The Drosophila PROS-28.1 gene is a member of the proteasome gene family

In the present communication, we report the identification of a new gene family which encodes the protein subunits of the proteasome. The proteasome is a high-M_r complex possessing proteolytic activity. Screening a Drosophila λgt11 cDNA expression library with the proteasome-specific antibody N19-28 we isolated a clone encoding the 28-kDa No. 1 proteasome protein subunit. In accordance with the nomenclature of proteasome subunits in Drosophila, the corresponding gene is designated PROS-28.1, and it encodes an mRNA of 1.1 kb with an open reading frame of 249 amino acids (aa). Genomic Southern-blot hybridization shows PROS-28.1 to be a member of a family of related genes. Analysis of the predicted aa sequence reveals a potential nuclear targeting signal, a potential site for tyrosine kinase and a potential cAMP/cGMP-dependent phosphorylation site. The aa sequence comparison of the products of PROS-28.1 and PROS-35 with the C2 proteasome subunit of rat shows a strong sequence similarity between the different proteasome subunits. The data suggest that at least a subset of the proteasome-encoding genes belongs to a family of related genes (PROS gene family) which may have evolved from a common ancestral PROS gene.     

Specific interaction of proteins with 5 S RNA and tRNA in the 42 S storage particle of Xenopus oocytes

During early oogenesis in amphibia, most of the 5 S RNA and tRNA is stored in a ribonucleoprotein particle that sediments at 42 S. In Xenopus laevis the 42 S particle contains two major proteins: of M_r 48 000 (P48) and 43 000 (P43). It is shown that heterogeneity in composition of the 42 S particle reflects a changing situation whereby initially, both 5 S RNA and tRNA are complexed with P48 (1 molecule 5 S RNA: 1 molecule P48; 2 or 3 molecules tRNA: 1 molecule P48), but later, tRNA becomes increasingly associated with P43 (in a 1:1 ratio) although 5 S RNA remains complexed with a cleavage product of P48. These changes relate to the eventual utilization of the excess 5 S RNA and tRNA in ribosome assembly and protein synthesis.     

Heat-shock proteins are associated with hnRNA in Drosophila melanogaster tissue culture cells

Ribonucleoprotein complexes of Drosophila melanogaster Kc tissue culture cells grown at 24°C or heat-shocked at 37°C were cross-linked in vivo by u.v. irradiation. Cross-linked heterogeneous nuclear ribonucleoprotein (hnRNP) complexes were fractionated by oligo(dT)-cellulose chromatography and CsCI density centrifugation. The hnRNP complexes of both 24°C and 37°C culture cells possess buoyant densities in CsCI between = 1.38 g/cm^-3 and 1.43 g/cm^-3. The ³⁵S-labelled proteins bound to the hnRNA of 37°C culture cells correspond in mol. wt. to the so-called heat-shock proteins of 70 K, 68 K, 27 K, 26 K, 23 K and 22 K. The 70 K and 68 K proteins are also present in hnRNP complexes of 24°C culture cells. In addition, several other Drosophila hnRNPs of 140 K, 56 K, 45 K, 43 K, 38 K, 37 K and 34 K, whose synthesis is strongly repressed under heat-shock conditions, could be identified. The results demonstrate that the so-called heat-shock proteins possess a function as RNPs.     

Molecular analysis of alpha ecdysone induced 16S complexes in Drosophila Schneider's S3 cells

The molecular organization of alpha ecdysone induced small heat shock proteins (small hsps) in Schneider's S3 tissue culture cells was analysed. Sucrose gradient centrifugation of cytoplasmic extracts and nondenaturing gel electrophoresis shows that hormone induced small hsps form 16S particles which differ in the relative molar ratios of the small hsps composing the 16S particles. The 16S particles possess a buoyant density in Cs2SO4 of rho = 1.34 g/cm3 which is indicative of RNP complexes with an RNA:protein ratio of 1:4. The RNA component of the 16S particles was identified by cDNA cloning using a cDNA library established from alpha ecdysone induced pupal 16S material. Northern hybridization using the 16S RNP specific partial cDNA clone Ec3 identifies a single alpha ecdysone inducible 300 nt RNA species. Our data suggest that the small hsps may unfold their so far unresolved function in form of RNP complexes.     

Sequence and Properties of Cagein,a Coiled-Coil Scaffold Protein Linking Basal Bodies in the Polykinetids of the Ciliate Euplotes aediculatus

In the hypotrich ciliate Euplotes, many individual basal bodies are grouped together in tightly packed clusters, forming ventral polykinetids. These groups of basal bodies (which produce compound ciliary organelles such as cirri and oral membranelles) are cross-linked into ordered arrays by scaffold structures known as “basal-body cages.” The major protein comprising Euplotes cages has been previously identified and termed “cagein.” Screening a E. aediculatus cDNA expression library with anti-cagein antisera identified a DNA insert containing most of a putative cagein gene; standard PCR techniques were used to complete the sequence. Probes designed from this gene identified a macronuclear “nanochromosome” of ca. 1.5 kb in Southern blots against whole-cell DNA. The protein derived from this sequence (463 residues) is predicted to be hydrophilic and highly charged; however, the native cage structures are highly resistant to salt/detergent extraction. This insolubility could be explained by the coiled-coil regions predicted to extend over much of the length of the derived cagein polypeptide. One frameshift sequence is found within the gene, as well as a short intron. BLAST searches find many ciliates with evident homologues to cagein within their derived genomic sequences.     

Human immunodeficiency virus-1 Tat protein interacts with distinct proteasomal alpha and beta subunits

The human immunodeficiency virus-1 (HIV-1) Tat protein was previously reported to compete the association of PA28 regulator with the alpha rings of the 20S proteasome and to inhibit its peptidase activity. However, the distinct interaction sites within the proteasome complex remained to be determined. Here we show that HIV-1 Tat binds to alpha4 and alpha7, six beta subunits of the constitutive 20S proteasome and the interferon-gamma-inducible subunits beta2i and beta5i. A Tat-proteasome interaction can also be demonstrated in vivo and leads to inhibition of proteasomal activity. This indicates that Tat can modulate or interfere with cellular proteasome function by specific interaction with distinct proteasomal subunits.     

The role of the ubiquitin-proteasome pathway in MHC class I antigen processing: implications for vaccine design

Proteasomes are multisubunit enzyme complexes that reside in the cytoplasm and nucleus of eukaryotic cells. By selective protein degradation, proteasomes regulate many cellular processes including MHC class I antigen processing. Three constitutively expressed catalytic subunits are responsible for proteasome mediated proteolysis. These subunits are exchanged for three homologous subunits, the immunosubunits, in IFNgamma-exposed cells and in cells with specialized antigen presenting function. Both constitutive and immunoproteasomes degrade endogenous proteins into small peptide fragments that can bind to MHC class I molecules for presentation on the cell surface to cytotoxic T lymphocytes. However, immunoproteasomes seem to fulfill this function more efficiently. IFNgamma further induces the expression of a proteasome activator, PA28, which can also enhance antigenic peptide production by proteasomes. In this review, we will introduce the ubiquitin-proteasome system and summarize recent findings regarding the role of the IFNgamma-inducible proteasome subunits and proteasome regulators in antigen processing. We review the different ways by which tumors and viruses have been found to target the proteasome system to avoid MHC class I presentation of their antigens, and discuss recent progressions in the development of computer assisted approaches to predict CTL epitopes within larger protein sequences, based on proteasome cleavage specificity. The availability of such programs as well as a general insight into the proteasome mediated steps in MHC class I antigen processing provides us with a rational basis for the design of new antiviral and anticancer T cell vaccines.     

The RTP site shared by the HIV-1 Tat protein and the 11S regulator subunit alpha is crucial for their effects on proteasome function including antigen processing

Nuclease A (NucA) from Anabaena sp. is a non-specific endonuclease able to degrade single and double-stranded DNA and RNA. The endonucleolytic activity is inhibited by the nuclease A inhibitor (NuiA), which binds to NucA with 1:1 stoichiometry and picomolar affinity. In order to better understand the mechanism of inhibition, the solution structure of NuiA was determined by NMR methods. The fold of NuiA is an alpha-beta-alpha sandwich but standard database searches by DALI and TOP revealed no structural homologies. A visual inspection of alpha-beta-alpha folds in the CATH database revealed similarities to the PR-1-like fold (SCOP nomenclature). The similarities include the ordering of secondary structural elements, a single helix on one face of the alpha-beta-alpha sandwich, and three helices on the other face. However, a major difference is in the IV helix, which in the PR-1 fold is short and perpendicular to the I and III helices, but in NuiA is long and parallel to the I and III helices. Additionally, a strand insertion in the beta-sheet makes the NuiA beta-sheet completely antiparallel in organization. The fast time-scale motions of NuiA, characterized by enhanced flexibility of the extended loop between helices III and IV, also show similarities to P14a, which is a PR-1 fold. We propose that the purpose of the PR-1 fold is to form a stable scaffold to present this extended structure for biological interactions with other proteins. This hypothesis is supported by data that show that when NuiA is bound to NucA significant changes in chemical shift occur in the extended loop between helices III and IV.