Peroxisome assembly mutations in humans: structural heterogeneity in Zellweger syndrome.

Empty membrane ghosts of peroxisomes were found in fibroblasts from a patient with Zellweger's syndrome, a genetic disease of humans (Santos et al: Science 239:1536-1538, 1988). Import of soluble matrix proteins into the organelle was defective. We have now studied fibroblasts from seven patients representing five complementation groups of the syndrome (defined by complementation for peroxisome enzyme function). We find that empty peroxisome ghosts are present in all seven cell samples. Three patients, representing three complementation groups, give the same membrane pattern by immunofluorescence: few large ghosts. Three other patients, representing two complementation groups, give a second pattern: many large ghosts. The seventh patient's pattern is distinct. Thus, all seven of these patients exhibit Peroxisome IMport (PIM) mutations. Since membrane assembly occurs in these cells, the results indicate that biogenesis of organelle content and membrane proteins proceed by different mechanisms. Growth and division of the empty peroxisomal membrane must occur, but are modified by the mutations (ghost size and abundance vary). Cell fusion and immunofluorescence analyses of peroxisome size and catalase packaging formally demonstrate genetic complementation groups for peroxisome assembly in Zellweger syndrome.     

Indentification of β-oxidation enzymes among peroxisomal polypeptides: Increase in Coomassie blue-stainable protein after clofibrate treatment

Peroxisomes contain enzymes catalyzing the β-oxidation of fatty acids, which have been purified and partially characterized. Hypolipidemic drugs, including clofibrate, cause a marked proliferation of peroxisomes and a striking increase in the activity of their β-oxidation system. We have compared by sodium dodecyl sulfate—polyacrylamide gel electrophoresis the polypeptide patterns of normal and clofibrate-induced peroxisomes and the purified β-oxidation enzymes. The data allow a tentative identification of the β-oxidation enzymes among the peroxisomal polypeptides; these enzymes constitute only a small part of the protein of normal peroxisomes. A subset of peroxisomal polypeptides, including the β-oxidation enzymes, is preferentially increased by clofibrate.     

Kinetochore microtubule numbers of different sized chromosomes

For three species of grasshoppers the volumes of the largest and the smallest metaphase chromosome differ by a factor of 10, but the microtubules (MTs) attached to the individual kinetochores show no corresponding range in numbers. Locusta mitotic metaphase chromosomes range from 2 to 21 μm, and the average number of MTs per kinetochore is 21 with an SD of 4.6. Locusta meiotic bivalents at late metaphase I range from 4 to 40 μm(3), and the kinetochore regions (= two sister kinetochores facing the same spindle pole) have an average of 25 kinetochore microtubules (kMTs) with an SD of 4.9. Anaphase velocities are the same at mitosis and meiosis I. The smaller mitotic metaphase chromosomes of neopodismopsis are similar in size, 6 to 45 μm(3), to Locusta, but they have an average more kMTs, 33, SD = 9.2. The four large Robertsonian fusion chromosomes of neopodismopsis have an average of 67 MTs per kinetochore, the large number possibly the result of a permanent dicentric condition. Chloealtis has three pairs of Robertsonian fusion chromosomes which, at late meiotic metaphase I, form bivalents of 116, 134, and 152 μm (3) with an average of 67 MTs per kinetochore similar to Locusta bivalents, but with a much higher average of 42 MTs per kinetochore region. It is speculated that, in addition to mechanical demands of force, load, and viscosity, the kMT numbers are governed by cell type and evolutionary history of the karyotype in these grasshoppers.     

Enhancement of HERG K(+) currents by Cd(2+) destabilization of the inactivated state

We have studied the functional effects of extracellular Cd(2+) on human ether-a-go-go-related gene (HERG) encoded K(+) channels. Low concentrations (10-200 &mgr;M) of extracellular Cd(2+) increased outward currents through HERG channels; 200 &mgr;M Cd(2+) more than doubled HERG currents and altered current kinetics. Cd(2+) concentrations up to 200 &mgr;M did not change the voltage dependence of channel activation, but shifted the voltage dependence of inactivation to more depolarized membrane potentials. Cd(2+) concentrations >/=500 &mgr;M shifted the voltage dependence of channel activation to more positive potentials. These results are consistent with a somewhat specific ability of Cd(2+) to destabilize the inactivated state. We tested the hypothesis that channel inactivation is essential for Cd(2+)-induced increases in HERG K(+) currents, using a double point mutation (G628C/S631C) that diminishes HERG inactivation (Smith, P. L., T. Baukrowitz, and G. Yellen. 1996. Nature (Lond.). 379:833-836). This inactivation-removed mutant is insensitive to low concentrations of Cd(2+). Thus, Cd(2+) had two distinct effects on HERG K(+) channels. Low concentrations of Cd(2+) caused relatively selective effects on inactivation, resulting in a reduction of the apparent rectification of the channel and thereby increasing HERG K(+) currents. Higher Cd(2+) concentrations affected activation gating as well, possibly by a surface charge screening mechanism or by association with a lower affinity site.     

Immunoblotting of hydrophobic integral membrane proteins

For diagnosis and research purposes it is frequently desirable to measure by immunoblotting small amounts of proteins in complex mixtures such as tissue biopsy homogenates. Standard immunoblot procedures that give excellent results for soluble proteins unexpectedly gave low and irreproducible signals with some hydrophobic membrane proteins. We found that this was due to inefficient electrophoretic transfer to nitrocellulose, which could be corrected by modification of the transblot buffer. Hydrophobic integral membrane proteins of peroxisomes as well as other rat and human liver proteins were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose filters. The nitrocellulose-bound proteins were detected both by staining and by immunoblotting with an antiserum against the 22-kDa integral membrane protein of peroxisomes plus 125I-labeled protein A. A modified transblot buffer with 0.7 M glycine and 25 mM Tris (pH 7.7) but no methanol allowed use of a much shorter transfer time and strikingly improved the electrophoretic transfer of membrane proteins such that a peroxisomal integral membrane protein could be easily detected in human liver biopsy homogenates.     

Peroxisomal integral membrane proteins in control and Zellweger fibroblasts

An entire organelle, the peroxisome, appears to be missing in Zellweger syndrome, causing profound neurological problems and neonatal death. One hypothesis for the molecular cause of this defect is a failure in the assembly of the peroxisomal membrane. An alternative is that the peroxisomal membrane is assembled, but the post-translational import of the matrix proteins is defective. We have investigated these possibilities by analytical cell fractionation, immunoblotting, and immunoelectron microscopy of fibroblasts. We identified four integral membrane proteins that can serve as markers for the human peroxisomal membrane. In Zellweger fibroblasts, peroxisomal membranes were found but they were abnormal; they had an equilibrium density of 1.10 g/cm3 instead of the normal density of 1.17 g/cm3, their diameters were generally 2-4 times greater than normal, and they lacked most content. The existence of these peroxisomal ghosts in Zellweger syndrome fibroblasts supports the hypothesis that the defect in this disease is in the protein import machinery.     

THE SYNTHESIS AND TURNOVER OF RAT LIVER PEROXISOMES : V. Intracellular Pathway of Catalase Synthesis

The subcellular distribution of the biosynthetic intermediates of catalase was studied in the livers of rats receiving a mixture of [³H]leucine and [¹⁴C]δ-aminolevulinic acid by intraportal injection. Postnuclear supernates were fractionated by a one-step gradient centrifugation technique that separates the main subcellular organelles, partly on the basis of size, and partly on the basis of density. Labeled catalase and its biosynthetic intermediates were separated from the gradient fractions by immunoprecipitation, and the distributions of radioactivity were compared with those of marker enzymes. The results show that catalase protein is synthesized outside the peroxisomes, but rapidly appears in these particles, mostly still in the form of the first hemeless biosynthetic intermediate. Addition of heme and completion of the catalase molecule take place within the peroxisomes. During the first 15 min after [³H]leucine administration, more than half of the newly formed first intermediate was recovered in the supernatant fraction, where it was found to exist as an aposubunit of about 60,000 molecular weight.     

STUDIES ON INSULIN BIOSYNTHESIS : Subcellular Distribution of Leucine-H3 Radioactivity During Incubation of Goosefish Islet Tissue

Islet tissue from the goosefish (Lophius piscatorius) was incubated in the presence of leucine-H³. The tissue was then separated into subcellular fractions and the radioactivity determined in total acid alcohol-soluble proteins, insoluble proteins, and insulin. At any time, microsomal protein had a higher activity than secretion granule protein. Pulse-chase experiments further suggest the microsomes as primary sites of protein synthesis. The data are evidence for microsomal synthesis of insulin and for its subsequent transfer into the secretion granules.