D. Greene scite author profile

Killer toxin secretion was blocked at the restrictive temperature in Saccharomyces cerevisiae sec mutants with conditional defects in the S. cerevisiae secretory pathway leading to accumulation of endoplasmic reticulum (sec18), Golgi (sec7), or secretory vesicles (secl). A 43,000-molecular-weight (43K) glycosylated protoxin was found by pulse-labeling in all sec mutants at the restrictive temperature. In secl8 the protoxin was stable after a chase; but in sec7 and seci the protoxin was unstable, and in secl 11K toxin was detected in cell lysates. The chymotrypsin inhibitor tosyl-L-phenylalanyl chloromethyl ketone (TPCK) blocked toxin secretion in vivo in wild-type cells by inhibiting protoxin cleavage. The unstable protoxin in wild-type and in sec7 and secl cells at the restrictive temperature was stabilized by TPCK, suggesting that the protoxin cleavage was post-secl8 and was mediated by a TPCK-inhibitable protease. Protoxin glycosylation was inhibited by tunicamycin, and a 36K protoxin was detected in inhibited cells. This 36K protoxin was processed, but toxin secretion was reduced 10-fold. We examined two kex mutants defective in toxin secretion; both synthesized a 43K protoxin, which was stable in kexi but unstable in kex2.Protoxin stability in kexi kex2 double mutants indicated the order kexi -* kex2 in the protoxin processing pathway. TPCK did not block protoxin instability in kex2 mutants. This suggested that the KEXI-and KEX2-dependent steps preceded the sec7 Golgi block. We attempted to localize the protoxin in S. cerevisiae cells. Use of an in vitro rabbit reticulocyte-dog pancreas microsomal membrane system indicated that protoxin synthesized in vitro could be inserted into and glycosylated by the microsomal membranes. This membrane-associated protoxin was protected from trypsin proteolysis. Pulse-chased cells or spheroplasts, with or without TPCK, failed to secrete protoxin. The protoxin may not be secreted into the lumen of the endoplasmic reticulum, but may remain membrane associated and may require endoproteolytic cleavage for toxin secretion.

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Substrate specificity and partial characterization of the PAF-acylhydrolase in human serum that rapidly inactivates platelet-activating factor.

Wardlow¹,

Cox²,

Meng³

et al. 1986

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The structure of the potent inflammatory mediator, platelet-activating factor, is 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine (AGEPC, PAF-acether). Human sera contain an acid labile factor (ALF) that is a Ca+2-independent 2-acylhydrolase-specific for AGEPC and AGEPC-like molecules. The enzyme functions by catalytically removing the sn-2 acetyl moiety from AGEPC, producing the biologically inactive sn-2 hydroxy form or 2-lyso-GEPC. Incubation of ALF with sn-2 acyl PAF analogs indicated that the enzyme hydrolyzes the sn-2 fatty acid only if the chain length is five carbons or less, the sn-1 position fatty acid length is greater than 10 carbon units, and at least one methyl group is present on the terminal amine of the choline group. The enzyme was active with either an ether or ester linkage at the sn-1 position. ALF is inactivated by heating to 65 degrees C for 30 min. It is pronase and trypsin sensitive but resistant to papain and papain with dithiothreitol. Further characteristics of human ALF indicated a broad pH range of activity with an optimum of pH 6.2 and an isoelectric point of 6.2 to 6.7. The specificity and Ca+2 independence of human ALF sets it apart from phospholipase A2. It is proposed that human ALF be called human serum PAF-acylhydrolase to distinguish it from other hydrolases currently known to exist.

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Secretion of Saccharomyces cerevisiae Killer Toxin: Processing of the Glycosylated Precursor

Bussey

Saville

Greene

et al. 1983

Molecular and Cellular Biology

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Killer toxin secretion was blocked at the restrictive temperature in Saccharomyces cerevisiae sec mutants with conditional defects in the S. cerevisiae secretory pathway leading to accumulation of endoplasmic reticulum ( sec18 ), Golgi ( sec7 ), or secretory vesicles ( sec1 ). A 43,000-molecular-weight (43K) glycosylated protoxin was found by pulse-labeling in all sec mutants at the restrictive temperature. In sec18 the protoxin was stable after a chase; but in sec7 and sec1 the protoxin was unstable, and in sec1 11K toxin was detected in cell lysates. The chymotrypsin inhibitor tosyl- l -phenylalanyl chloromethyl ketone (TPCK) blocked toxin secretion in vivo in wild-type cells by inhibiting protoxin cleavage. The unstable protoxin in wild-type and in sec7 and sec1 cells at the restrictive temperature was stabilized by TPCK, suggesting that the protoxin cleavage was post- sec18 and was mediated by a TPCK-inhibitable protease. Protoxin glycosylation was inhibited by tunicamycin, and a 36K protoxin was detected in inhibited cells. This 36K protoxin was processed, but toxin secretion was reduced 10-fold. We examined two kex mutants defective in toxin secretion; both synthesized a 43K protoxin, which was stable in kex1 but unstable in kex2 . Protoxin stability in kex1 kex2 double mutants indicated the order kex1 → kex2 in the protoxin processing pathway. TPCK did not block protoxin instability in kex2 mutants. This suggested that the KEX1 - and KEX2 -dependent steps preceded the sec7 Golgi block. We attempted to localize the protoxin in S. cerevisiae cells. Use of an in vitro rabbit reticulocyte-dog pancreas microsomal membrane system indicated that protoxin synthesized in vitro could be inserted into and glycosylated by the microsomal membranes. This membrane-associated protoxin was protected from trypsin proteolysis. Pulse-chased cells or spheroplasts, with or without TPCK, failed to secrete protoxin. The protoxin may not be secreted into the lumen of the endoplasmic reticulum, but may remain membrane associated and may require endoproteolytic cleavage for toxin secretion.

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D. Greene

Yeast killer toxin: Site-directed mutations implicate the precursor protein as the immunity component

Secretion ofSaccharomyces cerevisiaeKiller Toxin: Processing of the Glycosylated Precursor

Substrate specificity and partial characterization of the PAF-acylhydrolase in human serum that rapidly inactivates platelet-activating factor.

Secretion of Saccharomyces cerevisiae Killer Toxin: Processing of the Glycosylated Precursor

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