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Query: EC:3.4.25.1 (
proteasome
)
28,817
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
proteasome
11 S regulator (REG) consists of two homologous subunits, REGalpha and
REGbeta
. Each subunit is capable of activating the
proteasome
, and when combined, they form superactive REGalpha/
REGbeta
complexes. We have previously shown that a highly conserved loop in the REGalpha crystal structure is critical for
proteasome
activation. We now show that hetero-oligomers formed from REGalpha activation loop mutants and wild-type
REGbeta
or vice versa are partially active. By contrast, hetero-oligomers bearing mutations in the activation loops of REGalpha and
REGbeta
subunits are inactive, demonstrating that both alpha and beta subunits contribute to
proteasome
activation. We have also characterized REG proteins with mutations near or at their C termini. Partially active REGalpha(Y249C) and REGalpha(M247V) and an inactive REGalpha subunit bearing five additional C-terminal amino acids formed active hetero-oligomers with
REGbeta
.
REGbeta
subunits lacking 1, 2, or 9 C-terminal amino acids did not bind or activate the
proteasome
, but each of these mutants formed partially active hetero-oligomers with the monomer REGalpha(N50Y). However, hetero-oligomers formed from REG subunits lacking the last 14 amino acids were unable to bind the
proteasome
. Thus, C-terminal regions of both alpha and beta subunits are required for hetero-oligomers to bind the
proteasome
.
...
PMID:The proteasome activator 11 S regulator or PA28. Contribution By both alpha and beta subunits to proteasome activation. 980 39
The catalytic activity of the 20S
proteasome
can be modulated by endogenous proteins. A
proteasome
activator protein termed PA28 or 11S regulator, composed of two homologous subunits (alpha and beta) and a separate but related protein termed Ki antigen or PA28gamma have been characterized. To explore the functional relationship of these proteins, NT2 clone D1 human neuronal precursor cells, as well as HeLa S3 cells were labeled by immunofluorescence and immunoelectron microscopy with three different antisera directed against peptides derived from their sequences. It was found that both PA28alpha and
PA28beta
antisera label the cytoplasm and the nucleoli. In contrast, the PA28gamma antiserum labels the nucleus but not the nucleoli while in the cytoplasm it labels two different classes of structures identified as microtubular-like extensions and inclusion bodies that are most likely autophagosomes. The latter do not contain
proteasome
delta subunit antigen. The microtubular-like structures colocalize with beta-tubulin, are dispersed by nocodazole and are not affected by brefeldin A treatment. PA28alpha and
PA28beta
are co-localized in the cell whereas PA28gamma has a different distribution. PA28gamma complexed with the
proteasome
may serve a function other than or in addition to activation and may also have a
proteasome
-independent function.
...
PMID:Proteasome activator (PA28) subunits, alpha, beta and gamma (Ki antigen) in NT2 neuronal precursor cells and HeLa S3 cells. 984 Apr 65
Two
proteasome
activators PA28alpha and beta, which have been implicated in antigen processing for loading class I MHC molecules, are synthesized in response to Ifn-gamma. The human genes encoding these activators (PSME1 and PSME2, respectively) were analyzed by sequencing. Each gene comprised 11 exons, consistent with gene duplication during vertebrate evolution. The intron/exon organization of both genes was highly conserved, the major difference being the absence of the exon encoding the lysine and glutamic acid-rich 'KEKE' motif in
PA28beta
. Two other genes of relevance to the immune system were located close to those for PA28 at 14q11.2 including ISGF3G, a protein involved in transcription after IFNalpha signalling. These sequences were also characterized.
...
PMID:Organization of the genes encoding the human proteasome activators PA28alpha and beta. 1019 20
The PMSE2 gene encodes the beta-subunit of the
proteasome
activator PA28 and, as shown by genomic Southern blot analysis, there probably exist four copies sharing sequence homology with PMSE2. Here, we report that in the mouse genome there exist two different chromosomal loci for
PA28beta
, both of which are transcribed and and which encode a functional
PA28beta
subunit. One of these represents the previously described PMSE2 gene possessing an intron-exon structure and a gamma interferon (IFNgamma)-inducible promoter. The second one, named PMSE2b, which we describe here, exhibits all the characteristics of an expressed retrotransposon. Our data show that the
PA28beta
retrotransposon is inserted into a transcriptional active LINE1 element and is driven by a LINE1 F-type monomer promoter as revealed by luciferase assays. The resulting PMSE2b mRNA encodes a protein which is indistinguishable from that encoded by the IFNgamma-inducible PMSE2 gene. Since PA28 plays an important role in major histocompatibility complex class I antigen presentation, the implications for the mouse immune system through a constitutively expressed
PA28beta
subunit and the biological relevance of this finding are discussed.
...
PMID:A second gene encoding the mouse proteasome activator PA28beta subunit is part of a LINE1 element and is driven by a LINE1 promoter. 1022 92
There are two immune responses in vertebrates: humoral immunity is mediated by circulating antibodies, whereas cytotoxic T lymphocytes (CTL) confer cellular immunity. CTL lyse infected cells upon recognition of cell-surface MHC Class I molecules complexed with foreign peptides. The displayed peptides are produced in the cytosol by degradation of host proteins or proteins from intracellular pathogens that might be present. Proteasomes are cylindrical multisubunit proteases that generate many of the peptides eventually transferred to the cell surface for immune surveillance. In mammalian proteasomes, six active sites face a central chamber. As this chamber is sealed off from the enzyme's surface, there must be mechanisms to promote entry of substrates. Two protein complexes have been found to bind the ends of the
proteasome
and activate it. One of the activators is the 19 S regulatory complex of the 26 S
proteasome
; the other activator is '11 S REG' [Dubiel, Pratt, Ferrell and Rechsteiner (1992) J. Biol. Chem. 267, 22369-22377] or 'PA28' [Ma, Slaughter and DeMartino (1992) J. Biol. Chem. 267, 10515-10523]. During the past 7 years, our understanding of the structure of REG molecules has increased significantly, but much less is known about their biological functions. There are three REG subunits, namely alpha, beta and gamma. Recombinant REGalpha forms a ring-shaped heptamer of known crystal structure. 11 S REG is a heteroheptamer of alpha and beta subunits. REGgamma is also presumably a heptameric ring, and it is found in the nuclei of the nematode work Caenorhabditis elegans and higher organisms, where it may couple proteasomes to other nuclear components. REGalpha and
REGbeta
, which are abundant in vertebrate immune tissues, are located mostly in the cytoplasm. Synthesis of REG alpha and beta subunits is induced by interferon-gamma, and this has led to the prevalent hypothesis that REG alpha/beta hetero-oligomers play an important role in Class I antigen presentation. In the present review we focus on the structural properties of REG molecules and on the evidence that REGalpha/beta functions in the Class I immune response.
...
PMID:The proteasome activator 11 S REG (PA28) and class I antigen presentation. 1060 Jun 33
The
proteasome
activator PA28 binds to both ends of the central catalytic machine, known as the 20 S
proteasome
, in opposite orientations to form the enzymatically active
proteasome
. The PA28 family is composed of three members designated alpha, beta, and gamma; PA28alpha and
PA28beta
form the heteropolymer mainly located in the cytoplasm, whereas PA28gamma forms a homopolymer that predominantly occurs in the nucleus. Available evidence indicates that the heteropolymer of PA28alpha and
PA28beta
is involved in the processing of intracellular antigens, but the function of PA28gamma remains elusive. To investigate the role of PA28gamma in vivo, we generated mice deficient in the PA28gamma gene. The PA28gamma-deficient mice were born without appreciable abnormalities in all tissues examined, but their growth after birth was retarded compared with that of PA28gamma(+/-) or PA28gamma(+/+) mice. We also investigated the effects of the PA28gamma deficiency using cultured embryonic fibroblasts; cells lacking PA28gamma were larger and displayed a lower saturation density than their wild-type counterparts. Neither the expression of PA28alpha/beta nor the subcellular localization of PA28alpha was affected in PA28gamma(-/-) cells. These results indicate that PA28gamma functions as a regulator of cell proliferation and body growth in mice and suggest that neither PA28alpha nor
PA28beta
compensates for the PA28gamma deficiency.
...
PMID:Growth retardation in mice lacking the proteasome activator PA28gamma. 1060 95
PA28 is an interferon-gamma inducible modulator of
proteasome
function composed of two subunits, i.e. PA28alpha and
PA28beta
. Previously we showed that stabile overexpression of the PA28alpha subunit alone supported MHC class I antigen presentation of two viral epitopes. However, no information was obtained on the consequences when PA28alpha and
PA28beta
function in concert or when
PA28beta
is overexpressed on its own. Here we demonstrate that overexpression of PA28alpha and beta together is similarly efficient in supporting MHC class I antigen presentation of the MCMV pp89 9mer epitope as PA28alpha alone, excluding a potentially potentiating role of
PA28beta
. Surprisingly, and despite the fact that
PA28beta
alone was thought to be inactive and to only stabilize PA28 activity, overexpression of
PA28beta
also resulted in improved antigen presentation. However, by northernblot and immunoprecipitation experiments we show that while PA28alpha is able to act alone the observed effect in the
PA28beta
and PA28alphabeta transfectant cell lines is due to increased levels of PA28alphabeta complexes.
...
PMID:PA28alphabeta double and PA28beta single transfectant mouse B8 cell lines reveal enhanced presentation of a mouse cytomegalovirus (MCMV) pp89 MHC class I epitope. 1078 31
The REG homologs, alpha, beta and gamma, activate mammalian proteasomes in distinct ways. REGalpha and
REGbeta
activate the trypsin-like, chymotrypsin-like and peptidylglutamyl-preferring active sites, whereas REGgamma only activates the
proteasome
's trypsin-like subunit. The three REG homologs differ in carboxyl-terminal sequences that are located next to activation loops on their
proteasome
binding surface. To assess the importance of these carboxyl-terminal sequences in the activation of specific
proteasome
beta catalytic subunits, we characterized chimeras in which 8 or 12 residues were exchanged among the three proteins. Like the wild-type molecule, REGalpha chimeras activated all three
proteasome
catalytic subunits regardless of the carboxyl-terminal sequence. However, REGalpha-beta chimeras activated the
proteasome
at lower concentrations than wild-type REGalpha and higher levels of REGalpha-gamma chimeras were needed for maximal activation because exchanged carboxyl-terminal sequences can stabilize (REGalpha-beta) or destabilize (REGalpha-gamma) the REGalpha heptamer. REGgamma chimeras were equivalent to REGgamma in their activation properties, but they bound the
proteasome
less tightly than the wild-type molecule.
REGbeta
chimeras also bound the
proteasome
more weakly than wild-type
REGbeta
and were virtually unable to activate it. Our findings demonstrate that the carboxyl-terminal sequences of REG subunits can affect heptamer stability and
proteasome
affinity, but they do not determine which
proteasome
beta subunits become activated.
...
PMID:The proteasome activator 11 S REG or PA28: chimeras implicate carboxyl-terminal sequences in oligomerization and proteasome binding but not in the activation of specific proteasome catalytic subunits. 1083 74
The activation kinetics of constitutive and IFNgamma-stimulated 20S proteasomes obtained with homomeric (recPA28alpha, recPA28beta) and heteromeric (recPA28alphabeta) forms of recombinant 11S regulator PA28 was analysed by means of kinetic modelling. The activation curves obtained with increasing concentrations of the individual PA28 subunits (RecP28alpha/RecP28beta/RecP28alpha + RecP28beta) exhibit biphasic characteristics which can be attributed to a low-level activation by PA28 monomers and full
proteasome
activation by assembled activator complexes. The dissociation constants do not reveal significant differences between the constitutive and the immunoproteasome. Intriguingly, the affinity of the
proteasome
towards the recPA28alphabeta complex is about two orders of magnitude higher than towards the homomeric PA28alpha and
PA28beta
complexes. Striking similarities can been revealed in the way how PA28 mediates the kinetics of latent proteasomes with respect to three different fluorogenic peptides probing the chymotrypsin-like, trypsin-like and peptidylglutamyl-peptide hydrolyzing like activity: (a) positive cooperativity disappears as indicated by a lack of sigmoid initial parts of the kinetic curves, (b) substrate affinity is increased, whereby (c), the maximal activity remains virtually constant. As these kinetic features are independent of the peptide substrates, we conclude that PA28 exerts its activating influence on the
proteasome
by enhancing the uptake (and release) of shorter peptides.
...
PMID:Kinetic evidences for facilitation of peptide channelling by the proteasome activator PA28. 1101 76
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.
...
PMID:Tissue distribution of constitutive proteasomes, immunoproteasomes, and PA28 in rats. 1103 29
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