increase in cis-Pt toxicity and a simultaneous decrease in urinary platinum excretion. Irradiated animals that survived cis-Pt treatment showed increased radiation nephritis; the greatest effect occurred when cis-Pt was given 3 months or more after irradiation. MTX and cis-Pt clearance decreased when renal dysfunction was first observed and changes in renal function preceded changes in drug clearance and toxicity.