Binding of the transcription activator NRI (NTRC) to a supercoiled DNA segment imitates association with the natural enhancer: an electron microscopic investigation.

Electron microscopic visualization indicates that the transcription activator NRI (NTRC) binds with exceptional selectivity and efficiency to a sequence-induced superhelical (spiral) segment inserted upstream of the glnA promoter, accounting for its observed ability to substitute for the natural glnA enhancer. The cooperative binding of NRI to the spiral insert leads to protein oligomerization which, at higher concentration, promotes selective coating of the entire superhelical segment with protein. Localization of NRI at apical loops is observed with negatively supercoiled plasmid DNA.

A sequence-induced superhelical DNA segment serves as transcriptional enhancer.

The initiation of transcription at the sigma 54-dependent promoter glnAp2 of Escherichia coli is activated by the protein NR1(NTRC)-phosphate, which binds to two sites located upstream of the promoter that together constitute an enhancer. The cooperative binding facilitates the oligomerization of NR1-phosphate endowing it with the ATPase activity required for its ability to serve as transcriptional activator. We show here that these sites can be replaced by sequence-dependent superhelical inserts, lacking any homology to the nucleotide sequence of the enhancers.

Investigations on the dynamic structures of adenine- and thymine-containing DNA.

The structures of poly(dA-dT), poly(dA-dBr5U) and of poly(dA).poly(dT) have been investigated in solution and in fibers, by Raman spectroscopy. Both the alternating poly(dA-dT), poly(dA-dBr5U) and non-alternating poly(dA).

DNA with adenine tracts contains poly(dA).poly(dT) conformational features in solution.

The conformation of DNA's with adenine-thymine tracts exhibiting retardation in electrophoretic migration and considered as curved were investigated in solution by CD and RAMAN spectroscopy. The following curved multimers with adenine tracts but of different flanking sequences d(CA5TGCC)n, d(TCTCTA6TATATA5)n, d(GA4T4C)n yield CD spectroscopic features indicating a non-B structure of the dA.dT tract with similarities to polyd(A).

Structural changes in positively and negatively supercoiled DNA.

The effect of superhelical constraint on the structure of covalently closed circular DNA (cccDNA; pBR322) with positive and negative writhe (superturn) has been investigated as a function of decreasing and increasing specific linking difference (mean superhelical density sigma). At low and moderate negative superhelical densities sigma, the overall average structure is maintained in an unwound B-form slightly modified. The overwound cccDNAs with positive writhe differ from those with negative writhe by an absence of cruciform structure.

The synthetic DNA duplex of poly d(Abr5U).poly d(Abr5U) adopts an A-DNA-like structure.

An X-ray fiber diffraction study of the synthetic DNA duplex poly d(Abr5U).poly d(Abr5U) shows that its sodium salt adopts an unexceptional A-DNA-like structure. Similar to A-DNA, two molecules are packed in a monoclinic unit cell (a = 2.

Activation and inhibition of transcription by supercoiling.

Stimulation of transcriptional activity in vitro is observed at low and moderate negative superhelical densities up to the level of the natural superhelical form of the plasmid pBR322. We have isolated and identified three specific transcription products: ampicillinR RNA, tetracyclineR RNA and "Rep" RNA. Their enhancement of transcription occurs at different levels of superhelicity, suggesting a sequence-dependent structural alteration of promoters upon changes of axial writhe, which may generate kink formation.

Torsional stress induces left-handed helical stretches in DNA of natural base sequence: circular dichroism and antibody binding.

Above a threshold of torsional stress, the c.d. spectrum of covalently closed circular DNA of natural base sequence acquires a Z-like contribution and antibodies raised against Z-DNA are bound.

Conformation of DNA in chromatin reconstituted from poly [d(A-T)] and the core histones.

Present results provide direct evidence of the nature of a conformational change in DNA when nucleosomes are formed from core histones and poly [d(A-T)]. First, we have found some features which have characteristic aspects of the A like conformation of DNA. Thus, an increased contribution due to a sugar conformation close to C3'-endo puckering is detected in the Raman spectra.

Effect of 5-alkyl substitution of uracil on the thermal stability of poly [d(A-r5U)] copolymers.

The thermal transition of poly[d(A-r5U)] polydeoxynucleotides (where r was a hydrogen atom, or a methyl, ethyl, n-propyl, n-butyl or n-pentyl group) was studied by measuring the derivative melting profiles of the polymers in the range of 0.01--0.36 M K+, at pH 6.

Identification of beta,beta-turns and unordered conformations in polypeptide chains by vacuum ultraviolet circular dichroism.

Different conformations of polypeptides were characterized by measurements of the circular dichroism (CD) extended into the vacuum ultraviolet region. (i) The linear beta-pleated sheet structure was characterized in a broad ultraviolet region down to 165 nm by examination of copolypeptides composed of alternating hydrophobic and hydrophilic amino-acid residues, e.g.

Effect of non-histone proteins on thermal transition of chromatin and of DNA.

The effect of chromatin non-histone protein on DNA and chromatin stability is investigated by differential thermal denaturation method. 1) Chromatin (rat liver) yields a multiphasic melting profile. The major part of the melting curve of this chromatin is situated at temperatures higher than pure DNA, with a distinct contribution due to nucleosomes melting.

Nature of conformational changes in poly[d(A-T)-d(A-T)] in the premelting region.

The conformation of the synthetic DNA, poly-[d(A-T)-d(A-T)], has been investigated both in the solid state and in dilute aqueous solutions at different temperatures below its melting point. The change of the circular dichroism (CD) spectra of poly[d(A-T)-d(A-T)] solutions with decreasing temperatures from just below the melting point to 0 degrees involves a specific decrease of the intensity of the 262 nm CD band. This conformational change has been assigned to a gradual and partial transition from the B to C form, on the basis of the following results: (i) By the use of infrared dichroism measurements on oriented films we have defined humidity and salt conditions under which B and C forms of poly[d(A-T)-d(A-T](Li+) are stable.