Phenotypic Analysis of Random hns Mutations Differentiate DNA-Binding Activity from Properties of fimA Promoter Inversion Modulation and Bacterial Motility

H-NS is a major Escherichia coli nucleoid-associated protein involved in bacterial DNA condensation and global modulation of gene expression. This protein exists in cells as at least two different isoforms separable by isoelectric focusing. Among other phenotypes, mutations in hns result in constitutive expression of the proU and fimB genes, increased fimA promoter inversion rates, and repression of the flhCD master operon required for flagellum biosynthesis. To understand the relationship between H-NS structure and function, we transformed a cloned hns gene into a mutator strain and collected a series of mutant alleles that failed to repress proU expression. Each of these isolated hns mutant alleles also failed to repress fimB expression, suggesting that H-NS-specific repression of proU and fimB occurs by similar mechanisms. Conversely, alleles encoding single amino acid substitutions in the C-terminal DNA-binding domain of H-NS resulted in significantly reduced affinity for DNA yet conferred a wild-type fimA promoter inversion frequency, indicating that the mechanism of H-NS activity in modulating promoter inversion is independent of DNA binding. Furthermore, two specific H-NS amino acid substitutions resulted in hypermotile bacteria, while C-terminal H-NS truncations exhibited reduced motility. We also analyzed H-NS isoform composition expressed by various hns mutations and found that the N-terminal 67 amino acids were sufficient to support posttranslational modification and that substitutions at positions 18 and 26 resulted in the expression of a single H-NS isoform. These results are discussed in terms of H-NS domain organization and implications for biological activity.     

Sequence and promoter analysis of the highly expressed TEF gene of the filamentous fungus Ashbya gossypii

Ashbya gossypii carries only a single gene (TEF) coding for the abundant translation elongation factor 1α. Cloning and sequencing of this gene and deletion analysis of the promoter region revealed an extremely high degree of similarity with the well studied TEF genes of the yeast Saccharomyces cerevisiae including promoter upstream activation sequence (UAS) elements. The open reading frames in both species are 458 codons long and show 88.6% identity at the DNA level and 93.7% identity at the protein level. A short DNA segment in the promoter, between nucleotides -268 and -213 upstream of the ATG start codon, is essential for high-level expression of the A. gossypii TEF gene. It carries two sequences, GCCCATACAT and ATCCATACAT, with high homology to the UAS_rpg sequence of S. cerevisiae, which is an essential promoter element in genes coding for highly expressed components of the translational apparatus. UAS_rpg sequences are binding sites for the S. cerevisiae protein TUF, also called RAP1 or GRF1. In gel retardation with A. gossypii protein extracts we demonstrated specific protein binding to the short TEF promoter segment carrying the UAS_rpg homologous sequences.     

High-Mobility-Group A-Like CarD Binds to a DNA Site Optimized for Affinity and Position and to RNA Polymerase To Regulate a Light-Inducible Promoter in Myxococcus xanthus

The CarD-CarG complex controls various cellular processes in the bacterium Myxococcus xanthus including fruiting body development and light-induced carotenogenesis. The CarD N-terminal domain, which defines the large CarD_CdnL_TRCF protein family, binds to CarG, a zinc-associated protein that does not bind DNA. The CarD C-terminal domain resembles eukaryotic high-mobility-group A (HMGA) proteins, and its DNA binding AT hooks specifically recognize the minor groove of appropriately spaced AT-rich tracts. Here, we investigate the determinants of the only known CarD binding site, the one crucial in CarD-CarG regulation of the promoter of the carQRS operon (P_QRS), a light-inducible promoter dependent on the extracytoplasmic function (ECF) σ factor CarQ. In vitro, mutating either of the 3-bp AT tracts of this CarD recognition site (TTTCCAGAGCTTT) impaired DNA binding, shifting the AT tracts relative to P_QRS had no effect or marginally lowered DNA binding, and replacing the native site by the HMGA1a binding one at the human beta interferon promoter (with longer AT tracts) markedly enhanced DNA binding. In vivo, however, all of these changes deterred P_QRS activation in wild-type M. xanthus, as well as in a strain with the CarD-CarG pair replaced by the Anaeromyxobacter dehalogenans CarD-CarG (CarD_Ad-CarG_Ad). CarD_Ad-CarG_Ad is functionally equivalent to CarD-CarG despite the lower DNA binding affinity in vitro of CarD_Ad, whose C-terminal domain resembles histone H1 rather than HMGA. We show that CarD physically associates with RNA polymerase (RNAP) specifically via interactions with the RNAP β subunit. Our findings suggest that CarD regulates a light-inducible, ECF σ-dependent promoter by coupling RNAP recruitment and binding to a specific DNA site optimized for affinity and position.     

Localization of HIV-1 Vpr to the nuclear envelope: Impact on Vpr functions and virus replication in macrophages

Background

HIV-1 integrase (IN) is an emerging drug target, as IN strand transfer inhibitors (INSTIs) are proving potent antiretroviral agents in clinical trials. One credible theory sees INSTIs as docking at the cellular (acceptor) DNA-binding site after IN forms a transitional complex with viral (donor) DNA. However, mapping of the DNA and INSTI binding sites within the IN catalytic core domain (CCD) has been uncertain.

Methods

Structural superimpositions were conducted using the SWISS PDB and Cn3D free software. Docking simulations of INSTIs were run by a widely validated genetic algorithm (GOLD).

Results

Structural superimpositions suggested that a two-metal model for HIV-1 IN CCD in complex with small molecule, 1-(5-chloroindol-3-yl)-3-(tetrazoyl)-1,3-propandione-ene (5CITEP) could be used as a surrogate for an IN/viral DNA complex, because it allowed replication of contacts documented biochemically in viral DNA/IN complexes or displayed by a crystal structure of the IN-related enzyme Tn5 transposase in complex with transposable DNA. Docking simulations showed that the fitness of different compounds for the catalytic cavity of the IN/5CITEP complex significantly (P < 0.01) correlated with their 50% inhibitory concentrations (IC₅₀s) in strand transfer assays in vitro. The amino acids involved in inhibitor binding matched those involved in drug resistance. Both metal binding and occupation of the putative viral DNA binding site by 5CITEP appeared to be important for optimal drug/ligand interactions. The docking site of INSTIs appeared to overlap with a putative acceptor DNA binding region adjacent to but distinct from the putative donor DNA binding site, and homologous to the nucleic acid binding site of RNAse H. Of note, some INSTIs such as 4,5-dihydroxypyrimidine carboxamides/N -Alkyl-5-hydroxypyrimidinone carboxamides, a highly promising drug class including raltegravir/MK-0518 (now in clinical trials), displayed interactions with IN reminiscent of those displayed by fungal molecules from Fusarium sp., shown in the 1990s to inhibit HIV-1 integration.

Conclusion

The 3D model presented here supports the idea that INSTIs dock at the putative acceptor DNA-binding site in a IN/viral DNA complex. This mechanism of enzyme inhibition, likely to be exploited by some natural products, might disclose future strategies for inhibition of nucleic acid-manipulating enzymes.     

ARF-B(2): A Protein Complex that Specifically Binds to Part of the Anaerobic Response Element of Maize Adh 1

Crude whole cell extracts from maize (Zea mays L.) suspension cells were examined for DNA binding proteins that specifically interact with a portion of the maize Adh 1 promoter that was previously shown to be in contact with a trans-acting factor in vivo. A 17 base pair, double-stranded oligonucleotide probe was constructed that centered around a strong in vivo dimethylsulfate footprint (B₂) that coincides with part of the anaerobic response element (ARE). Gel retardation assays were used to characterize a major, specific DNA binding protein activity found in the crude extracts. The activity is present in both aerobic and hypoxically treated cultures and has been designated ARF-B₂ (ARE binding factor). ARF-B₂ appears to be a multicomponent complex, with a 54 kilodalton subunit termed ARF-B₂α in primary contact with the target DNA.