Atomic force microscopy of spherical intermediates on the pathway to fibril formation of influenza A virus nuclear export protein.

The nuclear export protein of the influenza A virus (NEP) is involved in many important processes of the virus life cycle. This makes it an attractive target for the treatment of a disease caused by a virus. Previously it has been shown, that recombinant variants of NEP are highly prone to aggregation in solution under various conditions with the formation of amyloid-like aggregates. In the present work, the amyloid nature of NEP aggregates was evidenced by Congo red binding assays. Atomic force microscopy has shown that NEP can form two types of spherical nanoparticles, which provide an alternative pathway for the formation of amyloid-like fibrils. Type I of these "fibrillogenic" spheres, formed under physiological conditions, represents the micelle-like particles with height 10-60 nm, which can generate worm-like flexible fibrils with the diameter 2.5-4.0 nm, length 20-500 nm and the Young's modulus ~73 MPa. Type II spherical aggregates with size of about 400-1000 nm, formed at elevated temperatures, includes fractions of drop-like and vesicle-like particles, generating more rigid amyloid-like fibrils with height of ~8 nm, and length of up to 2 µm. The hypothetical mechanism of fibril formation via nanospherical structures was suggested. RESEARCH HIGHLIGHTS: AFM has revealed two types of the influenza A virus nuclear export protein spherical aggregates. They provide an alternative pathway for the formation of amyloid-like fibrils. The mechanism of fibril formation via spherical structures is suggested.

Effect of DNA bending on transcriptional interference in the systems of closely spaced convergent promoters.

BACKGROUND: Over the past years there are increasing evidences that the interplay between two molecules of RNA polymerases, initiating transcription from promoters, oriented in opposite (convergent) directions, can serve as a regulatory factor of gene expression. The data concerning the molecular mechanisms of this so-called transcriptional interference (TI) are not well understood. METHODS: The interaction of RNA polymerase with circular DNA templates, containing the convergent promoters, was investigated in a series of in vitro transcription assays and atomic force microscopy (AFM). RESULTS: In this work, to study the mechanisms of transcription interference a series of plasmids with oppositely oriented closely spaced artificial promoters, recognized by Escherichia coli RNA polymerase, was constructed. The constructs differ in promoter structure and distance between the transcription start sites. We have demonstrated that the transcripts ratio (RNA-R/RNA-L) and morphology of convergent open promoter complexes (OPC) are highly dependent on the interpromoter distance. CONCLUSIONS: The obtained results allowed us to suggest the novel model of TI, which assumes the DNA bending upon binding of RNA polymerase with promoters and explains the phenomenon of complete inactivation of weaker promoter by the stronger one. GENERAL SIGNIFICANCE: The results show that the conformational transitions in DNA helix, associated with DNA bending upon binding of RNA polymerase with promoters, play crucial role in OPC formation in the systems with convergent promoters.

The model of amyloid aggregation of Escherichia coli RNA polymerase σ70 subunit based on AFM data and in vitro assays.

To propose a model for recently described amyloid aggregation of E.coli RNA polymerase σ(70) subunit, we have investigated the role of its N-terminal region. For this purpose, three mutant variants of protein with deletions Δ1-73, Δ1-100 and Δ74-100 were constructed and studied in a series of in vitro assays and using atomic force microscopy (AFM). Specifically, all RNA polymerase holoenzymes, reconstituted with the use of mutant σ subunits, have shown reduced affinity for promoter-containing DNA and reduced activity in run-off transcription experiments (compared to that of WT species), thus substantiating the modern concept on the modulatory role of N-terminus in formation of open complex and transcription initiation. The ability of mutant proteins to form amyloid-like structures has been investigated using AFM, which revealed the increased propensity of mutant proteins to form rodlike aggregates with the effect being more pronounced for the mutant with the deletion Δ1-73 (10 fold increase). σ(70) subunit aggregation ability has shown complex dependence on the ionic surrounding, which we explain by Debye screening effect and the change of the internal state of the protein. Basing on the obtained data, we propose the model of amyloid fibril formation by σ(70) subunit, implying the involvement of N-terminal region according to the domain swapping mechanism.

Is transketolase-like protein, TKTL1, transketolase?

Until recently it was assumed that the transketolase-like protein (TKTL1) detected in the tumor tissue, is catalytically active mutant form of human transketolase (hTKT). Human TKT shares 61% sequence identity with TKTL1. And the two proteins are 77% homologous at the amino acid level. The major difference is the absence of 38 amino acid residues in the N-terminal region of TKTL1. Site-specific mutagenesis was used for modifying hTKT gene; the resulting construct had a 114-bp deletion corresponding to a deletion of 38 amino acid residues in hTKT protein. Wild type hTKT and mutant variant (DhTKT) were expressed in Escherichia coli and isolated using Ni-agarose affinity chromatography. We have demonstrated here that DhTKT is devoid of transketolase activity and lacks bound thiamine diphosphate (ThDP). In view of these results, it is unlikely that TKTL1 may be a ThDP-dependent protein capable of catalyzing the transketolase reaction, as hypothesized previously.

AFM study of Escherichia coli RNA polymerase σ7° subunit aggregation.

The self-assembly of Escherichia coli RNA polymerase σ7° subunit was investigated using several experimental approaches. A novel rodlike shape was reported for σ7° subunit aggregates. Atomic force microscopy reveals that these aggregates, or σ7° polymers, have a straight rodlike shape 5.4 nm in diameter and up to 300 nm in length. Atomic force microscopy data, Congo red binding assay, and sodium dodecyl sulfate gel electrophoresis confirm the amyloid nature of observed aggregates. The process of formation of rodlike structures proceeds spontaneously under nearly physiological conditions. E. coli RNA polymerase σ7° subunit may be an interesting object for investigation of amyloidosis as well as for biotechnological applications that exploit self-assembled bionanostructures. Polymerization of σ7° subunit may be a competitive process with its three-dimensional crystallization and association with core RNA polymerase. FROM THE CLINICAL EDITOR: In this basic science study, the self-assembly of Escherichia coli RNA polymerase σ7°( subunit was investigated using atomic force microscopy and other complementary approaches.

Effects of substitutions at position 180 in the Escherichia coli RNA polymerase σ 70 subunit.

In order to investigate the role of His180 residue, located in the non-conserved region of the σ 70 subunit of Escherichia coli RNA polymerase, two mutant variants of the protein with substitutions for either alanine or glutamic acid were constructed and purified using the IMPACT system. The ability of mutant σ 70 subunits to interact with core RNA polymerase was investigated using native gel-electrophoresis. The properties of the corresponding reconstituted holoenzymes, as provided by gel shift analysis of their complexes with single- and double-stranded promoter-like DNA and by in vitro transcription experiments, allowed one to deduce that His180 influences several steps of transcription initiation, including core binding, promoter DNA recognition and open complex formation.