Larvae-induced plasma membrane wounds and glycoprotein deposition are insufficient for Trichinella spiralis invasion of epithelial cells.

Trichinella spiralis L1 larvae infect susceptible hosts by invading epithelial cells that line the small intestine. Invasion also occurs in vitro when larvae are inoculated into cultures of epithelial cells from several different animal species. To further investigate the mechanism of invasion, we studied the interaction of larvae with the rat epithelial cell line IEC-6. Larvae did not invade IEC-6 cells, but did cause the cells to take up parasite glycoproteins. Glycoprotein bearing cells remained viable and were detectable in monolayers for as long as 24 h, suggesting that the glycoproteins were not toxic for cells. Immunofluorescence revealed that parasite glycoproteins localized in the nuclei, mitochondria and cytoplasm and we found evidence for selection of certain molecules between nuclear and cytoplasmic compartments. Using fluorescent dextrans as fluid phase markers we found 17-38% of the cells in inoculated monolayers were engorged with dextran and that dextran was free in the cytoplasm. Increased dextran uptake was not lethal, required the presence of activated larvae, and was often associated with uptake of parasite glycoproteins. These observations suggest that larvae caused plasma membrane wounds. Our results showed that neither delivery of glycoproteins nor mechanical wounding is sufficient to allow entry of the parasite into resistant epithelial cells. Because both invasion-resistant and susceptible epithelial cells undergo non-lethal wounding, we propose that larvae-induced injury to epithelial cells may result in release of cell-specific mediators that signal larva to invade a particular cell line or, alternatively, to ignore it.

Invasion of intestinal epithelia in vitro by the parasitic nematode Trichinella spiralis.

Studies of nematode establishment in intestinal niches has been hindered by the lack of a readily manipulated in vitro assay. In this report, experiments are described wherein the larval stage of the parasitic nematode Trichinella spiralis was shown to invade epithelial cell monolayers in vitro. Larvae penetrated cells and migrated through them, leaving trails of dead cells in their wake. Cells derived from five different species were susceptible to invasion, reflecting the broad host range of T. spiralis in vivo. Epithelial cells derived from large and small intestines and kidneys were susceptible. Fibroblast and muscle cells were resistant. Larvae deposited glycoprotein antigens in the cells they invaded. Although the function of these antigens is unknown, they are targeted by rat antibodies that cause T. spiralis to be expelled from the intestine. The model system described provides the means to further investigate this process as well as the mechanisms by which this parasitic nematode establishes its intestinal niche.

Diagnostic efficacy of serum alkaline phosphatase and gamma-glutamyltransferase in dogs with histologically confirmed hepatobiliary disease: 270 cases (1980-1990).

The diagnostic efficacy of serum alkaline phosphatase (ALP) and gamma-glutamyltransferase (GGT) activities was examined, using the records of 270 dogs initially suspected of having hepatobiliary disease on the basis of history, findings on physical examination, results of baseline screening tests, or any combination of these data. Histologic examination of hepatic tissue was performed in each dog. Sixty-three dogs did not have histologic evidence of hepatobiliary disease and served as the control group. On the basis of diagnosis, dogs were assigned to 1 of 8 groups: dogs with cirrhosis (n = 34), steroid hepatopathy (n = 16), hepatic neoplasia (primary and secondary, n = 36), chronic hepatitis (n = 14), chronic passive congestion (n = 5), hepatic necrosis (n = 17), portosystemic vascular anomaly (n = 35), and cholestasis (extrahepatic bile-duct obstruction and intrahepatic cholestasis, n = 50). Of the 207 dogs with hepatobiliary disease, 29 (14%) had normal ALP and GGT activities, 31 (15%) had normal ALP activity, and 112 (54%) had normal GGT activity. Of the 63 control dogs, 29 (46%) had normal serum ALP and GGT activities, 32 had normal ALP activity (ALP specificity, 51%), and 55 had normal GGT activity (GGT specificity, 87%). The specificity of ALP and GGT in parallel (positive result = result of either test abnormal) was 46%, and in series (positive result = results of both tests abnormal) was 91%. The highest median activities of ALP developed in dogs with cholestasis, steroid hepatopathy, chronic hepatitis, and hepatic necrosis. The highest median activities of GGT developed in dogs with steroid hepatopathy, cholestasis, and hepatic necrosis.(ABSTRACT TRUNCATED AT 250 WORDS)

Evaluation of twelve-hour preprandial and two-hour postprandial serum bile acids concentrations for diagnosis of hepatobiliary disease in dogs.

In samples collected from 170 dogs suspected of having hepatobiliary disease, preprandial serum bile acids (PRSBA) and postprandial serum bile acids (POSBA) concentrations were measured, using a spectrophotometric enzymatic method. Dogs were assigned to 8 disease groups and 1 control group on the basis of hepatic histopathologic findings. Pre- and postprandial SBA concentrations and results of routine biochemical analyses (including total bilirubin, albumin, and BUN concentrations, and serum alkaline phosphatase (ALP), alanine transaminase (ALT), and aspartate transaminase (AST) activities) were expressed, using 4 indices: sensitivity, specificity, positive predictive value, and negative predictive value. Single tests and combinations of tests in series were evaluated. For diagnosis of hepatobiliary disease, the specificity of PRSBA was 100% at values greater than 20 mumol/L and of POSBA was 100% at values greater than 25 mumol/L. Test combinations with the best sensitivity for diagnosing the following diseases were: PRSBA-POSBA for cirrhosis, portosystemic vascular anomaly, and glucocorticoid hepatopathy; PRSBA-POSBA or PRSBA-ALP for cholestasis; PRSBA-POSBA or ALT-AST for chronic hepatitis; PRSBA-ALT for hepatic necrosis and passive congestion; and PRSBA-ALP for neoplasia. Test combinations with the overall highest sensitivity and positive predictive value for the fewest number of tests were PRSBA-POSBA, and either PRSBA or POSBA combined with an enzyme activity (ALT, AST, or ALP). The overall test efficacy for PRSBA vs POSBA was nearly identical: for PRSBA, it was 82.4%, and for POSBA, it was 82.3%. On the basis of the results of this study, PRSBA greater than 20 mumol/L or POSBA greater than 25 mumol/L (measured by use of an enzymatic procedure) indicates histopathologic abnormalities of the hepatobiliary system or portosystemic vascular anastomosis. Seemingly, determination of SBA concentrations can be used to indicate the propriety for hepatic biopsy. Pre- and postprandial serum bile acids concentrations should be evaluated in conjunction with routinely used hepatobiliary screening tests for best diagnostic advantage.

Effect of colostrum ingestion on gamma-glutamyltransferase and alkaline phosphatase activities in neonatal pups.

Analysis of hepatic enzyme activities in serum samples from 1- to 3-day-old pups revealed alkaline phosphatase (ALP) activities that were 30 times higher and gamma-glutamyltransferase (GGT) activities that were 100 times higher than activities in clinically normal adult dogs. A study was conducted to investigate high enzyme activity in pups and to determine whether there is any association between serum enzyme activity and colostrum ingestion, passive transfer of maternal serum enzyme (in colostrum or in utero), or excessive renal or hepatic tissue enzymes. Serum enzyme activity was quantified in 15 neonatal pups before and after ingestion of colostrum and in 3 colostrum-deprived neonates fed a milk substitute. Serum samples were collected on postpartum days 0, 1, 10, 15, and 30. Enzyme activity was also quantified in serum from pregnant and lactating bitches (collected on days -2, 0, 1, 10, 30), hepatic and renal tissue from clinically normal adult dogs and 1-day-old pups, colostrum, milk (collected on days 10 and 30), and milk replacer. Significant (P less than 0.01) differences in serum GGT and ALP activities between colostrum-deprived and suckling pups did not exist before initial feeding. Significant (P less than 0.001) increases in serum GGT and ALP activities developed within 24 hours in suckling pups, but not in the colostrum-deprived pups. At 10 and 30 days after birth, serum GGT and ALP activities were less than values before suckling in all pups. Enzyme activities in bitches' serum remained within the normal range for adult dogs throughout whelping and lactation.(ABSTRACT TRUNCATED AT 250 WORDS)