Macroautophagy Is Required for Multicellular Development of the Social Amoeba Dictyostelium discoideum*

Grant P. OttoDagger , Mary Y. WuDagger , Nevzat KazganDagger , O. Roger Anderson§, and Richard H. KessinDagger

From the Dagger  Department of Anatomy and Cell Biology, Columbia University, New York, New York 10032 and § Department of Biology, Lamont-Doherty Earth Observatory, Columbia University, Palisades, New York 10964

Received for publication, December 6, 2002, and in revised form, January 22, 2003

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Macroautophagy is a mechanism employed by eukaryotic cells to recycle non-essential cellular components during starvation, differentiation, and development. Two conjugation reactions related to ubiquitination are essential for autophagy: Apg12p conjugation to Apg5p, and Apg8p conjugation to the lipid phosphatidylethanolamine. These reactions require the action of the E1-like enzyme, Apg7p, and the E2-like enzymes, Apg3p and Apg10p. In Dictyostelium, development is induced by starvation, conditions under which autophagy is required for survival in yeast and plants. We have identified Dictyostelium homologues of 10 budding yeast autophagy genes. We have generated mutations in apg5 and apg7 that produce defects typically associated with an abrogation of autophagy. Mutants are not grossly affected in growth, but survival during nitrogen starvation is severely reduced. Starved mutant cells show little turnover of cellular constituents by electron microscopy, whereas wild-type cells show significant cytoplasmic degradation and reduced organelle number. Bulk protein degradation during starvation-induced development is reduced in the autophagy mutants. Development is aberrant; the autophagy mutants do not aggregate in plaques on bacterial lawns, but they do proceed further in development on nitrocellulose filters, forming defective fruiting bodies. The autophagy mutations are cell autonomous, because wild-type cells in a chimaera do not rescue development of the autophagy mutants. We have complemented the mutant phenotypes by expression of the cognate gene fused to green fluorescent protein. A green fluorescent protein fusion of the autophagosome marker Apg8 mislocalizes in the two autophagy mutants. We show that the Apg5-Apg12 conjugation system is conserved in Dictyostelium.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Protein turnover in eukaryotes is accomplished by two major mechanisms, autophagy or proteasomal degradation. Three modes of autophagy have been identified: chaperone-mediated autophagy, microautophagy, and macroautophagy. In chaperone-mediated autophagy, specific proteins containing targeting sequences are bound by chaperones that mediate direct transport across the lysosomal membrane (1). A lysosomal receptor, lysosomal-associated membrane protein type 2a, interacts with the substrate to facilitate transport into the lysosome (2, 3). Microautophagy is required for basal protein degradation in rat liver (4) or glucose-induced peroxisome degradation in the methylotropic yeast Pichia pastoris (5) and involves vacuolar membrane invagination to capture cargo directly. Macroautophagy is a non-selective mechanism used to deliver cytoplasmic components, including entire organelles, to the lysosome or vacuole during starvation (reviewed in Ref. 6). Initially, a membrane distinct from the vacuole/lysosome encloses a portion of cytoplasm to form a double-membraned vesicle called an autophagosome or autophagic vacuole. The autophagosome docks at and fuses with the vacuole/lysosome, releasing a single-membraned vesicle called an autophagic body, which is degraded by resident hydrolases. Molecular genetic analysis in the budding yeast, Saccharomyces cerevisiae, has identified many of the genes that are required for autophagy (7-9). These genes are required for phosphorylation reactions (10), a phosphatidylinositol 3-kinase complex (11, 12), and two novel ubiquitin-like conjugation reactions (13, 14). Starvation releases the repression of autophagy by the target of rapamycin (Tor)1 protein kinase, leading to the activation of another serine/threonine kinase, Apg1p, which activates autophagy through unknown downstream targets (15). Apg1p kinase activity is regulated by the phosphorylation status of a binding partner, Apg13; hyperphosphorylated Apg13p associates weakly with Apg1p. Upon Tor inactivation, Apg13p is dephosphorylated and binds more tightly to and activates Apg1p.

Autophagosome formation also requires the activity of two protein conjugation systems mechanistically related to ubiquitination. In the first, the carboxyl-terminal glycine of Apg12p is conjugated to an internal lysine of Apg5p, through the action of E1-like and E2-like enzymes, Apg7p and Apg10p, respectively (16-18). Apg16p binds to Apg5p and then oligomerizes to produce Apg12p-Apg5p·Apg16p oligomers (19, 20). A second conjugation system involves the conjugation of Apg8p/Aut7p to the membrane lipid phosphatidylethanolamine (14, 21), through the action of the E1-like and E2-like enzymes, Apg7p and Apg3p/Aut1p, respectively (22). Apg8p/Aut7p is the only component of the autophagy machinery in yeast that is transcriptionally up-regulated upon starvation (23).

Dictyostelium discoideum is a soil amoeba that feeds on bacteria but upon starvation completes a complex developmental cycle to produce a multicellular organism (reviewed in Ref. 24). Starving amoebae aggregate using a cyclic AMP signaling relay to form mounds of about 100,000 cells. The mound undergoes morphogenesis to produce a mature fruiting body composed of a sphere of spores held aloft a cellular stalk. To complete development and construct a fruiting body, Dictyostelium needs to mobilize resources allotted previously to growth. We reasoned therefore that autophagy would be important for Dictyostelium development. Additionally, given its genetic tractability, we believe that Dictyostelium is a good organism to extend the observations on autophagy made in budding yeast, plants, and mammalian cells and to ask questions about the control of autophagy during development. We find that apg5 and apg7 are essential for Dictyostelium development. Mutants disrupted in these genes do not aggregate on agar plates cleared of Klebsiella pneumoniae, as the wild-type parents do, but will aggregate if starved on nitrocellulose filters or non-nutrient agar. The autophagy mutants have no evident growth defects but die rapidly when starved of amino acids. Protein turnover, which is normally induced by starvation, is reduced in apg5- and apg7-. GFP fusions of Apg5 and Apg12 are present in two forms in growing and starving cells, corresponding to free and conjugated forms, implying similar conjugation reactions to those discovered in budding yeast. We also examine the subcellular localization of a GFP fusion of Apg8 in Dictyostelium and show the effects of autophagy on the ultrastructural organization of cells during starvation.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Strains-- All mutations were created in the strain DH1, which is a uracil auxotroph. All strains were grown in HL5 medium or on lawns of K. pneumoniae (25).

Development-- For multicellular development, axenically grown cells in mid-log phase (2-4 × 106 cells/ml) were washed twice in cold Sorensen C (SorC) buffer (16.7 mM Na2H/KH2PO4, 50 µM CaCl2, pH 6.0). The cells were resuspended in SorC buffer and plated on 25-mm, 0.45 µM nitrocellulose filters (Millipore Corp.), which rested on SorC-soaked Whatman grade 17 filter pads, at a density of 3.3 × 106 cells/cm2 or 1.6 × 107 cells/filter (25). For development on non-nutrient agar, cells were resuspended at 107 cells/ml, and 100 µl of these cells were plated on 35-mm SorC-1% Phytagel (Sigma) agar plates and allowed to dry.

Identification of D. discoideum Autophagy Genes-- Dictyostelium orthologues of budding yeast autophagy genes were identified by searching the partial Dictyostelium genome sequence at dicty.sdsc.edu/ with the S. cerevisiae amino acid sequence. This super computer at the University of San Diego, La Jolla, CA contains sequence data from all the members of the Dictyostelium Genome sequencing consortium. These include the Institute of Biochemistry I, Cologne, Germany, the Genome Sequencing Centre, Jena, Germany, the Baylor College of Medicine Dictyostelium Genome Center, and the Sanger Centre Dictyostelium Project. Sequence data obtained from the Genome Sequencing Centre, Jena are available at genome.imb-jena.de/dictyostelium. The sequence data produced by the D. discoideum Genome Project at the Sanger Centre can be obtained from ftp.sanger.ac.uk/pub/databases/D.discoideum_sequences/. Where contigs were not available, we assembled individual reads into contiguous sequences. The locations of intron/exon boundaries were inferred from sequence homology to the consensus splice donor and acceptor sites in Dictyostelium (26), by the AT richness of introns in D. discoideum, and by identifying fusions that maintained a single open reading frame.

Gene Disruption-- The complete apg5 gene was obtained by PCR reactions with primers 5-1A (ATGTCATCATTTGACGAAGAT) and 5-1B (ATCGATGGGTATGATTGGAAATGAACA) to generate the 5' region, and 5-2A (ATCGATTGATAGAATACTATTATGTTG) and 5-2B (CCTTAGTAGTTATTGCTATTA) to generate the 3' region. A ClaI site was generated in the PCR product by inclusion of appropriate sequence in the primers. The PCR products were ligated into pCR2.1-TOPO (Invitrogen). The blasticidin resistance cassette was removed from pBSR519 with ClaI and cloned into the generated ClaI site of the apg5 PCR product. The complete apg7 gene was obtained by PCR reactions with primers 7-1A (ATGACAAATACACTTCAGTTT) and 7-1B (GTCGACTGGTAATGAACATGGATCAC) to generate the 5' region, and 7-2A (GTCGACTTAAATCCAGGTTGGCCTTT) and 7-2B (AACGATAATTGTAAAAATAGAGA) to generate the 3' region. The PCR products were ligated into pGEM-T Easy (Promega). The blasticidin resistance cassette was removed from pBSR519 with BamHI and cloned into the BamHI site of the apg7 gene. These two plasmids, composed of the entire apg5 or apg7 gene interrupted by insertion of the selectable blasticidin resistance cassette, constitute the knockout constructs. The knockout constructs were linearized with ApaI prior to electroporation into DH1 cells by the method of Kuspa and Loomis (27). Transformants were selected with the drug blasticidin (5 µg/ml) in HL5 medium for 1 week. Transformants were harvested from Petri dishes and plated onto SM plates, and clones of mutant or wild-type phenotype were selected for further analysis. Homologous recombination of the knockout construct with the endogenous locus was confirmed by PCR or by Southern blot.

Expression Analysis-- Northern blot analysis was conducted as described previously (28), except that Nytran membrane (Schleicher & Schuell) was used to immobilize RNA. Cells were deposited on nitrocellulose filters for development, and a filter was harvested every 4 h for RNA extraction. 5-µg total RNA of wild-type or mutant cells was glyoxylated, size-fractionated on 1% agarose gels, transferred to nitrocellulose, and hybridized with random primer-labeled DNA probes. Probes were obtained by isolation of appropriate restriction fragments following separation on low melting temperature agarose gels.

GFP Fusion Constructs-- GFP fusions were produced by cloning the full-length genomic sequence of each gene (generated by PCR) into the pTX-GFP vector (29), a plasmid in which the expression of the gene of interest is under the control of the constitutive actin15 promoter. Isolation of the apg7 sequence was described earlier (see "Gene Disruption"). The apg5 gene was obtained by PCR with the primers 5-5GFP (GGTACCATGTCATCATTTGACGAAGA) and 5-3GFP (GGTACCGTAGTTATTGCTATTATTAT). The apg8 gene was obtained with the primers 8-5GFP (GAGCTCATGGTTCATGTATCAAGCTT) and 8-2 (GGCAAACTATTATTGTTTGGA). The apg12 gene was obtained with the primers 12-1 (TTAACC CCACGCCATTTGAA) and 12-3 (ATGGAGGAAGAAGAAAAAAA). PCR products were cloned into pGEM-T Easy (Promega). The apg5 sequence was cut from pGEM-T Easy with KpnI and ligated into KpnI-digested, dephosphorylated pTX-GFP. The apg8 sequence was cut from pGEM-T Easy with SacI and ligated into SacI-digested, dephosphorylated pTX-GFP. The apg7 and apg12 sequences were cut from pGEM-T Easy with NcoI and SacI and ligated into XbaI/SacI-digested pTX-GFP, along with a linker composed of the following two oligonucleotides: CATGGTGCATTGACGTAGCT and CTAGAGCTACGTCAATGCAC. This linker provides compatible cohesive ends for XbaI and NcoI sites. The linker oligonucleotides were annealed, and the ends were phosphorylated with T4 polynucleotide kinase and then purified with a Sephadex G50 column (Amersham Biosciences). The correct orientation of the inserts was confirmed by sequencing of the junctions with the primers pTX-Sac5' (GAGTTTGTAACAGCTGCTGG), pTX-Kpn5' (ATCAGATCCAAGCTTAAAAA), and pTX-Kpn3' (TTCACCCTCTCCACTGACAG) where appropriate. GFP fusion constructs were electroporated into DH1 cells and autophagy mutants, and transformants were selected with the drug G418 (5 µg/ml) in HL5 medium for 1 week. Transformants were harvested from Petri dishes and plated onto SM+G418 (40 µg/ml) plates with G418-resistant K. pneumoniae to obtain clones. GFP expression in transformants was confirmed by Western blotting with rabbit polyclonal serum against GFP (Molecular Probes).

Protein Turnover Assays-- Protein turnover assays were based on those of White and Sussman (30). Developing cells were recovered from Millipore filters in SorC buffer, pelleted by centrifugation, and resuspended in 50 mM Tris containing protease inhibitors (Complete, Mini; Roche Molecular Biochemicals). Cells were lysed by freeze-thaw before determining protein levels using the Pierce Coomassie® Plus protein assay reagent, following the manufacturer's instructions. Protein turnover assays were also conducted in axenic medium. Cells were shaken in FM medium (31) lacking amino acids at a density of 5 × 106 cells/ml. Three 1-ml aliquots of cells were harvested every 8 h and prepared as described for filters.

Electron Microscopy-- Electron microscopy procedures were as described (32). Briefly, cells were fixed with 2% phosphate-buffered glutaraldehyde, pH 7.2, followed by 2% osmium tetroxide fixation in the same buffer, sedimented by centrifugation and enrobed in agar, dehydrated with an aqueous/acetone series, and embedded in TAAB epon resin (Energy Beam Sciences, Agawam, MA).

Fluorescence Microscopy-- To examine the localization of GFP fusion proteins, axenic cells were incubated overnight in FM medium on 35-mm glass bottom microwell dishes (MatTEK Corporation), and the following day the medium was replaced with SorC 4-6 h prior to visualization (representing starving cells) or visualized directly (representing growing cells). Samples were viewed under a Nikon Eclipse TE300 microscope, and images were captured with a cooled CCD camera and processed using Metamorph 5 imaging software (Universal Imaging Corporation).

For chimeric development, cells were resuspended at 108 cells/ml, and 100 µl of these cells were plated on 35-mm SorC-1% Phytagel (Sigma) agar plates and allowed to dry. Structures were viewed after 32 h under a Zeiss Axioplan 2 microscope, and images were captured with a cooled CCD camera and processed using Openlab 3 imaging software (Improvision). We tapped the Petri dishes lightly against a hard surface to make the fruiting structures collapse onto the Phytagel. This treatment caused the sorus to burst in most cases, releasing the contained spores. This procedure made photography of these structures easier, because the number of Z-sections required to capture the full depth of the fruiting body was minimized.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Identification of Autophagy Genes in D. discoideum-- To identify autophagy genes in Dictyostelium, we searched the near complete D. discoideum genome sequence data base with budding yeast protein sequences using the BLAST algorithm. We identified putative Dictyostelium orthologues for Tor (AY204354), Apg1 (AY191011), Apg2 (AAM45260), Apg3 (AAL93575), Apg4 (AY191018), Apg5 (AY191012), Apg6 (AY191013), Apg7 (AY191014), Apg8 (AY191015), Apg9 (AY191016), and Apg12 (AY191017) (Fig. 1, and data not shown). Orthologues for Apg10, Apg13, Apg14, Apg16, and Apg17 were not identified. Similar searches of the Arabidopsis thaliana genome by others (33, 34) identified orthologues for Apg1-Apg13. Apg14, Apg16, and Apg17 orthologues were not found, consistent with our search of the Dictyostelium genome. Whereas multiple isoforms of Apg1, Apg4, Apg8, Apg12, and Apg13 are present in Arabidopsis, we identified only a single homologue for each autophagy protein in Dictyostelium, with the exception of Apg4. We identified two possible orthologues of Apg4, although incomplete sequence is available for one (data not shown).


View larger version (111K):
[in this window]
[in a new window]
 
Fig. 1.   Amino acid alignment of D. discoideum (Dd) Apg5 and Apg7 with orthologues from A. thaliana (At), H. sapiens (Hs) and S. cerevisiae (Sc). A, alignment of Apg5. The asterisk indicates the conserved lysine residue that forms an isopeptide bond with the carboxyl-terminal glycine of Apg12p. The accession numbers are as follows: A. thaliana, NP_197231 (RefSeq); H. sapiens, Q9H1Y0 (Swiss Prot); S. cerevisiae, S65160 (PIR). B, alignment of Apg7. The active site cysteine is indicated with an asterisk. The ATP binding motif is indicated by a dashed line. The accession numbers are as follows: A. thaliana, BAB88385 (GenBankTM); H. sapiens, NP_006386 (RefSeq); S. cerevisiae, NP_012041 (RefSeq). Alignments were performed using the BCM Search Launcher at searchlauncher.bcm.tmc.edu/multi-align/multi-align.html. The ClustalW 1.8 algorithm was used for multiple sequence alignments, and the resulting alignment was shaded using the Boxshade server at www.ch.embnet.org/software/BOX_form.html. Identical residues are shaded black, and similar residues are shaded gray.

In this study, we focus on apg5 and apg7. The homology of the Dictyostelium genes to orthologues in S. cerevisiae, A. thaliana, and Homo sapiens is shown in Fig. 1. Apg5 has a 54-amino acid asparagine-rich stretch in the amino terminus of the protein that is absent from the orthologues of the other species. Although asparagine-rich stretches are common in Dictyostelium proteins, their function is unknown. The lysine residue that is the site of isopeptide bond formation with Apg12 is conserved in all four species and corresponds to Lys-128 of A. thaliana, Lys-130 of H. sapiens, Lys-149 of S. cerevisiae, and Lys-186 of D. discoideum. Apg5 shares highest homology with the Arabidopsis gene, 24% identity over 393 residues. The homology to the human gene is also high, 29% identity over 277 residues. The degree of sequence conservation between species is even higher for Apg7. The Dictyostelium protein shares highest homology with the human protein: 39% identity over 719 residues. The ATP binding motif, Gly-X-Gly-X-X-Gly (amino acids 368-373), and the active site cysteine (Cys-563), are conserved in the Dictyostelium Apg7 protein.

Regulation of Autophagy Genes-- We examined the expression of autophagy genes during growth and throughout development of Dictyostelium. Transcription of apg1, apg8, and apg9 appears to be induced by starvation (Fig. 2). The expression levels of apg5, apg7, and apg12 were very low, which made it difficult to conclude whether starvation induces expression. We were unable to detect an apg6 transcript by Northern blotting. In budding yeast, only apg8 expression appears to be up-regulated by starvation (23).


View larger version (78K):
[in this window]
[in a new window]
 
Fig. 2.   Analysis of autophagy gene expression in Dictyostelium. 5-µg total RNA of wild-type or mutant cells were harvested at the indicated time points, size-fractionated on 1% agarose gels, transferred to nitrocellulose, and hybridized with the random primer-labeled DNA probes indicated. The approximate sizes of the transcripts are indicated. apg1, apg8, and apg9 expression is induced by starvation. apg1 and apg8 expression was induced as early as 4 h of development, whereas apg9 expression rises at 8 h of development. The remaining genes are expressed at similar levels during growth and development. An apg5 transcript is absent in apg5-, indicating a null mutation. A truncated ~1-kb apg7 transcript is produced in apg7-, corresponding to the insertion site of the blasticidin resistance cassette in the apg7 gene. The complemented strains express transcripts of the expected sizes composed of the cognate genes fused to the 821-bp GFP open reading frame (~2.4 kb for apg5- and ~3.5 kb for apg7-).

We generated two autophagy mutants by insertional mutagenesis: apg5- and apg7-. The apg5- mutant does not produce a transcript, and therefore we consider the insertional mutation a null. The apg7- strain expresses a truncated transcript of a size expected from the site of insertion of the resistance cassette and at similar levels to the uninterrupted transcript in parental DH1 cells. We believe that the apg7- strain is a null mutant, because the insertion precedes the ATP binding motif and the active site cysteine. The complemented strains, apg5- (act15/apg5-gfp) and apg7- (act15/gfp-apg7), express a transcript of the appropriate size composed of the structural gene and the GFP open reading frame (Fig. 2, right panel). The transcript levels are high throughout growth and development, because expression is from the constitutive actin15 promoter.

Autophagy Is Required for Development-- We tested the growth of autophagy mutants and parental strain in both shaking axenic culture (by hemocytometer counts) and on bacterial lawns (by plaque size). The two autophagy mutants grow as well as the parent under both conditions (data not shown). Both mutants show defective development when developing within plaques on bacterial lawns and when developed on nitrocellulose filters (see Fig. 3) or non-nutrient agar (data not shown). However, the defect observed under the two sets of conditions is strikingly different. When developed on nitrocellulose filters, mutant cells produce larger aggregates than wild-type, from which multiple tips arise. These tips give rise to slugs that rarely migrate from the enlarged mounds. The slugs culminate to form small, abnormal fruiting bodies with thickened stalks and empty sori (Fig. 3, C and E). In marked contrast, the mutants do not aggregate when they develop within plaques on bacterial lawns (Fig. 3B). We have tested development of cells grown on bacterial lawns and then starved for development on nitrocellulose filters. Under these conditions, both autophagy mutants aggregate, but they arrest development at an earlier stage than axenically grown cells developing on filters. The apg7- mutant arrests at the tight aggregate stage, whereas apg5- arrests at the loose mound stage (data not shown). Axenically grown mutant cells will develop on SM or SM/5 plates without bacteria as they do on nitrocellulose filters. These results indicate that a bacterial load in cells or a bacterial metabolite may inhibit development of the autophagy mutants.


View larger version (146K):
[in this window]
[in a new window]
 
Fig. 3.   Phenotypes of autophagy mutants. A, the parental strain, DH1, produces large sori containing spores, held aloft by a stalk. B, apg5- (shown) and apg7- (not shown) both do not aggregate when developed in situ on bacterial lawns. C, apg5- forms multi-tipped aggregates when developed on nitrocellulose filters. The multiple tips develop into aborted fruiting bodies. D, apg5- (act15/apg5gfp) forms normal fruiting bodies. E, apg7- has a similar phenotype to apg5-, producing aborted fruiting bodies with empty sori. F, apg7- (act15/gfpapg7) forms normal fruiting bodies that are similar to the parent.

Consistent with the severity of the developmental phenotype on nitrocellulose filters, apg5- and apg7- produce no viable, detergent-resistant spores (data not shown). The complemented strains, apg5- (act15/apg5-gfp) and apg7- (act15/gfp-apg7), rescue development (Fig. 3, D and F) and spore production to wild-type levels (data not shown). When mutant cells are developed on non-nutrient agar, development progresses further so that small, seemingly normal fruiting bodies form. However, when the contents of these sori are closely examined, the cells do not have the normal elliptical shape of wild-type spores but instead are round and less refractive and are therefore most likely amoebae.

Autophagy Mutations Are Cell Autonomous-- To determine whether the developmental defect of autophagy mutant cells could be rescued by development in the presence of their wild-type counterparts, we performed mosaic development experiments. We thought that perhaps nutritionally stressed cells would be cross-fed by wild-type neighbors. Mutant and wild-type cells were mixed at a 1:3 ratio. We examined spores produced by chimeric fruiting bodies for the presence of autophagy mutant cells (autophagy mutants do not produce spores on their own). Terminal developmental structures were treated with Triton X-100, which kills amoebae but not mature spores, and surviving cells were plated on K. pneumoniae lawns on SM plates. Wild-type spores produce plaques that contain developmental structures, whereas apg5- or apg7- spores produce clear plaques, because mutant amoebae do not aggregate within plaques on bacterial lawns. We examined 273 spores from 1:3 mixtures of apg5- and DH1, and 243 spores from 1:3 mixtures of apg7- and DH1. We never recovered any non-aggregating plaques on SM plates (we expect 25% of recovered spores to be mutant). Thus, the autophagy mutations we have created are cell autonomous, because spore production cannot be rescued by mixing with wild-type cells.

To follow the fate of specific cells, we used marked strains expressing GFP from a constitutive actin15 promoter. We examined the developmental phenotype of 25% marked:75% unmarked cell mixtures on 1% Phytagel-SorC. We determined the localization of GFP-expressing cells in the mosaic fruiting structures by taking Z-sections under a fluorescence microscope. Marked wild-type cells distribute to all structures of the fruiting body (Fig. 4B). The autophagy mutant cells appear to aggregate normally in mixtures with wild-type cells, although they accumulate predominantly at the periphery of mounds (data not shown). However, when slugs are formed, autophagy mutant cells accumulate at the rear of the slug and remain in the slime sheath after culmination commences, resulting in exclusion from the sorus (Fig. 4, D and F).


View larger version (98K):
[in this window]
[in a new window]
 
Fig. 4.   Autophagy mutations are cell autonomous. Cells expressing GFP from an actin15 promoter were mixed 1:3 with unlabelled wild-type cells and developed on nitrocellulose filters. Fluorescent images are two-dimensional projections of a 15-step 10-µm Z-series. Whereas labeled DH1 cells are found in all compartments of the fruiting structures (A and B), labeled apg5- (C and D) and apg7- (E and F) cells are found only in the slime sheath discarded by the migrating slug when culmination begins, in the basal disc, and sometimes the lower stalk. The sorus in C and D has not burst, as it has in A, B, E, and F. The sorus in each image is at the top, and the basal disc, where visible, is at the bottom of the image. Scale bar, 0.1 mm.

Autophagy Mutants Are Hypersensitive to Amino Acid Starvation-- We tested the ability of the autophagy mutants and wild-type cells to survive when starved of amino acids. This treatment is commonly used in budding yeast to stimulate autophagy, and yeast autophagy mutants die more rapidly than wild-type yeast when starved in this way (16, 35-39). We determined viability by the ability to form plaques on bacterial lawns. Amino acid-free FM medium was inoculated with 5 × 105 cells/ml, the cells were incubated on a shaker at 22 °C, and aliquots were plated with K. pneumoniae on SM/5 plates every 2 days. The parental strain, DH1, survives well, and viability only starts dropping slightly after 8 days (Fig. 5). The autophagy mutants are highly susceptible to amino acid starvation; the number of viable cells drops rapidly after 4 days to ~10% of parental levels. The complemented strain, apg5- (act15/apg5-gfp), behaves like the parental strain, whereas survival of the apg7- (act15/gfp-apg7) strain is not rescued as efficiently (Fig. 5).


View larger version (18K):
[in this window]
[in a new window]
 
Fig. 5.   Survival during nitrogen starvation. Growing cells were harvested and resuspended in FM medium lacking amino acids at 5 × 105/ml. Aliquots were taken at the indicated time points to determine viability by plaque formation on bacterial lawns. Wild-type cells survive for longer than a week under these conditions. The apg5- and apg7- strains rapidly lose viability after 2 days and display 50-fold fewer viable cells than the parental strain after 6 days. The apg5- (act15/apg5gfp) strain rescues viability completely, whereas the apg7- (act15/gfpapg7) strain shows an intermediate phenotype.

Bulk Protein Turnover Is Reduced in Autophagy Mutants-- Autophagy may have an important function in protein turnover when Dictyostelium cells starve. We determined total protein levels of cells starving on nitrocellulose filters. We find that parental cells lose 33% of total protein over 24 h, whereas apg5- (and apg7-; data not shown) loses less than 15% of total protein over the same time period (Fig. 6). The complemented strain, apg5- (act15/apg5-gfp), displays protein degradation comparable with the parental strain (similar results are seen for the apg7- (act15/gfp-apg7) strain; data not shown). A Dictyostelium mutant that does not aggregate, yakA- (40), was also tested to control for the effects of multicellular development on protein turnover; protein levels drop by 26% during 24 h of starvation (Fig. 6), meaning that protein degradation occurs despite the early block to development. This experiment has been repeated four times with similar results. All strains behave similarly when starved axenically in FM medium without amino acids, although the reduction in protein levels is not as marked (data not shown).


View larger version (15K):
[in this window]
[in a new window]
 
Fig. 6.   Protein turnover during starvation and development is reduced in autophagy mutants. Cells were placed on nitrocellulose filters for development and harvested at the indicated times. Total cellular protein was measured using the Bradford assay. Protein levels in the parental DH1 strain typically drop 30-40% after 24 h of development. The apg5- mutant does not show an appreciable drop in protein levels. The apg5- (act15/apg5gfp) strain shows wild-type levels of protein degradation.

The GFP-Apg8 Fusion Protein Localizes to Punctate Structures in the Cytoplasm-- To determine the localization of autophagy proteins in Dictyostelium cells and to ask whether this occurs normally in the apg5- and apg7- mutants, we created fusions of the autophagy proteins with GFP. We fused GFP to the amino termini of Apg7, Apg8, and Apg12 and to the carboxyl terminus of Apg5. We examined the distribution of GFP fusion proteins by fluorescence microscopy. Free GFP and GFP-Apg7 show diffuse cytoplasmic localization during both growth and starvation (data not shown). Diffuse cytoplasmic localization and, rarely, a single punctate spot are observed for Apg5-GFP and GFP Apg12 in both wild-type and apg5- genetic backgrounds, irrespective of nutritional status (data not shown). Very little signal is detected for Apg5-GFP in the apg7- background, and the frequency of cells with detectable expression is low. This localization data for Apg5-GFP and GFP-Apg12 is consistent with that observed in yeast, where most autophagy proteins (Apg5, Apg12, Apg1 etc.) localize to one or a few punctate spots adjacent to the vacuole, in the perivacuolar preautophagosomal structure (41).

In addition to diffuse cytoplasmic localization, GFP-Apg8 labels multiple punctate structures in wild-type cells in FM growth medium or SorC starvation medium (Fig. 7, B and D). These punctate structures are larger than those labeled by Apg5-GFP and GFP-Apg12 and are visualized more easily. We have observed that fewer punctate structures are observed in cells grown in the very rich, undefined medium HL5 (data not shown). In both autophagy mutants, we see an absence of the many small dots in the cytoplasm observed in DH1; instead, a single larger punctate structure is labeled regardless of the nutritional conditions (Fig. 7, F, H, J, and L). In budding yeast, Apg8p localizes to the preautophagosomal structure and labels the membranes of forming autophagosomes, and a portion of Apg8p remains inside the autophagosome after completion (23).


View larger version (118K):
[in this window]
[in a new window]
 
Fig. 7.   Localization of GFP-Apg8 in live cells. GFP-Apg8 shows cytoplasmic localization and labels punctate structures in wild-type cells growing in FM medium (A, phase image; B, GFP fluorescence). In wild-type cells starving in SorC (C, phase image; D, GFP fluorescence), a similar distribution of GFP-Apg8 fluorescence is seen. In the autophagy mutants, GFP-Apg8 again shows cytoplasmic localization, but in addition, a single large punctate structure is labeled, irrespective of nutrient conditions. E and F, apg5- in FM medium; G and H, apg5- in SorC; I and J, apg7- in FM medium; K and L, apg7- in SorC.

The Apg5-Apg12 Conjugation System Is Conserved in Dictyostelium-- We wanted to test whether the Apg5-Apg12 conjugation system described in S. cerevisiae is conserved in D. discoideum. For this experiment, we used the GFP fusions that we created to determine subcellular localization of the autophagy proteins. We were able to detect these fusions by Western blotting with a rabbit polyclonal antiserum against GFP (Molecular Probes). Both Apg5 and Apg12 GFP fusions are present in two forms in the parental strain DH1, corresponding to free and conjugated forms of the proteins (Fig. 8). Apg5-GFP displays two bands; one migrates at ~80 kDa, and the second migrates at ~100 kDa. GFP-Apg12 migrates at the expected mass of ~50 kDa, but the conjugated form (~130 kDa) is larger than the reciprocal conjugate of Apg5-GFP-Apg12. We are investigating this discrepancy. The interpretation of the nature of these two bands is confirmed by the absence of the higher molecular mass form of GFP-Apg5p in the apg7- mutant, because Apg7 is the E1 that activates Apg12 prior to conjugation with Apg5. The higher molecular mass form of GFP-Apg12 is absent in the apg5- and apg7- mutants, where the target of conjugation and the E1 activating enzyme, respectively, are absent. This is the predicted result if the Dictyostelium system functions like that of budding yeast.


View larger version (45K):
[in this window]
[in a new window]
 
Fig. 8.   Apg5-GFP and GFP-Apg12 fusion proteins are present in two forms. GFP was fused to the carboxyl terminus of Apg5 and the amino terminus of Apg12 and overexpressed from a constitutive actin15 promoter in the parental strain, DH1, and the two autophagy mutants, apg5- and apg7-. Cells were grown in HL5 medium (G) or starved in SorC (S) for 6 h and immunoblotted with anti-GFP antibody. The non-conjugated Apg5-GFP and GFP-Apg12 are present in all strains regardless of growth conditions. However, the Apg5-GFP-Apg12 conjugate is only present in DH1 and apg5- but is absent in the strain lacking E1-like activity, apg7-. The band above free Apg5-GFP is a nonspecific band. The GFP-Apg12-Apg5 conjugate is present only in the wild-type strain and is absent in the strain lacking a target for conjugation (apg5-) or the E1-like activating enzyme (apg7-).

Wild-type Cells Show Extensive Cytoplasmic Degradation When Starved of Amino Acids-- To study the defect in autophagy mutant cells, we examined ultrastructure by transmission electron microscopy. We looked at both growing cells and cells starved of amino acids for 36 h to stimulate autophagy. Growing mutant amoebae are indistinguishable from their growing wild-type counterparts (Fig. 9, A, C, and E). Many small vesicles concentrated at the cell periphery are observed (Fig. 9A); these are macropinosomes resulting from feeding on the FM medium. When cells are starved, we observe dramatic differences between wild-type and autophagy mutant strains. In the parent DH1, large vesicles containing predominantly membrane, but also a little granular material, are observed. Most organelles have been degraded, leaving an almost empty cytoplasm (Fig. 9B). However, in starved autophagy mutants, vesicles are observed that contain organelles and cytoplasmic components, but the contents have undergone little or no degradation. The cytoplasm of mutant amoebae contains many organelles and is densely packed with glycogen (Fig. 9, D and F). It appears that amoebae of the wild-type parental strain recycle cellular components to aid in survival during nitrogen starvation, whereas mutant amoebae do not. These studies reveal the presence of what appear to be autophagosomal structures in the autophagy mutants (see arrows in Fig. 9, D and F), although additional evidence besides morphology is required to substantiate this conclusion.


View larger version (144K):
[in this window]
[in a new window]
 
Fig. 9.   Ultrastructural features of growing and starving amoebae. Parental cells (A and B), apg5- cells (C and D), and apg7- cells (E and F) were grown in FM medium (A, C, and E) or in FM medium lacking amino acids (B, D, and F) for 36 h. A, wild-type cells in FM medium exhibit scattered mitochondria (M) and few vacuoles containing enclosed cytoplasm or membranous inclusions. B, cells in FM medium lacking amino acids exhibit less granular cytoplasm, fewer mitochondria (M), and large vacuoles enclosing membranous and lightly granular masses of cytoplasm (arrows) suggesting autolysis. C and E, mutant cells grown in FM medium are similar to growing wild-type cells. D and F, mutant cells grown in FM medium lacking amino acids exhibit scattered vacuoles containing membranous whorls and granular masses of cytoplasm (arrows), suggesting possible autophagosome formation, but less evidence of autolysis. D (inset) shows enclosure of a mitochondrion within a cup-shaped membrane that appears to be a forming autophagosome. F (inset) is a higher magnification view of a membranous whorl within the peripheral cytoplasm (arrow) of an apg7- cell grown in FM medium lacking amino acids. Scale bars = 1 µm (insets = 0.2 µm).


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In this study, we show that the autophagy pathway characterized in yeast, plants, and mammalian cells is conserved in D. discoideum. We identified putative Dictyostelium orthologues of S. cerevisiae proteins for Apg1-9, Apg12, and Tor. We were unable to locate orthologues of Apg10, Apg13, Apg16, or Apg17, either because they do not exist in social amoebae, are poorly conserved in evolution, or because we searched an incompletely sequenced genome. Unlike A. thaliana, we find only a single isoform of each protein with the exception of Apg4. We examined the expression of some of the identified autophagy genes in Dictyostelium and observe up-regulated transcription of apg1, apg8, and apg9 when cells are starved (Fig. 2). In yeast, the expression of only one autophagy gene, APG8, is significantly induced by starvation (23).

To analyze the functional conservation of macroautophagy, we generated and characterized the first autophagy mutants described in D. discoideum, in the apg5 and apg7 genes. Apg5 is the target of Apg12 conjugation, requiring the activity of the E1-like enzyme, Apg7. This conjugation reaction is chemically similar to ubiquitination and is required for the formation of autophagosomes (13, 42). Both Dictyostelium genes show significant homology with their budding yeast, plant, and mammalian counterparts (Fig. 1), with all residues known to be essential for function conserved. In addition, the Apg12-Apg5 conjugation system appears to be present in Dictyostelium (Fig. 7). Two forms of the GFP fusion proteins are detected in wild-type cells, but the higher molecular mass form of Apg5-GFP is absent in apg7-, and the conjugated form of GFP-Apg12 is absent in both apg5- and apg7-. This conjugation pattern is consistent with the functions assigned to Apg5, Apg7, and Apg12 from studies in budding yeast and mammalian cells. Apg5-GFP and GFP-Apg12 show diffuse cytoplasmic localization and rarely a single dot in growing and starving cells (data not shown). The GFP-Apg8 fusion shows a change in localization pattern dependent on the nutritional status and genetic background of the cell. In the wild-type strain, GFP-Apg8 localizes to many punctate spots in the cytoplasm (Fig. 7, B and D), in addition to diffuse cytoplasmic localization. Interestingly, the frequency of the dots is lowest in rich growth medium, HL5 (data not shown), and is higher in the defined medium, FM, and in phosphate buffer (SorC). These punctate structures may represent preautophagosomal complex(es) and/or forming/complete autophagosomes. In the apg5- and apg7- mutants, GFP-Apg8 labels only a single punctate structure that is much larger than the dots observed in the wild-type strain (Fig. 7, F, H, J, and L), and the localization/frequency of these structures does not change when cells are starved. It is unclear what these large structures represent, but immunoelectron microscopy with anti-GFP antibodies in GFP-Apg8-expressing strains may be informative.

We find that apg5 and apg7 are dispensable for growth in Dictyostelium but are required for normal development. When apg5- and apg7- mutants develop, they form large multi-tipped aggregates that fail to complete normal morphogenesis. Instead, aberrant fruiting bodies composed of thickened stalks and empty sori are formed (Fig. 3). These structures produce no viable, mature spores. Additionally, development and spore production cannot be rescued by co-developing autophagy mutant cells with wild-type cells in a chimeric organism (Fig. 4). Thus, these autophagy mutations are cell autonomous. It is not clear how these mutations prohibit proper development, but it may include interference with chemotaxis, motility, adhesion, intercellular signaling, or differentiation.

The apg5- and apg7- mutants exhibit additional attributes of autophagy mutants. Survival in medium lacking amino acids is severely reduced (Fig. 5), similar to that described for yeast and plants. Yeast autophagy mutants die rapidly when starved of amino acids, and plants carrying autophagy mutations are susceptible to nutrient limitation. Autophagy is the major mechanism of bulk protein turnover when yeast cells are starved for nitrogen, accounting for 80% of protein turnover (22). We find that starved Dictyostelium autophagy mutants degrade very little protein (10-15%), whereas starved wild-type cells and complemented autophagy mutants degrade 30-40% of the protein they contained at the end of growth (Fig. 6). A mutation in yakA, a gene that is required for the growth to development transition in Dictyostelium (40), does not affect the reduction in protein levels typical of starved cells, indicating that the earliest events in development are not required for the induction of autophagy-dependent proteolysis. We see a similar result when starvation-induced protein turnover is assayed in an adenylyl cyclase mutant (aca-) (data not shown). The aca- mutant also survives as well as wild-type when starved for amino acids (data not shown), confirming that autophagy can be induced even in the absence of early developmental events that are usually triggered by starvation.

Consistent with the protein turnover defect in apg5- and apg7-, we observe by transmission electron microscopy that turnover of organelles and cytoplasmic constituents in cells starved for amino acids for 36 h is impaired (Fig. 9). Wild-type cells show significant degradation of the cytoplasm, to such an extent that portions of the cytoplasm are electron-lucent. Additionally, large vesicles are observed that contain a small amount of membrane and granular material that appears highly degraded. Conversely, in the starved mutant cells, vesicles containing membrane whorls and cytoplasm with little evidence of degradation are observed. These enclosed membrane whorls are reminiscent of autophagosomes or autophagic vacuoles in mammalian cells (43, 44). The morphology of the autophagic system in Dictyostelium appears more similar to mammalian cells than to budding yeast and may reflect the more complex intracellular membrane structure and dynamics of Dictyostelium compared with yeast. In the latter, the autophagosome fuses with the vacuole, releasing the autophagic body into the vacuolar lumen for degradation by resident hydrolases. In contrast, in mammalian cells, primary autophagosomes appear to mature to autophagic vacuoles through incorporation of lysosomal membrane proteins, vacuole acidification, and acquisition of lysosomal hydrolases (45). Additional transmission electron microscopy studies are under way to better characterize the morphology of autophagy in Dictyostelium and the specific defect we observe in the autophagy mutants.

The underlying machinery used to generate autophagosomes is conserved among yeast, plants, humans, and now Dictyostelium. Genetic and cell biology studies in yeast have delineated the molecular framework required for autophagy. The challenge for the future is to elucidate the signaling pathways required to initiate autophagy, the mechanistic details of autophagosome formation, and the interaction of autophagy and endolysosomal pathways. Dictyostelium provides a useful system for these studies; it is genetically tractable, the endolysosomal system is similar to mammalian cells, and, most importantly, the effects of autophagy on multicellular development can be examined fruitfully.

    ACKNOWLEDGEMENTS

We thank all members of the Kessin laboratory and Howard Shuman and Hubert Hilbi for helpful discussions. We thank Thomas Huckaba, Edgar Gomes, and Chiann-Mun Chen for help with microscopy. We are grateful to the Dictyostelium Genome Sequencing Consortium for their efforts.

    FOOTNOTES

* This work was supported in part by National Institutes of Health Grant GM33136 (to R. H. K.). This is Lamont-Doherty Earth Observatory Contribution Number 6408.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

To whom correspondence should be addressed: Dept. of Anatomy and Cell Biology, Rm. 12-517, Columbia University, 630 W. 168th St., New York, NY 10032. Tel.: 212-305-5653; Fax: 212-305-3970; E-mail: rhk2@columbia.edu.

Published, JBC Papers in Press, March 7, 2003, DOI 10.1074/jbc.M212467200

    ABBREVIATIONS

The abbreviations used are: Tor, target of rapamycin; GFP, green fluorescent protein; SorC, Sorensen C.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

1. Dice, J. F., Terlecky, S. R., Chiang, H. L., Olson, T. S., Isenman, L. D., Short-Russell, S. R., Freundlieb, S., and Terlecky, L. J. (1990) Semin. Cell Biol. 1, 449-455[Medline] [Order article via Infotrieve]
2. Cuervo, A. M., and Dice, J. F. (2000) Traffic 1, 570-583[CrossRef][Medline] [Order article via Infotrieve]
3. Cuervo, A. M., and Dice, J. F. (2000) J. Cell Sci. 113, 4441-4450[Abstract/Free Full Text]
4. Mortimore, G. E., Lardeux, B. R., and Adams, C. E. (1988) J. Biol. Chem. 263, 2506-2512[Abstract/Free Full Text]
5. Tuttle, D. L., and Dunn, W. A., Jr. (1995) J. Cell Sci. 108, 25-35[Abstract/Free Full Text]
6. Reggiori, F., and Klionsky, D. J. (2002) Eukaryot. Cell 1, 11-21[Free Full Text]
7. Tsukada, M., and Ohsumi, Y. (1993) FEBS Lett. 333, 169-174[CrossRef][Medline] [Order article via Infotrieve]
8. Thumm, M., Egner, R., Koch, B., Schlumpberger, M., Straub, M., Veenhuis, M., and Wolf, D. H. (1994) FEBS Lett. 349, 275-280[CrossRef][Medline] [Order article via Infotrieve]
9. Noda, T., Matsuura, A., Wada, Y., and Ohsumi, Y. (1995) Biochem. Biophys. Res. Commun. 210, 126-132[CrossRef][Medline] [Order article via Infotrieve]
10. Noda, T., and Ohsumi, Y. (1998) J. Biol. Chem. 273, 3963-3966[Abstract/Free Full Text]
11. Kametaka, S., Okano, T., Ohsumi, M., and Ohsumi, Y. (1998) J. Biol. Chem. 273, 22284-22291[Abstract/Free Full Text]
12. Kihara, A., Noda, T., Ishihara, N., and Ohsumi, Y. (2001) J. Cell Biol. 152, 519-530[Abstract/Free Full Text]
13. Mizushima, N., Noda, T., Yoshimori, T., Tanaka, Y., Ishii, T., George, M. D., Klionsky, D. J., Ohsumi, M., and Ohsumi, Y. (1998) Nature 395, 395-398[CrossRef][Medline] [Order article via Infotrieve]
14. Ichimura, Y., Kirisako, T., Takao, T., Satomi, Y., Shimonishi, Y., Ishihara, N., Mizushima, N., Tanida, I., Kominami, E., Ohsumi, M., Noda, T., and Ohsumi, Y. (2000) Nature 408, 488-492[CrossRef][Medline] [Order article via Infotrieve]
15. Kamada, Y., Funakoshi, T., Shintani, T., Nagano, K., Ohsumi, M., and Ohsumi, Y. (2000) J. Cell Biol. 150, 1507-1513[Abstract/Free Full Text]
16. Shintani, T., Mizushima, N., Ogawa, Y., Matsuura, A., Noda, T., and Ohsumi, Y. (1999) EMBO J. 18, 5234-5241[Abstract/Free Full Text]
17. Tanida, I., Mizushima, N., Kiyooka, M., Ohsumi, M., Ueno, T., Ohsumi, Y., and Kominami, E. (1999) Mol. Biol. Cell 10, 1367-1379[Abstract/Free Full Text]
18. Yuan, W., Stromhaug, P. E., and Dunn, W. A., Jr. (1999) Mol. Biol. Cell 10, 1353-1366[Abstract/Free Full Text]
19. Kuma, A., Mizushima, N., Ishihara, N., and Ohsumi, Y. (2002) J. Biol. Chem. 277, 18619-18625[Abstract/Free Full Text]
20. Mizushima, N., Noda, T., and Ohsumi, Y. (1999) EMBO J. 18, 3888-3896[Abstract/Free Full Text]
21. Kirisako, T., Ichimura, Y., Okada, H., Kabeya, Y., Mizushima, N., Yoshimori, T., Ohsumi, M., Takao, T., Noda, T., and Ohsumi, Y. (2000) J. Cell Biol. 151, 263-276[Abstract/Free Full Text]
22. Schlumpberger, M., Schaeffeler, E., Straub, M., Bredschneider, M., Wolf, D. H., and Thumm, M. (1997) J. Bacteriol. 179, 1068-1076[Abstract]
23. Kirisako, T., Baba, M., Ishihara, N., Miyazawa, K., Ohsumi, M., Yoshimori, T., Noda, T., and Ohsumi, Y. (1999) J. Cell Biol. 147, 435-446[Abstract/Free Full Text]
24. Kessin, R. H. (2001) Dictyostelium-Evolution, Cell Biology, and the Development of Multicellularity , Cambridge University Press, Cambridge, United Kingdom
25. Sussman, M. (1987) in Methods in Cell Biology (Spudich, J. A., ed), Vol. 28 , pp. 9-29, Academic Press, Orlando, FL
26. Wu, L., and Franke, J. (1990) Gene 91, 51-56[Medline] [Order article via Infotrieve]
27. Kuspa, A., and Loomis, W. F. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 8803-8807[Abstract]
28. Podgorski, G. J., Franke, J., Faure, M., and Kessin, R. H. (1989) Mol. Cell. Biol. 9, 3938-3950[Medline] [Order article via Infotrieve]
29. Levi, S., Polyakov, M., and Egelhoff, T. T. (2000) Plasmid 44, 231-238[CrossRef][Medline] [Order article via Infotrieve]
30. White, G. J., and Sussman, M. (1961) Biochim. Biophys. Acta 53, 285-293[CrossRef][Medline] [Order article via Infotrieve]
31. Franke, J., and Kessin, R. (1977) Proc. Natl. Acad. Sci. U. S. A. 74, 2157-2161[Abstract]
32. Anderson, O. R. (1994) J. Eukaryot. Microbiol. 41, 124-128
33. Doelling, J. H., Walker, J. M., Friedman, E. M., Thompson, A. R., and Vierstra, R. D. (2002) J. Biol. Chem. 277, 33105-33114[Abstract/Free Full Text]
34. Hanaoka, H., Noda, T., Shirano, Y., Kato, T., Hayashi, H., Shibata, D., Tabata, S., and Ohsumi, Y. (2002) Plant Physiol. 129, 1181-1193[Abstract/Free Full Text]
35. George, M. D., Baba, M., Scott, S. V., Mizushima, N., Garrison, B. S., Ohsumi, Y., and Klionsky, D. J. (2000) Mol. Biol. Cell 11, 969-982[Abstract/Free Full Text]
36. Noda, T., Kim, J., Huang, W. P., Baba, M., Tokunaga, C., Ohsumi, Y., and Klionsky, D. J. (2000) J. Cell Biol. 148, 465-480[Abstract/Free Full Text]
37. Lang, T., Reiche, S., Straub, M., Bredschneider, M., and Thumm, M. (2000) J. Bacteriol. 182, 2125-2133[Abstract/Free Full Text]
38. Wang, C. W., Kim, J., Huang, W. P., Abeliovich, H., Stromhaug, P. E., Dunn, W. A., Jr., and Klionsky, D. J. (2001) J. Biol. Chem. 276, 30442-30451[Abstract/Free Full Text]
39. Shintani, T., Suzuki, K., Kamada, Y., Noda, T., and Ohsumi, Y. (2001) J. Biol. Chem. 276, 30452-30460[Abstract/Free Full Text]
40. Souza, G. M., Lu, S., and Kuspa, A. (1998) Development 125, 2291-2302[Abstract/Free Full Text]
41. Suzuki, K., Kirisako, T., Kamada, Y., Mizushima, N., Noda, T., and Ohsumi, Y. (2001) EMBO J. 20, 5971-5981[Abstract/Free Full Text]
42. Mizushima, N., Sugita, H., Yoshimori, T., and Ohsumi, Y. (1998) J. Biol. Chem. 273, 33889-33892[Abstract/Free Full Text]
43. Papadopoulos, T., and Pfeifer, U. (1987) Exp. Cell Res. 171, 110-121[Medline] [Order article via Infotrieve]
44. Niemann, A., Takatsuki, A., and Elsasser, H. P. (2000) J. Histochem. Cytochem. 48, 251-258[Abstract/Free Full Text]
45. Dunn, W. A., Jr. (1990) J. Cell Biol. 110, 1935-1945[Abstract]


Copyright © 2003 by The American Society for Biochemistry and Molecular Biology, Inc.