𝔖 Bobbio Scriptorium
✦   LIBER   ✦

Glutathione excretion in response to heterologous protein secretion in saccharomyces cerevisiae

✍ Scribed by Sarah J. Bannister; K. Dane Wittrup

Publisher
John Wiley and Sons
Year
2000
Tongue
English
Weight
210 KB
Volume
68
Category
Article
ISSN
0006-3592

No coin nor oath required. For personal study only.

✦ Synopsis

Glutathione is excreted in a dose-dependent, non-stoichiometric fashion from Saccharomyces cerevisiae cells expressing and secreting Bovine Pancreatic Trypsin Inhibitor (BPTI), a small, disulfide-bonded protein. Glutathione excretion commences 40 hours following induction of BPTI synthesis. Expression of several secretory proteins with varying disulfide and cysteine contents results in glutathione excretion with no apparent requirement for protein disulfide content. Glutathione excretion is also triggered by overexpression of Kar2p/BiP, a native ER-resident protein-folding chaperone, indicating that the response is a general one not restricted to overexpression of thiol-containing heterologous proteins. Functional vesicular transport is not required at the time of glutathione excretion, and glutathione excretion requires the presence of molecular oxygen. These data are consistent with a delayed oxidative stress response potentiated by earlier heterologous secretion, but are inconsistent with secretory transport of glutathione spent as oxidizing equivalents for disulfidebond formation in the endoplasmic reticulum.

πŸ“œ SIMILAR VOLUMES

Contrasting secretory processing of simu
Contrasting secretory processing of simultaneously expressed heterologous proteins in Saccharomyces cerevisiae
✍ Andy Rakestraw; K. Dane Wittrup πŸ“‚ Article πŸ“… 2006 πŸ› John Wiley and Sons 🌐 English βš– 265 KB πŸ‘ 1 views

## Abstract In this study, secretory processing of cell‐surface displayed Aga2p fusions to bovine pancreatic trypsin inhibitor (BPTI) and the single chain Fv (scFv) antibody fragment D1.3 are examined. BPTI is more efficiently processed than D1.3 both when secreted and surface‐displayed, and D1.3 e

Differences in response of Zymomonas mob
Differences in response of Zymomonas mobilis and Saccharomyces cerevisiae to change in extracellular ethanol concentration
✍ T. J. Hobley; N. B. Pamment πŸ“‚ Article πŸ“… 1994 πŸ› John Wiley and Sons 🌐 English βš– 360 KB πŸ‘ 2 views

## Abstract In high cell density batch fermentations, __Zymomonas mobilis__ produced 91 g L^βˆ’1^ ethanol in 90 min but culture viability fell significantly. Similar viability losses in rapid fermentations by yeast have recently been shown to be attributable in part to the high rate of change of the

Directed evolution of a secretory leader
Directed evolution of a secretory leader for the improved expression of heterologous proteins and full-length antibodies in Saccharomyces cerevisiae
✍ J. Andy Rakestraw; Stephen L. Sazinsky; Andrea Piatesi; Eugene Antipov; K. Dane πŸ“‚ Article πŸ“… 2009 πŸ› John Wiley and Sons 🌐 English βš– 474 KB πŸ‘ 1 views

## Abstract Because of its eukaryotic nature, simple fermentation requirements, and pliable genetics, there have been many attempts at improving recombinant protein production in __Saccharomyces__ __cerevisiae__. These strategies typically involve altering the expression of a native protein thought

Transient mRNA responses in chemostat cu
Transient mRNA responses in chemostat cultures as a method of defining putative regulatory elements: Application to genes involved in Saccharomyces cerevisiae acetyl-coenzyme A metabolism
✍ Van Den Berg, Marco A.; De Jong-Gubbels, Patricia; Yde Steensma, H. πŸ“‚ Article πŸ“… 1998 πŸ› John Wiley and Sons 🌐 English βš– 384 KB πŸ‘ 1 views

To identify common regulatory sequences in the promoters of genes, transcription of 31 genes of Saccharomyces cerevisiae was analysed during the transient response to a glucose pulse in a chemostat culture. mRNA levels were monitored during the subsequent excess glucose, ethanol and acetate phases,

Erratum to: Sequence, map position and g
Erratum to: Sequence, map position and genome organization of the RPL 17B gene, encoding ribosomal protein L17b in Saccharomyces cerevisiae
✍ Berroteran, Rhonda W.; Hampsey, Michael πŸ“‚ Article πŸ“… 1996 πŸ› John Wiley and Sons 🌐 English βš– 33 KB πŸ‘ 2 views

In the above paper (Yeast 11: 761-766 (1995)) ribosomal protein L17a is erroneously referred to as L17, which is a ribosomal protein distinct from L17a. All references to the products of the RPL 17A and RPL 17B genes should be L 17a.