APM-1, a novel human gene, identified by aberrant co-transcription with papillomavirus oncogenes in a cervical carcinoma cell line, encodes a BTB/POZ-zinc finger protein with growth inhibitory activity.

Integration of human papillomavirus (HPV) DNA into the host cell genome is an important step in cervical carcinogenesis. In tumour cells with integrated HPV DNA, transcription of viral oncogenes E6 and E7 continues into the flanking cellular sequences thereby producing viral-cellular fusion transcripts. Analysis of cellular sequences flanking the integrated HPV68 DNA in the cervical carcinoma cell line ME180 revealed homozygosity of the mutant allele in ME180 cells. We speculated that this could indicate the existence of a cellular tumour suppressor gene in the integration region. We report here the identification of a novel human gene, named APM-1, which is co-transcribed with the HPV68 E6 and E7 genes and is present in the 3'-cellular part of the ME180 viral-cellular fusion transcripts. The APM-1 gene encodes a protein with a BTB/POZ domain and four zinc fingers, and is located at chromosome 18q21. APM-1 transcripts are detected in normal cervical keratinocytes, but not in the majority of cervical carcinoma cell lines analysed. The APM-1 gene caused a reduction of clonal cell growth in vitro of HeLa and CaSki tumour cells. These characteristics make APM-1, the first novel human gene identified in a HPV integration region, a likely candidate for the postulated tumour suppressor gene.

A novel nuclear inhibitor I-92 regulates DNA binding activity of octamer binding protein p92 during the cell cycle.

Nuclear DNA binding protein p92 is a sequence specific octamer binding protein with identical molecular weight as the ubiquitous octamer binding protein Oct-1. It binds to octamer related sequences from the enhancer of human papillomavirus type 18. The activity and intracellular distribution of p92 is regulated by extracellular signals. In serum starved Hela-fibroblast hybrid cells p92 is localized to the cytosol. Serum stimulation leads to nuclear import of p92. In fractions of asynchronously growing cells, which were separated according to cell cycle phases into G1, S, and G2 populations by centrifugal elutriation, p92 DNA binding is confined to S phase. In binding site blots however, p92 DNA binding activity is also present in G1 and G2. In G1 and G2 DNA binding activity of p92 is masked by a novel nuclear inhibitor I-92. The cyclic association of p92 with its inhibitor I-92 provides a new mechanism of regulating S phase dependent activity of a sequence specific DNA binding protein.

Delineation of human papillomavirus type 18 enhancer binding proteins: the intracellular distribution of a novel octamer binding protein p92 is cell cycle regulated.

The enhancer of human papillomavirus type 18 consists of two functionally redundant domains, one is partially conserved between HPV18 and HPV16, both mediate strong transcriptional enhancement. In contrast, short fragments of the enhancer mediate low transcriptional enhancement, suggesting that there is functional cooperation between HPV enhancer binding factors. Previously interactions of the enhancer with NF-1, AP1 and steroid receptors were shown by EMSA. Here we show by binding site blotting, that four novel sequence specific proteins p110, p92, p42 and p40 bind to the enhancer. Nuclear proteins p110 and p92 bind at repeated sites in the enhancer, proteins p42 and p40 only at one site. Recognition sequences for p110 and p92 were identified in a TTGCTTGCATAA sequence motif and consist of an overlapping p110 and p92 recognition site. The specific interaction of p110 with G residues of this 12 nucleotide long sequence was demonstrated by a mutant recognition site. Single recognition sites for p42 and p40 were localized in the enhancer by the use of overlapping oligonucleotides. In addition, electrophoretic mobility shift analysis identified Oct-1 and AP2 interactions with the enhancer. The AP2 binding site was mapped to a AGGCACATATT motif. The p92 protein binds to enhancer oligonucleotides, containing at least one copy of Oct-1 like recognition sequences, these oligonucleotides also bind synthetic Oct-1 protein. During serum starvation or at high saturation density, p92 moves from the nucleus into the cytoplasm. Immunoblots of cytoplasmic extracts with anti-Oct-1 antisera showed, that p92 is a novel octamer binding factor, which is not immunologically related to the Oct-1 protein. The intracellular p92 distribution is regulated at the G0/G1 boundary of the cell cycle, by nucleo-cytoplasmic translocation.

Depressed PPD and tetanus toxoid presentation by monocytes to T lymphocytes in patients with rheumatoid arthritis: restoration by interferon gamma.

A diminished antigen presentation of blood monocytes to autologous T cells has been recently described in patients with rheumatoid arthritis (RA). In this study the defective presentation of common recall antigens by blood monocytes revealed it to be a monocyte dysfunction specific for RA which could not be found in other chronic inflammatory rheumatic or non-rheumatic diseases and which could be restored by recombinant human interferon gamma. In addition, RA monocytes in blood exhibited a strongly reduced expression of HLA-DR determinants on the cell surface. T cells from RA patients produced almost normal interleukin-2 (IL-2) levels and showed a normal IL-2 sensitivity after phytohemagglutinin (PHA) stimulation. Several reasons may be responsible for this altered monocyte function in RA. Among these an in vivo "preactivation" of monocytes associated with a reduced antigen-presenting capacity or an impaired regulation of monocyte/macrophage differentiation are discussed.

Reduced production of interferon alpha and interferon gamma in leukocyte cultures from patients with active rheumatoid arthritis.

Tests for lymphoproliferation and interferon induction in normal blood donors and patients with rheumatoid arthritis (RA) were performed in a whole-blood assay. Patients with high inflammatory RA showed significantly reduced lymphoproliferation and interferon gamma production after stimulation with phytohemagglutinin (PHA) and concanavalin A (Con A) when compared with patients with low inflammatory activity, or with normal control individuals. Similarly, patients with high and low inflammatory RA exhibited a significantly reduced interferon alpha production after stimulation with Newcastle Disease Virus (NDV) when compared with normal blood donors. Our findings may point to an important immunodeficiency of the circulating lymphocytes of RA patients and may explain some of the in vitro immunoregulatory abnormalities reported in this disease.