Molecular resolution of cell adhesion forces.

Recently, AFM-based force spectroscopy has been used to quantify single-molecule adhesion forces on living ameboid cells. Force spectroscopy was used to measure the rupture forces of single receptor-ligand bonds which can occur rapidly between the cell types used, a metastasising B16 melanoma cell and a vascular bEnd.3 endothelial cell. Parameters which influence the critical experimental conditions are discussed to discriminate between multiple bond ruptures and single bonds. Under physiological conditions of temperature and pH the force measurements show an average rupture force of 33 pN (SD = 12 pN) for single bonds. Single-molecule force spectroscopy will be very useful to study the regulation of cell adhesion on a molecular level in normal processes, such as leukocyte homing, and in major human disorders, including tumor metastasis, autoimmune diseases and atherosclerosis.

Activity of the DNA repair protein O6-methylguanine-DNA methyltransferase in human tumor and corresponding normal tissue.

The DNA repair protein O6-methylguanine-DNA methyltransferase (MGMT) is a main determinant of resistance of cells towards the cytostatic effect of N-nitrosoureas. Here we report the activity of MGMT in different types of human tumors. Colorectal tumors showed the highest mean of MGMT activity (481 +/- 258 fmol/mg protein) followed by ovarian tumors (437 +/- 291 fmol/mg), breast (306 +/- 204 fmol/mg), testicular (299 +/- 179 fmol/mg), and brain tumors (55 +/- 44 fmol/mg). Only in breast and brain tumors were MGMT-deficient samples found, with a frequency of 3 and 5%, respectively. No significant difference in mean MGMT activity was observed between breast tumors of grading I, II, and III. For brain tumors there was a tendency of MGMT to decline with increasing grading. Breast and colorectal carcinomas were compared with the corresponding normal tissue obtained from the same patient. The data showed for 11 out of 12 pairs of breast tissue and for 13 out of 15 pairs of colorectal tissue that MGMT activity in the tumor was equal to or, more frequently, higher than the activity found in the corresponding normal tissue. Thus, it appears that in these groups of tumors, increase of MGMT activity during tumor formation and progression is the rule rather than the exception.

Expression of variant CD44 epitopes in human astrocytic brain tumors.

Expression of CD44 and of specific splice-variants of CD44 has been causally related to metastatic behaviour in a variety of carcinomas and lymphomas. To elucidate whether, in principle, similar splice-variants could be involved in glioma cell invasion we examined the expression of CD44 and its splice-variants in a series of 38 primary human brain tumors (28 astrocytomas, WHO grade I-III and 10 glioblastomas, WHO grade IV) and in cell lines derived from 9 glioblastomas. All brain tumors examined showed strong immunoreactivity for an N-terminal epitope present on all CD44 isoforms known. Using a polyclonal antiserum raised against the complete sequence encoded by variant exons v3 to v10, CD44 splice-variants could be detected irrespective of the grade of malignancy in many of the tumor samples at a low level and often restricted to only a few clustered tumor cells. Thus, the N-terminal epitope probably indicates the presence of the smallest and most ubiquitous isoform CD44s. Interestingly, all glioblastomas expressed CD44 variants whereas expression in astrocytomas WHO grade I, II, and III could only be detected in about half of the tumor samples. Using reverse transcriptase-PCR we were able to detect different CD44 splice-variants in the glioblastoma cell lines and in cultured primary astrocytic cells. Glioblastoma cells analyzed by flow cytometry showed the expected binding capacity for hyaluronic acid which could be increased twofold after pretreatment with hyaluronidase. The results presented show that there is low expression of CD44 variants in human tumors of astrocytic origin. Expression of CD44 and its splice-variants could contribute to the migration capacity of neoplastic astrocytes, and may be considered as a target for new diagnostic and therapeutic approaches in the clinical management of brain tumors.

O6-methylguanine-DNA methyltransferase activity in breast and brain tumors.

The DNA repair protein O6-methylguanine-DNA methyltransferase (MGMT) is a main determinant of resistance of tumor cells to the cytostatic activity of chemotherapeutic alkylating agents (methylating and chloroethylating nitrosoureas) and is effective in protecting normal cells against genotoxic and carcinogenic effects resulting from DNA alkylation. Therefore, the level of expression of MGMT is significance for the response of both the tumor and the non-target tissue following application of nitrosoureas in tumor therapy. To determine the expression of MGMT in tumor tissue, we have assayed MGMT activity in 68 breast carcinomas and 38 brain tumors. There was a wide variation of MGMT expression in breast carcinomas ranging from below the level of detection up to 863 fmol/mg protein. About 4% of breast tumors did not display detectable MGMT, 15% had activity lower than 100 fmol/mg protein, and 26% expressed more than 500 fmol/mg. The mean level of expression was 321 fmol/mg. In brain tumors (astrocytoma WHO grade I, II, and III, and glioblastoma WHO grade IV) the MGMT activity was generally lower than in breast tumors, ranging from below the level of detection up to 238 fmol/mg. The mean level of expression was 55 fmol/mg. Five percent of the brain tumors had no detectable MGMT activity. The MGMT repair activity correlated well with the amount of MGMT protein present in tumor samples, as shown by Western-blot analysis, indicating that loss of MGMT repair activity is due to inability of these tumor cells to synthesize the protein.

A model for primitive neuroectodermal tumors in transgenic neural transplants harboring the SV40 large T antigen.

Using retrovirus-mediated transfer of the SV40 virus large T antigen into neural transplants, we have observed a high incidence of primitive neuroectodermal tumors (PNET). These neoplasms developed in 8 of 14 (57%) neural grafts after latency periods of 176 to 311 days. Histopathologically, the tumors exhibited features of human PNET such as formation of neuroblastic rosettes and immunocytochemical evidence for neuronal differentiation, synaptogenesis, and focal astrocytic differentiation. All neoplasms showed a striking migratory potential. The presence of the large T gene in the tumors was demonstrated by polymerase chain reaction-mediated amplification of a specific 242 bp segment of large T and DNA sequence analysis. Large T antigen was identified in tissue sections using an immunocytochemical reaction with the monoclonal antibody Pab 108. Cell lines were established from several tumors and subjected to G418 selection. Secondary tumors induced by intracerebral transplantation of these cells retained the characteristic morphological and immunocytochemical properties of PNETs. These experiments demonstrate a considerable transforming potential of SV40 large T antigen for neural precursor cells. The long latency period suggests that neoplastic transformation initiated by the large T gene requires additional spontaneous mutations of cooperating cellular genes. Because the mechanism of transformation by large T antigen appears to involve complex formation with and inactivation of cellular tumor suppressor gene products, these cell lines may serve as an interesting tool to search for novel neural tumor suppressor genes.

Tumor induction by ras and myc oncogenes in fetal and neonatal brain: modulating effects of developmental stage and retroviral dose.

Introduction into fetal rat brain cells of a replication-defective retroviral vector harboring v-Ha-ras and v-gag-myc rapidly causes the induction of highly malignant undifferentiated neuroectodermal tumors following transplantation into the brains of syngeneic hosts [Wiestler, et al. (1992) Cancer Res. 52: 3760-3767]. In the present study, we have investigated the modulating effect of the developmental stage of neural target cells and of the dose of the retroviral vector used in the grafting experiments. Exposure of fetal cells from embryonic day (E)12 or E14 produced a 100% incidence of malignant neuroectodermal tumors which led to the death of recipient animals after a median latency period of 32 days. A 100-fold reduction of the virus dose from 2.062 x 10(6) to 2.062 x 10(4) focus-forming units/ml resulted in a lower tumor incidence of 25%. Of six neural grafts exposed to v-Ha-ras and v-myc at E16, only one showed evidence of tumorigenesis (low-grade astrocytoma and hemangioma). All other transplants were morphologically normal for observation periods of 26 weeks, indicating a marked loss of transforming activity of ras and myc in more advanced stages of brain development. In retrovirus-exposed donor cells which caused the development of neural tumors in recipient rats, malignant transformation was also evident during culture in vitro, usually after 9-12 days. Oncogene complementation was also studied in the newborn rat brain. After microinjection of the retroviral vector into the brain at postnatal day (P)0, P1 and P3, 5 out of 20 animals (25%) developed a total of seven brain tumors. Histopathologically, three of these neoplasms were malignant neuroectodermal tumors which, in contrast to those induced in fetal brain transplants showed evidence of focal glial and/or neuronal differentiation. In addition, we observed one oligodendroglioma, two hemangiomas and a malignant hemangioendothelioma. These data indicate that neural precursor cells and endothelia of the rat brain represent the major target cells for the complementary action of ras and myc and that the use of target cells from later developmental stages (E16 and postnatal) leads to the induction of both primitive and more differentiated neoplasms.

Mutations of the p53 tumor suppressor gene in neoplasms of the human nervous system.

A variety of neoplasms of the human nervous system were analyzed for the presence of mutations in the p53 tumor suppressor gene. DNA was extracted from frozen or formalin-fixed, paraffin-embedded material. Single-strand conformation polymorphism (SSCP) analysis for exons 5-8 was followed by direct DNA sequencing. Mutations leading to an amino acid change were found in three of 11 (27%) low-grade (World Health Organization (WHO) Grade II) astrocytomas. They were located in codon 183 (TCA-->TGA) of exon 5, codon 237 (ATG-->ATA) of exon 7, and codon 273 (CGT-->CAT) of exon 8. In one of these cases, the sequence indicated loss of the wild-type allele. Of 12 juvenile pilocytic astrocytomas (WHO Grade I), none contained a p53 mutation, suggesting a different molecular basis for this childhood neoplasm. Except for a mutation in one of seven (14%) meningeal hemangiopericytomas (codon 238; TGT-->TTT, Cys-->Phe), no mutations were observed in exons 5-8 of the p53 gene in any of the following tumors of the nervous system and its coverings: 13 schwannomas, 12 central neurocytomas, 22 meningiomas, 10 choroid plexus papillomas and carcinomas, and 30 neuroblastomas of the sympathetic nervous system. These and published data support the view that p53 mutations are frequently involved both in low-grade and progressive (anaplastic) astrocytomas, including glioblastomas multiforme. Oligodendrogliomas, medulloblastomas, meningiomas, and hemangiopericytomas rarely (< 15%) show p53 mutations in exons 5-8, whereas none of the remaining nervous system neoplasms revealed evidence of an involvement of the p53 gene in their development.

Comparative study of p53 gene and protein alterations in human astrocytic tumors.

The p53 gene is a tumor suppressor gene involved in many common malignancies, including astrocytomas. Genetic analysis of the p53 gene and immunohistochemistry of the p53 protein have each been used to screen astrocytomas. To compare these methods, we performed immunohistochemistry with the monoclonal antibody PAb 1801 and single-strand conformational polymorphism (SSCP) with sequence analysis on 34 astrocytic tumors (WHO grades II, III and IV). Seven cases had detectable p53 protein and gene mutations, while twelve cases had neither detectable protein nor gene mutations. Four tumors had frameshift mutations in the p53 gene that were not revealed by immunohistochemistry. One tumor had a genetic polymorphism and no detectable p53 protein. Ten tumors had p53 protein accumulation but no mutations by SSCP; these cases may represent p53 mutations outside of the conserved exons or elevated levels of wild-type p53 protein. Thus, some p53 mutations are missed with PAb 1801 immunohistochemistry alone. p53 immunohistochemistry, however, may reveal p53 accumulation independent of mutations in the conserved portions of the gene. Finally, we suggest that glioblastomas with p53 mutations in the conserved region of the gene may be a subset that are more common in women and in younger patients.

A new approach to the molecular basis of neoplastic transformation in the brain.

Gene transfer into living organisms has evolved as a powerful approach to study in vivo effects of specific genes and to devise animal models of hereditary disorders. We have been particularly interested in an approach to introducing transforming genes into the nervous system. Since specific promoter sequences for targeting the expression of a transgene to many cell types of the brain are not yet isolated, a suitable transgenic mouse model was not available for these experiments. This has prompted us to develop an alternative strategy for gene transfer into the brain. The rationale is to introduce foreign genes into fetal brain transplants using embryonic CNS as donor tissue and replication-defective retroviral vectors as genetic vehicles. This technique relies on the extraordinary organotypic differentiation capacity of neural grafts and the expression of retrovirally transmitted genes in different cell types of CNS transplants. In contrast to transgenic animals but analogous to sporadic tumour formation, target cells for the retroviral vector will develop in an environment of unmodified neural tissue. We have introduced a number of neurotropic oncogenes into fetal brain transplants to study potential effects of such genes on the brain. This review will summarize some of the findings which have emerged from this experimental study including the tropism of several genes for endothelial cells, attempts to identify cooperating combinations of transforming genes and an experimental model for primitive neuroectodermal tumours in neural grafts.

p53 mutations are associated with 17p allelic loss in grade II and grade III astrocytoma.

Loss of genetic material on the short arm of chromosome 17 is observed in approximately 40% of human astrocytomas (WHO grades II and III) and in approximately 30% of cases of glioblastoma multiforme (WHO grade IV). Previous studies of glioblastoma multiforme have shown that the p53 gene, located on the short arm of chromosome 17, is frequently mutated in these glioblastomas. To explore whether lower-grade astrocytomas are also associated with corresponding mutations of the p53 gene, we have investigated a series of 22 human astrocytomas of WHO grades II and III both for loss of heterozygosity on chromosome 17p and for p53 mutations. Mutations in the conserved regions of the p53 gene were identified by single strand conformation polymorphism analysis of exons 5, 6, 7, and 8 and were verified by direct DNA sequencing of the polymerase chain reaction products. p53 mutations were observed in 3 of 8 grade II astrocytomas and 4 of 14 grade II astrocytomas. In all 22 tumors, allelic loss of the short arm of chromosome 17 was investigated by restriction fragment length polymorphism analysis. One-half of the grade II astrocytomas (4 of 8) and grade III astrocytomas (7 of 14) exhibited allelic loss on chromosome 17p. Mutations in the p53 gene were exclusively observed in tumors with allelic loss on 17p. Our results show that p53 mutations are not restricted to glioblastoma multiforme and may be important in the tumorigenesis of lower-grade astrocytomas and that p53 mutations in lower-grade astrocytomas are associated with loss of chromosome 17p. These findings are consistent with a recessive mechanism of action of p53 in WHO grade II and III astrocytoma tumorigenesis.

Retrovirus-mediated oncogene transfer into neural transplants.

A gene transfer model was developed which allows for the identification of transformation pathways in the developing nervous system. Transforming genes were introduced into fetal brain transplants using embryonic CNS as donor tissue and replication-defective retroviral vectors as genetic vehicles. This technique relies on the extraordinary organotypic differentiation capacity of neural grafts and the expression of retrovirally transmitted genes in various cell types of CNS transplants. In contrast to transgenic animals but analogous to sporadic tumor formation, target cells for the retroviral vector develop in an environment of unmodified neural tissue. We have introduced a number of neurotropic oncogenes into fetal brain transplants including genes with an associated tyrosine kinase activity (polyoma medium T, v-src), a novel member of the fibroblast growth factor (fgf) gene family and the SV40 large T antigen. These experiments have demonstrated a significant transformation potential of oncogenes in specific target cells of the brain, provided evidence for a dominant complementary transforming effect of simultaneously expressed ras and myc genes in neural precursor cells and have yielded intriguing model systems for human CNS neoplasms such as the cerebellar medulloblastoma. This review describes the transplantation model, demonstrates several striking phenotypes induced by oncogene expression in neural grafts and elaborates on future prospects of this experimental approach.

p53 mutations in nonastrocytic human brain tumors.

Genomic DNA from 51 primary human brain tumors was screened for the presence of mutations in the tumor suppressor gene, p53, using the polymerase chain reaction and single strand conformation polymorphism analysis, followed by direct DNA sequencing. Mutations leading to an amino acid change were found in 2 of 17 (12%) oligodendrogliomas and 2 of 19 (11%) medulloblastomas but none of 15 ependymomas. Sites of mutations were in exon 5 (codon 141), exon 6 (codon 193 and 213), and exon 7 (codon 246). In addition, there were silent mutations in exon 6 (codon 213) in one oligodendroglioma and in one ependymoma. This study points to the possible role of the p53 tumor suppressor gene in some central nervous system neoplasms of divergent histogenesis.