The relationship between group C adenovirus tumor antigen and the adenovirus single-strand DNA-binding protein

The group C adenoviruses code for a single-strand specific DNA-binding protein of molecular weight 72,000 daltons which is synthesized at early times after productive viral infection. Experiments were designed to determine whether this single-strand specific DNA-binding protein was expressed in adenovirus tumors and transformed cells.Two independently derived preparations of antisera from hamsters bearing group C adenovirus tumors were tested for antibody against the single-strand DNA-binding proteins. One antiserum contained antibodies that reacted with these DNA-binding proteins, while the second antiserum did not contain detectable levels of antibody. Five adenovirus type 2 transformed rat cell lines were tested for the presence of the single-strand specific DNA-binding proteins. Two of the five transformed cells expressed detectable levels of this protein. These results indicate that the group C adenovirus single-strand specific DNA-binding proteins are expressed in some, but not all, adenovirus tumors and transformed cell lines.Those transformed cell lines (type 2) containing a portion of the adenovirus genome designated by the Eco R-I-B restriction enzyme fragment express the single-strand specific DNA-binding proteins. Those cell lines missing this Eco R-I-B fragment do not contain this viral protein. Other experiments have located the structural gene of the single-strand specific DNA-binding protein in the Eco R-I-B DNA fragment, indicating that when this gene is present in a transformed cell, it is expressed.     

Roles for nutrients in epigenetic events

The field of epigenetics is the study of modifications of DNA and DNA-binding proteins that alter the structure of chromatin without altering the nucleotide sequence of DNA; some of these modifications may be associated with heritable changes in gene function. Nutrients play essential roles in the following epigenetic events. First, folate participates in the generation of S-adenosylmethionine, which acts as a methyl donor in the methylation of cytosines in DNA; methylation of cytosines is associated with gene silencing. Second, covalent attachment of biotin to histones (DNA-binding proteins) plays a role in gene silencing and in the cellular response to DNA damage. Third, tryptophan and niacin are converted to nicotinamide adenine dinucleotide, which is a substrate for poly(ADP-ribosylation) of histones and other DNA-binding proteins; poly(ADP-ribosylation) of these proteins participates in DNA repair and apoptosis. Here we present a novel procedure to map nutrient-dependent epigenetic marks in the entire genomes of any given species: the combined use of chromatin immunoprecipitation assays and DNA microarrays. This procedure is also an excellent tool to map the enzymes that mediate modifications of DNA and DNA-binding proteins in chromatin. Given the tremendous opportunities offered by the combined use of chromatin immunoprecipitation assays and DNA microarrays, the nutrition community can expect seeing a surge of information related to roles for nutrients in epigenetic events.     

Computer-aided design of modular protein devices: Boolean AND gene activation

Many potentially useful synthetic gene networks require the expression of an engineered gene if and only if two different DNA-binding proteins exist in sufficient concentration. While some natural and engineered systems activate gene expression according to a logical AND-like behavior, they often utilize allosteric or cooperative protein-protein interactions, rendering their components unsuitable for a toolbox of modular parts for use in multiple applications. Here, we develop a quantitative model to demonstrate that a small system of interacting fusion proteins, called a protein device, can activate an engineered gene according to the Boolean AND behavior while using only modular protein domains and DNA sites. The fusion proteins are created from transactivating, DNA-binding, non-DNA binding, and protein-protein interaction domains along with the corresponding peptide ligands. Using a combined kinetic and thermodynamic model, we identify the characteristics of the molecular components and their rates of constitutive production that maximize the fidelity of AND behavior. These AND protein devices facilitate the creation of complex genetic programs and may be used to create gene therapies, biosensors and other biomedical and biotechnological applications that turn on gene expression only when multiple DNA-binding proteins are simultaneously present.     

SPXX, a frequent sequence motif in gene regulatory proteins

A new DNA-binding unit, composed of four amino acid residues and common in gene regulatory proteins, is proposed. The occurrences of the sequences Ser-Pro-X-X (SPXX) and Thr-Pro-X-X (TPXX) in gene regulatory proteins are compared with those in general proteins. These sequences are found more frequently in gene regulatory proteins including homoeotic gene products, segmentation gene products, steroid hormone receptors and certain oncogene products, than they are in DNA-binding proteins that are not directly involved in gene regulation, such as the core histones, or in general proteins. It is therefore suggested that these sequences contribute to DNA-binding in a manner important for gene regulation. Amino acid residues characteristic of the types of proteins are found as the variable residues X: basic residues, Lys and Arg, in histones, H1 and sea urchin spermatogenous H2B; Tyr in RNA polymerase II; and Ser, Thr, Ala, Leu and Pro in other gene regulatory proteins S(T)PXX sequences are located on either side of other DNA-recognizing units such as Zn fingers, helix-turn-helices, and cores of histones. The structure of a S(T)PXX sequence is presumed to be a beta-turn I stabilized by two hydrogen bonds, and its potential mode of DNA-binding is discussed.     

Two related helix-loop-helix proteins participate in separate cell-specific complexes that bind the insulin enhancer.

Cell-specific expression of the insulin gene is dependent on a conserved 8-basepair sequence, GCCATCTG, present in two copies in the 5' flanking DNA of the rat insulin 1 gene (Nir and Far elements). A protein factor with well characterized binding affinities binds to this sequence and is unique to the nuclei of insulin-producing cells. Using the Nir element as a probe to screen a hamster insulinoma cDNA expression library, we cloned two cDNA inserts that encode two related helix-loop-helix DNA-binding proteins: Syrian hamster Pan-1 (shPan-1) and Syrian hamster Pan-2 (shPan-2). These clones have minimal differences from the previously reported human E47/E12 and rat PAN (rPan) DNA-binding proteins. In vitro translated protein products of both clones bound the insulin gene promoter Nir and far elements as well as the E2 elements of the mu heavy chain and kappa light chain immunoglobulin genes. Treating insulinoma cell nuclear extract with antiserum selectively directed to each of the two shPan proteins demonstrated the presence of each form of shPan in separate DNA-binding complexes, which together form the previously described, cell-specific, Nir element-binding complex. We conclude that shPan-1 and shPan-2 are the hamster homologs of the ubiquitous E47/E12 and rPan proteins, but form parts of distinct DNA-binding complexes apparently found only in the nuclei of insulin-producing cells.     

DNA-binding proteins in xeroderma pigmentosum fibroblasts.

DNA-binding proteins in human fibroblasts were examined by chromatography on DNA-cellulose columns. By successive chromatography on columns containing native, denatured, and UV-irradiated DNA-cellulose respectively the proteins binding to different types of DNA could be studied. Elution of the columns with sodium chloride followed by polyacrylamide gel electrophoresis allowed several DNA-binding proteins to be identified. All of the major DNA-binding proteins were present in strains of xeroderma pigmentosum cells respectively deficient in excision-repair and post-replication repair of ultraviolet-induced damage.     

Predicting DNA-binding proteins: approached from Chou’s pseudo amino acid composition and other specific sequence features

Summary. DNA-binding proteins play a pivotal role in gene regulation. It is vitally important to develop an automated and efficient method for timely identification of novel DNA-binding proteins. In this study, we proposed a method based on alone the primary sequences of proteins to predict the DNA-binding proteins. DNA-binding proteins were encoded by autocross-covariance transform, pseudo-amino acid composition, dipeptide composition, respectively and also the different combinations of the three encoded methods; further, these feature matrices were applied to support vector machine classifiers to predict the DNA-binding proteins. All modules were trained and validated by the jackknife cross-validation test. Through comparing the performance of these substituted modules, the best result was obtained from pseudo-amino acid composition with the overall accuracy of 96.6% and the sensitivity of 90.7%. The results suggest that it can efficiently predict the novel DNA-binding proteins only using the primary sequences. Authors’ address: Menglong Li, College of Chemistry, Sichuan University, Chengdu, Sichuan 610064, P.R. China     

The product of unr, the highly conserved gene upstream of N-ras, contains multiple repeats similar to the cold-shock domain (CSD), a putative DNA-binding motif.

We show that the open reading frame transcribed from the unr gene (immediately upstream of N-ras) in mammals consists of multiple repeats similar to the cold-shock domain (CSD), a putative DNA-binding motif found in prokaryotic cold-shock proteins, and eukaryotic DNA-binding proteins. Alignment of the CSD sequences of unr with those from other proteins reveals a core of similarity for which a consistent secondary structure prediction can be derived. This prediction suggests that the CSD consists primarily of beta-sheet, in contrast to most known eukaryotic DNA-binding proteins. Sequence analysis of the 3' end of the guinea pig unr gene shows that the core of one CSD repeat is encoded in a single exon, consistent with the modular assembly of the gene from ancestral CSD-coding units.