Reduced autophagic activity in primary rat hepatocellular carcinoma and ascites hepatoma cells.

Autophagy, measured as the sequestration of an endogenous cytosolic enzyme (LDH), showed a progressive rate reduction during diethylnitrosamine-induced rat liver carcinogenesis. In primary hepatocellular carcinomas the autophagic activity was only one-fourth of that seen in normal hepatocytes. Reduced autophagy was also observed in peritumorous hepatocytes and in cells from preneoplastic liver, and a complete suppression of autophagic protein degradation was seen in normal hepatocytes treated with ascitic fluid from an ascites hepatoma, suggesting that tumour cells and their precursors may produce autophagy-suppressive factors with an autocrine and paracrine action. In cells from the transplantable rat ascites hepatoma, Yoshida AH-130, autophagic activity was negligible during active (logarithmic) growth, but increased to approximately 0.4%/h at high cell density, i.e. in stationary phase. In contrast to normal hepatocytes, autophagy in the AH-130 cells was not inhibited by ascitic fluid. The hepatoma cells would thus appear to have lost some aspects of autophagy regulation while retaining others. However, even the highest rate of hepatoma cell autophagy was only one-tenth of the maximal activity seen in normal hepatocytes, confirming the hypothesis that reduced autophagy may be an important aspect of growth deregulation in liver cancer.

The Atlantic salmon prepro-gonadotropin releasing hormone gene and mRNA.

Screening for the gene encoding salmon gonadotropin releasing hormone (sGnRH) in an Atlantic salmon (Salmo salar) genomic library resulted in isolation of a positive clone designated lambda sGnRH-1. An anchor polymerase chain reaction (PCR) technique was used to amplify GnRH cDNA derived from salmon hypothalamic mRNA. The cDNA sequence was aligned to the 7607 base pair genomic sequence which was shown to encode the entire prepro-GnRH gene. The cDNA proved that the cloned gene is expressed in the hypothalamus of mature salmon. The coding domain of sGnRH differs from the mammalian GnRH by six nucleotide changes which allow the two amino acid differences between the two GnRH variants. Salmon GnRH associated peptide (GAP) differs extensively in sequence and size from the mammalian counterpart. Compared to the GnRH cDNA of a cichlid species the similarity is 69.3% in the protein coding sequence.

Nonselective autophagy of cytosolic enzymes by isolated rat hepatocytes.

Seven cytosolic enzymes with varying half-lives (ornithine decarboxylase, 0.9 h; tyrosine aminotransferase, 3.1 h; tryptophan oxygenase, 3.3 h; serine dehydratase, 10.3 h; glucokinase, 12.7 h; lactate dehydrogenase, 17.0 h; aldolase, 17.4 h) were found to be autophagically sequestered at the same rate (3.5%/h) in isolated rat hepatocytes. Autophagy was measured as the accumulation of enzyme activity in the sedimentable organelles (mostly lysosomes) of electrodisrupted cells in the presence of the proteinase inhibitor leupeptin. Inhibitors of lysosomal fusion processes (vinblastine and asparagine) allowed accumulation of catalytically active enzyme (in prelysosomal vacuoles) even in the absence of proteolytic inhibition, showing that no inactivation step took place before lysosomal proteolysis. The completeness of protection by leupeptin indicates, furthermore, that a lysosomal cysteine proteinase is obligatorily required for the initial proteolytic attack upon autophagocytosed proteins. The experiments suggest that sequestration and degradation of normal cytosolic proteins by the autophagic-lysosomal pathway is a nonselective bulk process, and that nonautophagic mechanisms must be invoked to account for differential enzyme turnover.

Experimental characterization of the autophagic-lysosomal pathway in isolated rat hepatocytes.

When isolated rat hepatocytes are incubated under amino-acid-free conditions autophagy is maximally activated and overall lysosomal proteolysis is greatly enhanced. To facilitate this, cytoplasmic material is sequestered by autophagic membranes, and the resulting autophagosomes enter the lysosomes by a fusion process to have their contents degraded. The various steps in the autophagic-lysosomal pathway have been investigated by utilizing reversible electropermeabilization to introduce radioactive sugar probes into the hepatocyte cytosol. The inert disaccharide sucrose and the inert trisaccharide raffinose have been used as sequestration probes to study the sequestrational step of autophagy, while the hydrolysable disaccharide lactose has been used to study the fusion and intralysosomal hydrolysis steps. Sucrose and lactose have been used to map the extent of convergence between the autophagic and endocytic (heterophagic) pathways. Sequestration of native cytosolic enzymes has been measured to investigate the question of selectivity in the autophagic process. Finally, the effect of insulin on the sequestrational step has been evaluated.