A large variety of human tumours manifest a heterozygous or homozygous deletion in the 9p21 chromosome region. The list includes malignant melanoma, glioma, lung, bladder, pancreatic and renal cancers (Kamb et al, 1994;Nobori et al, 1994), as well as gynaecological tumours (reviewed by Wong et al, 1997). Two putative tumour suppressor genes have been identified in this region: p16 (also known as p16 INK4A , cyclin-dependent kinase 4 inhibitor, CDK4I, CDKN2, and MTS1), and p15 (p15 INK4B ).The p16 gene makes two different proteins, p16 and p19 ARF (p19 alternative reading frame), using different overlapping reading frames, starting with different first exons. The p16 protein uses exon 1α, and p19 ARF uses exon 1β; these two exons are alternatively spliced to the same second and third exons. The p16 and p15 proteins belong to a family of negative regulators of the cell cycle. Specific binding of p16 protein to the CDK4 or CDK6 cyclindependent protein kinases inhibits the phosphorylation activity of CDK-cyclin D complexes towards the nuclear RB/E2F protein complex (Serrano et al, 1993). p16 normally prevents phosphorylation of RB, resulting in RB's retention of E2F. Failure to release E2F at the late G1 checkpoint blocks the cell from entering the S phase (Hengstschläger et al, 1996;Lukas et al, 1996). The p19 ARF protein, although it has an unrelated amino acid sequence, has cell cycle arresting functions. It is the p16 protein that now appears to be the major target of mutations and deletions at the 9p21 loci.The p15 (MTS2) putative tumour suppressor gene is located 25 kb centromeric of the p16 gene on 9p. p15 contains sequences highly homologous to exon 2 of p16 and, like p16, inhibits both CDK4 and CDK6 kinase activities (Guan et al, 1994;Hannon and Beach, 1994). Homozygous deletions of p15 and hypermethylation-associated loss of p15 expression have been reported in glioblastomas (Jen et al, 1994).The p16/p19 ARF and p15 genes appear to play variably important roles in human tumorigenesis, with critical tissue specificities and uncertain implications for clinical prognoses. Little is currently known about the potential role of these genes in reproductive tract biology, and specifically in uterine tumours. We have begun to examine the expression of the p16 gene at the level of mRNA and protein, the methylation status of the 5′-CpG island of p16 exon 1α, and for p16 point mutations and homozygous deletions in these tumours. We have also analysed the p15 gene for mutations and homozygous deletions. We report that the inactivation of the p16 gene, either by homozygous gene deletion, mutation or loss of protein expression, occurs in a small but significant subset of these uterine tumours. Summary The roles of the p16 and p15 inhibitor of cyclin-dependent kinase tumour suppressor genes were examined in human uterine cervical and endometrial cancers. p16 mRNA, examined by reverse transcription polymerase chain reaction (RT-PCR), was significantly reduced in five of 19 (26%) cervical and four of 25 (16%) endometrial tu...
