Growth, morphology, and serial transplantation of anaplastic human gliomas in athymic mice

Suppression of tumour growth from transplanted astrocytoma cells transfected with luciferase in mice by bioluminescence mediated, systemic, photodynamic therapy

BACKGROUND

Grade 4 astrocytomas are usually incurable due to their diffusely infiltrative nature. Photodynamic therapy (PDT) is a promising therapeutic option, but external light delivery is impractical when cancer cells infiltrate unknown areas of normal brain. Hence the search for endogenous sources to generate light at cancer cells. In vitro, astrocytoma cells, transfected with firefly luciferase, can be killed by bioluminescence-mediated PDT (bPDT). This study asks if bPDT can suppress tumour growth In vivo, when all components of treatment are administered systemically.

METHODS

Transfected astrocytoma cells were injected subcutaneously or intra-cranially in athymic CD1 nu/nu mice. bPDT required ip bolus of mTHPC (photosensitiser) and delivery of the d-luciferin substrate over 7 days via an implanted osmotic pump. Control animals had no treatment, photosensitiser only or d-luciferin only. For subcutaneous tumours, size and BLI (light emitted after d-luciferin bolus) were measured before and every 2 days after PDT. For intracranial tumours, monitoring was weekly BLI.

RESULTS

For subcutaneous tumours, there was significant suppression of the tumour growth rate (P<0.05), and absolute tumour size (P<0.01) after bPDT. Proliferation of subcutaneous and intracranial tumours (monitored by BrdU uptake) was significantly reduced in treated mice. (P<0.001) CONCLUSIONS: This study reports bPDT suppression of tumour growth from luciferase transfected astrocytoma cells with all components of treatment given systemically, as required for effective management of recurrent astrocytomas in unknown sites. However, research on systemic bPDT is needed to establish whether effects on non-transfected tumours can be achieved without any unacceptable effects on normal tissues.

Labeling Monoclonal Antibody with α-emitting 211At at High Activity Levels via a Tin Precursor

Background: In a previous clinical study, the authors evaluated the potential of antitenascin C monoclonal antibody (mAb) 81C6 labeled with ²¹¹At via the prosthetic agent N-succinimidyl 3-[²¹¹At]astatobenzoate (SAB) for the treatment of primary brain tumors. Although encouraging results were obtained, labeling chemistry failed while attempting to escalate the dose to 370 MBq. The goal of the current study was to develop a revised procedure less susceptible to radiolysis-mediated effects on ²¹¹At labeling that would be suitable for use at higher activity levels of this α-emitter. Materials and Methods: Addition of N-chlorosuccinimide to the methanol used to remove the ²¹¹At from the cryotrap after bismuth target distillation was done to thwart radiolytic decomposition of reactive ²¹¹At and the tin precursor. A series of 11 reactions were performed to produce SAB at initial ²¹¹At activity levels of 0.31-2.74 GBq from 50 μg of N-succinimidyl 3-trimethylstannylbenzoate (Me-STB), which was then reacted with murine 81C6 mAb without purification of the SAB intermediate. Radiochemical purity, immunoreactive fraction, sterility, and apyrogenicity of the ²¹¹At-labeled 81C6 preparations were evaluated. Results: Murine 81C6 mAb was successfully labeled with ²¹¹At using these revised procedures with improved radiochemical yields and decreased overall synthesis time compared with the original clinical labeling procedure. Conclusions: With 2.74 GBq of ²¹¹At, it was possible to produce 1.0 GBq of ²¹¹At-labeled 81C6 with an immunoreactive fraction of 92%. These revised procedures permit production of ²¹¹At-labeled mAbs suitable for use at clinically relevant activity levels.

Antitenascin antibody 81C6 armed with 177Lu: in vivo comparison of macrocyclic and acyclic ligands

INTRODUCTION

When labeled with iodine-131, the antitenascin monoclonal antibody (mAb) 81C6 has shown promise as a targeted radiotherapeutic in patients with brain tumors. Because of its more favorable gamma-ray properties, lutetium-177 might be a better low-energy beta-emitter for this type of therapy.

MATERIALS AND METHODS

Chimeric 81C6 (ch81C6) was labeled with (177)Lu using the acyclic 1B4M ligand and the macrocyclic ligands NHS-DOTA and MeO-DOTA and evaluated for binding to tenascin. Three paired-label tissue distribution experiments were performed in normal mice receiving one of the (177)Lu-labeled immunoconjugates plus (125)I-labeled ch81C6 labeled using Iodogen. Paired-label experiments in athymic mice bearing subcutaneous D54 MG human glioma xenografts were done to directly compare the biodistribution of ch81C6-1B4M-(177)Lu and (125)I-labeled ch81C6, and ch81C6-MeO-DOTA-(177)Lu and (125)I-labeled ch81C6. Similar comparisons were done using murine (mu) instead of ch81C6. The primary parameter utilized for evaluation was the (177)Lu/(125)I uptake ratio in each tissue.

RESULTS

In the studies performed in normal mice, the NHS-DOTA ligand yielded the highest (177)Lu/(125)I uptake ratios in tissues indicative of loss of label from the chelate; for this reason, only 1B4M and MeO-DOTA were evaluated further. The (177)Lu/(125)I ratio in bone increased gradually with time for the chimeric conjugates; however, there were no significant differences between ch81C6-1B4M-DTPA-(177)Lu and ch81C6-MeO-DOTA-(177)Lu. In contrast, mu81C6-1B4M-DTPA-(177)Lu and mu81C6-MeO-DOTA-(177)Lu showed a more dramatic increase in the (177)Lu/(125)I ratio in bone - from 2.4+/-0.3 and 1.7+/-0.2 at Day 1 to 8.5+/-1.1 and 4.2+/-0.5 at Day 7, respectively.

CONCLUSION

With these antitenascin constructs, the nature of the mAb had a profound influence on the relative degree of loss of (177)Lu from these immunoconjugates. MeO-DOTA shows promise as a bifunctional chelate for labeling 81C6 mAbs with (177)Lu.

Receptor expression, cytogenetic, and molecular analysis of six continuous human glioma cell lines

Six human glioma cell lines were established from tissues obtained from five patients diagnosed with Kernohan grade IV glioblastoma multiforme and one from a patient with a grade II astrocytoma. One line was from a recurrent patient who had received prior therapy; the other lines were derived from patients at initial diagnosis and/or before cytoreductive therapies other than surgery were given. Considerable variability in phenotypic, karyotypic, and cell surface marker expression was displayed between the six human glioma cell lines. The karyotypes ranged from apparently normal (grade II astrocytoma) to those with complex rearrangements. Trisomy of chromosome 7 was the most common abnormality. The extensive cytogenetic and molecular characterization of these lines may facilitate their utilization in cellular and molecular biologic studies.

Characterization of human homologs of the Drosophila seven in absentia (sina) gene

Studies of Drosophila photoreceptor development have illustrated the means by which signal transduction events regulate cell fate decisions in a multicellular organization. Development of the R7 photoreceptor is best understood, and its formation is dependent on the seven in absentia (sina) gene. We have characterized two highly conserved human homologs of sina, termed SIAH1 and SIAH2. SIAH1 maps to chromosome 16q12 and encodes a 282-amino-acid protein with 76% amino acid identity to the Drosophila SINA protein. SIAH2 maps to chromosome 3q25 and encodes a 324-amino-acid protein that shares 68% identity with Drosophila SINA and 77% identity with human SIAH1. SIAH1 and SIAH2 were expressed in many normal and neoplastic tissues, and only subtle differences in their expression were noted. However, one of three murine homologs, Siah1B, was strongly induced in fibroblasts undergoing apoptotic cell death. While a previous study suggested that SINA was a nuclear protein, epitope-tagged SINA and SIAH1 proteins were found in the cytoplasm of Drosophila and mammalian cells. Their substantial evolutionary conservation, role in specifying cell fate, and activation in apoptotic cells suggest the SIAH proteins have important roles in vertebrate development. Furthermore, given the role of sina in Drosophila photoreceptor development, SIAH2 is a candidate for the Usher syndrome type 3 gene at chromosome 3q21-q25.

Tissue distribution and radiation dosimetry of astatine-211-labeled chimeric 81C6, an alpha-particle-emitting immunoconjugate

A paired-label study was performed in athymic mice bearing subcutaneous D-54 MG human glioma xenografts to compare the localization of human/mouse anti-tenascin chimeric antibody 81C6 labeled by reaction with N-succinimidyl 3-[211At]astatobenzoate and N-succinimidyl 3-[131I]iodobenzoate. Over the 48-h observation period, the distribution of 211At- and 131I-labeled antibody were quite similar in tumor and normal tissues except stomach. These data were used to calculate human radiation doses for both intravenously and intrathecal administered 211At-labeled chimeric 81C6 using a quality factor of 5 for alpha-emissions.

In vivo growth conditions suppress the expression of ganglioside GM2 and favour that of lacto series gangliosides in the human glioma D-54MG cell line

The human glioma D-54MG cell line grown in vitro primarily expresses ganglio series gangliosides, particularly GM2. Subcutaneous injection of these cells into nude mice produced xenografts with an increased content of the human glioma-associated lacto series gangliosides, primarily 3'-isoLM1, an alteration that was dose dependent, with the highest dose (1 x 10(8)) resulting in a phenotype that was most like that of the inoculum. After one passage in vivo, the lacto series dominated and reached a proportional level that was kept throughout the 10 passages. The mRNA levels of the GM2-synthase clearly coincided with GM2 expression and was 20 times higher in cells grown in vitro than in those grown in vivo. These results support the view that ganglioside expression in human gliomas is strongly influenced by environmental factors.

A pial window model for the intracranial study of human glioma microvascular function

A new model for human brain tumor uses the intracranial placement of tumor xenografts under transparent glass cranial windows in nude rats, which require no immunosuppression for tumor engraftment. Adult male nude rats underwent implantation of human anaplastic astrocytomas (D-54 MG in 10 rats, D-317 MG in 11 rats). The tumors were placed on the pial surface of the left cerebral hemisphere under a glass cranial window overlying the cranium. Six control animals underwent cranial window placement alone. Tumor volumes were estimated from direct measurements of tumor dimensions, revealing a mean doubling time of 1.58 days for the D-54 MG tumors and 2.62 days for the D-317 MG tumors. When tumor volume estimates reached 35 mm3, photomicrographs revealed tumor vasculature in each tumor cell line that was distinct from both the other xenograft and the normal brain parenchyma. Qualitative differences in vascular appearance were supported by length/density coefficient calculations in each study group, with D-317 MG demonstrating the highest vascular density. Vessel caliber tended to be smaller in D-54 MG tumors than in D-317 MG tumors. Laser-Doppler measurements of local blood flow in tumors and normal parenchyma revealed significantly lower blood flow in both tumor cell lines than in control brain. Evaluation of leukocyte/endothelial cell interactions indicated more leukocyte rolling in D-54 MG tumors than in D-317 MG tumors; no evidence of this cell interaction was found in normal pial vasculature. This model allows direct serial inspection of human brain tumor growth and vascular function in an experimental animal and could be used to study tumor vascular and inflammatory responses to a variety of therapeutic manipulations.

Generation and characterization of a mouse/human chimeric antibody directed against extracellular matrix protein tenascin

The murine anti-tenascin monoclonal antibody 81C6, following iodination, has been shown to be an efficient localizing and therapeutic agent in both subcutaneous and intracranial human glioma xenograft models in athymic mice and rats. Similarly, effective monoclonal antibody 81C6 localization has been demonstrated in glioma patients, and Phase I trials with the intact murine IgG2b kappa molecule are currently in progress. In order to maximize the potential for repeated administration by minimizing murine Fc-mediated immunogenicity and reducing Fc-mediated immune effects, we created murine 81C6 variable region/human IgG2 chimeric monoclonal antibodies by the molecular cloning of the variable region genes of mouse 81C6 and their genetic linkage to human constant region exons. The resulting chimeric constructs were introduced into SP2/0 cells, and stable transfectomas were selected by G418 and mycophenolic acid resistance. The resistant clones were screened for anti-tenascin activity on tenascin-coated plates by enzyme-linked immunosorbent assay. The N-terminal amino acid sequence of both heavy and light chains of the purified chimeric 81C6 antibody matched exactly with that of the native mouse 81C6 as well as with that deduced from the nucleotide sequence. The production level of chimeric 81C6 (13.9 mg/ml) from ascites in the highest expressing transfectoma was much higher than that of native mouse 81C6 (2.5 mg/ml). The chimeric antibody showed the same specificity and equivalent affinity for human intact tenascin or tenascin-expressing cells as the native mouse 81C6 antibody. Direct comparison of radioiodinated chimeric and radioiodinated mouse 81C6 biodistribution in subcutaneous and intracranial xenograft-bearing mice showed higher tumor-to-normal tissue ratios for chimeric 81C6 as compared with native mouse 81C6. The improved localizing and clearance characteristics of chimeric 81C6 in xenograft model systems suggests that chimeric 81C6 would be an improved reagent for intracompartmental therapy of tenascin-expressing tumors in the human central nervous system.

Mouse/human chimeric Me1-14 antibody: genomic cloning of the variable region genes, linkage to human constant region genes, expression, and characterization

Murine monoclonal antibody Me1-14, which recognizes an epitope on chondroitin proteoglycan sulfate expressed in malignant glioma and melanoma, has been used for radioimmunolocalization and therapy both in animal models and in patients. Here, we report the generation, characterization, and in vivo biodistribution of mouse/human chimeric Me1-14. Rearranged immunoglobulin genes from the Me1-14 hybridoma were identified by Southern blot analysis. Putative rearranged light- and heavy-chain genes were cloned from Lambda-ZapII Me1-14 genomic libraries and sequenced for nucleotide analysis. One of the putative heavy-chain Eco RI fragments (3.5 kb) had all the features of an intact variable region, including a functional leader sequence, in-frame V-D and D-J junctions, and cysteines 22 and 92. The deduced amino acid sequence from the heavy-chain variable region gene showed considerable homology with the invariant protein sequence of the mouse heavy-chain subgroup IIIB. Like the heavy-chain gene, one of the putative rearranged kappa-chain Hind III fragments (4 kb) had all of the characteristics of the functional variable region, and the deduced amino acid sequence showed homology to the invariant sequence of kappa-chain group V. The variable region genes for heavy- and light-chains were linked to human constant region exons in the expression vectors at the unique sites and cotransfected into mouse SP2/0 cells. The production level of chimeric Me1-14 from ascites in the highest expressing transfectoma was 1.8 mg/ml. The chimeric Me1-14 antibody exhibited the same specificity and similar affinity as that of parent Me1-14. Direct comparison of radioiodinated chimeric and murine Me1-14 in paired-label biodistribution analysis in subcutaneous xenograft-bearing mice showed higher tumor-to-normal organ ratios for chimeric Me1-14 IgG2, suggesting that this chimeric Me1-14 may be potentially useful in vivo for diagnostic and therapeutic purposes in patients.

Gangliosides associated with primary brain tumors and their expression in cell lines established from these tumors

Human primary brain tumors differ in their ganglioside composition when compared to adjacent tissues. One ganglioside found in all malignant glioma specimens, but not detected in normal adult brain, is 3'-isoLM1, a ganglioside of the lacto series. This ganglioside was also identified in medulloblastomas with astrocytic differentiation and in brain tissues containing benign proliferating astrocytes. The appearance of 3'-isoLM1 was seen over large regions of brain from glioma but was found mainly in areas either adjacent to the macroscopic tumor or areas corresponding to the tumor in the opposite hemisphere. A high concentration of 3'-isoLM1 was also seen in the corpus callosum, the anatomical structure along which glioma cells may migrate to the opposite brain hemisphere. Ganglioside expressed by cell lines established from primary malignant brain tumors varied widely among cell lines and within a given cell line propagated under different conditions. In in vitro-cultured glioma and medulloblastoma cell lines, gangliosides of the ganglio series dominated and the expression of the lacto series gangliosides, including 3'-isoLM1 was low if at all detectable. However, in vivo growth of solid subcutaneous tumors in nude mice or rats led to a significantly increased expression of the often dominant gangliosides of the lacto series and revealed a decreased expression of ganglio series gangliosides. In conclusion, these findings indicate that environmental factors could strongly influence the expression of gangliosides that may lead to a switch from the ganglio to the lacto series. These results also suggest that ganglioside 3'-isoLM1 is associated with proliferating astrocytes, of both neoplastic and non-neoplastic origin and that this ganglioside may be involved in cell-cell recognition and attachment during development and tumor cell migration.

Characterization of a continuous human glioma cell line DBTRG-05MG: growth kinetics, karyotype, receptor expression, and tumor suppressor gene analyses

The establishment of a new glioma cell line, DBTRG-05MG, in a modified RPMI 1640 medium is described. The cells were derived from an adult female with glioblastoma multiforme who had been treated with local brain irradiation and multidrug chemotherapy; the tumor showed substantial change in histologic appearance compared to the original biopsy 13 mo. previously. The line has been successfully cryopreserved and passaged up to 20 times. The karyotype of the cells demonstrated it as a hypotetraploid line; the DNA index of 1.9 confirmed the karyotype analyses. By immunocytochemical analysis, the cell line reacted with polyclonal antibodies to vimentin, S100, and neuron specific enolase, reflecting its primitive neuroectodermal character. Positive immunostaining for epidermal growth factor receptor correlated with the excess of chromosome 7 seen in the karyotype. The cell line reacted negatively to antibodies against platelet-derived growth factor and its receptor, neuronal cell adhesion molecule, and glial fibrillary acidic protein. By flow cytometry, the cells were major histocompatibility class I antigen positive and class I antigen negative. Growth kinetic studies demonstrated an approximate population doubling time of 34 to 41 h and a colony forming efficiency of 71.4%. Western blot analysis showed the presence of low levels of normal-sized retinoblastoma protein. When compared to the patient's lymphocyte DNA, no loss of heterozygosity of the p53 tumor suppressor gene was observed in the DBTRG-05MG cell line DNA.

The radiation dose-response relationship in a human glioma xenograft and an evaluation of the influence of glutathione depletion by buthionine sulfoximine

We have used an extensively characterized human glioma cell line in an athymic mouse model to evaluate new therapeutic approaches for human supratentorial high grade gliomas. The tumor, D-54MG, is a subline of a human anaplastic glioma. Eight days after homozygous nu/nu BALB/c athymic mice received intracranial (IC) injections of a tumor homogenate, the whole brain was irradiated with either single fractions of 4, 8, 9, and 12 Gy or twice daily fractions, separated by least 6 hr, of 2.28 Gy x 2 or 7.53 Gy x 2. To evaluate whether or not glutathione depletion influenced animal survival, animals at each dose level received either intraperitoneal (IP) buthionine sulfoximine (BSO) alone or I.P. BSO plus BSO in the drinking water. There was a stepwise prolongation of animal survival with increasing doses of external beam radiation. Mean survival in 9 of the 10 control groups (8-12 animals per group) ranged from 14.1 to 18.8 days. Mean survival ranged from 15.3 to 22.5 days at 4 Gy, 25 to 30 days at 8 Gy, 22.3 to 29.7 days at 9 Gy, and 32.9 to 33.6 days at 12 Gy single dose irradiation. At 2.28 Gy x 2 split dose irradiation mean survival was 29.3 days, for 7.53 Gy x 2 mean survival was over 47 days. The data for single fraction irradiation fit a linear regression line (r = 0.908) of mean animal survival = (1.22 [dose in Gy] + 16.7) days. Tumor GSH levels were decreased with all BSO dosing regimens tested. The most aggressive regimen (I.P. BSO+oral BSO for 5 days), reduced tumor GSH to 6.2% of control. Increased survival in irradiated glutathione depleted mice versus mice receiving radiation alone was not seen.

Chromosomal composition of malignant human gliomas through serial subcutaneous transplantation in athymic mice

The karyotypes of seven human glioblastomas were followed through serial subcutaneous passage in athymic mice. One tumor maintained the same hypodiploid stemline as seen in the original biopsy. Three tumors that originally had near-diploid stemlines showed an increase in stemline number to pseudodiploid or hyperdiploid due to gains of whole chromosomes. One tumor showed an entirely different karyotypic profile in the xenograft than had been demonstrated originally. Two tumors showed a shift from near-diploid stemlines to near-tetraploid and near-pentaploid stemlines. Structural abnormalities, including double minutes, that were present originally were maintained in the xenografts, and acquisition of new marker types was rare. Five of the seven lines showed an increased growth rate with serial passage as measured by a shortening of tumor doubling time and decreased time to 1000-mg size. There was, however, no obvious relationship between this change in growth rate and the karyotypic or histologic pattern. These studies demonstrate that most subcutaneous xenografts derived from malignant human gliomas retain karyotypes similar to those seen originally, making these systems useful models for studying the biologic significance of the chromosomal abnormalities of these tumors.

Buthionine sulfoximine-mediated depletion of glutathione in intracranial human glioma-derived xenografts

D-54 MG, a human glioma-derived continuous cell line growing as subcutaneous or intracranial xenografts in athymic mice, was found to be sensitive to the effects of D,L-buthionine-(SR)-sulfoximine, a selective inhibitor of gamma-glutamylcysteine synthetase. Intraperitoneal administration of one dose of buthionine sulfoximine (BSO, 5 mmol/kg) resulted in depletion of total intracellular glutathione to 57 and 47% of control 12 hr, and 73 and 23% of control 24 hr, after BSO in subcutaneous and intracranial xenografts respectively. Concurrent measurement of total glutathione in the contralateral (non-tumor-containing) cerebral hemisphere in mice bearing intracranial D-54 xenografts demonstrated insignificant depletion of glutathione. Multiple doses of BSO, at 12-hr intervals, resulted in further depletion to 27% (s.c.) and 16.5% (i.c.) of control 12 hr following the final dose of BSO. Quantitative analysis of BSO delivery to xenograft and contralateral brain tissue revealed transfer constants, K1, of 15.8-24.1 x 10(-3) and 2.4 x 10(-3) ml.g-1.min-1 for xenograft and "normal" brain respectively. This highly selective depletion of glutathione in neoplastic tissue versus surrounding non-neoplastic host tissue may have therapeutic implications for the rational use of chemotherapeutic and radiotherapeutic intervention.

Human tumor xenografts as model for drug testing

This paper reviews the history of xenografts, the endpoints commonly used to evaluate response and chemotherapeutic results obtained with serially maintained human tumor xenografts from different laboratories, and discusses the potential clinical relevance of the heterotransplant model for cancer chemotherapy. Specifically, an attempt is made to correlate the published xenograft data with the clinical data. Drug testing with different types of xenotransplanted tumors has shown that the response of xenografts obtained in immune-deficient animals is comparable to that in clinical practice. In addition, xenografts of a particular tumor type are able to identify agents of known clinical activity against that disease.

The localisation of radiolabelled murine monoclonal antibody 81C6 and its Fab fragment in human glioma xenografts in athymic mice

The localisation of the radioiodinated Fab fragment of monoclonal antibody (Mab) 81C6, reactive with a glioma-associated extracellular matrix antigen, was studied in athymic mice bearing subcutaneous and intracranial xenografts of D-54 MG glioma cells. In vitro 81C6 Fab showed a marked loss of immunoreactivity and affinity for antigen compared to intact Mab 81C6. In vivo, the plasma half-life of 81C6 Fab was 7.0 hours compared to 2.1 days for 81C6. 81C6 Fab levels in tumours peaked at 2.6-3.8% injected dose/g in 2-6 h; Mab 81C6 reached 33.9% dose/g at 48 h. Localisation indices and tumour:tissue ratios were superior for Mab 81C6. Estimated radiation doses to tumour and normal tissues were lower for 131I-81C6 Fab than 131I-81C6. To realise the theoretical benefits of fragments as localising agents, Fab fragments of higher immunoreactivity and affinity, or bivalent F(ab')2 fragments are required.

Comparative localization of glioma-reactive monoclonal antibodies in vivo in an athymic mouse human glioma xenograft model

Radioiodinated murine monoclonal antibodies (Mabs) 81C6, Me 1-14, C12, D12, and E9, made against or reactive with human gliomas but not normal brain, and Mab UJ13A, a pan-neuroectodermal Mab reactive with normal human glial and neural cells, were evaluated in paired label studies in the D-54 MG subcutaneous human glioma xenograft model system in nude mice. Following intravenous injection in the tail vein of mice bearing 200-400 mm3 tumors, specific localization of Mabs to tumor over time (6 h-9 days) was evaluated by tissue counting; each Mab demonstrated a unique localization profile. The comparison of localization indices (LI), determined as a ratio of tissue level of Mab to control immunoglobulin with simultaneous correction for blood levels of each, showed Mabs 81C6 and Me 1-14 to steadily accumulate in glioma xenografts, maintaining LI from 5-20 at 7-9 days after Mab injection. Mab UJ13A peaked at day 1, maintaining this level through day 2, and declining thereafter. Mabs D12 and C12 peaked at days 3 and 4, respectively, and E9 maintained an LI of greater than 3 from days 3-9. Percent injected dose localized/g of tumor varied from a peak high of 16% (81C6) to a low of 5% (Me 1-14 and UJ13A). Immunoperoxidase histochemistry, performed with each Mab on a battery of primary human brain neoplasms, revealed that Mabs 81C6 and E9, which demonstrated the highest levels of percent injected dose localized/g of tumor over time, reacted with antigens expressed in the extracellular matrix. This finding suggests that extracellular matrix localization of antigen represents a biologically significant factor affecting localization and/or binding in the xenograft model used. The demonstration of significant localization, varied kinetics and patterns of localization of this localizing Mab panel warrants their continued investigation as potential imaging and therapeutic agents for human trials.

The morphology and biologic behavior of human glioblastoma growing in nude mice

Seven human glioblastomas (five small cell glioblastomas [SCG] and two anaplastic astrocytomas with giant cells [AA]) grown in serial passage in BALB/c nude mice and nude rats, were studied histologically and compared to human donor tumors. Four SCG maintained many basic features seen in donor tissue, i.e., cell type, tendency to produce micronecrotic palisading (MNP), high cellularity, numerous mitoses. Significant vascular proliferation was seen only in nude rat hosts of one of the SCG lines transplanted from mice at passage 11. Giant capillaries, cyst formation and hemorrhages were features of large (1.0 cm) heterotransplanted SCG. One SCG altered morphology from first passage, showing an adenoid pattern and mucinous change. Both AA preserved original tissue characteristics in initial passages. Later dedifferentiation occurred with small cells predominating. These small cells were larger and rounder than those of the SCG. Large AA showed central necrosis but rarely MNP, hemorrhages and focal inflammatory infiltrates.

Antifibrinolytic therapy of experimentally grown malignant brain tumors

This study was designed to evaluate the effect of an inhibitor of plasminogen activation on the growth of a human glioblastoma line grown in nude mice up to the seventh passage. The tumors produced plasminogen activators and showed histological characteristics similar to those of the original tumor. Three groups of mice were studied. Group A received 5% epsilon aminocaproic acid (EACA); Group B received 2.5% EACA; and Group C served as a control. There was no statistical difference among the three groups with regard to: 1) age at time of tumor transplantation; 2) the interval between implant and treatment; or 3) tumor volume at time of treatment. Blood measurements of EACA, performed in a limited number of animals, have shown that the drug at 5% concentration had reached toxic levels. Statistically significant differences between the three groups were noted in the following categories: 1) rate of tumor growth; 2) tumor volume at time of death, where Group A had smaller tumors than Group C; and 3) mean survival times of Groups A and B as compared to Group C. A statistically significant negative correlation was found between the rate of tumor growth and the length of survival of animals in Group C, while no correlation could be found for either Group A or B, indicating that the antifibrinolytic therapy modified this important biological variable. This study supports the hypothesis that the fibrinolytic system plays a role in the growth and development of malignant gliomas and that interference with the fibrinolytic system may retard the growth of these tumors grown in nude mice.

In vivo imaging of intracranial human glioma xenografts comparing specific with nonspecific radiolabeled monoclonal antibodies

Current diagnostic and therapeutic modalities for malignant human gliomas are largely nonspecific. The development of monoclonal antibodies (MA's) with their high degree of specificity may allow precise tumor imaging and selective administration of therapeutic agents. However, the ability of these antibodies to specifically localize tumor tissue in vivo remains speculative. This study compares the localization and imaging properties of two MA's: a specific human glioma-associated extracellular matrix glycoprotein MA, 81C6, and a nonspecific control MA, 45.6, against a human glioma cell line, D-54 MG, intracranially inoculated into athymic rats. Forty-one animals received MA's labeled with iodine-131 (131I) or 125I and underwent imaging with a gamma camera. The images were independently evaluated and compared to tissue radioactivity levels. Radiolabeled antiglioma MA 81C6 specifically localized in intracranial xenografts. The percent of injected dose per gram of tissue for tumor was 1.707 +/- 0.405/gm for 81C6 and 0.118 +/- 0.056/gm for 45.6. All other organs had equivalent levels of specific and nonspecific MA's. For brain, these were 0.004 +/- 0.002/gm and 0.005 +/- 0.005/gm, respectively, and for the other organs, the range was from 0.053 to 0.284/gm. Statistically, 45.6 achieved levels in tumor that were significantly higher than normal brain (p less than 0.05) but significantly less than that achieved with 81C6 (p less than 0.005). With 81C6, the degree of localization was high enough to allow imaging of intracranial tumors at sizes as small as 20 mg. Intracranial tumors were imaged with 45.6 only when they achieved sizes greater than 300 mg. In this imaging study, radiolabeled 81C6, a specific antiglioma MA, proved to be significantly better for imaging small and intermediate-sized tumors than the control MA's. Large tumors were visualized by both MA's, although higher quality scans were obtained earlier and more frequently with specific MA's than with nonspecific immunoglobulin G. These data suggest that specific MA's have a role to play in both the diagnosis and treatment of primary intracranial human tumors.

Primary brain tumours in Fischer 344 rats chronically exposed to acrylonitrile in their drinking-water

Acrylonitrile (ACN) has been tested for carcinogenicity by various routes in a number of rat strains. At relatively high levels of administration (e.g. 500 ppm in the drinking-water) there were statistically significant increases in microscopically detectable primary brain tumours, which were difficult to classify. In a further study of ACN-induced brain tumours, ACN was administered to groups of 50 male and 50 female F-344 rats from 6 wk of age at levels of 0, 100 and 500 ppm in the drinking-water. A fourth group of 300 rats (147 males, 153 females), was also given 500 ppm ACN. Neurological signs were observed in 0, 4, 16 and 29, respectively, of the rats in these four groups within 12-18 months. Among the treated animals, females died slightly earlier than males. Few controls of either sex had died by month 18, but, apart from those killed for tumour donation, a high proportion of the rats in the 500-ppm groups had died by that time. Of the 49 brain tumours found in rats exposed to 500 ppm ACN, 11 were only detectable microscopically, 28 were 1-5 mm in diameter and 10 were greater than 5 mm. Despite this variation in size, all the tumours were similar in cellular and architectural features. They were densely cellular, with occasional areas of focal necrosis, and were infiltrative at the margins. They were negative for glial fibrillary acidic protein (GFAP). Ultrastructurally, the tumour cells showed intermingling cytoplasmic processes but no glial filaments and no neurosecretory granules or specialized cell contacts. Samples of tumour tissue were successfully grown in culture, but transplantation of samples from these cultures (observed for up to 12 wk) was unsuccessful. However, a direct intracerebral transplantation from a large tumour was successful.

A serially transplantable human giant cell glioblastoma that maintains a near-haploid stem line

We have karyotyped a human giant cell glioblastoma removed from an 11-year-old girl and have established from it a subcutaneously transplantable line in athymic nude mice. The original tumor contained near-haploid cells with 25 or 26 chromosomes, including two copies of #1, (7 or 7p+) and #18. There were also hyperdiploid (49-52) cells that were tetraploid for these same three chromosome types; doubled versions of the hyperdiploid population were also seen. The stemline of the mouse-grown tumor was 26,X, +1, +7p+, +18 in the first passage and has remained consistently near-haploid through ten serial in vivo passages. Growth stabilization has occurred with an average latency of less than 3 months. This transplantable line is available for evaluating chemotherapeutic responsiveness of human giant cell glioblastoma and for studying near-haploidy in solid human tumors.