The early secretory pathway contributes to autophagy in yeast

Autophagy is a starvation response in eukaryotes by which the cell delivers cytoplasmic components to the vacuole for degradation, and is mediated by a double membrane structure called the autophagosome. We have previously proposed that the specific combination of COPII like components, including Sec24p, is required for autophagy (Ishihara, N. et al. (2001) Mol. Biol. Cell, 12: 3690-3702). The autophagic defect in sec24 deleted mutant cells was, however, suppressed upon the recovery of its secretory flow by the overexpression of its homologue, Sfb2p. We have also reported that the autophagic defect is not observed in sec13 and sec31 mutants, a phenomenon that can be explained by the fact that starvation stress suppresses the secretory defect of these mutants. These observations indicate that the active flow in the early secretory pathway plays an important role in autophagy; that is, autophagy proceeds in the presence, but not in the absence of the early secretory flow. Both autophagy and its closely related cytoplasm to vacuole-targeting (Cvt) pathway occur through a pre-autophagosomal structure (PAS), and since the PAS and the functional Cvt pathway exist in all sec mutants, the early secretory pathway must be involved specifically in autophagy, subsequent to PAS formation.     

A screen for dominant negative mutants of SEC18 reveals a role for the AAA protein consensus sequence in ATP hydrolysis

An evolutionarily ancient mechanism is used for intracellular membrane fusion events ranging from endoplasmic reticulum-Golgi traffic in yeast to synaptic vesicle exocytosis in the human brain. At the heart of this mechanism is the core complex of N-ethylmaleimide-sensitive fusion protein (NSF), soluble NSF attachment proteins (SNAPs), and SNAP receptors (SNAREs). Although these proteins are accepted as key players in vesicular traffic, their molecular mechanisms of action remain unclear. To illuminate important structure-function relationships in NSF, a screen for dominant negative mutants of yeast NSF (Sec18p) was undertaken. This involved random mutagenesis of a GAL1-regulated SEC18 yeast expression plasmid. Several dominant negative alleles were identified on the basis of galactose-inducible growth arrest, of which one, sec18-109, was characterized in detail. The sec18-109 phenotype (abnormal membrane trafficking through the biosynthetic pathway, accumulation of a membranous tubular network, growth suppression, increased cell density) is due to a single A-G substitution in SEC18 resulting in a missense mutation in Sec18p (Thr(394)-->Pro). Thr(394) is conserved in most AAA proteins and indeed forms part of the minimal AAA consensus sequence that serves as a signature of this large protein family. Analysis of recombinant Sec18-109p indicates that the mutation does not prevent hexamerization or interaction with yeast alpha-SNAP (Sec17p), but instead results in undetectable ATPase activity that cannot be stimulated by Sec17p. This suggests a role for the AAA protein consensus sequence in regulating ATP hydrolysis. Furthermore, this approach of screening for dominant negative mutants in yeast can be applied to other conserved proteins so as to highlight important functional domains in their mammalian counterparts.     

Sec24p and Iss1p function interchangeably in transport vesicle formation from the endoplasmic reticulum in Saccharomyces cerevisiae

The Sec23p/Sec24p complex functions as a component of the COPII coat in vesicle transport from the endoplasmic reticulum. Here we characterize Saccharomyces cerevisiae SEC24, which encodes a protein of 926 amino acids (YIL109C), and a close homologue, ISS1 (YNL049C), which is 55% identical to SEC24. SEC24 is essential for vesicular transport in vivo because depletion of Sec24p is lethal, causing exaggeration of the endoplasmic reticulum and a block in the maturation of carboxypeptidase Y. Overproduction of Sec24p suppressed the temperature sensitivity of sec23-2, and overproduction of both Sec24p and Sec23p suppressed the temperature sensitivity of sec16-2. SEC24 gene disruption could be complemented by overexpression of ISS1, indicating functional redundancy between the two homologous proteins. Deletion of ISS1 had no significant effect on growth or secretion; however, iss1Delta mutants were found to be synthetically lethal with mutations in the v-SNARE genes SEC22 and BET1. Moreover, overexpression of ISS1 could suppress mutations in SEC22. These genetic interactions suggest that Iss1p may be specialized for the packaging or the function of COPII v-SNAREs. Iss1p tagged with His(6) at its C terminus copurified with Sec23p. Pure Sec23p/Iss1p could replace Sec23p/Sec24p in the packaging of a soluble cargo molecule (alpha-factor) and v-SNAREs (Sec22p and Bet1p) into COPII vesicles. Abundant proteins in the purified vesicles produced with Sec23p/Iss1p were indistinguishable from those in the regular COPII vesicles produced with Sec23p/Sec24p.     

Human SEC13Rp functions in yeast and is located on transport vesicles budding from the endoplasmic reticulum

In the yeast Saccharomyces cerevisiae, Sec13p is required for intracellular protein transport from the ER to the Golgi apparatus, and has also been identified as a component of the COPII vesicle coat structure. Recently, a human cDNA encoding a protein 53% identical to yeast Sec13p has been isolated. In this report, we apply the genetic assays of complementation and synthetic lethality to demonstrate the conservation of function between this human protein, designated SEC13Rp, and yeast Sec13p. We show that two reciprocal human/yeast fusion constructs, encoding the NH2-terminal half of one protein and the COOH-terminal half of the other, can each complement the secretion defect of a sec13-1 mutant at 36 degrees C. The chimera encoding the NH2-terminal half of the yeast protein and the COOH-terminal half of the human protein is also able to complement a SEC13 deletion. Overexpression of either the entire human SEC13Rp protein or the chimera encoding the NH2-terminal half of the human protein and the COOH-terminal half of the yeast protein inhibits the growth of a sec13- 1 mutant at 24 degrees C; this growth inhibition is not seen in a wild- type strain nor in other sec mutants, suggesting that the NH2-terminal half of SEC13Rp may compete with Sec13-1p for a common target. We show by immunoelectronmicroscopy of mammalian cells that SEC13Rp (like the putative mammalian homologues of the COPII subunits Sar1p and Sec23p) resides in the region of the transitional ER. We also show that the distribution of SEC13Rp is not affected by brefeldin A treatment. This report presents the first demonstration of a putative mammalian COPII component functioning in yeast, and highlights a potentially useful approach for the study of conserved mammalian proteins in a genetically tractable system.     

COPII囊泡衣被蛋白SEC24A在巨自噬通路中的功能研究

细胞自噬是一种重要且保守的细胞内降解过程,通过形成双层膜的自噬体包裹细胞内容物进行降解。内质网来源的COPII囊泡被认为是饥饿诱导的应激过程中自噬体的膜源。探究了COPII囊泡衣被蛋白SEC24A在巨自噬通路中的作用。利用siRNA干扰技术敲低SEC24A的表达,EBSS饥饿处理对照组和SEC24A敲低组HeLa细胞2 h诱导自噬发生,经Western blot和免疫荧光实验检测自噬底物蛋白p62和自噬标志蛋白LC3-II的蛋白水平变化,以确定SEC24A是否参与自噬。通过RFP-GFP-LC3串联荧光检测自噬体和自噬溶酶体的数目,利用蛋白酶K保护实验验证自噬缺陷发生在自噬体闭合之前或者之后,利用免疫荧光实验检测敲低SEC24A对自噬通路上ATG复合物的影响,以确定SEC24A调控自噬通路的位点。通过免疫共沉淀实验验证SEC24A与自噬相关蛋白ATG9A是否存在相互作用。蛋白检测实验发现,饥饿条件下与对照细胞相比,敲低SEC24A细胞内自噬底物蛋白p62积累,而标志蛋白LC3-II减少。RFP-GFP-LC3串联荧光实验显示,敲低SEC24A后自噬体及自噬溶酶体的数目均减少。蛋白酶K保护实验显示,SEC24A敲低细胞中受膜结构保护的p62和GFP-LC3均减少,提示SEC24A作用位点在自噬体闭合之前。免疫荧光实验显示,敲低SEC24A的表达后ATG14L、ATG16L1点状结构减少,而ATG9A点状结构的数量没有明显变化,提示SEC24A作用于ATG14L、ATG16L1上游。免疫共沉淀实验显示SEC24A与ATG9A存在相互作用。研究结果不仅有助于深化对自噬体形成过程和分子机制的了解,也为全面解读COPII囊泡及其衣被蛋白在自噬中的重要作用提供了信息。     

Endoplasmic reticulum exit of a secretory glycoprotein in the absence of sec24p family proteins in yeast

Glycoproteins exit the endoplasmic reticulum (ER) of the yeast Saccharomyces cerevisiae in coat protein complex II (COPII) coated vesicles. The coat consists of the essential proteins Sec23p, Sec24p, Sec13p, Sec31p, Sar1p and Sec16p. Sec24p and its two nonessential homologues Sfb2p and Sfb3p have been suggested to serve in cargo selection. Using temperature-sensitive sec24-1 mutants, we showed previously that a secretory glycoprotein, Hsp150, does not require functional Sec24p for ER exit. Deletion of SFB2, SFB3 or both from wild type or the deletion of SFB2 from sec24-1 cells did not affect Hsp150 transport. SFB3 deletion has been reported to be lethal in sec24-1. However, here we constructed a sec24-1 Deltasfb3 and a sec24-1 Deltasfb2 Deltasfb3 strain and show that Hsp150 was secreted slowly in both. Turning off the SEC24 gene did not inhibit Hsp150 secretion either, and the lack of SEC24 expression in a Deltasfb2 Deltasfb3 deletant still allowed some secretion. The sec24-1 Deltasfb2 Deltasfb3 mutant grew slower than sec24-1. The cells were irregularly shaped, budded from random sites and contained proliferated ER at permissive temperature. At restrictive temperature, the ER formed carmellae-like proliferations. Our data indicate that ER exit may occur in vesicles lacking a full complement of Sec23p/24p and Sec13p/31p, demonstrating diversity in the composition of the COPII coat.     

Sfb2p, a yeast protein related to Sec24p, can function as a constituent of COPII coats required for vesicle budding from the endoplasmic reticulum

The COPII coat is required for vesicle budding from the endoplasmic reticulum (ER), and consists of two heterodimeric subcomplexes, Sec23p/Sec24p, Sec13p/Sec31p, and a small GTPase, Sar1p. We characterized a yeast mutant, anu1 (abnormal nuclear morphology) exhibiting proliferated ER as well as abnormal nuclear morphology at the restrictive temperature. Based on the finding that ANU1 is identical to SEC24, we confirmed a temperature-sensitive protein transport from the ER to the Golgi in anu1-1/sec24-20 cells. Overexpression of SFB2, a SEC24 homologue with 56% identity, partially suppressed not only the mutant phenotype of sec24-20 cells but also rescued the SEC24-disrupted cells. Moreover, the yeast two-hybrid assay revealed that Sfb2p, similarly to Sec24p, interacted with Sec23p. In SEC24-disrupted cells rescued by overexpression of SFB2, some cargo proteins were still retained in the ER, while most of the protein transport was restored. Together, these findings strongly suggest that Sfb2p functions as the component of COPII coats in place of Sec24p, and raise the possibility that each member of the SEC24 family of proteins participates directly and/or indirectly in cargo-recognition events with its own cargo specificity at forming ER-derived vesicles.     

Sec31 encodes an essential component of the COPII coat required for transport vesicle budding from the endoplasmic reticulum.

The COPII vesicle coat protein promotes the formation of endoplasmic reticulum- (ER) derived transport vesicles that carry secretory proteins to the Golgi complex in Saccharomyces cerevisiae. This coat protein consists of Sar1p, the Sec23p protein complex containing Sec23p and Sec24p, and the Sec13p protein complex containing Sec13p and a novel 150-kDa protein, p150. Here, we report the cloning and characterization of the p150 gene. p150 is encoded by an essential gene. Depletion of this protein in vivo blocks the exit of secretory proteins from the ER and causes an elaboration of ER membranes, indicating that p150 is encoded by a SEC gene. Additionally, overproduction of the p150 gene product compromises the growth of two ER to Golgi sec mutants: sec16-2 and sec23-1. p150 is encoded by SEC31, a gene isolated in a genetic screen for mutations that accumulate unprocessed forms of the secretory protein alpha-factor. The sec31-1 mutation was mapped by gap repair, and sequence analysis revealed an alanine to valine change at position 1239, near the carboxyl terminus. Sec31p is a phosphoprotein and treatment of the Sec31p-containing fraction with alkaline phosphatase results in a 50-75% inhibition of transport vesicle formation activity in an ER membrane budding assay.     

Membrane Delivery to the Yeast Autophagosome from the Golgi�CEndosomal System

While many of the proteins required for autophagy have been identified, the source of the membrane of the autophagosome is still unresolved with the endoplasmic reticulum (ER), endosomes, and mitochondria all having been evoked. The integral membrane protein Atg9 is delivered to the autophagosome during starvation and in the related cytoplasm-to-vacuole (Cvt) pathway that occurs constitutively in yeast. We have examined the requirements for delivery of Atg9-containing membrane to the yeast autophagosome. Atg9 does not appear to originate from mitochondria, and Atg9 cannot reach the forming autophagosome directly from the ER or early Golgi. Components of traffic between Golgi and endosomes are known to be required for the Cvt pathway but do not appear required for autophagy in starved cells. However, we find that pairwise combinations of mutations in Golgi-endosomal traffic components apparently only required for the Cvt pathway can cause profound defects in Atg9 delivery and autophagy in starved cells. Thus it appears that membrane that contains Atg9 is delivered to the autophagosome from the Golgi-endosomal system rather than from the ER or mitochondria. This is underestimated by examination of single mutants, providing a possible explanation for discrepancies between yeast and mammalian studies on Atg9 localization and autophagosome formation.     

The Atg17-Atg31-Atg29 complex and Atg11 regulate autophagosome-vacuole fusion

The macroautophagy (hereafter autophagy) process involves de novo formation of double-membrane autophagosomes; after sequestering cytoplasm these transient organelles fuse with the vacuole/lysosome. Genetic studies in yeasts have characterized more than 40 autophagy-related (Atg) proteins required for autophagy, and the majority of these proteins play roles in autophagosome formation. The fusion of autophagosomes with the vacuole is mediated by the Rab GTPase Ypt7, its guanine nucleotide exchange factor Mon1-Ccz1, and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins. However, these factors are not autophagosome-vacuole fusion specific. We recently showed that 2 autophagy scaffold proteins, the Atg17-Atg31-Atg29 complex and Atg11, regulate autophagosome-vacuole fusion by recruiting the vacuolar SNARE Vam7 to the phagophore assembly site (PAS), where an autophagosome forms in yeast.     

Evidence for overlapping and distinct functions in protein transport of coat protein Sec24p family members

Budding of transport vesicles from the endoplasmic reticulum in yeast requires the formation, at the budding site, of a coat protein complex (COPII) that consists of two heterodimeric subcomplexes (Sec23p/Sec24p and Sec13p/Sec31p) and the Sar1 GTPase. Sec24p is an essential protein and involved in cargo selection. In addition to Sec24p, the yeast Saccharomyces cerevisiae expresses two non-essential Sec24p-related proteins, termed Sfb2p (product of YNL049c) and Sfb3p/Lst1p (product of YHR098c). We here show that Sfb2p and, less efficiently, Sfb3p/Lst1p are able to bind, like Sec24p, the integral membrane cargo protein Sed5p. We also demonstrate that Sfb2p, like Sec24p and Sfb3p/Lst1p, forms a complex with Sec23p in vivo. Whereas the deletion of SFB2 did not affect transport kinetics of various proteins, the maturation of the glycolipid-anchored plasma membrane protein Gas1p was differentially impaired in sfb3 knock-out cells. We generated several conditional-lethal sec24 mutants that, combined with null alleles of SFB2 and SFB3/LST1, led to a complete block of transport between the endoplasmic reticulum and the Golgi (sec24-11/Deltasfb2) or to cell death (sec24-11/Deltasfb3). Of the Sec24p family members, Sfb2p is the least abundant at steady state, but high intracellular concentrations of Sfb2p can rescue sec24 mutants under restrictive conditions. The data presented strongly suggest that the Sec24p-related proteins function as COPII components.     

Sec2 protein contains a coiled-coil domain essential for vesicular transport and a dispensable carboxy terminal domain

SEC2 function is required at the post-Golgi apparatus stage of the yeast secretory pathway. The SEC2 sequence encodes a protein product of 759 amino acids containing an amino terminal region that is predicted to be in an alpha-helical, coiled-coil conformation. Two temperature-sensitive alleles, sec2-41 and sec2-59, encode proteins truncated by opal stop codons and are suppressible by an opal tRNA suppressor. Deletion analysis indicates that removal of the carboxyl terminal 251 amino acids has no apparent phenotype, while truncation of 368 amino acids causes temperature sensitivity. The amino terminal half of the protein, containing the putative coiled-coil domain, is essential at all temperatures. Sec2 protein is found predominantly in the soluble fraction and displays a native molecular mass of greater than 500 kD. All phenotypes of the temperature-sensitive sec2 alleles are partially suppressed by duplication of the SEC4 gene, but the lethality of a sec2 disruption is not suppressed. The sec2-41 mutation exhibits synthetic lethality with the same subset of the late acting sec mutants as does sec4-8 and sec15-1. The Sec2 protein may function in conjunction with the Sec4 and Sec15 proteins to control vesicular traffic.     

Apg2 is a novel protein required for the cytoplasm to vacuole targeting, autophagy, and pexophagy pathways

To survive starvation conditions, eukaryotes have developed an evolutionarily conserved process, termed autophagy, by which the vacuole/lysosome mediates the turnover and recycling of non-essential intracellular material for re-use in critical biosynthetic reactions. Morphological and biochemical studies in Saccharomyces cerevisiae have elucidated the basic steps and mechanisms of the autophagy pathway. Although it is a degradative process, autophagy shows substantial overlap with the biosynthetic cytoplasm to vacuole targeting (Cvt) pathway that delivers resident hydrolases to the vacuole. Recent molecular genetics analyses of mutants defective in autophagy and the Cvt pathway, apg, aut, and cvt, have begun to identify the protein machinery and provide a molecular resolution of the sequestration and import mechanism that are characteristic of these pathways. In this study, we have identified a novel protein, termed Apg2, required for both the Cvt and autophagy pathways as well as the specific degradation of peroxisomes. Apg2 is required for the formation and/or completion of cytosolic sequestering vesicles that are needed for vacuolar import through both the Cvt pathway and autophagy. Biochemical studies revealed that Apg2 is a peripheral membrane protein. Apg2 localizes to the previously identified perivacuolar compartment that contains Apg9, the only characterized integral membrane protein that is required for autophagosome/Cvt vesicle formation.     

Analysis of Sec22p in endoplasmic reticulum/Golgi transport reveals cellular redundancy in SNARE protein function

Membrane-bound soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins form heteromeric complexes that are required for intracellular membrane fusion and are proposed to encode compartmental specificity. In yeast, the R-SNARE protein Sec22p acts in transport between the endoplasmic reticulum (ER) and Golgi compartments but is not essential for cell growth. Other SNARE proteins that function in association with Sec22p (i.e., Sed5p, Bos1p, and Bet1p) are essential, leading us to question how transport through the early secretory pathway is sustained in the absence of Sec22p. In wild-type strains, we show that Sec22p is directly required for fusion of ER-derived vesicles with Golgi acceptor membranes. In sec22Delta strains, Ykt6p, a related R-SNARE protein that operates in later stages of the secretory pathway, is up-regulated and functionally substitutes for Sec22p. In vivo combination of the sec22Delta mutation with a conditional ykt6-1 allele results in lethality, consistent with a redundant mechanism. Our data indicate that the requirements for specific SNARE proteins in intracellular membrane fusion are less stringent than appreciated and suggest that combinatorial mechanisms using both upstream-targeting elements and SNARE proteins are required to maintain an essential level of compartmental organization.     

LST1 is a SEC24 homologue used for selective export of the plasma membrane ATPase from the endoplasmic reticulum.

In Saccharomyces cerevisiae, vesicles that carry proteins from the ER to the Golgi compartment are encapsulated by COPII coat proteins. We identified mutations in ten genes, designated LST (lethal with sec-thirteen), that were lethal in combination with the COPII mutation sec13-1. LST1 showed synthetic-lethal interactions with the complete set of COPII genes, indicating that LST1 encodes a new COPII function. LST1 codes for a protein similar in sequence to the COPII subunit Sec24p. Like Sec24p, Lst1p is a peripheral ER membrane protein that binds to the COPII subunit Sec23p. Chromosomal deletion of LST1 is not lethal, but inhibits transport of the plasma membrane proton-ATPase (Pma1p) to the cell surface, causing poor growth on media of low pH. Localization by both immunofluorescence microscopy and cell fractionation shows that the export of Pma1p from the ER is impaired in lst1Delta mutants. Transport of other proteins from the ER was not affected by lst1Delta, nor was Pma1p transport found to be particularly sensitive to other COPII defects. Together, these findings suggest that a specialized form of the COPII coat subunit, with Lst1p in place of Sec24p, is used for the efficient packaging of Pma1p into vesicles derived from the ER.     

Remodeling of ER‐exit sites initiates a membrane supply pathway for autophagosome biogenesis

Autophagosomes are double‐membrane vesicles generated during autophagy. Biogenesis of the autophagosome requires membrane acquisition from intracellular compartments, the mechanisms of which are unclear. We previously found that a relocation of COPII machinery to the ER–Golgi intermediate compartment (ERGIC) generates ERGIC‐derived COPII vesicles which serve as a membrane precursor for the lipidation of LC3, a key membrane component of the autophagosome. Here we employed super‐resolution microscopy to show that starvation induces the enlargement of ER‐exit sites (ERES) positive for the COPII activator, SEC12, and the remodeled ERES patches along the ERGIC. A SEC12 binding protein, CTAGE5, is required for the enlargement of ERES, SEC12 relocation to the ERGIC, and modulates autophagosome biogenesis. Moreover, FIP200, a subunit of the ULK protein kinase complex, facilitates the starvation‐induced enlargement of ERES independent of the other subunits of this complex and associates via its C‐terminal domain with SEC12. Our data indicate a pathway wherein FIP200 and CTAGE5 facilitate starvation‐induced remodeling of the ERES, a prerequisite for the production of COPII vesicles budded from the ERGIC that contribute to autophagosome formation.     

Engineering of vesicle trafficking improves heterologous protein secretion in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is a widely used platform for the production of heterologous proteins of medical or industrial interest. However, heterologous protein productivity is often restricted due to the limitations of the host strain. In the protein secretory pathway, the protein trafficking between different organelles is catalyzed by the soluble NSF (N-ethylmaleimide-sensitive factor) receptor (SNARE) complex and regulated by the Sec1/Munc18 (SM) proteins. In this study, we report that over-expression of the SM protein encoding genes SEC1 and SLY1, improves the protein secretion in S. cerevisiae. Engineering Sec1p, the SM protein that is involved in vesicle trafficking from Golgi to cell membrane, improves the secretion of heterologous proteins human insulin precursor and α-amylase, and also the secretion of an endogenous protein invertase. Enhancing Sly1p, the SM protein regulating the vesicle fusion from endoplasmic reticulum (ER) to Golgi, increases α-amylase production only. Our study demonstrates that strengthening the protein trafficking in ER-to-Golgi and Golgi-to-plasma membrane process is a novel secretory engineering strategy for improving heterologous protein production in S. cerevisiae.     

Human ARF4 expression rescues sec7 mutant yeast cells.

Vesicle-mediated traffic between compartments of the yeast secretory pathway involves recruitment of multiple cytosolic proteins for budding, targeting, and membrane fusion events. The SEC7 gene product (Sec7p) is a constituent of coat structures on transport vesicles en route to the Golgi complex in the yeast Saccharomyces cerevisiae. To identify mammalian homologs of Sec7p and its interacting proteins, we used a genetic selection strategy in which a human HepG2 cDNA library was transformed into conditional-lethal yeast sec7 mutants. We isolated several clones capable of rescuing sec7 mutant growth at the restrictive temperature. The cDNA encoding the most effective suppressor was identified as human ADP ribosylation factor 4 (hARF4), a member of the GTPase family proposed to regulate recruitment of vesicle coat proteins in mammalian cells. Having identified a Sec7p-interacting protein rather than the mammalian Sec7p homolog, we provide evidence that hARF4 suppressed the sec7 mutation by restoring secretory pathway function. Shifting sec7 strains to the restrictive temperature results in the disappearance of the mutant Sec7p cytosolic pool without apparent changes in the membrane-associated fraction. The introduction of hARF4 to the cells maintained the balance between cytosolic and membrane-associated Sec7p pools. These results suggest a requirement for Sec7p cycling on and off of the membranes for cell growth and vesicular traffic. In addition, overexpression of the yeast GTPase-encoding genes ARF1 and ARF2, but not that of YPT1, suppressed the sec7 mutant growth phenotype in an allele-specific manner. This allele specificity indicates that individual ARFs are recruited to perform two different Sec7p-related functions in vesicle coat dynamics.     

Characterization of a novel autophagy-specific gene, ATG29

Autophagy is a process whereby cytoplasmic proteins and organelles are sequestered for bulk degradation in the vacuole/lysosome. At present, 16 ATG genes have been found that are essential for autophagosome formation in the yeast Saccharomyces cerevisiae. Most of these genes are also involved in the cytoplasm to vacuole transport pathway, which shares machinery with autophagy. Most Atg proteins are colocalized at the pre-autophagosomal structure (PAS), from which the autophagosome is thought to originate, but the precise mechanism of autophagy remains poorly understood. During a genetic screen aimed to obtain novel gene(s) required for autophagy, we identified a novel ORF, ATG29/YPL166w. atg29Delta cells were sensitive to starvation and induction of autophagy was severely retarded. However, the Cvt pathway operated normally. Therefore, ATG29 is an ATG gene specifically required for autophagy. Additionally, an Atg29-GFP fusion protein was observed to localize to the PAS. From these results, we propose that Atg29 functions in autophagosome formation at the PAS in collaboration with other Atg proteins.