Decrease of peroxisomal enzymes in Tetrahymena and its prevention by actinomycin D and cycloheximide

Effects of cycloheximide and actinomycin D on the amino acid transport system of Tetrahymena

Tetrahymena pyriformis were grown in axenic culture to late logarithmic and stationary phases, resuspended in an inorganic medium, and the rates of transport of alpha-aminoisobutyric acid (AIB) and of the decarboxylation of L-[1-14C]leucine and L-[1-14C]tyrosine were measured. There was a rapid loss of each of these measures of amino acid transport in both late log phase and stationary phase cells, Addition of actinomycin D to the washed cells caused a small increase in the rate of loss of capacity to decarboxylate tyrosine and leucine. Addition of cycloheximide to the washed cells caused a reduction in the rates of loss of capacity to transport AIB and to decarboxylate leucine and tyrosine except that in late log phase cells cycloheximide markedly increased the rate of loss of capacity to decarboxylate leucine. When cells that had been pretreated with chlorpromazine to reduce their amino acid transport capacity were washed and resuspended in proteose peptone the capacity to decarboxylate tyrosine and leucine increased to control values within 1.5 hours. Addition of actinomycin D reduced the rate of recovery of transport systems in this cell. The finding that AIB and N-methylaminoisobutyrate are both taken up by Tetrahymena, the latter at one-eighth the rate of the former, but that neither one alters the rate of uptake of the other provides preliminary support for this possibility. The present results further suggest that the transport system(s) has a short lifetime and that the balance between rate of synthesis and rate of loss of the transport system is controlled in part by the presence of exogenous amino acids.

Regulation of neutral protease activity through the life cycles of Tetrahymena pyriformis

Substantial fluctuations in the intracellular specific activity of neutral proteases, as assayed at pH 8 with azocasein as substrate, occur during the life cycle of the protozoan Tetrahymena pyriformis. Specific activity increases during growth in 2% proteose peptone, despite slow secretion into the medium. The most rapid increase occurs during late stationary phase and appears to be a response to one or more low molecular weight (less than 10 000), heat-stable, trypsin-insensitive, polar molecules secreted into the medium. In contrast, intracellular specific activity drops by a factor of 2--5 within the first 2--3 h after transfer to non-nutritive medium. The decrease in activity under these conditions results from an enhanced rate of secretion and the cessation of net synthesis. Its kinetics are unaffected by cycloheximide and concanavalin A.

Enzyme inactivation by a cellular neutral protease: enzyme specificity, effects of ligands on inactivation, and implications for the regulation of enzyme degradation

A protease from Tetrahymena pyriformis inactivated eight of nine commercially available enzymes tested, including lactate deyhdrogenase, isocitrate dehydrogenase (TPN-specific), glucose-6 phosphate dehydrogenase, D-amino acid oxidase, fumarase, pyruvate kinase, hexokinase, and citrate synthase. Urate oxidase was not inactivated. Inactivation occurred at neutral pH, was prevented by inhibitors of the protease, and followed first order kinetics. In those cases tested, inactivation was enhanced by mercaptoethanol. Most of the enzyme-inactivating activity was due to a protease of molecular weight 25,000 that eluted from DEAE-Sephadex at 0.3 M KCl. A second protease of this molecular weight, which was not retained by the gel, inactivated only isocitrate dehydrogenase and D-amino acid oxidase. These two proteases could also be distinguished by temperature and inhibitor sensitivity. Two other protease peaks obtained by DEAE-Sephadex chromatography had little or no no enzyme inactivating activity, while another attacked only D-amino acid oxidase. At least six of the enzymes could be protected from proteolytic inactivation by various ligands. Isocitrates dehydrogenase was protected by isocitrate, TPN, or TPNH, glucose-6-dehydrogenase by glucose-6-P or TPN, pyruvate kinase by phosphoenolypyruvate or ADP, hexokinase by glucose, and fumarase by a mixture of fumarate and malate. Lactate dehdrogenase was not protected by either of its substrates of coenzymes. Citrate synthase was probably protected by oxalacetate. Our data suggest that the protease or proteases discussed here may participate in the inactivation or degradation of a least some enzymes in Tetrahymena. Since the inactivation occurs at neutral pH, this process could be regulated by variations in the cellular levels of substrates, coenzymes, or allosteric regulators resulting form changes in growth conditions or growth state. Such a mechanism would permit the selective retention of enzymes of metabolically active pathways.

Synthesis of glycolytic and peroxisomal enzymes in Tetrahymena following a change in culture conditions

The specific activity of a peroxisomal enzyme, lactate oxidase, and of pyruvate kinase and lactate dehydrogenase, which are not peroxisomal, increased rapidly when shaken cultures of Tetrahymena were transferred to conditions of oxygen restriction and supplemented with glucose. Two other peroxisomal enzymes, catalase and TPN-linked isocitrate dehydrogenase, did not increase substantially, nor did succinate dehydrogenase. The increases were reduced if glucose was not added at the time of transfer, and were prevented by actinomycin D or cycloheximide, but not by chloramphenicol. The results suggest an involvement of peroxisomes in the metabolism of glycolytic endproducts when the availability of oxygen to the cell is limiting.