Levels of proteolytic activities as intermediate marker endpoints in oral carcinogenesis.

It is essential to identify intermediate marker endpoints of carcinogenesis for the evaluation of the effectiveness of cancer-chemopreventive agents. We have observed that levels of proteolytic activities (as detected by 4 different substrates) are increased 2-3-fold (P < 0.003) in oral buccal mucosa cells of smokers and patients with oral leukoplakia or erythroplakia as compared to a nonsmoking comparison group. In addition, proteolytic activity levels in the buccal cells were increased nearly 3-fold in patients with oral trauma (P < 0.01) or diabetes (P < 0.02), as well as pregnant women (P < 0.04). Excluding these subgroups of patients in epidemiological studies increase the differences in levels of proteolytic activities between both the nonsmoking comparison group and smokers and between the comparison group and patients with oral leukoplakia or erythroplakia. Evaluation of prerandomization levels of proteolytic activities of patients in cancer chemoprevention trials will increase the statistical power by allowing stratified randomization based on levels of proteolytic activities. The observed increases in levels of proteolytic activities in tissues at higher than normal risk of cancer development suggest that levels of proteolytic activities should be used as immediate marker endpoints in human cancer prevention trials using protease inhibitors as potential anticarcinogenic agents.

Monoclonal antibodies differentially reactive with native and reductively modified Bowman-Birk protease inhibitor.

Bowman-Birk protease inhibitor (BBI) is a potent anticarcinogen that suppresses malignant transformation at nanomolar concentrations. Small amounts of BBI in its native form can be measured by immunoassay using specific monoclonal antibodies (MAbs); however, the MAbs currently available are not capable of detecting BBI metabolites in human body fluids. To develop new reagents for the study of BBI exposure and pharmacokinetics, we produced four MAbs, designated 3B6, 3E3, 4H8 and 5G2, from hybridomas derived from a mouse immunized with reductively modified BBI. The epitopes recognized by the four MAbs were characterized using BBI in its native form or modified by different methods. MAb 3B6 reacted with native BBI. Partial reduction of BBI with 720 Gy of gamma radiation in an oxygen-free solution of 100 mM formate increased the reactivity of BBI with 3B6; however, extensive reduction of BBI with 100 mM DL-dithiothreitol (DTT) completely abolished this antigenic reactivity. In contrast, the other three MAbs reacted with BBI molecules that had been reduced either with 720 Gy of radiation in formate solution or with DTT. Alkylation of the radiochemically reduced BBI with N-ethylmaleimide further increased the reactivity of BBI with 3E3, 4H8 and 5G2, possibly by preventing the formation of new disulfide bonds within the BBI molecules. The binding of 4H8 and 5G2 to BBI antigen was inhibited by the binding of 3E3, and vice versa. Thus, the epitopes recognized by 3E3, 4H8 and 5G2 are probably located close to one another on the reduced BBI molecules. These three MAbs were able to react with BBI metabolites in urine samples collected from volunteers after oral administration of BBI. The ability of these MAbs to detect BBI metabolites indicates that BBI may be reductively modified in vivo and these MAbs may be useful reagents for monitoring the uptake of BBI into human tissues in cancer chemoprevention studies with BBI.

The third component of Xenopus complement: cDNA cloning, structural and functional analysis, and evidence for an alternate C3 transcript.

Although the third component of complement has been purified from two amphibian species, Xenopus laevis and the axolotl, only limited information is available about its primary structure in these species. We now present (a) 95% of the cDNA sequence encoding C3 from a Xenopus laevis/Xenopus gilli (Xenopus LG) hybrid (b) an analysis of the C3 convertase and factor I cleavage sites in Xenopus C3, and (c) evidence for an alternative form of C3. The Xenopus LG sequence has a 57% nucleotide and 52% amino acid sequence identity to human C3 and contains one potential N-glycosylation site in the beta-chain. The deduced amino acid sequence showed that the C3 convertase and factor I cleavage sites (Arg-Ser) are conserved in Xenopus C3 and protein sequencing of Xenopus C3 fragments fixed on zymosan during complement activation demonstrated that Xenopus C3 is indeed cleaved by C3 convertase and factor I at these sites. Our screening of a liver cDNA library identified an unusual C3 clone with a deletion of 2502 bp, suggesting the presence of a novel C3 transcript in Xenopus LG liver. The presence of this C3 transcript was confirmed by reverse transcription polymerase chain reaction using Xenopus LG liver mRNA and specific oligonucleotide probes. This transcript encoded a putative 102-kDa protein comprising the beta-chain of C3, together with the first 59 residues and the last 103 residues of the alpha-chain; it would therefore lack many of the ligand binding sites found in the intact alpha-chain. However, the molecule may be an analog of a truncated C3 molecule that is found in the serum of allergic dermatitis patients and acts as an inhibitor of eosinophil cytotoxicity and neutrophil adherence.

Effects of protease inhibitors on levels of proteolytic activity in normal and premalignant cells and tissues.

Our studies utilizing different types of protease inhibitors as anticarcinogenic agents in in vivo and in vitro systems have recently been reviewed. These studies suggest that the protease inhibitors which prevent carcinogenesis affect processes in the early stages of carcinogenesis, although they can be effective at long time periods after carcinogen exposure in both in vitro and in vivo systems. While there is strong evidence that these protease inhibitors can affect both the initiation and promotion stages of carcinogenesis, they have no effect on already transformed cells. Our results have suggested that the first event in carcinogenesis is a high frequency epigenetic event and that a later event, presumably genetic, leads to the malignant state. Protease inhibitors appear capable of reversing the initiating event, presumably by stopping an ongoing cellular process begun by carcinogen exposure. The major lines of investigation on the mechanism of the protease inhibitor suppression of carcinogenesis relate to the ability of anticarcinogenic protease inhibitors to affect the expression of certain oncogenes, and the levels of certain types of proteolytic activities. The anticarcinogenic protease inhibitors have no observable effects on normal cells, but can reverse carcinogen-induced cellular changes for several different end-points studied. The most direct method of determining the mechanism of action of the anticarcinogenic protease inhibitors is to identify and characterize the proteases with which they interact. In the cells of the in vivo and in vitro systems in which protease inhibitors can prevent carcinogenesis, only a few proteases have been observed to interact with the anticarcinogenic protease inhibitors. Proteases have been identified by both substrate hydrolysis and affinity chromatography.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosomal assignment of a gene encoding a new collagen type (COL15A1) to 9q21 --> q22.

The collagens constitute a large family of extracellular matrix components primarily responsible for maintaining the structure and biological integrity of connective tissue. These proteins exhibit considerable diversity size, sequence, tissue distribution, and molecular composition. Fourteen types of homo- and/or heterotrimeric molecules, thus far reported, are encoded by a minimum of 27 genes. Nineteen of these genes, including several that are closely linked, have been assigned to 10 separate autosomes, and one collagen gene has been mapped to the X chromosome. We have isolated a 2.1-kb human cDNA clone coding for a collagen molecule different in sequence and structure from types I-XIV collagens. This polypeptide has been designated the alpha 1 chain of type XV collagen. To determine the location of the corresponding gene, the cDNA clone was hybridized to rodent-human hybrid DNAs and to human metaphase chromosomes. The results obtained using the hybrid cell lines showed that this newly identified collagen gene, COL15A1, is present in the pter --> q34 region of chromosome 9. In situ hybridization allowed sublocalization to 9q21 --> q22, a region to which no other collagen genes had previously been assigned. Our data further demonstrate the complex arrangement of the many collagen genes in the human genome.