Turnover of peroxisomal vesicles by autophagic proteolysis in cultured fibroblasts from Zellweger patients.

Previous studies have shown that in fibroblasts from patients with the Zellweger syndrome (ZS) aberrant membrane structures are present which contain peroxisomal membrane proteins (Santos, M. J. et al., Science 239, 1536-1538 (1988)). In order to characterize these structures we have performed double labeling immunoelectron microscopy experiments using antisera directed against the 69 kDa peroxisomal integral membrane protein (PMP) and lysosomal hydrolases. The results indicate that at least 80% of the structures earlier referred to as 'peroxisomal ghosts' contain lysosomal hydrolases. In addition, we have studied the effect of culture of ZS fibroblasts in the presence of 3-methyladenine, an inhibitor of autophagy, on the intracellular distribution of the 69 kDa PMP. Immunofluorescence experiments showed that in the presence of 3-methyladenine there is an increase in fluorescent spots and a change in the distribution of the spots from mainly perinuclear to randomly distributed throughout the cytoplasm. Double labeling immunoelectron microscopy revealed that after culture in the presence of 3-methyladenine the 69 kDa PMP also accumulates mainly in compartments containing lysosomal hydrolases. In one ZS cell line we found that after culture in the presence of 3-methyladenine there was also an accumulation of structures which were as small as normal microperoxisomes. We conclude that in ZS fibroblasts the 69 kDa PMP is mainly present in lysosomal compartments, presumably degradative autophagic vacuoles. Furthermore, in ZS fibroblasts peroxisomes of apparently normal morphology may be synthesized, but they are degraded by autophagic proteolysis.

Peroxisomes of normal morphology but deficient in 3-oxoacyl-CoA thiolase in rhizomelic chondrodysplasia punctata fibroblasts.

Rhizomelic Chondrodysplasia Punctata (RCDP) is an autosomal recessive disorder in which plasmalogen biosynthesis and phytanate catabolism are impaired. Peroxisomal structure and the intracellular localization of catalase, the 69 kDa peroxisomal integral membrane protein (PMP), and 3-oxoacyl-CoA thiolase were studied in cultured skin fibroblasts from control subjects and patients with RCDP. A punctate fluorescence pattern characteristic for peroxisomes was seen in control cells incubated with either anti-(catalase), anti-(69 kDa PMP) or anti-(3-oxoacyl-CoA thiolase). Incubation of mutant cells with anti-(catalase) or anti-(69 kDa PMP) resulted in the same pattern. However, when RCDP fibroblasts were incubated with a monoclonal anti-(3-oxoacyl-CoA thiolase) antibody no punctate fluorescence could be observed. Cryosections from control and RCDP cells were examined by electron microscopy using double immunogold labelling. RCDP fibroblasts contained structures indistinguishable from control peroxisomes, the membranes reacting with anti-(69 kDa PMP) and the matrix with anti-(catalase). However, the matrix of RCDP peroxisomes, unlike control peroxisomes, did not react with anti-(3-oxoacyl-CoA thiolase). We conclude that RCDP fibroblasts contain regularly shaped peroxisomes, comparable to control peroxisomes in number as well as in content of catalase and 69 kDa PMP. However, in RCDP peroxisomes the amount of 3-oxoacyl-CoA thiolase protein proved to be below the limit of detection.

Presence of peroxisomal membrane proteins in liver and fibroblasts from patients with the Zellweger syndrome and related disorders: evidence for the existence of peroxisomal ghosts.

The presence and intracellular localization of peroxisomal integral membrane proteins (PMP) were investigated in liver and cultured skin fibroblasts from control subjects and patients with the Zellweger syndrome and related disorders in which peroxisomes are virtually absent. Immunoblotting experiments showed that 22, 36 and 69 kDa PMPs were present and were confined to the membranous fraction both in the control liver and in the livers from the Zellweger patients. The 22 and 36 kDa PMPs were present in significantly lower amounts in the patients' livers than in the control liver. A reduced amount of the 69 kDa PMP was found in liver from one Zellweger but not in liver from another. The subcellular localization in fibroblasts of catalase and the 69 kDa PMP was studied by indirect immunofluorescence. A characteristic punctate fluorescence was seen in control cells incubated with either anti-(catalase) or with anti-(69 kDa PMP). Incubation of mutant cells with anti-(catalase) resulted in a diffuse fluorescence, whereas with anti-(69 kDa PMP) fluorescent particles were visualized which, in some cell lines, were larger and fewer in number than in control cells. Cryosections of control and mutant cells were examined by electron microscopy using immunogold labeling. Control cells contained small structures consisting of a single membrane enclosing a homogeneous matrix; the membranes reacted with anti-(69 kDa PMP) and the matrix with anti-(catalase). The mutant cell lines contained spherical or ellipsoidal structures whose membranes reacted with anti-(69 kDa PMP); no labeling was observed with anti-(catalase). We conclude that peroxisomal ghosts, the membranes of which contain the 69 kDa PMP, are present in peroxisome-deficient cell lines from all complementation groups studied so far.

Kinetoplast DNA from Trypanosoma vivax and T. congolense.

We have analysed kinetoplast DNA (kDNA) of the African trypanosomes Trypanosoma vivax and T. congolense. The maxi-circles from these organisms resemble those of T. brucei in size, but only to a limited extent in sequence as judged from restriction enzyme digests and DNA X DNA hybridization. The kDNA networks of T. vivax have three distinguishing features: they contain the highest maxi-circle concentration of any kDNA (at least twice that of T. brucei); they contain the smallest mini-circles (465 bp) yet found thus far and the width of the kDNA nucleoid in thin sections is correspondingly small (55 nm against 91 nm for T. brucei); they contain a substantial fraction of mini-circle dimers.

Purification, morphometric analysis, and characterization of the glycosomes (microbodies) of the protozoan hemoflagellate Trypanosoma brucei.

Trypanosoma brucei glycosomes (microbodies containing nine enzymes involved in glycolysis) have been purified to near homogeneity from bloodstream-form trypomastigotes for the purpose of morphologic and biochemical analysis. Differential centrifugation followed by two isopycnic centrifugations in an isotonic Percoll and in a sucrose gradient, respectively, resulted in 12- to 13-fold purified glycosomes with an overall yield of 31%. These glycosomes appeared to be highly pure and contained less than 1% mitochondrial contamination as judged by morphometric and biochemical analyses. In intact cells, glycosomes displayed a remarkably homogeneous size distribution centered on an average diameter of 0.27 micron with a standard deviation of 0.03 micron. The size distribution of isolated glycosomes differed only slightly from that measured in intact cells. One T. brucei cell contained on average 230 glycosomes, representing 4.3% of the total cell volume. The glycosomes were surrounded by a single membrane and contained as phospholipids only phosphatidyl choline and phosphatidyl ethanolamine in a ratio of 2:1. The purified glycosomal fraction had a very low DNA content of 0.18 microgram/mg protein. No DNA molecules were observed that could not have been derived from contaminating mitochondrial or nuclear debris.

DNA circles with cruciforms from Isospora (Toxoplasma) gondii.

We have isolated a closed circular duplex DNA fraction from the unicellular parasite Isospora (Toxoplasma) gondii and examined the purified DNA by electron microscopy. A major part of this circular DNA consists of 12-micron circles containing a cruciform with 0.5-micron tails. We also found 23-micron circles with the properties expected of head-to-tail dimers of the 12-micron circles. Some of these dimers have two cruciforms with 0.4-micron tails, some have one cruciform with 0.8-micron tails. When ethidium bromide was diffused into the DNA solution, circles with tails were replaced by twisted circles without tails. Direct mixing of the DNA with high ethidium bromide concentrations (5 micrograms/ml) gave rise to highly twisted circles with tails. This proves that the tailed circles are covalently continuous and indicates that ethidium bromide blocks branch migration. The 0.5-micron tails are part of a 1.7-micron palindrome, which was visualized by spreading denatured DNA under snap-back conditions. We argue that the cruciform is not present in vivo and that the 12-micron circles may represent the mitochondrial DNA of Toxoplasma.

Fine structure of the 21S ribosomal RNA region on yeast mitochondrial DNA. II. The organization of sequences in petite mitochondrial DNAs carrying genetic markers from the 21S region.

We have investigated the organization of sequences in ten rho- petite mtDNAs by restriction enzyme analysis and electron microscopy. From the comparison of the physical maps of the petite mtDNAs with the physical map of the mtDNA of the parental rho+ strain we conclude that there are at least three different classes of petite mtDNAs: I. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA. II. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA with a terminal inverted duplication. III. Mixed repeats of an (almost) continuous rho+ mtDNA segment. In out petite mtDNAs of the second type, the inverted duplications do not cover the entire conserved rho+ mtDNA segment. We have found that the petite mtDNAs of the third type contain a local inverted duplication at the site where repeating units can insert in two orientations. At least in one case this local inverted duplication must have arisen by mutation. The rearrangements that we have found in the petite mtDNAs do not cluster at specific sites on the rho+ mtDNA map. Large rearrangements or deletions within the conserved rho+ mtDNA segment seem to contribute to the suppressiveness of a petite strain. There is also a positive correlation between the retention of certain segments of the rho+ mtDNA and the suppressiveness of a petite strain. We found no correlation between the suppressiveness of a petite strain and its genetic complexity. The relevance of these findings for the mechanism of petite induction and the usefulness of petite strains for the physical mapping of mitochondrial genetic markers and for DNA sequence analysis are discussed.

Origin and direction of replication of the bacteriocinogenic plasmid Clo DF13.

Cairn's type replicative intermediates of both the wildtype Clo DF13 plasmid and the copy mutant CLO DF13 cop3 were isolated by dye-buoyant density centrifugation. Replicative intermediates were linearized at the HpaI or Sa1I cleavage site, and examined with the electron-microscope. The data show that replication of both the Clo DF13 wild type plasmid and the Clo DF13 cop3 plasmid, initiates at about 2.8% on the physical map. Replication proceeds unindirectionally and counterclockwise on this map.

The structure of kinetoplast DNA. 1. The mini-circles of Crithidia lucilae are heterogeneous in base sequence.

We have analysed limit digests of mini-circles from kinetoplast DNA of Crithidia luciliae by gel electrophoresis. Endonucleases HapII and AluI cut the circles into at least 37 and 21 fragments, respectively, and leave no circles intact. In both cases the added molecular weights of the fragments, estimated from mobility in gels, exceeds 18 X 10(6), i.e. more than 12 times the molecular weight of the mini-circle DNA. Endonucleases HindII + III, EcoRI and HpaI cut only part of the circles. These results show that the mini-circles are heterogeneous in base sequence. Different sequence classes are present in different amounts. DNA-DNA renaturation analysis of mini-circle DNA yields a complexity of about 3 X 10(6), i.e. twice the molecular weight on one mini-circle. The delta tm of native and renatured duplexes is about 1 degree C, showing that the sequence heterogeneity is a micro-heterogeneity. Electron microscopy, gel electrophoresis and sedimentation analysis show that the circles that are not cut by endonucleases HindII + III remain catenated in very large associations. These associations lack the 'rosette' structures and the long edge loops characteristic of intact kinetoplast DNA. This suggests that the mini-circle classes cut by endonucleases HindII + III are present throughout the network and that the maxi-circle component of the network (see accompanying paper) is not essential to hold the network together. Prolonged electrophoresis on 1.5% or 2% agarose gels resolves the open mini-circles into three and linearized mini-circles into four bands, present in different amounts. We conclude that the mini-circles are also heterogeneous in size, the difference in size between the two extreme size classes being 4% of the contour length. Digestion with endonuclease HapII shows that at least three out of these four bands differ in sequence. Possible mechanisms that could account for the micro-heterogeneity in sequence of mini-circles are discussed.

The organization of genes in yeast mitochondrial DNA II. The physical map of EcoRI and HindII + III fragments.

1. We have isolated large fragments of the mtDNA of the yeast Saccharomyces carlsbergensis and digested these with restriction endonucleases. The digestion products were separated by electrophoresis in agarose gels. 2. Endonucleases EcoRI, HindII + III, HpaI, HindIII and HapII yield 9, 11, 6, 0 and greater than 80 fragments, respectively. 3. By analysis of partial digestion products and by redigesting the fragments obtained with one endonuclease with a second, we have established the order of all EcoRI and HindII + III fragments. The map is circular and its contour length is 22.1 +/- 0.35 mum, in good agreement with earlier estimates of the size of yeast mtDNA, using electron microscopy and renaturation kinetics. 4. A comparison of the fragmentation pattern of mtDNAs from S. carlsbergensis and various strains of Saccharomyces cerevisiae with endonuclease HindII + III suggests that the overall gene order is similar.

The structure of kinetoplast DNA. I. Properties of the intact multi-circular complex from Crithidia luciliae.

We have developed a modified isolation procedure that yields kinetoplast DNA networks containing more than 90% closed circular DNA, as judged by two criteria: (a) In 0.15 M NaCl/0.015 M sodium citrate (pH 7.0), less than 10% of the intact kinetoplast DNA melts in the temperature region of sonicated kinetoplast DNA. In 7.2 M NaCl04 the kinetoplast DNA melts with a Tm 26 degrees C higher than sonicated kinetoplast DNA. Even after complete melting in 7.2 M NaClO4 at 90 degrees C, the network remains intact, as judged by regain of hypochromicity on cooling and analysis in CsCl containing propidium dixodide. (b) In alkaline sucrose gradients more than 90% of the kinetoplast DNA sediments in a single peak. 2. In CsCl gradients containing ethidium bromide of propidium diiodide intact kinetoplast DNA gives a single uni-modal band showing an extremely restricted dye uptake. From the position of the bank relative to the bands of PM2 DNA, the superhelix density of these networks is calculated to be +3.9 twists per 1000 base pairs. The superhelix density of closed mini-circles, efficiently liberated from the networks by shear in a French press, is -0.5 twists per 1000 base pairs. We attribute the high superhelix density (the highest yet observed in any DNA) of intact networks to their compact, highly catenated structure, leading to an additional constraint on dye uptake, superimposed on the restriction due to closed circularity.

Mitochondrial DNA of Tetrahymena pyriformis strain ST contains a long terminal duplication-inversion.

1. We have studied denatured Tetrahymena mtDNA by electron microscopy using the formamide technique. 2. After denaturation all DNA is single stranded, but within a few minutes single-stranded circles with a duplex tail are formed. 3. The duplex tail is 1.3 mum long, i.e. 8 percent of the length of native mtDNA, and it often contains a small single-stranded eye. 4. Digestion of the duplex DNA with exonuclease III of Escherichia coli abolishes its ability to form circles and duplex tails after denaturation. 5. Renaturation of denatured mtDNA leads to the formation of duplex circles with single-stranded section and/or duplex tails. In addition, a minority of duplex circles without apparent tails is formed, but these circles contain a small ambiguous section. 6. We conclude that this mtDNA contains a long terminal duplication-inversion, that could be involved in the replication of this linear mtDNA.