Adenovirus E1A down-regulates LMP2 transcription by interfering with the binding of stat1 to IRF1

The LMP2 gene, which encodes a protein required for efficient presentation of viral antigens, requires both unphosphorylated Stat1 and IRF1 for basal expression. LMP2 expression is down-regulated by the adenovirus protein E1A, which binds to Stat1 and CBP/p300, and by the mutant E1A protein RG2, which binds to Stat1 but not to CBP/p300, but not by the mutant protein Delta2-36, which does not bind to either Stat1 or CBP/p300. Stat1 and IRF1 associate in untreated cells and bind as a complex to the overlapping ICS-2/GAS element of the LMP2 promoter. E1A interferes with the formation of this complex by occupying domains of Stat1 that bind to IRF1. These results reveal how adenovirus infection attenuates LMP2 expression, thereby interfering with the presentation of viral antigens.     

Genomic sequence comparison of the human and mouse adenosine deaminase gene regions

A challenge for mammalian genetics is the recognition of critical regulatory regions in primary gene sequence. One approach to this problem is to compare sequences from genes exhibiting highly conserved expression patterns in disparate organisms. Previous transgenic and transfection analyses defined conserved regulatory domains in the mouse and human adenosine deaminase (ADA) genes. We have thus attempted to identify regions with comparable similarity levels potentially indicative of critical ADA regulatory regions. On the basis of aligned regions of the mouse and human ADA gene, using a 24-bp window, we find that similarity overall (67.7%) and throughout the noncoding sequences (67.1%) is markedly lower than that of the coding regions (81%). This low overall similarity facilitated recognition of more highly conserved regions. In addition to the highly conserved exons, ten noncoding regions >100 bp in length displayed >70% sequence similarity. Most of these contained numerous 24-bp windows with much higher levels of similarity. A number of these regions, including the promoter and the thymic enhancer, were more similar than several exons. A third block, located near the thymic enhancer but just outside of a minimally defined locus control region, exhibited stronger similarity than the promoter or thymic enhancer. In contrast, only fragmentary similarity was exhibited in a region that harbors a strong duodenal enhancer in the human gene. These studies show that comparative sequence analysis can be a powerful tool for identifying conserved regulatory domains, but that some conserved sequences may not be detected by certain functional analyses as transgenic mice. Received: 27 March 1998 / Accepted: 22 September 1998     

Structure and domain organization of the CD19 antigen of human, mouse, and guinea pig B lymphocytes. Conservation of the extensive cytoplasmic domain.

The CD19 molecule is a 95,000 Mr cell-surface protein of human B lymphocytes with two extracellular Ig-like domains and a 240 amino acid cytoplasmic tail. cDNA encoding human CD19 and the cytoplasmic domain of the mouse CD19 Ag were previously isolated. In this report, those cDNA were used to isolate cDNA or genomic DNA encoding the complete mCD19 protein and a portion of CD19 from the guinea pig. Mouse pre-B and B cell lines expressed two CD19 mRNA species of 2.7 and 2.2 kb, whereas myeloma cell lines were negative as were T cell lines. Similarly, among mouse organs, only spleen contained detectable CD19 mRNA. These results suggest that only B cells express CD19 in mouse, as in man. Sequence determination revealed substantial conservation, with hCD19 and mCD19 being 66% and hCD19 and gpCD19 being 73% identical in amino acid sequence. The cytoplasmic region of CD19 was most highly conserved with human/mouse being 73% identical and human/guinea pig being 83% identical in amino acid sequence. Isolation of the hCD19 and mCD19 genes and determination of exon/intron boundaries revealed that both genes were structurally similar and were composed of at least 15 exons, 4 encoded extracellular domains, and 9 encoded cytoplasmic domains. Six of the exons that encoded cytoplasmic domains were essentially identical in sequence in all three species indicating that these regions have undergone considerable selective pressure to conserve sequences. Thus, CD19 appears to be well conserved in structure and expression through recent mammalian evolution and the highly conserved cytoplasmic domains may play a critical role in the transduction of CD19-mediated signals.     

Structures and chromosomal localizations of two human genes encoding synaptobrevins 1 and 2

Synaptobrevins 1 and 2 are small integral membrane proteins specific for synaptic vesicles in neurons. Two cosmid clones containing the human genes encoding synaptobrevins 1 and 2 (gene symbols SYB1 and SYB2, respectively) were isolated and characterized. The coding regions of the synaptobrevin genes are highly homologous to each other and are interrupted at identical positions by introns of different size and sequence. Each gene is organized into five exons whose boundaries correspond to those of the protein domains. Exon I contains part of the initiator methionine codon whereas exon II encodes the variable and immunogenic amino-terminal domain of the synaptobrevins. The third exon comprises the highly conserved central domain of the synaptobrevins, exon IV encodes most of the transmembrane region, and exon V contains the last residues of the transmembrane region and the small intravesicular carboxyl terminus. Comparisons of the synaptobrevin sequences in five species from Drosophila with man indicate a selective conservation of sequences adjacent to the synaptic vesicle surface, suggesting a function at the membrane-cystosol interface. The chromosomal localizations of the human and mouse SYB1 and SYB2 genes were determined using hybrid cell lines. SYB1 was localized to the short arm of human chromosome 12 and to mouse chromosome 6 whereas SYB2 was found on the distal portion of the short arm of human chromosome 17 and on mouse chromosome 11. A PstI restriction fragment length polymorphism was identified at the SYB2 locus.     

Molecular structure of microtubule-associated protein 2b and 2c from rat brain

Full length cDNA clones encoding microtubule-associated proteins (MAP) 2b and 2c from rat brain have been isolated and sequenced. The cDNA fragments spanning the coding regions for both MAP2b and MAP2c were assembled and expressed in Escherichia coli. The mobility of these bacterial expressed proteins in sodium dodecyl sulfate gels is identical to that of MAP2b and MAP2c from rat brain. The protein sequence of rat MAP2b has been compared to the full length sequence from mouse and the partial sequence from human high molecular weight MAP2. This comparison has revealed that MAP2b is composed of several highly conserved domains flanked by domains with extensive sequence divergence. Two of the conserved domains, found either at the NH2 or COOH terminus, overlap with the binding domain for the regulatory subunit of the cAMP-dependent protein kinase II and the microtubule-binding domain, respectively. A third homologous domain of unknown function lies in a central region of MAP2b. Secondary structure prediction suggests that the portion of MAP2b which extends from the microtubule surface is composed of an extensive number of alpha-helices separated by small turns which may account for the extended yet flexible structure of MAP2. Interestingly, the 4000-base pair deletion from the middle of MAP2b which generates MAP2c not only removes these helices, but also this third highly conserved MAP2b domain.     

Sequence homologies in mammalian 5.8S ribosomal RNA.

Oligonucleotide products of complete pancreatic or T1 RNase digestion or partial T1 RNase digestion of HeLa cell (human) and MPC-11 cell (mouse) 5.8S rRNA are identical with those obtained from Novikoff hepatoma (rat) 5.8S rRNA except for minor differences at the termini. pCp is the only major 5' terminus of both human and mouse RNAs; both pGp and pCp 5' termini were found in rat 5.8S RNA. Furthermore, HeLa cells contain C-U-U at the 3' end rather than the C-U terminus of mouse and rat. The results indicate that the nucleotide sequence has been highly conserved during the evolution of mammals and suggest that, as reported for 5S rRNA, this sequence is essentially constant throughout the Mammalia.     

Molecular cloning, chromosome mapping and characterization of UBQLN3 a testis-specific gene that contains an ubiquitin-like domain

The sequence of the ubiquitin protein is highly conserved between species and has facilitated the cloning of numerous ubiquitin-like proteins. In the present study, we report the cloning of the cDNA for human ubiquilin 3 (UBQLN3). The deduced amino acid sequence of UBQLN3 contains a UBQ domain (ubiquitin-like) in the amino terminus as well as two highly conserved domains found in several recently cloned ubiquitin-like proteins. One of these domains, termed the NP domain, is a highly conserved 93 amino acid region present in UBQLN3 and several ubiquitin-like proteins. The last conserved domain is the UBA domain (ubiquitin-associated) found in a variety of proteins of the ubiquination pathway. The human UBQLN3 gene was mapped to the 11p15 region of chromosome 11. Northern blot analysis of multiple human and mouse tissues demonstrated UBQLN3 mRNA expression specifically in testis.