Accumulation of small hyaluronan oligosaccharides in tumour interstitial fluid correlates with lymphatic invasion and lymph node metastasis.

BACKGROUND: Association studies have implicated the glycosaminoglycan hyaluronan (hyaluronic acid, HA) and its degrading enzymes the hyaluronidases in tumour progression and metastasis. Oligosaccharides of degraded HA have been ascribed a number of biological functions that are not exerted by high-molecular-weight HA (HMW-HA). However, whether these small HA oligosaccharides (sHA) have a role in tumour progression currently remains uncertain due to an inability to analyse their concentration in tumours. METHODS: We report a novel method to determine the concentration of sHA ranging from 6 to 25 disaccharides in tumour interstitial fluid (TIF). Levels of sHA were measured in TIF from experimental rat tumours and human colorectal tumours. RESULTS: While the majority of HA in TIF is HMW-HA, concentrations of sHA up to 6 µg ml(-1) were detected in a subset of tumours, but not in interstitial fluid from healthy tissues. In a cohort of 72 colorectal cancer patients we found that increased sHA concentrations in TIF are associated with lymphatic vessel invasion by tumour cells and the formation of lymph node metastasis. CONCLUSIONS: These data document for the first time the pathophysiological concentration of sHA in tumours, and provide evidence of a role for sHA in tumour progression.

Lovastatin inhibits proliferation of pancreatic cancer cell lines with mutant as well as with wild-type K-ras oncogene but has different effects on protein phosphorylation and induction of apoptosis.

Besides its pharmacological effect on cholesterol biosynthesis, lovastatin inhibits p21ras proteins by substrate depletion for post-translational protein farnesylation and geranylation. This inhibition has previously been used to reverse cell proliferation after cellular transformation by the mutant p21ras oncogene. We investigated the biological effects of lovastatin on two pancreatic carcinoma cell lines. The SW-850 cell line contained the k-ras wild-type gene and the A818-4 cell line contained the mutant gene with a point mutation at codon 12 (GGTZCGT; glyZarg). Lovastatin inhibited the proliferation of pancreatic carcinoma cells dose-dependently showing an IC20-30 at 5 microM and IC40-50 at 10 microM. Proliferation of both cancer cell lines, A818-4 (p21ras-M) and SW-850 (p21ras-WT) were inhibited to a very similar extent. After 24 h of drug exposure, cell cycle arrest in G1 and G2/M-phase occurred in a large proportion of cells. At this time, neither cell line showed alteration of protein phosphorylation and did not undergo apoptosis. However, after 72 h of drug exposure, lovastatin significantly decreased protein phosphorylation on tyrosine, serine and threonine residues in A818-4 (p21ras-M) cells. Only a minute reduction of protein phosphorylation was detected in SW-850 (p21ras-WT) cells. Apoptosis occurred in both cell lines, but the SW-850 (p21ras-WT) showed a higher percentage of apoptotic cells than the A818-4 (p21ras-M). In conclusion, there is further evidence for a growth inhibitory effect on cancer cells regardless of the ras mutation status. However, as the effects on protein phosphorylation and induction of apoptosis differed between the mutant and wild-type cell lines, the mechanism of action of lovastatin may depend on partially different mechanisms.