Alpha-factor-directed synthesis and secretion of mature foreign proteins in Saccharomyces cerevisiae.

Brake, Anthony J.; Merryweather, James P.; Coit, Doris; Heberlein, Ulrike; Masiarz, Frank R.; Mullenbach, Guy T.; Urdea, Mickey S.; Valenzuela, Pablo; Barr, Philip J.

doi:10.1073/pnas.81.15.4642

Cited by 414 publications

(204 citation statements)

References 27 publications

(27 reference statements)

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“…Both constructs contained a Myc epitope tag followed by a hexahistidine sequence at the C terminus (Myc-His) but differed in the presence or absence of a Glu-Ala-Glu-Ala sequence following an amino-terminal ␣ factor signal sequence. This Glu-Ala repeat may promote more efficient signal sequence cleavage under certain circumstances (29). After pilot experiments, we chose to use the construct lacking the Glu-Ala repeat for subsequent protein production, because expression levels from both constructs were similar, but N-terminal sequence analysis (data not shown) revealed that the Glu-Ala repeat was retained.…”

Section: Resultsmentioning

confidence: 99%

Demonstration of Lysosomal Localization for the Mammalian Ependymin-related Protein Using Classical Approaches Combined with a Novel Density Shift Method

Valle¹,

Sleat²,

Sohár³

et al. 2006

Journal of Biological Chemistry

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Most newly synthesized soluble lysosomal proteins are delivered to the lysosome via the mannose 6-phosphate (Man-6-P)-targeting pathway. The presence of the Man-6-P post-translational modification allows these proteins to be affinity-purified on immobilized Man-6-P receptors. This approach has formed the basis for a number of proteomic studies that identified multiple as yet uncharacterized Man-6-P glycoproteins that may represent new lysosomal proteins. Although the presence of Man-6-P is suggestive of lysosomal function, the subcellular localization of such candidates requires experimental verification. Here, we have investigated one such candidate, ependymin-related protein (EPDR). EPDR is a protein of unknown function with some sequence similarity to ependymin, a fish protein thought to play a role in memory consolidation and learning. Using classical subcellular fractionation on rat brain, EPDR co-distributes with lysosomal proteins, but there is significant overlap between lysosomal and mitochondrial markers. For more definitive localization, we have developed a novel approach based upon a selective buoyant density shift of the brain lysosomes in a mutant mouse lacking NPC2, a lysosomal protein involved in lipid transport. EPDR, in parallel with lysosomal markers, shows this density shift in gradient centrifugation experiments comparing mutant and wild type mice. This approach, combined with morphological analyses, demonstrates that EPDR resides in the lysosome. In addition, the lipidosis-induced density shift approach represents a valuable tool for identification and validation of both luminal and membrane lysosomal proteins that should be applicable to high throughput proteomic studies.Recent genomic and proteomic studies have revealed the presence of numerous previously uncharacterized proteins encoded by the mammalian genome. Determining the biological role of such proteins poses a fundamental challenge. Although sequence and structural similarities to proteins of known function may provide useful information, knowledge of the site of function is essential in understanding uncharacterized proteins. In addition to providing insight into protein function, mapping of proteins to cellular organelles or structures involved in specific biological processes may provide valuable clues to how the organelles carry out these processes.One cellular compartment that contains protein constituents of characteristic function is the lysosome, an acidic, membrane-delimited organelle present in all eukaryotic cells (1). The lysosome contains over 60 soluble proteins, most of which are hydrolases that function in concert to degrade macromolecules introduced via the endocytic and autophagic pathways into simple constituents that can be reutilized by the cell. A number of recent proteomic studies investigating soluble luminal lysosomal proteins have relied upon the fact that these proteins contain an unusual carbohydrate modification that allows for their specific affinity purification. Most luminal lysosomal proteins are t...

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Section: Resultsmentioning

confidence: 99%

Demonstration of Lysosomal Localization for the Mammalian Ependymin-related Protein Using Classical Approaches Combined with a Novel Density Shift Method

Valle¹,

Sleat²,

Sohár³

et al. 2006

Journal of Biological Chemistry

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“…The yeast expression system of a random peptide library (Brake et al, 1984) seemed particularly suitable for this study; in this method, peptides are secreted into the culture medium and are therefore directly accessible to the antibody without solubilization of the cells. Furthermore, Klepfer et al (1993) demonstrated that yeast was able to translate the rabies virus G gene as a 68 kDa protein immunoreactive not only with a polyclonal antiserum but also with three neutralizing MAbs that were known to react only with native protein, indicating that the yeast was probably able to efficiently process this protein.…”

Section: Introductionmentioning

confidence: 99%

Immunodominant epitopes defined by a yeast-expressed library of random fragments of the rabies virus glycoprotein map outside major antigenic sites

Lafay

Benmansour

Chébli

et al. 1996

Journal of General Virology

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Nineteen yeast colonies secreting rabies virus glycoprotein (G) peptides immunoreactive with polyclonal anti-rabies virus sera were selected from a random expression library. The peptides, around 80 amino acids long, spanned amino acids only recognized by about 1% of our MAbs. Three of these WB + MAbs had significant neutralizing activity; two were used for the selection of antigenic mutants (MAR mutants). Some mutants had a substitution within the region delimited by the peptides, confirming the pertinence of both the peptide and escape mutant approaches. However, a few mutants had a substitution outside the peptide-delimited region, suggesting that remote mutation(s) could affect epitope accessibility in the native protein.

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“…6,1986 on May 10, 2018 by guest http://mcb.asm.org/ Downloaded from independent of the other side of the junction for this particular secretory system. Further experiments may elucidate these possibilities.…”

Section: Discussionmentioning

confidence: 94%

“…Recently there have been several reports of secretion of heterologous protein products by using the a-factor gene of yeast cells (4,6,26). These systems result in proper processing of heterologous proteins during the secretion process.…”

Section: Discussionmentioning

confidence: 99%

Saccharomyces cerevisiae secretes and correctly processes human interferon hybrid proteins containing yeast invertase signal peptides.

Chang¹,

Matteucci²,

Perry³

et al. 1986

Mol. Cell. Biol.

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Synthetic oligonucleotides coding for the yeast invertase secretion signal peptide were fused to the gene for the mature form of human interferon (huIFN-a2). Two plasmids (E3 and F2) were constructed. E3 contained the invertase signal codons in a reading frame with the mature huIFN-a2 gene. F2 had a deletion of the codon for alanine at amino acid residue -5 in the invertase signal and an addition of a methionine codon located between the coding sequences for the invertase signal and mature huIFN-ca2. Both hybrid genes were located adjacent to the promoter from the 3-phosphoglycerate kinase gene on the multicopy yeast expression plasmid, YEplPT. Yeast transformants containing these plasmids produced somewhat more IFN than did the same expression plasmid containing the IFN gene with its human secretion signal sequence. HuIFN-a2, purified from the medium of yeast cells containing E3, was found to be processed at the correct site. The huIFN-a2 made by plasmid F2 was found to be completely processed at the junction between the invertase signal (a variant) and the methionine of methionine-huIFN-a2. These results strongly suggested that the invertase signal (or its variant) attached to huIFN was efficiently recognized by the presumed signal recognition particle and was cleaved by the signal peptidase in the yeast cells. These results also suggested that amino acid changes on the right side of the cleavage site did not necessarily prevent cleavage or secretion.

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Alpha-factor-directed synthesis and secretion of mature foreign proteins in Saccharomyces cerevisiae.

Cited by 414 publications

References 27 publications

Demonstration of Lysosomal Localization for the Mammalian Ependymin-related Protein Using Classical Approaches Combined with a Novel Density Shift Method

Demonstration of Lysosomal Localization for the Mammalian Ependymin-related Protein Using Classical Approaches Combined with a Novel Density Shift Method

Immunodominant epitopes defined by a yeast-expressed library of random fragments of the rabies virus glycoprotein map outside major antigenic sites

Saccharomyces cerevisiae secretes and correctly processes human interferon hybrid proteins containing yeast invertase signal peptides.

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