Extended reading frame of a ubiquitin gene encodes a stable, conserved, basic protein

Histone Posttranslational Modifications of CD4⁺ T Cell in Autoimmune Diseases

The complexity of immune system is tempered by precise regulation to maintain stabilization when exposed to various conditions. A subtle change in gene expression may be magnified when drastic changes are brought about in cellular development and function. Posttranslational modifications (PTMs) timely alter the functional activity of immune system, and work proceeded in these years has begun to throw light upon it. Posttranslational modifications of histone tails have been mentioned in a large scale of biological developments and disease progression, thereby making them a central field to investigate. Conventional assessments of these changes are centered on the transcription factors and cytokines in T cells regulated by variable histone codes to achieve chromatin remodeling, as well as involved in many human diseases, especially autoimmune diseases. We here put forward an essential review of core posttranslational modulations that regulate T cell function and differentiation in the immune system, with a special emphasis on histone modifications in different T helper cell subsets as well as in autoimmune diseases.

The HBx protein of hepatitis B virus regulates the expression, intracellular distribution and functions of ribosomal protein S27a

The pleiotropic HBx protein of hepatitis B virus is linked functionally to the development of hepatocellular carcinoma (HCC) via effectors and signalling pathways of the host. To identify such effectors in a macrocarcinogenic environment, a PCR-based cDNA subtraction analysis was carried out in the X15-myc oncomouse model of HCC. Altogether, 19 categories of genes, mainly involved in protein biosynthesis and the electron-transport chain, were found to be upregulated in the liver of these mice. Ribosomal protein S27a (RPS27a), which is a natural fusion protein of N-terminal ubiquitin and C-terminal extension protein (CEP), topped the list of expressed genes, with >20-fold higher expression compared with its normal level. Sustained and elevated expression of RPS27a in the mouse liver and its moderate expression in cell culture in the presence of HBx suggested an indirect role of RPS27a in hepatocarcinogenesis. Nevertheless, a remarkable change in the intracellular distribution of ubiquitin from cytoplasm to late-endosomal lysosomes, and of CEP from nucleoli to the perinucleolar region/nuclear foci, was observed in the presence of HBx. RPS27a accelerated the progression of the cell cycle and cooperated with HBx in this process. Further, the knockdown of RPS27a expression by RNA interference in an HBx microenvironment led to retarded cell-cycle progression and reduced cell size. Thus, these results suggest strongly that RPS27a could be an effector of HBx-mediated hepatocarcinogenesis.

Assembly of protein-RNA complexes using natural RNA and mutant forms of an RNA cytosine methyltransferase

This work reveals that mutant forms of RNA methyltransferases that form 5-methylcytosine (m5C) have characteristics that may make them useful for biomacromolecular assembly. The experiments utilized bacterially expressed Trm4p, a tRNA methyltransferase cloned from Saccharomyces cerevisiae. Like DNA m5C methyltransferases, Trm4p mediates methylation using a covalent intermediate, which would allow Trm4p to be trapped as a stable protein-RNA complex when the substrate RNA contains a modified cytosine base such as 5-fluorocytosine. However, mutant forms of Trm4p are identified that fail to release RNA resulting in the formation of denaturant stable methyltransferase-RNA complexes that contain only natural nucleotides. The ability to form stable complexes with natural RNA gives these mutant forms of Trm4p greater potential versatility for biomacromolecule construction applications than the wild-type Trm4p enzyme or DNA methyltransferases for which the trapping of the covalent intermediate requires the presence of a nucleotide analogue at the site of modification.

Effects of cyclization on conformational dynamics and binding properties of Lys48-linked di-ubiquitin

In solution, Lys48-linked di-ubiquitin exists in dynamic equilibrium between closed and open conformations. To understand the effect of interdomain motion in polyubiquitin chains on their ability to bind ligands, we cyclized di-ubiquitin by cross-linking the free C terminus of the proximal ubiquitin with the side chain of residue 48 in the distal ubiquitin, using a chemical cross-linker, 1,6-Hexane-bis-vinylsulfone. Our NMR studies confirm that the cyclization affects conformational dynamics in di-ubiquitin by restricting opening of the interface and shifting the conformational equilibrium toward closed conformations. The cyclization, however, did not rigidly lock di-ubiquitin in a single closed conformation: The chain undergoes slow exchange between at least two closed conformations, characterized by interdomain contacts involving the same hydrophobic patch residues (Leu8-Ile44-Val70) as in the uncyclized di-ubiquitin. Lowering the pH changes the relative populations of these conformations, but in contrast with the uncyclized di-ubiquitin, does not lead to opening of the interface. This restriction of domain motions inhibits direct access of protein molecules to the hydrophobic patch residues located at the very center of the interdomain interface in di-ubiquitin, although the residual motions are sufficient to allow access of small molecules to the interface. This renders di-ubiquitin unable to bind protein molecules (e.g., UBA2 domain) in the normal manner, and thus could interfere with Ub(2) recognition by various downstream effectors. These results emphasize the importance of the opening/closing domain motions for the recognition and function of di-ubiquitin and possibly longer polyubiquitin chains.

RNA methyltransferases utilize two cysteine residues in the formation of 5-methylcytosine

Proteins that have sequence homology with known RNA m(5)C methyltransferases contain two conserved cysteines, each of which lies within a sequence that bears similarity to a methyltransferase active site. Other enzymes that transfer a methyl group to carbon 5 of a pyrimidine nucleotide, such as the bacterial DNA m(5)C methyltransferases, utilize their single conserved cysteine residue to form a covalent Michael adduct with carbon 6 of the pyrimidine ring during catalysis. We present a model for the utilization of two cysteines in catalysis by RNA m(5)C methyltransferases. It is proposed that one thiol acts in a classical fashion by forming a covalent link to carbon 6 of the pyrimidine base, while the other cysteine assists breakdown of the covalent adduct. Therefore, alteration of the assisting cysteine is anticipated to stabilize the covalent enzyme-RNA intermediate. The model was conceived as a possible explanation for the effects of mutations that change the conserved cysteines in Nop2p, an apparent RNA m(5)C methyltransferase that is essential for ribosome assembly and yeast viability. Evidence for the predicted accumulation of protein-RNA complexes following mutation of the assisting cysteine has been obtained with Nop2p and a known tRNA m(5)C methyltransferase called Ncl1p (Trm4).

The ubiquitin superfamily: members, features, and phylogenies

The ubiquitin superfamily is a rich repository of small, conserved, functionally unique, and important proteins. Its member proteins fold simply and similarly, with kinetic and thermodynamic ease (Sorenson, J. M.; Head-Gordon, T. Toward minimalist models of larger proteins: A ubiquitin-like protein. Proteins 2002, 46, 368-379). They have been implicated in numerous cancers, neurodegenerations, inflammations, and various disorders affecting signal transduction or protein half-life. These proteins serve the cell generally as portable recognition tags with distinct intracellular roles; indeed, tagging with small protein modifiers has become a new hallmark of post-translational modifications and other signal transduction phenomenon (Finley, D. J. Signal transduction. An alternative to destruction. Nature 2001, 412, 283, 285-286). Because many ubiquitin-like proteins bear similarities in sequence, structure, and function, we gathered protein sequences containing the ubiquitin domain from public databases and created a highly granular and defined protein catabolism database to catalog, summarize, reference, and relate them to their targets and specific ligases (to be described elsewhere). In this paper, we reveal a compilation of proteins possessing the ubiquitin domain. This comprises the first and most important part of our database content. We searched available organismal proteomes for sequence-related members of the ubiquitin superfamily and here present over 200 proteins possessing this domain. These proteins were organized phylogenetically and functionally, thereby defining several new families. To our knowledge, this is the most complete assemblage of ubiquitin domains to date.

Structure of the human ubiquitin fusion gene Uba80 (RPS27a) and one of its pseudogenes

Ubiquitin is a highly conserved 76 amino acid protein that is generated in the cell by proteolysis of larger proteins containing either polyubiquitin chains or ubiquitin fused to carboxyl extension proteins (CEPs). In humans, the two human ubiquitin-CEP genes are Uba80 and Uba52, which code for ubiquitin fused to ribosomal protein S27a and L40, respectively. Working from a recently generated physical map of human chromosome 2p16, we determined the genetic and physical location and the genomic structure of the Uba80 gene in its entirety. A comparison of Uba80 to Uba52 revealed that the two genes share a conserved 5'-end structure, but that the structure of the ubiquitin coding regions was not conserved. Analysis of 400 bp of the promoter of Uba80 revealed strong similarity not only to the Uba52 promoter, but also to the other known human ribosomal gene promoters that have been identified to date. Homology searches also detected the presence of a pseudogene for Uba80, and the structure of this sequence feature is also reported.

Unique gene organization: alternative splicing in Drosophila produces two structurally unrelated proteins

The Ub80 gene in eukaryotes produces a ubiquitin fusion protein in which ubiquitin is fused in frame to a tail protein (Redman and Rechsteiner, 1988; Finley et al., 1989; Barrio et al., 1994). The tail protein is incorporated into the ribosome, and ubiquitin is thought to act as a chaperone. The DUb80 gene of Drosophila melanogaster was cloned by Barrio et al. (1994) and contains a 5'-untranslated exon, followed by a large intron and then the first coding exon. We report that the large intron of DUb80 contains an open reading frame, which produces a 259-aa protein (IP259) that is conserved in eukaryotes from yeast to mammals. Transcription of the DUb80 and IP259 mRNAs begins at the same start sites. However, alternate splicing of the primary transcript produces two structurally unrelated proteins. This is the second reported instance of two structurally unrelated proteins being produced via alternate splicing, suggesting that this form of genomic organization may be more common than previously thought.

Post-translational processing of rat ribosomal proteins. Ubiquitous methylation of Lys22 within the zinc-finger motif of RL40 (carboxy-terminal extension protein 52) and tissue-specific methylation of Lys4 in RL29

The complete amino acid sequences of rat and yeast (Saccharomyces cerevisiae) ribosomal proteins derived from precursors containing an N-terminal ubiquitin or ubiquitin-like sequence (C-terminal extension proteins or CEPs) were determined and investigated for any post-translational modifications by reverse-phase HPLC purification, direct amino acid sequence and mass spectrometric analyses. Covalent modifications were detected in the rat liver proteins RS27a (CEP-80), RL29, RL37 and RL40 (CEP-52), while RS30 (CEP), RL36a, RL39 and RL41 were unmodified. Heterogeneity of RS27a was due to C-terminal truncations, with Lys80 missing from about 20% of the liver RS27a population; C-terminal processing was also detected with RL29 and RL37. No other covalent modifications of liver, brain or thymus RS27a were detected. The rat RL40 structure was identical to the cDNA-predicted sequence except for complete stoichiometric N epsilon-trimethylation of Lys22 within its zinc-finger motif; this modification occurred in the ribosomes of all three rat tissues investigated but not in yeast ribosomes. The methylation characteristics of RL40 were distinct from those of ribosomal protein RL29 in the rat, which was differentially monomethylated at Lys4 in the liver, brain and thymus (27%, > 99% and 95% methylation, respectively). In the case of liver, there was no appreciable difference in the RL29 methylation status of free and membrane-bound ribosomes. The possibilities of an essential role for RL40 methylation in the formation of rat ribosomes, and a distinct regulatory role for RL29 methylation in the rat, are discussed.

Expression of ubiquitin, actin, and actin-like genes in African swine fever virus infected cells

Northern blot hybridisation was used to study the accumulation of specific cellular mRNAs (ubiquitin and actin) in Vero cells infected with African swine fever virus (ASFV). ASFV modulates the cytoplasmic levels of ubiquitin and actin mRNAs throughout infection. Before viral DNA replication, degradation of ubiquitin mRNAs is dependent on de novo protein synthesis, since treatment with cycloheximide (CH) allowed the accumulation of ubiquitin mRNAs, while treatment with cytosine arabinoside (araC) induced a reduction in ubiquitin transcripts. Nevertheless, viral DNA replication is essential to the final increase observed in ubiquitin mRNA degradation. Furthermore, ubiquitin transcription seems to be tightly related to viral gene transcription, since before viral DNA replication ubiquitin and viral transcripts accumulate at opposite rates. Concerning actin transcription, the first step in actin mRNA degradation does not depend on de novo protein synthesis, since treatment with CH induced a reduction in actin mRNA. The second step in actin mRNA degradation, similarly to ubiquitin, depends on viral DNA replication. Finally, in the present study it has also been shown that ASFV codifies for actin-like genes. This is the first report of a virus encoding an actin-like gene.

Ubiquitin fusion proteins are overexpressed in colon cancer but not in gastric cancer

A cDNA clone (AF3) encoding the ubiquitin A gene 52 amino acid extension fusion protein (UbA52) was isolated from a subtracted cDNA library of human colorectal carcinoma minus adjacent normal mucosa. In Northern hybridization the mRNA signal for UbA52 was greater in surgical samples of colonic carcinoma (T) than in paired adjacent normal (N) tissues in 24 of 29 cases (T/N = 3.4 +/- 0.5, P < 0.01). An oligonucleotide probe specific for only the 52 amino acid extension confirmed the overexpression of UbA52. In contrast, there was no overexpression of UbA52 mRNA in gastric cancer samples (n = 7, T/N = 1.0 +/- 0.3). The mRNA of several ribosomal proteins, and of another ubiquitin A gene fusion protein, UbA80, with an 80 amino acid extension of ribosomal protein S27a, have been reported to be over-expressed in colon cancer, but not as yet at the protein level. Using rabbit antisera to the ribosomal protein component S27a we demonstrate over-expression of S27a at the protein level in colonic (n = 5), but not gastric (n = 6) carcinomas. Therefore it is likely that both UbA80 and UbA52 are overexpressed in colon cancer, but not in gastric cancer.

The smaller protein formed as a ubiquitin fusion in Drosophila is processed from ubiquitin and found on the 60S ribosomal subunit

The only gene in Drosophila melanogaster for a 52 amino acid ribosomal protein (CEP52) is fused to a ubiquitin coding sequence. This study examines expression and proteolytic processing of the encoded fusion protein. Most antibody preparations made against a portion of human CEP52 readily detect the insect protein. The size of the immunoreactive polypeptide indicates that CEP52 is cleaved from ubiquitin and this apparent proteolytic processing was confirmed by amino-terminal sequence analysis of CEP52 isolated by two-dimensional gel electrophoresis. Ribosomes from embryonic, larval and adult Drosophila melanogaster contain equivalent amounts of CEP52 and the protein is associated with the large ribosomal subunit. Stained two-dimensional gels indicate that the quantity of CEP52 associated with ribosomes is similar to that of other ribosomal proteins of corresponding size. A previous investigation had indicated the possibility of intact ubiquitin-CEP52 fusion protein in Dictyostelium discoideum, Saccharomyces cerevisiae and Drosophila melanogaster. One of three antibody preparations used in this study of insect CEP52 reacts with a 40S subunit protein that is the correct size to be the uncleaved fusion protein. However, the putative fusion protein does not react with ubiquitin antibodies and has negligible positive charge at pH5, demonstrating that it is not unprocessed ubiquitin-CEP52.

The cDNA sequence and expression of an ubiquitin-tail gene fusion in Neurospora crassa

The genome of Neurospora crassa contains at least one natural fusion gene encoding a single ubiquitin (UBI) unit with a 78-amino acid C-terminal extension. The predominantly basic tail sequence corresponds to a highly conserved ribosomal protein identified in other organisms. The 0.7-kb UBI fusion transcript is mainly expressed in germinating conidia and other stages of active cell replication. Under starvation conditions attained by nutrient depletion, or after polyamine depletion, the UBI fusion gene is shut off while the polyUBI transcript is preserved. Cycloheximide addition promotes polyUBI, but not UBI fusion transcript accumulation in N. crassa.

Identification of the long ubiquitin extension as ribosomal protein S27a

Two proteins of unknown function are encoded by 3' in-frame extensions of ubiquitin genes. The polypeptides are synthesized as an additional 52 or 76-80 amino acids on the C terminus of ubiquitin, an unusual arrangement conserved in man, yeast and plants (J. Callis and R. Vierstra, personal communication). Although not homologous to each other or to ubiquitin, both extension proteins are highly basic and contain patterns of cysteine and histidine similar to those proposed to form 'zinc fingers'. The longer C-terminal extension protein (CEP80) is 30% lysine and arginine and, when denatured, behaves like a small cationic protein. Its properties after isolation in physiological conditions, however, suggested that CEP80 is part of an RNA-protein complex. Using the antibodies that confirmed the presence of CEP80 in eukaryotic cells, we show here that the protein is located on ribosomes. Immunoblotting of rat 40S subunit proteins specifically identifies CEP80 as ribosomal protein S27a.