Heidi Holkeri scite author profile

Heat stress is an obvious hazard, and mechanisms to recover from thermal damage, largely unknown as of yet, have evolved in all organisms. We have recently shown that a marker protein in the ER of Saccharomyces cerevisiae, denatured by exposure of cells to 50°C after preconditioning at 37°C, was reactivated by an ATP-dependent machinery, when the cells were returned to physiological temperature 24°C. Here we show that refolding of the marker enzyme Hsp150Δ–β-lactamase, inactivated and aggregated by the 50°C treatment, required a novel ER-located homologue of the Hsp70 family, Lhs1p. In the absence of Lhs1p, Hsp150Δ–β-lactamase failed to be solubilized and reactivated and was slowly degraded. Coimmunoprecipitation experiments suggested that Lhs1p was somehow associated with heat-denatured Hsp150Δ– β-lactamase, whereas no association with native marker protein molecules could be detected. Similar findings were obtained for a natural glycoprotein of S. cerevisiae, pro-carboxypeptidase Y (pro-CPY). Lhs1p had no significant role in folding or secretion of newly synthesized Hsp150Δ–β-lactamase or pro-CPY, suggesting that the machinery repairing heat-damaged proteins may have specific features as compared to chaperones assisting de novo folding. After preconditioning and 50°C treatment, cells lacking Lhs1p remained capable of protein synthesis and secretion for several hours at 24°C, but only 10% were able to form colonies, as compared to wild-type cells. We suggest that Lhs1p is involved in a novel function operating in the yeast ER, refolding and stabilization against proteolysis of heatdenatured protein. Lhs1p may be part of a fundamental heat-resistant survival machinery needed for recovery of yeast cells from severe heat stress.

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Production of a recombinant industrial protein using barley cell cultures

Ritala

Wahlström

Holkeri

et al. 2008

Protein Expression and Purification

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A Phaseolin Domain Involved Directly in Trimer Assembly Is a Determinant for Binding by the Chaperone BiP

Foresti

Frigerio

Holkeri

et al. 2003

THE PLANT CELL ONLINE

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The binding protein (BiP; a member of the heat-shock 70 family) is a major chaperone of the endoplasmic reticulum (ER). Interactions with BiP are believed to inhibit unproductive aggregation of newly synthesized secretory proteins during folding and assembly. In vitro, BiP has a preference for peptide sequences enriched in hydrophobic amino acids, which are expected to be exposed only in folding and assembly intermediates or in defective proteins. However, direct information regarding sequences recognized in vivo by BiP on real proteins is very limited. We have shown previously that newly synthesized monomers of the homotrimeric storage protein phaseolin associate with BiP and that phaseolin trimerization in the ER abolishes such interactions. Using different phaseolin constructs and green fluorescent protein (GFP) fusion proteins, we show here that one of the two ␣ -helical regions of polypeptide contact in phaseolin trimers (35 amino acids located close to the C terminus and containing three potential BiP binding sites) effectively promotes BiP association with phaseolin and with secretory GFP fusions expressed in transgenic tobacco or in transfected protoplasts. We also show that overexpressed BiP transiently sequesters phaseolin polypeptides. We conclude that one of the regions of monomer contact is a BiP binding determinant and suggest that during the synthesis of phaseolin, the association with BiP and trimer formation are competing events. Finally, we show that the other, internal region of contact between monomers is necessary for phaseolin assembly in vivo and contains one potential BiP binding site.

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Different degradation pathways for heterologous glycoproteins in yeast

Holkeri¹,

Makarow²

1998

FEBS Letters

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Rat nerve growth factor receptor ectodomain (NGFR e ) and Escherichia coli L L-lactamase were translocated into the yeast endoplasmic reticulum (ER), glycosylated, misfolded and rapidly degraded. NGFR e underwent ATPdependent thermosensitive degradation independently of vesicular transport. Since no evidence for degradation by the cytoplasmic 26S proteosome complex could be obtained, NGFR e appeared to be degraded in the ER. L L-Lactamase exited the ER by vesicular traffic and was transported from the Golgi via the Vps10 receptor pathway to the vacuole for degradation. Machineries in the ER and the Golgi appear to recognize distinct structural features on misfolded heterologous proteins and guide them to different degradation pathways.z 1998 Federation of European Biochemical Societies.

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Heidi Holkeri

The Hsp70 Homologue Lhs1p Is Involved in a Novel Function of the Yeast Endoplasmic Reticulum, Refolding and Stabilization of Heat-denatured Protein Aggregates

Production of a recombinant industrial protein using barley cell cultures

A Phaseolin Domain Involved Directly in Trimer Assembly Is a Determinant for Binding by the Chaperone BiP

Different degradation pathways for heterologous glycoproteins in yeast

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