Requirements for cell cycle arrest by p16INK4a.

Analysis of tumor-derived mutations has led to the suggestion that p16INK4a, cyclin D1, cdk4, and the retinoblastoma protein (pRB) are components of a regulatory pathway that is inactivated in most tumor cells. Cell cycle arrest induced by p16INK4a, an inhibitor of cyclin D-dependent kinases, requires pRB, and it has been proposed that this G1 arrest is mediated by pRB-E2F repressor complexes. By comparing the properties of primary mouse embryonic fibroblasts specifically lacking pRB-family members, we find that pRB is insufficient for a p16INK4a-induced arrest. In addition to pRB, a second function provided by either p107 or p130, two pRB-related proteins, is required for p16INK4a to block DNA synthesis. We infer that p16INK4a-induced arrest is not mediated exclusively by pRB, but depends on the nonredundant functions of at least two pRB-family members.

pRB and p107/p130 are required for the regulated expression of different sets of E2F responsive genes.

The activity of the E2F transcription factor is controlled by physical association with the retinoblastoma protein (pRB) and two related proteins, p107 and p130. The pRB family members are thought to control different aspects of E2F activity, but it has been unclear what the respective functions of these proteins might be. To dissect the specific functions of pRB, p107, and p130 we have investigated how the expression of E2F-regulated genes is changed in cultures of primary cells lacking each of these family members. Whereas no changes were found in the expression of E2F-target genes in cells lacking either p107 or p130, deregulated expression of E2F targets was seen in cells lacking pRB and in cells lacking both p107 and p130. Surprisingly, the genes that were disregulated in these two settings were completely different. These findings show that pRB and p107/p130 indeed provide different functions in E2F regulation and identify target genes that are dependent on pRB family proteins for their normal expression.

Gene therapy of metastatic cancer by in vivo retroviral gene targeting.

We have achieved efficient transduction of tumour metastases in vivo by the vascular delivery of retroviral producer cells. Experimental liver metastases in mice were created by intrasplenic injection of tumour cells into the portal venous circulation. Following the establishment of micrometastases, delivery of retroviral producer cells by the same route with a vector containing the Escherichia coli beta-galactosidase (lacZ) gene demonstrated selective in vivo gene transfer to tumour deposits. By this approach, two retroviral producer cell lines encoding cytokines (IL-4 and IL-2) directed tumoricidal inflammatory responses to established metastases. Cytokine gene targeting inhibited metastasis formation and caused significant overall reduction in tumour burden. These results suggest a novel therapeutic approach for the treatment of disseminated cancer.

Enhancement of interleukin-4-mediated tumor regression in athymic mice by in situ retroviral gene transfer.

Intratumoral grafting of genetically engineered cells that produce interleukin-4 (IL-4) has been shown to produce tumor regression as well as prolong survival of mice harboring intracerebral gliomas. We sought to determine whether retroviral-mediated gene delivery into tumor cells in situ resulted in enhanced tumor regression by IL-4. Two mouse fibroblast lines were obtained: they both secreted similar levels of IL-4 but one produced a retrovirus vector bearing the IL-4 gene (CRE-MFG-IL-4 cells), whereas the other did not (NIH3T3-IL-4 cells). In mixed transplantation assays in the subcutaneous flanks of athymic mice, CRE-MFG, IL-4 cells were more effective than NIH3T3-IL-4 cells in inhibiting the growth of rat C6 glioma cells (p < 0.005, ANOVA). Subcutaneous tumors injected with fibroblasts that produced a control retrovirus vector without producing IL-4 (CRE-MFG-LacZ cells) did not inhibit subcutaneous tumor growth. An intracranial assay was used to evaluate survival of athymic mice harboring intracranial gliomas. Three days after implanting rat C6 glioma cells into the right frontal lobes of athymic mice, NIH3T3-IL-4 cells (n = 10) or CRE-MFG-IL-4 cells (n = 10) were stereotactically inoculated into the tumor bed. The average survival of mice treated with CRE-MFG-IL-4 cells was 38 days (+/- 2.4, SE), whereas that of mice treated with NIH3T3-IL-4 cells was 31 days (+/- 0.8, SE) (p < 0.005, ANOVA; p < 0.001, log-rank analysis).(ABSTRACT TRUNCATED AT 250 WORDS)

Gene transfer into experimental brain tumors mediated by adenovirus, herpes simplex virus, and retrovirus vectors.

Three vectors derived from retrovirus, herpes simplex virus type 1 (HSV), and adenovirus were compared in cultured rat 9L gliosarcoma cells for gene transfer efficiency and in a 9L rat brain tumor model for histologic pattern and distribution of foreign gene delivery, as well as for associated tumor necrosis and inflammation. At a multiplicity of infection of 1, in vitro transfer of a foreign gene (lacZ from Escherichia coli) into cells was more efficient with either the replication-defective retrovirus vector or the replication-conditional thymidine kinase (TK)-deficient HSV vector than with the replication-defective adenovirus vector. In vivo, stereotactic injections of each vector into rat brain tumors revealed three main histopathologic findings: (i) retrovirus and HSV vector-mediated gene transfer was relatively selective for cells within the tumor, whereas adenovirus vector-mediated gene transfer occurred into several types of endogenous neural cells, as well as into cells within the tumor; (ii) gene transfer to multiple infiltrating tumor deposits without apparent gene transfer to intervening normal brain tissue occurred uniquely in one animal inoculated with the HSV vector, and (iii) extensive necrosis and selective inflammation in the tumor were evident with the HSV vector, whereas there was minimal evidence of tumor necrosis and inflammation with either the retrovirus or adenovirus vectors.

Type I human complement C2 deficiency. A 28-base pair gene deletion causes skipping of exon 6 during RNA splicing.

Two variants of a genetic deficiency of complement protein C2 (C2D) have been previously identified. No C2 protein translation is detected in type I deficiency, while type II deficiency is characterized by a selective block in C2 secretion. Type I C2 deficiency was described in a family in which the C2 null allele (C2Q0) is associated with the major histocompatibility haplotype/complotype HLA-A25,B18,C2Q0,BfS,C4A4, C4B2,Drw2; this extended haplotype occurs in over 90% of C2-deficient individuals (common complotype/haplotype). To determine the molecular basis of type I C2 deficiency, the C2 gene and cDNA were characterized from a homozygous type I C2-deficient individual with the common associated haplotype/complotype. We found a 28-base pair deletion in the type I C2Q0 gene, beginning 9 base pairs upstream of the 3'-end of exon 6, that generates a C2 transcript with a complete deletion of exon 6 (134 base pair) and a premature termination codon. In studies of eight kindred, the 28-base pair deletion was observed in all C2Q0 alleles associated with the common type I deficient complotype/haplotype; this deletion was not present in normal C2 nor in type II C2-deficient genes. These data demonstrate that: 1) type I human complement C2 deficiency is caused by a 28-base pair genomic deletion that causes skipping of exon 6 during RNA splicing, resulting in generation of a premature termination codon, 2) the 28-base pair deletion in the type I C2Q0 gene is strongly associated with the HLA haplotype/complotype A25,B18,C2Q0,BfS,C4A4,C4B2,Drw2, suggesting that all C2-deficient individuals with this haplotype/complotype will harbor the 28-base pair C2 gene deletion, and 3) type II C2 deficiency is caused by a different, as yet uncharacterized, molecular genetic defect.