Polymorphism at codon 72 of p53 is not associated with cervical cancer risk.

P53 allelic polymorphism at codon 72 has been studied as a possible predisposing factor for cervical carcinogenesis with inconsistent results. Storey and colleagues recently published the interesting finding of a 7-fold increased risk for cervical cancer in women homozygous for the arginine allele at codon 72. This stimulated a number of independent investigations, the majority of which found no association of cervical cancer and arginine homozygosity. With the use of a modified Storey method for determining codon 72 allelotypes, DNA was examined from 431 microdissected, formalin-fixed, archival cervical conization specimens ranging from low-grade squamous lesions to invasive cancer. An alternative independent method using restriction fragment length polymorphism analysis was performed on all arginine homozygotes and all indeterminate cases for confirmation and final allelotype assignment. With the use of Storey's method alone, logistic regression suggested an association (odds ratio, 1.42) between arginine homozygosity and invasive disease. However, with the use of the combined method for accurate allelotyping, this trend disappeared (odds ratio, 1.00), the discordance was clearly resolvable as being due to methodologic variables. With the use of two separate methods for codon 72 allelotyping and accounting for a number of the issues raised in previously published reports, there is no increased risk for invasive cervical cancer associated with arginine homozygosity at codon 72 of p53.

Human papillomavirus and Epstein-Barr virus in sinonasal Schneiderian papillomas. An in situ hybridization and polymerase chain reaction study.

Using the polymerase chain reaction (PCR), it has been recently reported that the Epstein-Barr virus (EBV) is present in the majority of Schneiderian sinonasal papillomas (SNP) of the inverted type and may play a role in the pathogenesis of these lesions. The reported prevalence rates of human papillomavirus (HPV) in different types of SNP is also controversial and in need of clarification. Twenty-eight SNP from 27 patients were histologically classified and evaluated for evidence of EBV using PCR and 2 different sensitive and specific in situ hybridization (ISH) procedures for EBER1. Similarly, two methods of ISH were also used for the detection of HPV, using biotinylated DNA probes sensitive for 14 different HPV types as well as more sensitive and specific radioactive RNA probes for HPV types 6, 11, and 16. Polymerase chain reaction was successful in 19 papillomas, including 12 of 19 inverted SNP, 1 of 1 inverted SNP with squamous cell carcinoma, 4 of 5 fungiform SNP, and 2 of 3 oncocytic lesions. Southern blot hybridization of PCR products showed the presence of EBV DNA in two lesions, including one inverted SNP and the single inverted SNP with squamous cell carcinoma. By both DNA- and RNA-mRNA ISH, positivity for EBER was detected in rare stomal lymphocytes but not the overlying epithelium in the inverted SNP with SCC. The remaining cases, including the other inverted SNP positive for EBV by PCR, were completely negative by both ISH techniques. Human papillomavirus was detected by ISH in 1 of 19 (5%) inverted, 1 of 1 (100%) inverted with squamous cancer, 5 of 5 (100%) fungiform, and 0 of 3 (0%) oncocytic SNP. Three SNP contained HPV 6 (all fungiform), three SNP labeled for HPV 11 (two fungiform and the inverted SNP with squamous cancer), and one inverted SNP contained HPV 16. Of the five fungiform SNP, four showed foci of koilocytosis. The results indicate that EBV is not present in sinonasal papillomas. The presence of EBV positive stromal lymphocytes in these lesions may account for a proportion of PCR-positive cases. Oncocytic SNP are unassociated with HPV, whereas inverted SNP contain HPV in a minority of cases. In contrast, fungiform SNP are consistently associated with HPV types 6 and 11 and usually show histologic evidence of viral infection.

Further studies on growth factor production by the TC-1 stromal cell line: pre-B stimulating activity.

Adherent murine stromal cells support long-term in vitro lymphopoiesis or myelopoiesis dependent on the culture conditions used. A cell line, TC-1, isolated from long-term liquid murine marrow cultures under conditions approaching those permissive for lymphoid growth, has been found to produce an activity that acts synergistically with interleukin-3 (IL-3) or colony-stimulating factor-1 (CSF-1) to stimulate in vitro myeloid colonies, but which has no intrinsic colony-stimulating activity. We report here the presence of multiple growth factors in conditioned medium (CM) from the TC-1 line, including granulocyte-macrophage colony-stimulating factor (GM-CSF) (bioassay with antibody blocking and messenger RNA [mRNA] analysis), granulocyte CSF (G-CSF) and IL-4 (factor-dependent cell line bioassay), and CSF-1 (radioimmunoassay, mRNA) along with a pre-B cell inducing activity, which appears separate from these CSFs and segregates with the myeloid synergizing activity through anion exchange, sizing, and Conconavalin A chromatography. Because these activities are not yet purified to homogeneity, their identity or lack of identity remains an open question. Assays of TC-1 CM or cellular mRNA analysis have given negative results for IL-1, IL-2, IL-3, IL-6, and IL-7, and IL-6 does not stimulate pre-B cells in this assay. However, IL-4 and G-CSF do stimulate in vitro induction of pre-B cells from pre-B and B-cell-depleted Balb/C marrow and are present in CM by selective cell line assay. A monoclonal antibody to IL-4 that inhibited its pre-B inducing activity did not inhibit pre-B inducing activity of TC-1 CM. These data suggest the existence of a unique synergizing and pre-B inducing factor(s) in TC-1 CM. Given the known capacity of subliminal levels of growth factors to act synergistically, an alternate possibility is that these biologic phenomena represent the actions of low concentrations of growth factors acting synergistically and possibly associated with some core protein.

Stromal cell regulation of lymphoid and myeloid differentiation.

In vitro microenvironmental influences seem to be critical for both B lymphocyte and myeloid differentiation. Studies on murine Dexter cultures and Whitlock-Witte lymphocyte cultures suggest the presence of two critical stromal regulatory cells: an alkaline-phosphatase-positive epithelioid cell and a macrophage. Further data suggest that these cells are capable of producing colony stimulating factor-1, granulocyte-macrophage CSF, a myeloid synergizing activity, and probably separate B cell growth factors. Isolation of a cell line from Dexter stroma was accomplished and this line produced CSF-1, GM-CSF, a pre-B cell and myeloid synergizing activity, and an activity acting on differentiated B cells. We speculate that the Dexter and Whitlock-Witte in vitro culture systems are regulated by factors produced by the two adherent cell types. A lineage nonspecific factor capable of inducing cells into the B lineage or synergizing with interleukin-3, GM-CSF, and CSF-1 is produced, which presumably acts on early stem cells. In addition, the cell line produces GM-CSF, CSF-1, and a factor acting on differentiated B cells. We speculate that in these culture systems, these "terminal differentiating hormones" regulate the final pathway of differentiation, whereas the pre-B-synergizing activity supports early stem cells that can then respond to the other differentiating hormones.