Proteasome subunit zeta,a putative ribonuclease,is also found as a free monomer

20 S Proteasomes are large proteinase complexes found in eukaryotic cells where they degrade cell proteins in an ATP-dependent manner. Proteasomes consist of 14 different subunits. One of them, zeta, was found in HeLa cells at a concentration of 890 g per g of cell protein. A large proportion of zeta was found in the free state rather than incorporated into proteasomes, namely 28% in HeLa cells and 37% in BSC-1 cells. Free zeta was found in both nuclei and cytoplasm. In HeLa cells free zeta had a t1/2 of 2.8 h, compared to 5 d for proteasomes, and did not exchange with zeta in proteasomes. We confirmed (Petit F et al.: Biochem. J. 326: 93–98 (1997)) that both 20 S proteasomes and free zeta subunits possess RNase activity though the activities were very low: 4 mMoles and 0.6 mMoles of tobacco mosaic virus RNA degraded per mole of enzyme per min, respectively. The physiological function of the relatively abundant zeta monomers is not known.     

Cooperation of multiple chaperones required for the assembly of mammalian 20S proteasomes

The 20S proteasome is a catalytic core of the 26S proteasome, a central enzyme in the degradation of ubiquitin-conjugated proteins. It is composed of 14 distinct gene products that form four stacked rings of seven subunits each, alpha(1-7)beta(1-7)beta(1-7)alpha(1-7). It is reported that the biogenesis of mammalian 20S proteasomes is assisted by proteasome-specific chaperones, named PAC1, PAC2, and hUmp1, but the details are still unknown. Here, we report the identification of a chaperone, designated PAC3, as a component of alpha rings. Although it can intrinsically bind directly to both alpha and beta subunits, PAC3 dissociates before the formation of half-proteasomes, a process coupled with the recruitment of beta subunits and hUmp1. Knockdown of PAC3 impaired alpha ring formation. Further, PAC1/2/3 triple knockdown resulted in the accumulation of disorganized half-proteasomes that are incompetent for dimerization. Our results describe a cooperative system of multiple chaperones involved in the correct assembly of mammalian 20S proteasomes.     

Intracellular degradation of hemoglobin transferred into fibroblasts by fusion with red blood cells

Hamster fibroblast protein and rabbit hemoglobin were labelled by incubation of fibroblasts (BHK21) or reticulocytes with [³H]leucine. Alternatively, human or rabbit hemoglobin was labelled by carbamoylation of erythrocytes with K¹⁴CNO. The labelled hemoglobins were introduced into fibroblasts by virus-mediated fusion between the blood cells and fibroblasts. The hemoglobins became uniformly distributed throughout the cytoplasm. Degradation was assessed from release of acid-soluble radioactivity into the medium. Radioactivity from [¹⁴C]-carbamoylhemoglobin was released as carbamoylvaline and homocitrulline, and these compounds were not metabolized or reincorporated by the cells. Intermediate degradation products could not be detected. The degradation of hemoglobin followed first-order kinetics. The half-life of both carbamoylated and native rabbit hemoglobin in hamster fibroblasts was 28 h, and the half-life of carbamoylated human hemoglobin was about 150 h in fibroblasts from hamster (BHK21), mouse (Balb/3T3), and man (MRC 5), corresponding to that of the more stable endogenous proteins. Phenylhydrazine increased the intracellular degradation of carbamoylated human hemoglobin about 13 times, whereas the degradation of endogenous proteins was little affected. Hemoglobin was degraded in homogenates at 31% h^?1 at pH 5 and 0.3% h^?1 at pH 7.4. Phenylhydrazine increased these rates to 45% h^?1 and 9.7% h^?1, respectively. Growing hamster fibroblasts, which are brought into quiescence by serum deprivation or by high culture density, increase the degradation of endogenous protein and of hemoglobin in parallel.     

The 20S Proteasome as an Assembly Platform for the 19S Regulatory Complex

26S proteasomes consist of cylindrical 20S proteasomes with 19S regulatory complexes attached to the ends. Treatment with high concentrations of salt causes the regulatory complexes to separate into two sub-complexes, the base, which is in contact with the 20S proteasome, and the lid, which is the distal part of the 19S complex. Here, we describe two assembly intermediates of the human regulatory complex. One is a dimer of the two ATPase subunits, Rpt3 and Rpt6. The other is a complex of nascent Rpn2, Rpn10, Rpn11, Rpn13, and Txnl1, attached to preexisting 20S proteasomes. This early assembly complex does not yet contain Rpn1 or any of the ATPase subunits of the base. Thus, assembly of 19S regulatory complexes takes place on preexisting 20S proteasomes, and part of the lid is assembled before the base.     

Adrm1, a putative cell adhesion regulating protein, is a novel proteasome-associated factor

We have identified Adrm1 as a novel component of the regulatory ATPase complex of the 26 S proteasome: Adrm1 was precipitated with an antibody to proteasomes and vice versa. Adrm1 co-migrated with proteasomes on gel-filtration chromatography and non-denaturing polyacrylamide gel electrophoresis. Adrm1 has been described as an interferon-gamma-inducible, heavily glycosylated membrane protein of 110 kDa. However, we found Adrm1 in mouse tissues only as a 42 kDa peptide, corresponding to the mass of the non-glycosylated peptide chain, and it could not be induced in HeLa cells with interferon. Adrm1 was present almost exclusively in soluble 26 S proteasomes, albeit a small fraction was membrane-associated, like proteasomes. Adrm1 was found in cells in amounts equimolar with S6a, a 26 S proteasome subunit. HeLa cells contain no pool of free Adrm1 but recombinant Adrm1 could bind to pre-existing 26 S proteasomes in cell extracts. Adrm1 may be distantly related to the yeast proteasome subunit Rpn13, mutants of which are reported to display no obvious phenotype. Accordingly, knock-down of Adrm1 in HeLa cells had no effect on the amount of proteasomes, or on degradation of bulk cell protein, or accumulation of polyubiquitinylated proteins. This indicates that Adrm1 has a specialised role in proteasome function.     

Cloning and characterization of mouse Lmp3 cDNA, encoding a proteasome β subunit

We isolated and sequenced a cDNA encoding mouse proteasome subunit LMP3 from a macrophage cDNA library. The gene encodes a 264-amino-acid protein with a calculated molecular mass of 29.11 kDa and an isoelectric point (pl) of 5.44. Comparison of the predicted protein sequence with that of the human and rat homologues, N3, revealed 11 and eight changes, respectively, in the cleaved NH₂-terminal presequence of the precursor protein (pre-LMP3), and six and 10 changes, respectively, in the processed product. To corroborate the predicted molecular mass and pI, we analyzed LMP3 by immunoprecipitation with a mAb to human N3 that crossreacts with mouse LMP3. Precursor and processed forms of LMP3 were identified by 2D NEPHGE-PAGE, and their mobilities suggest the Lmp3 clone encodes the entire protein sequence.     

Intracellular protein degradation in growing, in density-inhibited, and in serum-restricted fibroblast cultures.

Exponentially growing Balb/3T3 mouse fibroblasts contain protein populations with slow and fast turnover. These two stability classes were labelled selectively with 3H-leucine. The intracellular degradation of the proteins was then followed as the release into the medium of radioactive leucine. The degradation rate of both stability classes of protein is increased by about 55% in cultures whose growth is inhibited by high cell density. Serum-deprivation, which also halts cell growth, accelerates protein breakdown to a smaller extent, the increases for relatively stable and unstable proteins being 30% and 13%, respectively. The density-dependent increase in protein breakdown is also found in BHK21 cells but not in chick fibroblasts. Protein degradation in Balb/3T3 cells transformed by simian virus 40 is affected by serum-deprivation but not by cell density. The proteins which are relatively stable during growth were shown to become less stable in density-inhibited or serum-deprived cultures, and vice versa. Cycloheximide inhibits degradation to a variable extent. Dibutyryl adenosine-3',5'-cyclic monophosphate has no effect on the protein degradation under the conditions investigated here.     

Tissue distribution of constitutive proteasomes, immunoproteasomes, and PA28 in rats

We investigated the expression of standard proteasomes, immunoproteasomes, and their regulators, PA28, and PA700, in rat tissues. Immunoproteasomes (with subunits LMP2, LMP7, and MECL1) were abundant in the spleen but almost absent in the brain. In contrast, standard proteasomes (with X, Y, and Z) were highly expressed in the brain but not in the spleen. Both proteasome types were present in the lung and the liver. PA700 subunits (p112, S5a, and p45) were found in all tissues. PA28alpha, PA28beta, and PA28gamma were also expressed in all tissues, except for the brain which contained very little PA28beta. The results did not depend on rat sex or age. The cleavage specificity for peptide substrates differed greatly between brain and spleen proteasomes. Hybrid proteasomes, containing both PA28alphabeta and PA700, were not present in the brain but in all other tissues examined.     

The human multicatalytic proteinase: affinity purification using a monoclonal antibody

A monoclonal antibody, coupled to Sepharose CL-4B, was used for the rapid purification of the human multicatalytic proteinase in a single chromatographic step under mild conditions. The enzyme was homogeneous as judged by nondenaturing polyacrylamide gel electrophoresis. Electrophoresis under dissociating and reducing conditions revealed at least ten components with molecular masses in the range 22-34 kDa. Affinity-purified enzyme was identical to conventionally purified enzyme with respect to enzymatic properties, molecular mass and subunit composition.