Treponema denticola chymotrypsin-like proteinase may contribute to orodigestive carcinogenesis through immunomodulation.

BACKGROUND: Periodontal pathogens have been linked to oral and gastrointestinal (orodigestive) carcinogenesis. However, the exact mechanisms remain unknown. Treponema denticola (Td) is associated with severe periodontitis, a chronic inflammatory disease leading to tooth loss. The anaerobic spirochete Td is an invasive bacteria due to its major virulence factor chymotrypsin-like proteinase. Here we aimed to investigate the presence of Td chymotrypsin-like proteinase (Td-CTLP) in major orodigestive tumours and to elucidate potential mechanisms for Td to contribute to carcinogenesis. METHODS: The presence of Td-CTLP within orodigestive tumour tissues was examined using immunohistochemistry. Oral, tonsillar, and oesophageal squamous cell carcinomas, alongside gastric, pancreatic, and colon adenocarcinomas were stained with a Td-CTLP-specific antibody. Gingival tissue from periodontitis patients served as positive controls. SDS-PAGE and immunoblot were used to analyse the immumodulatory activity of Td-CTLP in vitro. RESULTS: Td-CTLP was present in majority of orodigestive tumour samples. Td-CTLP was found to convert pro MMP-8 and -9 into their active forms. In addition, Td-CTLP was able to degrade the proteinase inhibitors TIMP-1, TIMP-2, and α-1-antichymotrypsin, as well as complement C1q. CONCLUSIONS: Because of its presence within tumours and regulatory activity on proteins critical for the regulation of tumour microenvironment and inflammation, the Td-CTLP may contribute to orodigestive carcinogenesis.

Pharmacokinetics and pharmacodynamics of irinotecan and its metabolites from plasma and saliva data in patients with metastatic digestive cancer receiving Folfiri regimen.

PURPOSE: Irinotecan is extensively metabolized into at least four compounds and previous pharmacokinetic-pharmacodynamic studies have given varying results. We hypothesized that saliva, a noninvasive, safe and painless biological sampling process, could be a good predictor of the behavior of irinotecan and its metabolites. METHODS: Thirty-five patients with metastatic digestive cancer were treated with a Folfiri regimen every 2 weeks. The irinotecan-administered dose was 180 mg/m(2); 17 patients participated in a dose-escalating study. Irinotecan and its metabolites (SN-38, SN-38G, APC, NPC) were quantified in plasma and saliva by high-performance liquid chromatography with fluorescence detection. RESULTS: The mean irinotecan systemic clearance and steady-state volume of distribution values were 14.3 l/h/m(2) and 211 l/m(2), respectively. The intrapatient variability (22-28%) was far lower than the interindividual variability (33-88%). Age and weight were the two physiological parameters that influenced drug disposition. For irinotecan, SN-38, APC and NPC, similar pharmacokinetic profiles were observed from plasma and saliva data. The saliva/plasma AUC ratios averaged 1 for irinotecan, 0.3 for SN-38, 0.17 for APC and 0.27 for NPC. Neutropenia, diarrhea and nausea were the main toxicities encountered. From both plasma and saliva data, the percentage decrease in neutrophil count appeared to be related to irinotecan and SN-38 AUCs. CONCLUSIONS: All these findings provide a rationale for an individual adaptation of irinotecan dosing. In case of difficult venous access, the titration of irinotecan and of its active metabolite SN-38 in saliva may prove relevant.

Acetaldehyde, microbes, and cancer of the digestive tract.

Excessive alcohol consumption and heavy smoking are the main risk factors of upper digestive tract cancer in industrialized countries. The association between heavy drinking and cancer appears to he particularly prominent in Asian individuals who have an inherited deficient ability to detoxify the first metabolite of ethanol oxidation, acetaldehyde. Alcohol itself is not carcinogenic. However, according to cell culture and animal experiments acetaldehyde is highly toxic, mutagenic, and carcinogenic. In addition to somatic cells, microbes representing normal human gut flora are also able to produce acetaldehyde from ethanol. After the ingestion of alcoholic beverages, this results in high local acetaldehyde concentrations in the saliva, gastric juice, and the contents of the large intestine. In addition, microbes may produce acetaldehyde endogenously without alcohol administration. This review summarizes the epidemiological, genetic, and biochemical evidence supporting the role of locally produced acetaldehyde in the pathogenesis of digestive tract cancer. Special emphasis is given to those factors that regulate local acetaldehyde concentration in the contents of the gastrointestinal tract. The new evidence presented in this review may open a microbiological approach to the pathogenesis of digestive tract cancer and may have an influence on future preventive strategies.