HIV-1 tolerates changes in A-count in a small segment of the pol gene.

BACKGROUND: The HIV-1 RNA genome has a biased nucleotide composition with a surplus of As. Several hypotheses have been put forward to explain this striking phenomenon, but the A-count of the HIV-1 genome has thus far not been systematically manipulated. The reason for this reservation is the likelihood that known and unknown sequence motifs will be affected by such a massive mutational approach, thus resulting in replication-impaired virus mutants. We present the first attempt to increase and decrease the A-count in a relatively small polymerase (pol) gene segment of HIV-1 RNA. RESULTS: To minimize the mutational impact, a new mutational approach was developed that is inspired by natural sequence variation as present in HIV-1 isolates. This phylogeny-instructed mutagenesis allowed us to create replication-competent HIV-1 mutants with a significantly increased or decreased local A-count. The local A-count of the wild-type (wt) virus (40.2%) was further increased to 46.9% or reduced to 31.7 and 26.3%. These HIV-1 variants replicate efficiently in vitro, despite the fact that the pol changes cause a quite profound move in HIV-SIV sequence space. CONCLUSIONS: Extrapolating these results to the complete 9 kb RNA genome, we may cautiously suggest that the A-rich signature does not have to be maintained. This survey also provided clues that silent codon changes, in particular from G-to-A, determine the subtype-specific sequence signatures.

Specific mutations within the AT-rich region of a plasmid replication origin affect either origin opening or helicase loading.

Prokaryotic and eukaryotic replicons possess a distinctive region containing a higher than average number of adenine and thymine residues (the AT-rich region) where, during the process of replication initiation, the initial destabilization (opening) of the double helix takes place. In many prokaryotic origins, this region consists of repeated 13-mer motifs whose function has not yet been specified. Here we identify specific mutations within the 13-mer sequences of the broad-host-range plasmid RK2 that can result in defective origin opening or that do not affect opening but induce defects in helicase loading. We also show that after the initial recruitment of helicase at the DnaA-box sequences of the plasmid origin, the helicase is translocated to the AT-rich region in a reaction requiring specific sequence of the 13-mers and appropriate facing of the origin motifs. Our results demonstrate that specific sequences within the AT-rich region of a replication origin are required for either origin opening or helicase loading.

Triad pattern algorithm for predicting strong promoter candidates in bacterial genomes.

BACKGROUND: Bacterial promoters, which increase the efficiency of gene expression, differ from other promoters by several characteristics. This difference, not yet widely exploited in bioinformatics, looks promising for the development of relevant computational tools to search for strong promoters in bacterial genomes. RESULTS: We describe a new triad pattern algorithm that predicts strong promoter candidates in annotated bacterial genomes by matching specific patterns for the group I sigma70 factors of Escherichia coli RNA polymerase. It detects promoter-specific motifs by consecutively matching three patterns, consisting of an UP-element, required for interaction with the alpha subunit, and then optimally-separated patterns of -35 and -10 boxes, required for interaction with the sigma70 subunit of RNA polymerase. Analysis of 43 bacterial genomes revealed that the frequency of candidate sequences depends on the A+T content of the DNA under examination. The accuracy of in silico prediction was experimentally validated for the genome of a hyperthermophilic bacterium, Thermotoga maritima, by applying a cell-free expression assay using the predicted strong promoters. In this organism, the strong promoters govern genes for translation, energy metabolism, transport, cell movement, and other as-yet unidentified functions. CONCLUSION: The triad pattern algorithm developed for predicting strong bacterial promoters is well suited for analyzing bacterial genomes with an A+T content of less than 62%. This computational tool opens new prospects for investigating global gene expression, and individual strong promoters in bacteria of medical and/or economic significance.

AT-rich sequences from the arbuscular mycorrhizal fungus Gigaspora rosea exhibit ARS function in the yeast Saccharomyces cerevisiae.

Autonomous replicating sequences are DNA elements that trigger DNA replication and are widely used in the development of episomal transformation vectors for fungi. In this paper, a genomic library from the mycorrhizal fungus Gigaspora rosea was constructed in the integrative plasmid YIp5 and screened in the budding yeast Saccharomyces cerevisiae for sequences that act as ARS and trigger plasmid replication. Two genetic elements (GrARS2, GrARS6) promoted high-rates of yeast transformation. Sequence analysis of these elements shows them to be AT-rich (72-80%) and to contain multiple near-matches to the yeast autonomous consensus sequences ACS and EACS. GrARS2 contained a putative miniature inverted-repeat transposable element (MITE) delimited by 28-bp terminal inverted repeats (TIRs). Disruption of this element and removal of one TIR increased plasmid stability several fold. The potential for palindromes to affect DNA replication is discussed.

Extended upstream A-T sequence increases T7 promoter strength.

Bacteriophage T7 promoters contain a consensus sequence from -17 to +6 relative to the transcription start site, +1. In addition, the strong class III promoters are characterized by an extended AT-rich region upstream of -17, which is often interrupted by one or more GC base pairs in the weaker class II promoters. Herein we studied the role of the AT-rich region upstream of -17 in transcription regulation of T7 RNA polymerase. Equilibrium DNA binding studies with promoter fragments of consensus sequence truncated at various positions between -17 and -27 showed that the polymerase-promoter complex is significantly stabilized as the upstream AT-rich sequence is extended to and beyond -22. Similarly, promoters in which the AT-rich region from -17 to -22 is interrupted by several GC base pairs showed weak binding. Kinetic studies indicated that the presence of extended AT-rich sequence slows the dissociation rate constant of the polymerase-promoter complex and slightly stimulates the association rate constant, thereby increasing the stability of the complex. Measurement of the transcription activity revealed that the extended AT-rich region does not affect the kinetics of abortive synthesis up to the formation of 8-nucleotide RNA but causes accumulation of longer abortive products between 9 and 13 nucleotides. The observed effects of the upstream DNA region were AT sequence-specific, and the results suggested a larger role for the extended AT-rich sequence that has been unappreciated previously. We propose that the AT-rich DNA sequence upstream of -17 plays a role in modulating the efficiency of transcription initiation by affecting both the affinity of T7 RNA polymerase for the promoter and the efficiency of promoter clearance.

Sequence specific recognition of DNA by tailor-made hairpin conjugates of achiral seco-cyclopropaneindoline-2-benzofurancarboxamide and pyrrole-imidazole polyamides.

Hairpin conjugates of achiral seco-cyclopropaneindoline-2-benzofurancarboxamide (achiral seco-CI-Bf) and three diamides (ImPy 1, PyIm 2, and PyPy 3, where Py is pyrrole, and Im is imidazole), linked by a gamma-aminobutyrate group, were synthesized. The sequence-specific covalent alkylation of the achiral CI moiety with adenine-N3 in the minor groove was ascertained by thermally induced DNA cleavage experiments. The results provide evidence that hairpin conjugates of achiral seco-CI-Bf-gamma-polyamides could be tailored to target specific DNA sequences according to a set of general rules: the achiral CI moiety selectively reacts with adenine-N3, a stacked pair of imidazole/benzofuran prefers a G/C base pair, and a pyrrole/benzofuran prefers an A/T or T/A base pair. Models for the binding of hairpin conjugates 1-3 with sequences 5'-TCA(888)G-3', 5'-CAA(857)C-3', and 5'-TTA(843)C-3' are proposed.

Selection of AU-rich transiently expressed sequences: reversal of cDNA abundance.

Study of early and transient response gene expression is important for understanding the mechanisms of response to growth stimuli and exogenous agents such as microbes, stress, and radiation. Many of the cytokines, proto-oncogenes, and other transiently expressed gene products are encoded by mRNAs that contain AU-rich elements (AREs) in their 3' untranslated regions (UTRs). In this article, we describe an approach to selectively synthesize ARE-containing cDNA (ARE-cDNA) using an innovative combination of culture treatment, thermostabilization of reverse transcriptase (RT) by the disaccharide trehalose, and use of optimized ARE-specific oligomers. The monocytic cell line, THP-1, was treated with cycloheximide and endotoxin to enrich for ARE-mediated gene expression followed by the RT procedure. Selection of ARE-cDNA with simultaneous suppression of abundant cDNA was made possible using the procedure as monitored by the preferential expression of IL-8, an ARE-cDNA molecule, over the abundant housekeeping cDNA, beta-actin. The use of trehalose dramatically reversed cDNA abundance, resulting in almost complete suppression of housekeeping cDNA. Finally, construction of specialized ARE-cDNA libraries confirmed the selectivity of ARE-cDNAs and the presence of rare genes. The ability to reverse the abundance of housekeeping and other highly expressed genes toward ARE genes facilitates the discovery and study of rare early response and transiently expressed genes.

Amplification of the Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 lytic origin of DNA replication is dependent upon a cis-acting AT-rich region and an ORF50 response element and the trans-acting factors ORF50 (K-Rta) and K8 (K-bZIP).

Kaposi's sarcoma-associated herpesvirus (KSHV), also known as human herpesvirus 8 (HHV8), has significant sequence homology to Epstein-Barr virus (EBV). In cell culture, HHV8 is primarily latent, and viral genes associated with lytic replication are not expressed. Two lytic origins of DNA replication (oriLyt) are present within the HHV8 genome and are composed of an AT-rich region adjacent to GC-rich DNA sequences. We have now identified essential cis- and trans-acting elements required for oriLyt-dependent DNA replication. The transient replication assay was used to show that two AT-rich elements, three consensus AP1 transcription factor-binding sites, an ORF50 response element (RE), and a consensus TATA box motif are essential for efficient origin-dependent DNA replication. Transient transfection of luciferase reporter constructs indicated that the downstream region of the HHV8 oriLyt responds to ORF50 and suggests that part of the oriLyt may be an enhancer/promoter. In addition, a transient cotransfection-replication assay elucidated the set of trans-acting factors required for lytic DNA replication. These factors consist of homologues to the core replication proteins: ORF6 (ssDNA binding protein), ORF9 (DNA polymerase), ORF40-41 (primase-associated factor), ORF44 (helicase), ORF56 (primase), and ORF59 (polymerase processivity factor) common to all herpesviruses along with ORF50 (K-Rta) and K8 (K-bZIP).

Human PABP binds AU-rich RNA via RNA-binding domains 3 and 4.

Poly(A) binding protein (PABP) binds mRNA poly(A) tails and affects mRNA stability and translation. We show here that there is little free PABP in NIH3T3 cells, with the vast majority complexed with RNA. We found that PABP in NIH3T3 cytoplasmic lysates and recombinant human PABP can bind to AU-rich RNA with high affinity. Human PABP bound an AU-rich RNA with Kd in the nm range, which was only sixfold weaker than the affinity for oligo(A) RNA. Truncated PABP containing RNA recognition motif domains 3 and 4 retained binding to both AU-rich and oligo(A) RNA, whereas a truncated PABP containing RNA recognition motif domains 1 and 2 was highly selective for oligo(A) RNA. The inducible PABP, iPABP, was found to be even less discriminating than PABP in RNA binding, with affinities for AU-rich and oligo(A) RNAs differing by only twofold. These data suggest that iPABP and PABP may in some situations interact with other RNA regions in addition to the poly(A) tail.

Synthesis of signals for de novo DNA methylation in Neurospora crassa.

Most 5-methylcytosine in Neurospora crassa occurs in A:T-rich sequences high in TpA dinucleotides, hallmarks of repeat-induced point mutation. To investigate how such sequences induce methylation, we developed a sensitive in vivo system. Tests of various 25- to 100-bp synthetic DNA sequences revealed that both T and A residues were required on a given strand to induce appreciable methylation. Segments composed of (TAAA)(n) or (TTAA)(n) were the most potent signals; 25-mers induced robust methylation at the special test site, and a 75-mer induced methylation elsewhere. G:C base pairs inhibited methylation, and cytosines 5' of ApT dinucleotides were particularly inhibitory. Weak signals could be strengthened by extending their lengths. A:T tracts as short as two were found to cooperate to induce methylation. Distamycin, which, like the AT-hook DNA binding motif found in proteins such as mammalian HMG-I, binds to the minor groove of A:T-rich sequences, suppressed DNA methylation and gene silencing. We also found a correlation between the strength of methylation signals and their binding to an AT-hook protein (HMG-I) and to activities in a Neurospora extract. We propose that de novo DNA methylation in Neurospora cells is triggered by cooperative recognition of the minor groove of multiple short A:T tracts. Similarities between sequences subjected to repeat-induced point mutation in Neurospora crassa and A:T-rich repeated sequences in heterochromatin in other organisms suggest that related mechanisms control silent chromatin in fungi, plants, and animals.

Cell-specific regulatory modules control expression of genes in vascular and visceral smooth muscle tissues.

A novel approach with chimeric SM22alpha/telokin promoters was used to identify gene regulatory modules that are required for regulating the expression of genes in distinct smooth muscle tissues. Conventional deletion or mutation analysis of promoters does not readily distinguish regulatory elements that are required for basal gene expression from those required for expression in specific smooth muscle tissues. In the present study, the mouse telokin gene was isolated, and a 370-bp (-190 to 180) minimal promoter was identified that directs visceral smooth muscle-specific expression in vivo in transgenic mice. The visceral smooth muscle-specific expression of the telokin promoter transgene is in marked contrast to the reported arterial smooth muscle-specific expression of a 536-bp minimal SM22alpha (-475 to 61) promoter transgene. To begin to identify regulatory elements that are responsible for the distinct tissue-specific expression of these promoters, a chimeric promoter in which a 172-bp SM22alpha gene fragment (-288 to -116) was fused to the minimal telokin promoter was generated and characterized. The -288 to -116 SM22alpha gene fragment significantly increased telokin promoter activity in vascular smooth muscle cells in vitro and in vivo. Conversely, a fragment of the telokin promoter (-94 to -49) increased the activity of the SM22alpha promoter in visceral smooth muscle cells of the bladder. Together, these data demonstrate that both vascular- and visceral smooth muscle-specific regulatory modules direct gene expression in subsets of smooth muscle tissues.

cis-Acting elements that regulate the low-pH-inducible urease operon of Streptococcus salivarius.

Differential expression of the Streptococcus salivarius 57.I urease operon in response to pH is effected by repression of transcription from a proximal promoter, PUREI: To localize the cis-acting elements involved in the regulation of the urease operon, the intact promoter region and its derivatives were generated and fused to a promoterless chloramphenicol acetyltransferase (cat) gene. The promoter-cat fusions were established in the lacZ gene of S. salivarius by using a newly constructed integration vector. CAT-specific activities were examined in batch-grown cells at pH 7.5 and 5.5. The results indicated that a 21 bp region immediately 5' to the -35 element was required for efficient repression of PureI at neutral pH and that the 39 bp (-57 to -95) 5' to this region contained sequences required for optimal expression of PUREI: A potential secondary repressor-binding site was tentatively identified further upstream of the -35 element (-96 to -115). To further analyse the cis-acting elements, base changes were introduced into two AT-rich repeats within the primary repressor-binding site. One such derivative, S. salivarius M1, with five base substitutions immediately 5' to the -35 element, expressed 20-fold more CAT-specific activity at neutral pH than the strain carrying wild-type PureI-cat. Also, the pH sensitivity of strain M1 was greatly reduced, suggesting that this AT-rich region is crucial for repression of the urease operon. Deletion of three consecutive 15- or 16-base segments from -52 to -96 in the S. salivarius M1 background resulted in lower activities compared to strain M1, confirming the presence of sequences required for optimal expression of the operon. All of the PureI-cat fusions were also integrated into the gtfG gene of Streptococcus gordonii DL1, a non-ureolytic oral Streptococcus sp. Repression of PureI was observed at neutral pH in S. gordonii and the effects of the various mutations of the repressor-binding site largely paralleled those seen in S. salivarius, suggesting that the cis-elements may be a target for a global regulatory circuit that controls gene expression in streptococci in response to pH.

DNA sequence recognition of thiazole-containing cross-linked polyamides can be favored.

The binding ability of cross-linked thiazolated polyamides (containing the base sequence-reading elements thiazole(Th)-pyrrole(Py)-pyr-role(Py) and thiazole(Th)-imidazole(Im)-pyrrol(Py) to various DNA dodecamers has been investigated. CD titration experiments at high salt concentration demonstrate that the dimers with a heptanediyl linker (C7 dimer) show a significantly higher sequence specificity than their corresponding monomers. The dimer of Th-Py-Py primarily prefers binding to pure AT sequences and that of Th-Im-Py to the dodecamer sequences containing a GC pair within the central sequence (e.g. AACGTT). Surprisingly, the sequence binding ability is strongly influenced by the presence of a T-A step: e.g. Th-Py-Py has a similar affinity to the sequences TTTAAA and ATCGTA; likewise Th-Im-Py shows a preference for these sequences. The CD results correlate with footprinting data. Related biochemical studies on the effect of polyamides on DNA gyrase activity in vitro show that the C7 dimers most effectively inhibit the enzyme activity compared with the monomers and the natural reference minor groove binder distamycin. The highest inhibitory potency is observed for the Th-Py-Py-dimer. The role of the T-A step in binding of the cross-linked dimer to the minor groove is discussed in light of the sequence recognition of the TATA box binding protein.

PPARgamma ligand inhibits osteopontin gene expression through interference with binding of nuclear factors to A/T-rich sequence in THP-1 cells.

Peroxisome proliferator-activated receptor gamma (PPARgamma) is a member of the nuclear receptor superfamily that acts as a key player in adipocyte differentiation, glucose metabolism, and macrophage differentiation. Osteopontin (OPN), a component of extracellular matrix, is elevated during neointimal formation in the vessel wall and is synthesized by macrophages in atherosclerotic plaques. In the present study, we investigated the molecular mechanisms regulating OPN gene expression by PPARgamma in THP-1 cells, a cell line derived from human monocytic leukemia cells. Northern and Western blot analyses showed that exposure of THP-1 cells to PMA (phorbol 12-myristate 13-acetate) increases OPN mRNA and protein levels in a time-dependent manner. PMA-induced OPN expression was significantly decreased by troglitazone (Tro) and other PPARgamma ligands. Transient transfection assays of the human OPN promoter/luciferase construct showed that PPARgamma represses OPN promoter activity, and the PPARgamma-responsive region within the OPN promoter lies between -1000 and -970 relative to the transcription start site. Site-specific mutation analysis and electrophoretic mobility shift assays indicated that a homeobox-like A/T-rich sequence between -990 and -981, which functions as a binding site for PMA-induced nuclear factors other than PPARgamma, mediates the repression of OPN expression by Tro. Furthermore, concatenated A/T-rich sequences conferred the PPARgamma responsiveness on the heterologous promoter. Taken together, these data suggest that PPARgamma ligand inhibits OPN gene expression through the interference with the binding of nuclear factors to A/T-rich sequence in THP-1 cells.

The Schizosaccharomyces pombe origin recognition complex interacts with multiple AT-rich regions of the replication origin DNA by means of the AT-hook domains of the spOrc4 protein.

The interaction between an origin sequence and the origin recognition complex (ORC), which is highly conserved in eukaryotes, is critical for the initiation of DNA replication. In this report, we have examined the interaction between the Schizosaccharomyces pombe (sp) autonomously replicating sequence 1 (ars1) and the spORC. For this purpose, we have purified the spORC containing all six subunits, a six-subunit complex containing the N-terminal-deleted spOrc4 subunit (spORC(Delta N-Orc4)), and the spOrc4 subunit by using the baculovirus expression system. Wild-type spORC showed sequence-specific binding to ars1, and the spOrc4 protein alone showed the same DNA-binding properties as wild-type spORC. In contrast, the spORC(Delta N-Orc4) and the Delta N-spOrc4p alone did not bind significantly to ars1. These findings indicate that the N-terminal domain of the spOrc4 protein that contains multiple AT-hook motifs is essential for the ars1-binding activity. DNA-binding competition assays with fragments of ars1 and DNase I footprinting studies with full-length ars1 revealed that the spORC interacted with several AT-rich sequence regions of ars1. These DNA-binding properties of spORC correlate with the previously determined sequence requirements of the S. pombe ars1. These studies indicate that because of its unique Orc4 subunit, S. pombe uses a mechanism to recognize its origins different from that used by Saccharomyces cerevisiae.

Insulin-responsive nuclear proteins facilitate Sp1 interactions with the insulin-like growth factor-I gene.

The diabetes-induced decrease in insulin-like growth factor-I transcription appears to be mediated by footprint region V in exon 1. Since region V contains both an Sp1 site and an AT-rich element that recognizes an insulin-responsive binding protein (IRBP), we tested the hypothesis that Sp1 interactions are facilitated by an IRBP. Binding of nuclear extracts to region V probes was reduced by mutational or chemical interference with the AT-rich element. Blocking the AT site also reduced interactions of Sp1 with region V in vitro and blunted transactivation of region V reporter constructs by Sp1 in vivo. Sp1 binding was enhanced by small quantities of hepatic nuclear extracts, but enhancement was reduced by the AT mutation and abolished by a 5-base pair insertion between the AT-rich and GC-rich sites, and transactivation by Sp1 in vivo was diminished by inserting bases between the AT-rich and GC-rich elements. However, treating cells with insulin increased the ability of nuclear extracts to enhance Sp1 binding. These findings indicate that the presence of the AT-rich element is essential for the actions of Sp1 in vitro and in vivo, and the combination of both spacing requirements and insulin responsiveness suggests that IRBP may interact directly with Sp1.

Competition between the replication initiator DnaA and the sequestration factor SeqA for binding to the hemimethylated chromosomal origin of E. coli in vitro.

BACKGROUND: Following replication initiation, the replication origin (oriC) in Escherichia coli enters a hemimethylated state at Dam methylation sites which are recognized by the SeqA protein. SeqA binds preferentially to hemimethylated GATC sequences of DNA in vitro. SeqA is essential for the synchronous initiation of chromosome replication from oriC copies in vivo. RESULTS: We show that: (i) purified SeqA binds AT-rich and 13-mers regions and two DnaA boxes, R1 and M, of hemimethylated oriC. (ii) SeqA inhibits the in vitro replication of a hemimethylated oriC plasmid more efficiently than the fully methylated, (iii) SeqA inhibits competitive binding of DnaA protein to the regions of the hemimethylated oriC plasmid, explaining the mechanism of its inhibitory effect. The inhibition of DnaA binding by SeqA also occurs efficiently on a small hemimethylated oriC fragment containing both R1 and M DnaA boxes, but not the 13-mer region. CONCLUSIONS: SeqA binds strongly the long region from the AT-rich region to the M DnaA box of the hemimethylated oriC DNA and releases DnaA molecules from the long region.

Differential in vivo modifications of the HMGI(Y) nonhistone chromatin proteins modulate nucleosome and DNA interactions.

The HMGI(Y) family of "high mobility group" nonhistone proteins are architectural transcription factors whose overexpression is highly correlated with both cancerous transformation and increased malignancy and metastatic potential of tumors in vivo. Here we report on the types of posttranslational modifications found in vivo on the HMG-I and HMG-Y proteins isolated from two human breast epithelial cell lines, MCF-7 and MCF-7/PKC-alpha, that represent different stages of neoplastic progression. The MCF-7 cell line exhibits many characteristics of normal breast epithelial cells and does not form tumors when injected into nude mice, whereas the MCF-7/PKC-alpha cell line, a derivative of MCF-7 that expresses a transgene coding for the enzyme protein kinase C-alpha (PKC-alpha), is both malignant and highly metastatic. Using MALDI mass spectrometry, we show that the HMG-Y protein is more highly modified than the HMG-I protein in both the MCF-7 and the MCF-7/PKC-alpha cells. Significantly, the HMG-Y protein isolated from the highly metastatic MCF-7/PKC-alpha cells possesses a unique constellation of phosphorylations, methylations, and acetylations not found on the HMG-I protein isolated from either the MCF-7 or MCF-7/PKC-alpha cells. We further demonstrate that some of the same amino acid residues phosphorylated on recombinant HMGI(Y) proteins by purified PKC in vitro are also phosphorylated on the HMG-I(Y) proteins isolated from MCF-7/PKC-alpha cells, suggesting that PKC phosphorylates these proteins in vivo. Quantitative substrate binding analyses indicate that the biochemical modifications present on the HMG-I and HMG-Y proteins differentially influence the ability of these proteins to interact with both A.T-rich DNA substrates and nucleosome core particles in vitro, suggesting a similar modulation of such binding affinities in vivo. To our knowledge, this is the first demonstration of differences in the types of in vivo biochemical modifications found on the HMG-I and HMG-Y proteins in cells and also the first experimental evidence suggesting a possible linkage between such posttranslational modifications and the neoplastic potential of cells.