Autoxidation and yellowing of methyl linolenate.

The autoxidation of fatty esters of linseed oil is studied extensively, and the products formed from these reactions are identified. The mechanism suggested for autoxidation, helps to understand fat deterioration resulting in offensive odours and flavours, and to develop new antioxidants to prevent this decomposition. The oxidation following oxidative copolymerization should be investigated in order to understand and to develop new methodology to prevent yellowing. Although the yellowing of indoor oil paints could be prevented to an extent, no compound is known to completely inhibit this process nor has the cause for this yellow colouration been isolated, leaving the doors wide open for further investigation.

Relationship of mitotic arrest and apoptosis to antitumor effect of paclitaxel.

BACKGROUND: Microtubules are cellular organelles with functions that include control of cell division by mitosis, cell morphology, and transport of material within the cell. The anticancer drug paclitaxel (Taxol) promotes accelerated assembly of excessively stable microtubules. Consequently, treated cells tend to become arrested in mitosis. The drug also induces apoptotic cell death in vitro and in vivo. Prior to this study, the relative contributions of mitotic arrest and apoptosis to the in vivo antitumor effect and the relationship between the two factors had not been established; moreover, it is not known whether paclitaxel-induced mitotic arrest inevitably results in cell death. PURPOSE: Our aim was to quantify the mitotic arrest and apoptosis induced by paclitaxel in 16 murine tumors in vivo and to correlate these two factors with the drug's antitumor effect. METHODS: Inbred C3Hf/Kam mice were implanted with one of the following 16 syngeneic tumors: seven adenocarcinomas (MCa-4, MCa-29, MCa-35, MCa-K, OCa-I, ACa-SG, and HCa-I), two squamous cell carcinomas (SCC-IV and SCC-VII), six sarcomas (FSa, FSa-II, Sa-IIa, Sa-NH, NFSa, and Sa-4020), and one lymphoma (Ly-TH). The tumor growth delay induced by paclitaxel (40 mg/kg body weight given intravenously) was measured in 163 control and 163 treated mice, and its significance was assessed by Student's t test. In a separate group of 439 mice, the percentage of cells in mitosis or apoptosis was scored micromorphometrically at various times after paclitaxel administration. The significance of correlations between paclitaxel-induced tumor growth delay and paclitaxel-induced levels of mitosis or apoptosis was determined by simple correlation and Spearman's rank correlation. P values reported represent two-sided tests of statistical significance. RESULTS: Statistically significant tumor growth delays were found in response to paclitaxel treatment of mice for three of four murine mammary carcinomas (all P < or = .010), an ovarian carcinoma (P = .00003), a salivary gland adenocarcinoma (P = .0002), a lymphoma (P = .0002), and two of six sarcomas (both P < or = .034), but not for either of two squamous cell carcinomas or for the hepatocellular carcinoma. Paclitaxel-induced mitotic arrest was apparent in all tumor types, but to various degrees, and was not significantly correlated with growth delay (R2 = .16; P = .124). In contrast, apoptotic cell death in response to paclitaxel was not ubiquitous, but it was strongly correlated with growth delay (R2 = .59; P = .001). The pretreatment level of apoptosis was correlated with both paclitaxel-induced apoptosis (R2 = .71; P = .00004) and tumor growth delay (R2 = .55; P = .001). CONCLUSION: The antitumor effect of paclitaxel was correlated with paclitaxel-induced apoptosis and base-line apoptosis, but not with mitotic arrest. IMPLICATIONS: Apoptosis is an important mechanism of cell death in response to paclitaxel treatment of in vivo murine tumors. An underlying tumor type-specific propensity for apoptosis is implied by the correlation between pretreatment and paclitaxel-induced apoptosis. Both the extent of pretreatment apoptosis and the paclitaxel-induced percentage of apoptosis may be useful predictors of response to the drug.

Role of reoxygenation in induction of enhancement of tumor radioresponse by paclitaxel.

We reported previously (L. Milas et al., Cancer Res., 54: 3506-3510, 1994) that paclitaxel greatly enhances the response of a murine mammary carcinoma to subsequent irradiation and hypothesized that the enhanced radioresponse was mediated by tumor cell reoxygenation caused by treatment with paclitaxel. Because paclitaxel induced massive tumor cell destruction by apoptosis, it was reasoned that as apoptotic cells were removed from the tumor more hypoxic cells would have access to oxygen, be reoxygenated, and, thus, become more sensitive to radiation. The present study tested this hypothesis by assessing the effect of 60 or 40 mg/kg paclitaxel on radioresponse of an 8-mm MCA-4 tumor irradiated under air-breathing or hypoxic conditions 9, 24, 48, or 72 h after paclitaxel administration. If the hypothesis was correct, paclitaxel would enhance tumor radioresponse more under air breathing than under hypoxic conditions, and the enhancement would increase as the time between paclitaxel administration and tumor irradiation increased within a few days after paclitaxel treatment but only when radiation was given under air-breathing conditions. The effect of the treatments was determined by tumor growth delay and the radiation dose required to control 50% of the tumors (TCD50). Paclitaxel greatly enhanced tumor radioresponse under air-breathing (and not hypoxic) conditions, increasing tumor growth delay, and reducing TCD50. These effects increased as the time interval between paclitaxel administration and tumor irradiation increased within the observation period of 72 h after paclitaxel treatment. The enhancement factors for tumor growth delay ranged from 1.19 at 9 h to 1.86 at 48 h and for TCD50, from 1.16 at 9 h to 1.47 at 72 h after paclitaxel. Direct measurements of tumor pO2 showed a median value in untreated tumors of 6.2 mmHg, which increased to 10.5 mmHg at 24 h and to 31.2 mmHg at 48 h after paclitaxel administration. Overall, these results show that paclitaxel is a potent enhancer of tumor radioresponse and that its effect is mediated by reoxygenation of hypoxic tumor cells.

Enhancement of tumor radioresponse of a murine mammary carcinoma by paclitaxel.

Paclitaxel is a chemotherapeutic agent with potent microtubule stabilizing activity that arrests cells in G2-M. Because G2 and M are the most radiosensitive phases of the cell cycle, paclitaxel has potential as a cell cycle-specific radiosensitizer. In this study, we investigated the ability of paclitaxel to increase tumor radioresponse in vivo using a murine mammary carcinoma and the dependency of this response on accumulation of tumor cells in mitosis. Mice bearing 8-mm tumors were treated with paclitaxel (60 mg/kg i.v.), 9, 15, or 21 Gy of single-dose radiation, or with a regimen of both agents in which radiation was given 1, 9, or 24 h after paclitaxel. The effect of the treatments was determined by tumor growth delay. Microscopically, the percentage of mitotically arrested cells was only 4% 1 h after treatment with paclitaxel, increased to a maximum value of 30% at 9 h, and decreased to 12% 24 h after paclitaxel. Paclitaxel enhanced tumor radioresponse by factors of 1.21 to 2.49. The degree of enhancement increased with increases in both the dose of radiation and the time between paclitaxel administration and radiation delivery. Radiation efficiently destroyed mitotically arrested cells by apoptosis. The greatest enhancement of radiation response was not at the time of the highest mitotic arrest but at 1 day after paclitaxel treatment, showing that paclitaxel potentiates tumor radioresponse by mechanisms in addition to blocking the cell cycle in mitosis, possibly by tumor reoxygenation. Thus, these results show that paclitaxel is a potent in vivo radiopotentiating agent and has the potential to be usefully combined with radiotherapy.

The Withers archive: Online availability of rod Wither's data.

The contents of the lab notebooks of H.R. Withers have been digitized and stored as 23 excel files, a total of approximately 45 megabytes. A procedure is described whereby those interested may gain access to the data.

Comparison of secretion and subcellular localization of von Willebrand protein with that of thrombospondin and fibronectin in cultured human vascular endothelial cells.

Cultured human vascular endothelial cells synthesize von Willebrand protein, thrombospondin and fibronectin. These proteins are secreted in the culture medium and incorporated into the extracellular matrix. We have compared the subcellular localization and the secretion of these proteins in response to stimulants in cultured human umbilical vein endothelial cells. Density gradient centrifugation using colloidal silica showed that the storage and secretion organelle with von Willebrand protein did not contain thrombospondin or fibronectin. Indirect immunofluorescence microscopy indicated that thrombospondin and fibronectin are not located in the rod-shaped organelles containing von Willebrand protein. Thrombin, ionophore A23187 and phorbol myristate acetate did not affect secretion of thrombospondin and fibronectin, while von Willebrand protein secretion was stimulated upon incubation of cells with these agents for 30 min. Prolonged incubation of cultured endothelial cells after a 1-h treatment with phorbol myristate acetate resulted in an increased secretion of von Willebrand protein into the conditioned medium; in contrast, accumulation of thrombospondin and fibronectin in endothelial cell-conditioned medium was decreased. These findings indicate that, unlike in platelets, these major endothelial proteins are not located in the same subcellular compartments. Von Willebrand protein is distinguished from thrombospondin and fibronectin both by its unique subcellular localization and its secretion rate in response to stimuli.

Docetaxel enhances tumor radioresponse in vivo.

Although the radiosensitizing potential of paclitaxel has been investigated extensively in cancer treatment, a sister taxane, docetaxel, has been studied rarely. We investigated the ability of docetaxel to enhance in vivo tumor radioresponse and influence radiation injury to normal tissue. In addition, mitotic arrest and apoptosis in tumors and normal tissues were assessed after docetaxel administration to determine whether these cellular effects underly its radio-modifying action. Mice bearing in their legs 8-mm isotransplants of a murine mammary carcinoma, designated MCA-4, were treated with 33 mg/kg docetaxel i.v., 9-21 Gy single-dose local tumor irradiation, or both (in which case radiation was given 9 or 48 h after docetaxel). Tumor growth delay was the end point of the treatments. Mitotic arrest and apoptosis were assayed 1-72 h after treatment with docetaxel. Normal tissue radioresponse was determined using jejunal crypt cell survival 3.5 days after mice were exposed to 9.2-14.8 Gy single-dose, total-body irradiation; the mice were treated with 33 mg/kg docetaxel i.v. 3, 9, or 48 h before irradiation. Docetaxel was assessed for its ability to induce mitotic arrest and apoptosis in jejunum 1-72 h after treatment. Docetaxel induced both mitotic arrest and apoptosis in both tumor and jejunum. Mitotic arrest preceded apoptosis and peaked in the tumor at 9-12 h after treatment; it peaked at 3 h in jejunum. Docetaxel enhanced tumor radioresponse by a factor of 1.45 when the drug was given 9 h before radiation and 2.33 when it was given 48 h before. In contrast, it only slightly enhanced radiation-induced damage of the jejunum and only when given 3 or 9 h before irradiation. Thus, docetaxel given within 2 days before irradiation acted as a potent enhancer of tumor radioresponse and increased the therapeutic gain of irradiation.

Inverse relationship between epidermal growth factor receptor expression and radiocurability of murine carcinomas.

The study investigated whether a relationship exists between the extent of epidermal growth factor receptor (EGFR) expression and in vivo radiocurability of murine tumors. EGFR expression was determined in nine carcinomas (four mammary carcinomas, designated MCa-4, MCa-29, MCa-35, and MCa-K; two squamous cell carcinomas, designated SCC-IV and SCC-VII; an ovarian adenocarcinoma, OCa-I; a hepatocarcinoma, HCa-I; and an adenosquamous carcinoma, ACa-SG) syngeneic to C3Hf/Kam mice using Western blot analysis. These tumors greatly differed in their radioresponse, assessed by TCD50 assay, and in their susceptibility to radiation-induced apoptosis. Likewise, the expression of EGFR greatly varied, by as much as 21-fold, and the magnitude of the EGFR expression positively correlated with increased tumor radioresistance. The levels of EGFR inversely correlated with radiation-induced apoptosis, suggesting that the lack of sensitivity to apoptosis induction was a major mechanism responsible for radioresistance of tumors with high EGFR. This correlation was highly significant only for wild-type p53 carcinomas. Radiation activated EGFR autophosphorylation and increased the activity of protein tyrosine kinase, but only in tumors with high EGFR expression. Thus, EGFR expression was a major determinant of tumor radioresponse in vivo. The pretreatment assessment of EGFR expression could predict radiotherapy outcome and may assist in selecting an effective treatment modality.

Antitumor activity of poly(L-glutamic acid)-paclitaxel on syngeneic and xenografted tumors.

Poly(L-glutamic acid)-paclitaxel (PG-TXL) is a new water-soluble paclitaxel derivative that has shown remarkable antitumor activity against both ovarian and breast tumors. The purpose of this study was to test whether the antitumor efficacy of PG-TXL depends on tumor type, as is the case for paclitaxel, and to test whether paclitaxel-resistant tumors could be responsive to PG-TXL. We evaluated the therapeutic activity of PG-TXL against four syngeneic murine tumors (MCa-4, MCa-35, HCa-1, and FSa-II) inoculated i.m. into C3Hf/Kam mice, a human SKOV3ip1 ovarian tumor injected i.p. into nude mice, and a human MDA-MB-435Lung2 breast tumor grown in the mammary fat pad of nude mice. Two paclitaxel-responsive murine tumors, MCa-4 and MCa-35, showed significant growth delay with PG-TXL given as a single i.v. injection at its maximum tolerated dose of 160 mg of equivalent paclitaxel/kg or even at a lower dose of 120 mg of equivalent paclitaxel/kg. The other two murine tumors, HCa-1 and FSa-II, did not respond particularly well to either of the two agents, although significant growth delay was observed for both tumors with PG-TXL. In mice with SKOV3ip1 tumors, the median survival times for mice treated with PG alone and PG-TXL at doses of 60 or 120 mg of equivalent paclitaxel/kg were 43, 61, and 75 days, respectively; no survival difference was found between paclitaxel-treated and Cremophor vehicle-treated mice. In mice with MDA-MB-435Lung2 tumor, PG-TXL at a dose of 120 mg of equivalent paclitaxel/kg produced regression of the tumor in 50% of the animals, and in the remaining mice, micrometastases in the lung were found only in 25% of the animals. In comparison, treatment with paclitaxel at 60 mg/kg did not result in tumor regression, and the rate of lung metastases was 42%. These results clearly demonstrate that PG-TXL has significant therapeutic activity against breast and ovarian tumors tested in this study. Future studies to elucidate the mechanism of action of PG-TXL and to assess its clinical applications are warranted.

Cell attachment and fibrinogen binding properties of platelet and endothelial cell thrombospondin are not affected by structural differences in the 70 and 18 kDa protease-resistant domains.

Structural differences between platelet and endothelial cell thrombospondin (TBSP) were found in two protease-resistant domains (70 and 18 kDa). The 70 kDa fragment is involved in the binding of TBSP to fibrinogen and the 18 kDa fragment in the attachment to various cultured cells. Despite these structural differences, platelet and endothelial cell TBSP bound with the same affinity to fibrinogen and mediated the attachment of smooth muscle cells but not of endothelial cells.

Structural and immunological differences between human platelet and endothelial thrombospondins.

The structural and immunological properties of human thrombospondins isolated from platelets and from endothelial cells were compared. Both thrombospondins were digested with either trypsin or thermolysin, in the presence or absence of calcium, then injected onto a Superose 12 gel filtration column. The isolated thermolysin-generated fragments of thrombospondins were identified by radioimmunoassays using either different monoclonal antibodies or a polyclonal antibody directed against platelet thrombospondin. The results show that platelet and endothelial thrombospondins are both partially protected from trypsin digestion in the presence of calcium but have different trypsin and thermolysin fragmentation patterns. The thermolysin-generated fragments from platelet and endothelial thrombospondins are recognized differently by a monoclonal antibody whereas all of them are identified by a polyclonal antibody.

Enhanced radioresponse of paclitaxel-sensitive and -resistant tumours in vivo.

Paclitaxel is a potent chemotherapeutic drug and also has the potential to act as a radioenhancing agent. The latter is based on its ability to arrest cells in the radiosensitive G2M phases of the cell cycle; the weight of supporting evidence is derived mainly from in vitro studies. Our previous in vivo experiments identified enhanced tumour radioresponse predominantly attributable to tumour reoxygenation occurring as a result of paclitaxel-induced apoptosis. The current study investigated whether paclitaxel enhanced the radioresponse of tumours which are insensitive to apoptosis induction, but exhibited mitotic arrest, and compared the degree and kinetics of the response to that in tumours which develop apoptosis. The mouse mammary carcinoma MCa-29 (apoptosis sensitive) and the squamous cell carcinoma SCC-VII (apoptosis resistant) were used. In addition, the study investigated whether paclitaxel affected normal skin radioresponse to determine if a therapeutic gain could be achieved. Paclitaxel enhanced the radioresponse of both types of tumours. In the SCC-VII tumour, radiopotentiation occurred within 12 h of paclitaxel administration coincident with mitotic arrest, where enhancement factors (EFs) ranged from 1.15 to 1.37. In MCa-29 tumour, the effect was greater, EFs ranging from 1.59 to 1.91 and occurred between 24 and 72 h after paclitaxel when apoptosis was the predominant microscopic feature of treated tumours and when tumour oxygenation was found to be increased. The acute skin radioresponse and late leg contracture response were essentially unaffected by prior treatment with paclitaxel. Therefore, by two distinct mechanisms, paclitaxel was able to enhance the radioresponse of paclitaxel-sensitive and -resistant tumours, but not the normal tissue radioresponse, thus providing true therapeutic gain.

Modification of radiation-induced carcinogenesis in mice by misonidazole and WR-2721.

The effects of the radiosensitizer misonidazole (MISO) and the radioprotector WR-2721 on radiation-induced carcinogenesis in C3Hf/Kam mice were investigated. The right hind legs were exposed to graded single doses of gamma-rays. MISO and WR-2721 were given i.p. 30 min before irradiation at a dose of 1 mg/g and 0.4 mg/g, respectively. The RCD50, or radiation dose inducing tumors in 50% of the irradiated legs, was determined 650 days after treatment. The same animals were also checked for the effect of these drugs on hair loss and radiation-induced leg contractures. MISO enhanced radiation carcinogenesis by a factor of 1.43, whereas WR-2721 reduced it by a factor of 1.75. These effects on carcinogenesis correlated well with the modifying effects of the two agents on radiation-induced hair loss (early damage) and leg contractures (late damage).

Reemergence of apoptotic cells between fractionated doses in irradiated murine tumors.

PURPOSE: The purpose of this investigation was to follow up our previous studies on the development of apoptosis in irradiated murine tumors by testing whether an apoptotic subpopulation of cells reemerges between fractionated exposures. METHODS AND MATERIALS: Mice bearing a murine ovarian carcinoma, OCa-I, were treated in vivo with two fractionation protocols: two doses of 12.5 Gy separated by various times out to 5 days and multiple daily fractions of 2.5 Gy. Animals were killed 4 h after the last dose in each protocol, and the percent apoptosis was scored from stained histological sections made from the irradiated tumors according to the specific features characteristic of this mode of cell death. RESULTS: The 12.5 + 12.5 Gy protocol yielded a net total percent apoptosis of about 45% when the two doses were separated by 5 days (total dose = 25 Gy), whereas the 2.5 Gy per day protocol yielded about 50% net apoptotic cells when given for 5 days (total dose = 12.5 Gy). These values are to be compared to the value of 36% apoptotic cells that is yielded by large single doses (> 25 Gy). Thus, these results indicate that an apoptotic subpopulation of cells reemerged between the fractions in both protocols, but the kinetics appeared to be delayed in the 12.5 + 12.5 Gy vs. the multiple 2.5 Gy protocol. CONCLUSION: This reemergence of cells with the propensity for radiation-induced apoptosis between fractionated exposures is consistent with a role for this mode of cell death in the response of tumors to radiotherapy and may represent the priming of a new subpopulation of tumor cells for apoptosis as part of normal tumor homeostasis to counterbalance cell division.

Association of increased radiocurability of murine carcinomas with low constitutive expression of p21(WAF1/CIP1) protein.

PURPOSE: The study investigated whether basal, constitutive levels of p21(WAF1/CIP1) protein in murine carcinomas are related to in vivo tumor radioresponse. The study is based on recent observations demonstrating that in vitro cancer cell lines are resistant to cytotoxic drugs when they express high basal levels of p21(WAF1/CIP1) protein, and that the loss of the p21 gene in the HCT116 human colorectal cancer cell line results in increased radioresponse of xenografts derived from that cell line. METHODS AND MATERIALS: Protein levels of p21(WAF1/CIP1), p53, bax, and bcl-2 were determined in 8 carcinomas (3 mammary carcinomas designated MCa-4, MCa-29, and MCa-35, 2 squamous cell carcinomas designated SCC-IV and SCC-VII, ovarian adenocarcinoma OCa-I, hepatocarcinoma HCa-I, and adenosquamous carcinoma ACa-SG) syngeneic to C3Hf/Kam mice using Western blot analysis. The tumors, growing in the right hind legs of mice, were 8 mm in diameter at the time of analysis. These tumors greatly differ in their radioresponse, assessed by TCD50 assay, and in their susceptibility to radiation-induced apoptosis. RESULTS: Protein levels of these oncogenes varied among tumors, with p21(WAF1/CIP1) showing the greatest variation: its mean densitometric value ranged from 1 to 19. Bcl-2 levels also showed broad variation in densitometric values, from 1 to 10. In comparison, bax and p53 (7 of 8 tumors contained wild-type p53) varied much less among different tumor types; their variation was within a 5-fold range, and the level of p53 was similar in 6 of 8 tumors. Tumor radioresponse correlated significantly (R = 0.77, p = 0.02) only with the magnitude of p21(WAF1/CIP1)expression: tumors with high levels of p21(WAF1/CIP1)were less radiocurable than those with lower levels. Tumor radiocurability showed a significant positive correlation (p = 0.02) with the extent of radiation-induced apoptosis, indicating that tumors that responded to radiation with higher percentages of apoptosis were more curable by radiation. Despite a strong trend to correlation, (p = 0.15), p21(WAF1/CIP1) expression did not correlate significantly with radiation-induced apoptosis, which suggested that p21(WAF1/CIP1) influenced tumor radioresponse by mechanisms beyond that of apoptosis induction. CONCLUSION: Our findings showed that murine tumors exhibit wide variation in constitutive levels of p21(WAF1/CIP1) which had a significant relationship with tumor radioresponse: tumors with high levels of p21(WAF1/CIP1) were less radiocurable than those with lower levels. These findings support the concept that p21(WAF1/CIP1) is a major determinant of tumor radioresponse in vivo, and may have important clinical implications. The pretreatment assessment of p21(WAF1/CIP1) protein could serve as a useful predictor of radiotherapy outcome and may assist in selecting an effective treatment modality.

Maximizing therapeutic gain with gemcitabine and fractionated radiation.

PURPOSE/OBJECTIVE: The nucleoside analogue gemcitabine inhibits cellular repair and repopulation, induces apoptosis, causes tumor growth delay, and enhances radiation-induced growth delay. After single doses of drug and radiation, maximum enhancement of tumor response was obtained when gemcitabine preceded radiation by at least 24 h. Conversely, the cellular radioresponse of the normal gastrointestinal epithelium was slightly protected when gemcitabine and radiation were separated by 24 h. This differential response created a time frame within which therapeutic gain could be maximized. In our present investigation, we sought to define the most therapeutically beneficial scheme of gemcitabine administration when combined with fractionated radiotherapy. METHODS AND MATERIALS: C3Hf/Kam mice were given identical drug and radiation schedules of administration, and both normal tissue (jejunal mucosa) and tumor (Sa-NH) responses were measured. Irradiation was given once per day for 5 days in normal tissue and tumor growth delay studies and twice per day for the tumor cure endpoint. A total dose of 25 mg/kg gemcitabine was given i.p. in 1 of 3 schedules: a single dose of 25 mg/kg 24 h before the start of fractionated irradiation, 12.5 mg/kg 24 h before the first and third radiation doses, or 24 h before each of 5 radiation doses. Groups of mice bearing 7- or 8-mm diameter tumors were treated with gemcitabine alone or in combination with fractionated irradiation under ambient or hypoxic conditions. The survival response of the jejunal mucosa was quantified by the microcolony assay and histologically by quantifying apoptosis, mitosis, S-phase fraction, and crypt cellularity. RESULTS: For tumor growth delay, dose-modifying factors (DMFs) were similar (1.34-1.46) for all 3 schedules of drug administration. In contrast, the response of the jejunum was strongly dependent on the schedule of gemcitabine administration. A single dose of gemcitabine before the start of fractionated radiotherapy resulted in slight radioprotection (DMF 0.96). Two doses and 5 daily doses of gemcitabine enhanced radiation response by factors of 1.09 and 1.23, respectively. Major factors affecting the response of the jejunal mucosa were apoptotic death of S-phase cells exposed to gemcitabine and cell cycle synchrony of surviving cells. Tumor reoxygenation was found to be a major mechanism for tumor radioenhancement, in addition to those reported earlier. CONCLUSION: All 3 schedules of drug administration produced therapeutic gain; however, when gemcitabine was given more than once in a 5-fraction radiation treatment schedule, normal tissue toxicity increased. The highest therapeutic gain (1.4) was achieved by giving a single dose of gemcitabine (25 mg/kg) 24 h before the start of fractionated radiotherapy.

Cyclic amidine inhibitors of indolamine N-methyltransferase.

Syntheses of a large number of mono- and bicyclic, as well as a few tricyclic, amidine derivatives related to 2,3,4,6,7,8,-hexahydropyrrolo[1,2-a]pyrimidine (DBN) are reported. In vitro potencies for inhibition of the enzyme indolamine N-methyltransferase (INMT) from rabbit and human lung are presented. Four bicyclic amidine derivatives and 11 monocyclic derivatives were found to be equal or superior to DBN in in vitro potencies. With the bicyclic amidines, increasing ring size or introduction of substituents reduced activity. Among the monocyclic analogues, the most potent representatives were five- or six-membered systems with an exocyclic imino group, combined with methyl of ethyl substituents on the endocyclic nitrogen. Introduction of additonal substituents decreased inhibitory potency. 2,3,5,6-Tetrahydro-8H-imidazo[2,1-c][1,4]thiazine and 3-methyl-2-iminothiazolidine have been shown to cause inhibition of lung INMT when administered orally to rabbits.

Synthesis, biodistribution and imaging properties of indium-111-DTPA-paclitaxel in mice bearing mammary tumors.

UNLABELLED: Paclitaxel, an antineoplastic agent that stabilizes microtubules and arrests cells in the G2/M cell cycle phase, has shown activity against many common cancers, including ovarian and breast tumors. In order to evaluate the potential value of radiolabeled paclitaxel as an imaging tool in tumors, we synthesized 111In-DEPA-paclitaxel and investigated its biodistribution and gamma scintigraphic imaging properties. METHODS: Mice bearing a paclitaxel-responsive mammary tumor (MCA-4) were used. DTPA-paclitaxel was labeled with 111In with a radiochemical yield of 84% and radiochemical purity of 90%. Each mouse received 5 microCi of radiotracers intravenously for biodistribution studies and 100 microCi for gamma scintigraphic studies. Indium-111-DTPA was used as a control. RESULTS: In tumor-bearing mice, 111In-DTPA was characterized by rapid clearance from the plasma with negligible retention in the tumor, the liver and other body parts. In contrast, 111In-DTPA-paclitaxel exhibited a pharmacological profile resembling that of paclitaxel. Furthermore, a significant uptake of 111In-DTPA-paclitaxel was observed in the tumor. The tumor-to-muscle ratios were 2.64, 3.16 and 6.94 at 30 min, 2 hr and 24 hr, respectively, although absolute uptake in the tumor decreased from 1.95% (injected dose/g) at 30 min to 0.21% at 24 hr after injection. The tumor-to-blood ratio reached 50 at 24 hr after injection. Gamma scintigraphy and autoradiographic studies clearly showed the retention of radiolabeled paclitaxel in the tumor 24 hr after injection. CONCLUSION: These studies suggest that 111In-DTPA-paclitaxel may be clinically useful in studying the uptake of paclitaxel in solid tumors.

Quantitation by radioimmunoassay of thrombospondin synthesised and secreted by human endothelial cells.

Synthesis and secretion of thrombospondin by cultured human endothelial cells was quantified using a sensitive radioimmunoassay. Two endothelial lines were examined; those from umbilical veins and those from saphenous veins. The foetal line secreted approximately 17 micrograms/10(6) cells of the antigen at 24 hr, whereas the saphenous line secreted five times less in the same period. Intracellular values were similar in both lines. Thrombin and calcium ionophore A23187 were added to umbilical vein endothelial cultures. In contrast to platelets where both agents cause a rapid release reaction, no such thrombospondin release was observed in endothelial cells.

Radiation-induced apoptosis in a murine lymphoma in vivo.

A number of radiobiologic parameters of radiation-induced apoptosis were investigated in a syngeneic murine B-cell lymphoma, designated LY-TH. These included radiation dose effect, kinetics of apoptosis development, the effect of hypoxia and split-dose recovery. Tumors, 8 mm in size, were locally irradiated with graded doses ranging from 1 to 10-Gy gamma rays. Radiation-induced apoptosis was observed as early as 1 h after irradiation, peaked between 4 and 6 h and could no longer be detected 24 h later. The magnitude of the apoptotic response generally increased with radiation dose, but lower doses seemed to be relatively more effective than higher doses. Tumor hypoxia, produced by tumor clamping, inhibited induction of apoptosis by a factor of about 2.5. When two doses of radiation were separated by times of 1-10 days, the proportion of apoptotic cells induced by the second dose was greatly reduced compared to the initial dose. This reduction was the greatest when the second dose was given 2 days after the first dose. The proportion of apoptotic cells induced by the second dose slowly recovered after 2 days but it did not return to the initial levels after as long as 10 days.