A role for the DnaJ homologue Scj1p in protein folding in the yeast endoplasmic reticulum

Members of the eukaryotic heat shock protein 70 family (Hsp70s) are regulated by protein cofactors that contain domains homologous to bacterial DnaJ. Of the three DnaJ homologues in the yeast rough endoplasmic reticulum (RER; Scj1p, Sec63p, and Jem1p), Scj1p is most closely related to DnaJ, hence it is a probable cofactor for Kar2p, the major Hsp70 in the yeast RER. However, the physiological role of Scj1p has remained obscure due to the lack of an obvious defect in Kar2p-mediated pathways in scj1 null mutants. Here, we show that the Deltascj1 mutant is hypersensitive to tunicamycin or mutations that reduce N-linked glycosylation of proteins. Although maturation of glycosylated carboxypeptidase Y occurs with wild-type kinetics in Deltascj1 cells, the transport rate for an unglycosylated mutant carboxypeptidase Y (CPY) is markedly reduced. Loss of Scj1p induces the unfolded protein response pathway, and results in a cell wall defect when combined with an oligosaccharyltransferase mutation. The combined loss of both Scj1p and Jem1p exaggerates the sensitivity to hypoglycosylation stress, leads to further induction of the unfolded protein response pathway, and drastically delays maturation of an unglycosylated reporter protein in the RER. We propose that the major role for Scj1p is to cooperate with Kar2p to mediate maturation of proteins in the RER lumen

Ribonucleoparticle-independent transport of proteins into mammalian microsomes

There are at least two different mechanisms for the transport of secretory proteins into the mammalian endoplasmic reticulum. Both mechanisms depend on the presence of a signal peptide on the respective precursor protein and involve a signal peptide receptor on the cis-side and signal peptidase on the trans-side of the membrane. Furthermore, both mechanisms involve a membrane component with a cytoplasmically exposed sulfhydryl. The decisive feature of the precursor protein with respect to which of the two mechanisms is used is the chain length of the polypeptide. The critical size seems to be around 70 amino acid residues (including the signal peptide). The one mechanism is used by precursor proteins larger than about 70 amino acid residues and involves two cytosolic ribonucleoparticles and their receptors on the microsomal surface. The other one is used by small precursor proteins and relies on the mature part within the precursor molecule and a cytosolic ATPase

Nuclear Import of Ho Endonuclease Utilizes Two Nuclear Localization Signals and Four Importins of the Ribosomal Import System *

Activity of Ho, the yeast mating switch endonuclease, is restricted to a narrow time window of the cell cycle. Ho is unstable and despite being a nuclear protein is exported to the cytoplasm for proteasomal degradation. We report here the molecular basis for the highly efficient nuclear import of Ho and the relation between its short half-life and passage through the nucleus. The Ho nuclear import machinery is functionally redundant, being based on two bipartite nuclear localization signals, recognized by four importins of the ribosomal import system. Ho degradation is regulated by the DNA damage response and Ho retained in the cytoplasm is stabilized, implying that Ho acquires its crucial degradation signals in the nucleus. Ho arose by domestication of a fungal VMA1 intein. A comparison of the primary sequences of Ho and fungal VMA1 inteins shows that the Ho nuclear localization signals are highly conserved in all Ho proteins, but are absent from VMA1 inteins. Thus adoption of a highly efficient import strategy occurred very early in the evolution of Ho. This may have been a crucial factor in establishment of homothallism in yeast, and a key event in the rise of the Saccharomyces sensu stricto. Ho endonuclease initiates a mating type switch in Saccharomyces cerevisiae and related yeasts by making a site-specific double strand break in a 24-bp cognate site in the mating type gene, MAT. Repair of the double strand break is by gene conversion using one of the silent cassettes of mating type information (HML␣ or HMRa) as a template. Repair occurs before replication of the MAT locus and each daughter cell has the new mating type with a regenerated Ho cognate site (1). Ho activity is tightly regulated: HO is transcribed briefly at the end of G 1 , its transcription is restricted to haploid mother cells, i.e. cells that have divided at least once (2), and the protein is rapidly degraded by the ubiquitin-26 S proteasome system (3). Cells in which Ho is retained in the nucleus beyond its normal time window of activity show perturbation of the cell cycle (4). Ho is marked for degradation by functions of the DNA damage response (DDR), 7 specifically the MEC1, RAD9, and CHK1 pathway (5). Despite being a nuclear protein, Ho must exit the nucleus to be degraded in the proteasomes. The DDR functions are important for Ho phosphorylation: phosphorylation of threonine 225 is crucial for Ho nuclear export and additional phosphorylations are required for recruitment of Ho for ubiquitylation. Ho is ubiquitylated by the SCF (Skp1-Cdc53-F-box protein) E3 ubiquitin ligase complex, to which it is recruited by the F-box protein Ufo1 (6). In mec1 mutants Ho is stabilized and accumulates in the nucleus; conversely trapping Ho in the nucleus by deletion of its nuclear exportin, Msn5, leads to stabilization of the protein (4). Ddi1 binds ubiquitylated Ho and is required for interaction of Ho with the proteasome; in its absence Ho is stabilized. The finding that Ho is not degraded within the nucleus, but in the cytoplasm, is further strengthened by the direct demonstration of accumulation of ubiquitylated Ho in the cytoplasm of ⌬ddi1 mutants (7). Ho nuclear import is very rapid and efficient. Ectopic expression of HO leads to rapid cleavage of MAT (8), and to a mating type switch at any phase of the cell cycle in both mother and daughter cells. This indicates that there is no impediment to its nuclear import (9). Macromolecules are conveyed through nuclear pore complexes in the nuclear envelope by soluble karyopherins. Karyopherins comprise two structurally related families, ␣-and ␤-karyopherins. These recognize specific nuclear localization sequence (NLS) peptide motifs in the cargo molecule: NLSs may comprise a short stretch of basic residues (classical/ cNLS), or two basic clusters 10 -12 residues apart (bipartite NLS) (10). Cargoes may be recognized by an adaptor protein, ␣-karyopherin/Srp1, which mediates their binding to the transport receptor, ␤-karyopherin/ Kap95 (11). Additionally, a family of about 14 ␤-karyopherins bind an array of cargoes directly and also makes contacts with the nucleoporin subunits of the nuclear pore complexes. Directionality of transport is determined by interaction with the GTPase Ran/yeast Gsp1. RanGTP is at a high concentration in the nucleus due to the asymmetric distribution of the Ran regulators. The nuclear guanine nucleotide exchange factor, RanGEF/yeast Prp20, converts RanGDP to RanGTP, whereas the GTPase activating protein, RanGAP/yeast Rna1, is localized in the cytoplasm and catalyzes the hydrolysis of RanGTP. Importin-cargo complexes assemble in the cytoplasm and after translocation into the nucleus they dissociate upon binding of RanGTP to the importin (12). To investigate how the efficient nuclear import that supports the unique biological function of Ho is achieved we located and analyzed its nuclea

Schlenstedt G: The histones H2A/H2B and H3/H4 are imported into the yeast nucleus by different mechanisms

Proteins are imported from the cytoplasm into the nucleus by importin b-related transport receptors. The yeast Saccharomyces cerevisiae contains ten of these importins, but only two of them are essential. After transfer through the nuclear pore, importins release their cargo upon binding to the Ran GTPase, the key regulator of nuclear transport. We investigated the import of the core histones in yeast and found that four importins are involved. The essential Pse1p and the nonessential importins Kap114p, Kap104p, and Yrb4p/Kap123p specifically bind to histones H2A and H2B. Release of H2 histones from importins requires Ran-GTP and DNA simultaneously suggesting a function of the importins in intranuclear targeting. H3 and H4 associate mainly with Pse1p and the dissociation requires Ran but not DNA, which points to a different import mechanism. Import of green fluorescent protein fusions to H2A and H2B requires primarily Pse1p and Kap114p, whereas Yrb4p plays an auxiliary role. Pse1p is predominantly necessary for nuclear uptake of H3 and H4, while Kap104p and Yrb4p also support import. We conclude from our in vivo and in vitro experiments that import of the essential histones is mediated mainly by the essential importin Pse1p, while the non-essential Kap114p functions in a parallel import pathway for H2A and H2B

Kap120 Functions as a Nuclear Import Receptor for Ribosome Assembly Factor Rpf1 in Yeast

The nucleocytoplasmic exchange of macromolecules is mediated by receptors specialized in passage through the nuclear pore complex. The majority of these receptors belong to the importin β protein family, which has 14 members in Saccharomyces cerevisiae. Nine importins carry various cargos from the cytoplasm into the nucleus, whereas four exportins mediate nuclear export. Kap120 is the only receptor whose transport cargo has not been found previously. Here, we characterize Kap120 as an importin for the ribosome maturation factor Rpf1, which was identified in a two-hybrid screen. Kap120 binds directly to Rpf1 in vitro and is released by Ran-GTP. At least three parallel import pathways exist for Rpf1, since nuclear import is defective in strains with the importins Kap120, Kap114, and Nmd5 deleted. Both kap120 and rpf1 mutants accumulate large ribosomal subunits in the nucleus. The nuclear accumulation of 60S ribosomal subunits in kap120 mutants is abolished upon RPF1 overexpression, indicating that Kap120 does not function in the actual ribosomal export step but rather in import of ribosome maturation factors

Nup2p, a Yeast Nucleoporin, Functions in Bidirectional Transport of Importin α

Import of proteins containing a classical nuclear localization signal (NLS) into the nucleus is mediated by importin α and importin β. Srp1p, the Saccharomyces cerevisiae homologue of importin α, returns from the nucleus in a complex with its export factor Cse1p and with Gsp1p (yeast Ran) in its GTP-bound state. We studied the role of the nucleoporin Nup2p in the transport cycle of Srp1p. Cells lacking NUP2 show a specific defect in both NLS import and Srp1p export, indicating that Nup2p is required for efficient bidirectional transport of Srp1p across the nuclear pore complex (NPC). Nup2p is located at the nuclear side of the central gated channel of the NPC and provides a binding site for Srp1p via its amino-terminal domain. We show that Nup2p effectively releases the NLS protein from importin α-importin and β and strongly binds to the importin heterodimer via Srp1p. Kap95p (importin β) is released from this complex by a direct interaction with Gsp1p-GTP. These data suggest that besides Gsp1p, which disassembles the NLS-importin α-importin β complex upon binding to Kap95p in the nucleus, Nup2p can also dissociate the import complex by binding to Srp1p. We also show data indicating that Nup1p, a relative of Nup2p, plays a similar role in termination of NLS import. Cse1p and Gsp1p-GTP release Srp1p from Nup2p, which suggests that the Srp1p export complex can be formed directly at the NPC. The changed distribution of Cse1p at the NPC in nup2 mutants also supports a role for Nup2p in Srp1p export from the nucleus