Expression of Werner and Bloom syndrome genes is differentially regulated by in vitro HIV-1 infection of peripheral blood mononuclear cells.

In HIV infection, continuous immune activation leads to accelerated ageing of the adaptive immune system, similar to that observed in elderly people. We investigated the expression of WRN and BLM (genes involved in disorders characterized by premature ageing, genomic instability and cancer predisposition) in peripheral blood mononuclear cells (PBMC) activated in vitro with phytohaemagglutinin (PHA) and infected with different HIV-1 strains. The steady state levels of mRNA were analysed by reverse transcription-polymerase chain reaction (RT-PCR), and protein expression was assayed using immunocytochemistry and Western blot techniques. In uninfected PBMC, PHA stimulation induced an increase in BLM mRNA and protein expression, while WRN expression remained virtually unchanged. When PBMC were infected in vitro with a lymphotropic HIV-1 strain, the level of BLM mRNA showed a peak at 24 h of infection, followed by a decline to uninfected culture levels. A similar result failed to be seen using an R5-tropic HIV-1 strain. In accordance with mRNA expression, in HIV-infected cultures PBMC were stained more frequently and more intensely by a BLM-specific antibody as compared to uninfected cultures, staining peaking at 24. Conversely, WRN expression was not modulated by HIV-1. The proportion of cells showing BLM up-regulation, established by immunocytochemical staining, was much greater than the proportion of productively infected PBMC, as established by proviral DNA measurement. This result indicates that BLM up-regulation is probably a result of an indirect bystander cell effect. Activation of the BLM gene in infected PBMC suggests that premature ageing could be a further immunopathogenetic mechanism involved in HIV-induced immunodeficiency, and points to a possible new candidate target for innovative therapeutic intervention.

In vivo binding and hierarchy of assembly of the yeast RNA polymerase I transcription factors.

Transcription by RNA polymerase I in Saccharomyces cerevisiae requires a series of transcription factors that have been genetically and biochemically identified. In particular, the core factor (CF) and the upstream activation factor (UAF) have been shown in vitro to bind the core element and the upstream promoter element, respectively. We have analyzed in vivo the DNAse I footprinting of the 35S promoter in wild-type and mutant strains lacking one specific transcription factor at the time. In this way we were able to unambiguously attribute the protections by the CF and the UAF to their respective putative binding sites. In addition, we have found that in vivo a binding hierarchy exists, the UAF being necessary for CF binding. Because the CF footprinting is lost in mutants lacking a functional RNA polymerase I, we also conclude that the final step of preinitiation-complex assembly affects binding of the CF, stabilizing its contact with DNA. Thus, in vivo, the CF is recruited to the core element by the UAF and stabilized on DNA by the presence of a functional RNA polymerase I.

Site-specific in vivo cleavages by DNA topoisomerase I in the regulatory regions of the 35 S rRNA in Saccharomyces cerevisiae are transcription independent.

Eukaryotic type I DNA topoisomerase controls DNA topology by transiently breaking and resealing one strand of DNA at a time. During transcription and replication its action reduces the torsional stress derived from these activities. The association of DNA topoisomerase I with the nucleolus has been reported and this enzyme was shown to be involved in yeast rDNA metabolism. Here, we have investigated the in vivo presence of DNA topoisomerase I cleavage sites in the non-transcribed spacer of the rDNA cluster. We show a specific profile of highly localized cleavage in relevant areas of this region. The sites are detected in the promoter and in the enhancer regions of the 35 S gene. The analysis of mutants in which transcription is prevented and/or reduced, namely a strain lacking the 43 kDa subunit of RNA polymerase I, a second one that does note transcribe, lacking a subunit of the core factor and another member of the RNA polymerase I transcription factors lacking one of the UAF component which transcribes at very low level, show that DNA topoisomerase I cleavage sites are not related to transcription by RNA polymerase I. These findings point to a role for DNA topoisomerase I that is additional to the commonly recognized function in removing the transcription-induced topological stress.

DNA protein-interactions at the Saccharomyces cerevisiae 35 S rRNA promoter and in its surrounding region.

This study represents a detailed analysis of the structural context of the RNA polymerase I promoter of Saccharomyces cerevisiae. We determined the presence of regularly spaced nucleosomes in the non-transcribed spacer (NTS) and found that five of them have well defined positions. We show that this nucleosome positioning is restricted to the region between the 35 S and 5 S rRNA promoters, beyond which a more delocalized chromatin structure is evident. A more refined analysis detects the DNA-protein interactions on the RNA polymerase I promoter at nucleotide resolution and provides the first in vivo footprints, attributable to factors like REB1, CF, UAF and an additional protection that seems to be sensitive to the topological context. Moreover, when this analysis is extended to different growth media (YPD versus YNB), some of these protections show a growth condition dependent behaviour.

Chromatin structure of the Saccharomyces cerevisiae DNA topoisomerase I promoter in different growth phases.

We have determined the chromatin organization of the Saccharomyces cerevisiae DNA topoisomerase I promoter. Three nucleosomal core particles have been mapped at nucleotide level over the promoter region, encompassing the presumptive TATA sequence and the two RNA initiation sites; the most upstream nucleosome particle forms on to a 29 bp-long poly(dA-dT) element. This simple organization remains constant throughout both the logarithmic and the linear phase of growth, with the exception of an increased accessibility to micrococcal nuclease of the nucleosome covering the TATA box and the RNA initiation sites during the diauxic shift (the switching from the fermentative to the respiratory metabolism) in parallel with an increase of the DNA topoisomerase I mRNA. In addition, a strong disorganization of the bulk chromatin structure in the late stationary phase is also reported.

Chromatin remodeling during Saccharomyces cerevisiae ADH2 gene activation.

We have analyzed at both low and high resolution the distribution of nucleosomes over the Saccharomyces cerevisiae ADH2 promoter region in its chromosomal location, both under repressing (high-glucose) conditions and during derepression. Enzymatic treatments (micrococcal nuclease and restriction endonucleases) were used to probe the in vivo chromatin structure during ADH2 gene activation. Under glucose-repressed conditions, the ADH2 promoter was bound by a precise array of nucleosomes, the principal ones positioned at the RNA initiation sites (nucleosome +1), at the TATA box (nucleosome -1), and upstream of the ADR1-binding site (UAS1) (nucleosome -2). The UAS1 sequence and the adjacent UAS2 sequence constituted a nucleosome-free region. Nucleosomes -1 and +1 were destabilized soon after depletion of glucose and had become so before the appearance of ADH2 mRNA. When the transcription rate was high, nucleosomes -2 and +2 also underwent rearrangement. When spheroplasts were prepared from cells grown in minimal medium, detection of this chromatin remodeling required the addition of a small amount of glucose. Cells lacking the ADR1 protein did not display any of these chromatin modifications upon glucose depletion. Since the UAS1 sequence to which Adr1p binds is located immediately upstream of nucleosome -1, Adr1p is presumably required for destabilization of this nucleosome and for aiding the TATA-box accessibility to the transcription machinery.

DNA topological context affects access to eukaryotic DNA topoisomerase I.

We have analyzed the reactivity of a 217 base pair segment of the intrinsically curved Crithidia fasciculata kinetoplast DNA towards eukaryotic DNA topoisomerase I. The substrates were open [linear fragment and nicked circle] and closed minidomains [closed relaxed circle and circles with linking differences of -1 and -2]. We interpreted the results with the aid of a model that was used to predict the structures of the topoisomers. The modelling shows that the delta Lk(-1) form is unusually compact because of the curvature in the DNA. To determine the role of sequence-directed curvature in both the experimental and modeling studies, controls were examined in which the curved Crithidia sequence was replaced by an uncurved sequence obtained from the plasmid pBR322. Reactivity of the Crithidia DNA [as analyzed both by the cleavage and topoisomerization reactions] markedly varied among the DNA forms: (i) the hierarchy of overall reactivity observed is: linear fragment > nicked circular, closed circular [delta Lk(0)], interwound [delta Lk(-2)] > bent interwound [delta Lk(-1)]; (ii) the intensity of several cleavage positions differs among DNA forms. The results show that eukaryotic DNA topoisomerase I is very sensitive to the conformation of the substrates and that its reactivity is modulated by the variation of the compactness of the DNA molecule. The C. fasciculata sequence contains a highly curved segment that determines the conformation of the closed circle in a complex way.

ABFI contributes to the chromatin organization of Saccharomyces cerevisiae ARS1 B-domain.

The involvement of the ABFI transcription factor in organizing the chromatin structure of the Saccharomyces cerevisiae ARS1 region has been previously postulated. We studied the ARS1 chromatin structure both on the chromosome and on plasmids carrying wild type or mutated ABFI binding sites, using a recently developed no-background technique for nucleosome mapping, coupled with high resolution micrococcal nuclease in vivo footprinting. We show that ABFI protein acts as a boundary element of chromatin structure, by limiting the invasion by nucleosomes toward the essential A-domain.

Conformational information in DNA: its role in the interaction with DNA topoisomerase I and nucleosomes.

Information in DNA is not limited to sequence information. Both local and global conformational parameters are pivotal to the interaction with a number of relevant proteins. The function of the major components of the transcription machinery (RNA polymerase II, DNA topoisomerase I, nucleosomes, the TATA-binding factor) is dependent on the topological status of the substrate DNA molecule. The topological requirements and the conformational consensus that dictate the rules for localization of nucleosomes and define the active sites for DNA topoisomerase I have been established; the reaction of DNA topoisomerase I is regulated by a topological feedback mechanism. The integrating function of the free energy of supercoiling in the transcription process and the regulatory role of DNA topoisomerase I are discussed.

In vivo analysis of chromatin following nystatin-mediated import of active enzymes into Saccharomyces cerevisiae.

In vivo DNA-protein interactions are usually studied at the molecular level using DNA-degrading agents of low molecular weight. In order to be useful, macromolecular probes of chromatin structure, such as enzymes must first cross the cell membrane. In this paper we describe the introduction and evaluation of macromolecules with enzymatic activity into yeast spheroplasts treated with the polyene antibiotic nystatin. We report the low resolution analysis of chromatin structure in the promoter region of the Saccharomyces cerevisiae gene encoding DNA topoisomerase I by this technique using micrococcal nuclease and restriction enzymes.

DNA topoisomerase I controls the kinetics of promoter activation and DNA topology in Saccharomyces cerevisiae.

Inactivation of the nonessential TOP1 gene, which codes for Saccharomyces cerevisiae DNA topoisomerase I, affects the rate of transcription starting at the ADH2 promoter. For both the chromosomal gene and the plasmid-borne promoter, mRNA accumulation is kinetically favored in the mutant relative to a wild-type isogenic strain. The addition of ethanol causes in wild-type yeast strains a substantial increase in linking number both on the ADH2-containing plasmid and on the resident 2 microns DNA. Evidence has been obtained that such an in vivo increase in linking number depends on (i) the activity of DNA topoisomerase I and of no other enzyme and (ii) ethanol addition, not on the release from glucose repression. A direct cause-effect relationship between the change in supercoiling and alteration of transcription cannot be defined. However, the hypothesis that a metabolism-induced modification of DNA topology in a eukaryotic cell plays a role in regulating gene expression is discussed.

The conformation of constitutive DNA interaction sites for eukaryotic DNA topoisomerase I on intrinsically curved DNAs.

The analysis of the sites which are cleaved constitutively and preferentially by eukaryotic DNA topoisomerase I on two intrinsically curved DNAs reveals the conformational features that provoke the cleavage reaction on the curve-inducing sequence elements in the absence of supercoiling. This analysis is based on the observation (Caserta et al. (1989) Nucleic Acids Res. 17, 8521-8532 and (1990) Biochemistry 29, 8152-8157) that the reaction of eukaryotic DNA topoisomerase I occurs on two types of DNA sites: sites S (Supercoiled induced) and sites C (Constitutive, whose presence is topology-independent). We report that sites C are abundant on the intrinsically curved DNAs analyzed. The DNAs studied were two intrinsically curved segments of different origin: the Crithidia fasciculata kinetoplast DNA and the bent-containing domain B of the Saccharomyces cerevisiae ARS1. On these DNA segments DNA topoisomerase I cleaves at the junctions between the poly(A) tracts and mixed-sequence DNA. Analysis of the conformation of the double helix around the cleavage sites has revealed that the reaction occurs in correspondence of a defined DNA conformational motif. This motif is described by the set of Eulerian angular values that define the axial path of DNA (helical twist, deflection angle, direction) and of the orthogonal components of wedge (roll and tilt).

Regulation of the function of eukaryotic DNA topoisomerase I: analysis of the binding step and of the catalytic constants of topoisomerization as a function of DNA topology.

It was previously observed that two steps of the reaction of eukaryotic DNA topoisomerase I (topoisomerization and cleavage) depend upon the conformation of the DNA substrate: in both instances the supercoiled form is a more efficient substrate than the relaxed one. This paper reports the analysis of two other steps of the reaction: the binding of DNA topoisomerase I to DNA and the catalytic constants (Kcs) of topoisomerization as a function of the topology of the substrate. Binding. Competition assays show that supercoiled DNA binds the enzyme with even slower kinetics than the relaxed form. Therefore, the preferential topoisomerization of supercoiled DNA is not due to the binding step. Additional evidence that the rate-limiting step of the topoisomerization reaction is not the binding of the enzyme to DNA is provided by the fact that the kinetics of relaxation is first order. Catalysis. The Kcs of the topoisomerization reaction have been calculated and it was shown that they do not vary as a function of the topology of the substrate or of its size. Taken together, the data on binding, cleavage, topoisomerization, and Kcs suggest that the preferential topoisomerization of torsionally strained DNA is due to the higher availability, on this topological form, of DNA sites that allow the onset of the reaction.

In vitro preferential topoisomerization of bent DNA.

The steps of the topoisomerization reaction by calf thymus DNA topoisomerase I on a DNA domain containing an intrinsically bent DNA sequence have been analyzed. High preferentiality of binding, cleavage and topoisomerization on the bent segment relative to the rest of the DNA domain was observed. These studies show the importance of the local DNA conformation in the reaction of eukaryotic DNA topoisomerase I and the interest of the use of this enzyme as a tool for the analysis of DNA conformation and DNA dynamics.

Regulation of the function of eukaryotic DNA topoisomerase I: topological conditions for inactivity.

The effects of supercoiling on the cleavage reaction by eukaryotic DNA topoisomerases I (wheat germ, chicken erythrocyte, and calf thymus) have been analyzed on DNA fragments (0.96 and 2.3 kilobases) encompassing an immunoglobulin kappa light-chain promoter. In one topological condition of the substrate, the absolutely relaxed state, cleavage was found to be impeded. This finding defines the topology-dependent step of the eukaryotic DNA topoisomerase I reaction and shows that for the cleavage reaction topology is more critical than sequence effects. These findings suggest a simple model for the regulation of the DNA topoisomerase I reaction based on topological factors, which may explain the regulatory function of the enzyme in in vivo eukaryotic transcription.

The intrinsic topological information of the wild-type and of up-promoter mutations of the Saccharomyces cerevisiae alcohol dehydrogenase II regulatory region.

A 569-base pair fragment encompassing the upstream regulatory region, the RNA initiation sites, and the initial part of the coding region of the Saccharomyces cerevisiae alcohol dehydrogenase II gene has been analyzed for the presence of sites which undergo conformational modification under torsional stress. Fine mapping of P1 and S1 endonuclease-sensitive sites was obtained on single topoisomers produced by in vitro ligation. It was shown that the upstream activator sequence, the TATA sequence, a region directly upstream to the RNA initiation sites, and several positions in the first segment of the transcribed region change conformation as a function of the applied torsional stress in a precisely coordinate fashion. The superhelical density optima for this coordinate modifications have been determined. Analysis of the conformational changes of the promoter sequence in several naturally occurring (Young, E. T., Williamson, V. M., Taguchi, A., Smith, M., Sledziewski, L., Russel, D., Osterman, J., Denis, C., Cox, D., and Beier, D., (1982) in Genetic Engineering of Microorganisms for Chemicals (Hollander, A., De Moss, R. D., Kaplan, S., Konisky, J., Savage, D., and Wolle, R. S., eds) pp. 335-361, Plenum Publishing Corp., New York) up-promoter constitutive mutants was performed. This analysis has shown that the conformation of functionally relevant sites changes as a function of sequence mutations that have taken place elsewhere; this shows that the conformational behavior of the whole promoter region is linked and suggests transmission in cis of topological effects in RNA polymerase II promoters.

DNA conformational variations in the in vitro torsionally strained Ig kappa light chain gene localize on consensus sequences.

We have analyzed the localization and the dependence upon superhelical density of the DNA sites which modify their conformation under torsional strain in a mouse Ig L kappa gene. The conformational variations occur on DNA sites which have been defined as protein interaction sites and consensus sequence motifs: the 5'-upstream regulatory decanucleotides, the TATA sequence, the consensus heptanucleotides of the J recombinational sequences.

Eukaryotic DNA topoisomerase I reaction is topology dependent.

The effects of supercoiling on the topoisomerization reaction by eukaryotic DNA topoisomerases I have been analyzed. The systems used were: DNA topoisomerase I from wheat germ, chicken erythrocyte and calf thymus on a 2.3 kb DNA fragment which encompasses the immunoglobulin kappa-light chain (L kappa) promoter of the mouse plasmacytoma MPC11; S. cerevisiae DNA topoisomerase I on a 2.2 kb DNA fragment from the same organism which encompasses the regulatory and the coding region of the ADH II gene; wheat germ DNA topoisomerase I on the plasmid pUC18. It was found in every system that lack of torsional stress prevents topoisomerization of the substrate. A simple regulatory model of DNA topoisomerase I function, based on topological considerations, is presented.

Topological properties of DNA domains and interaction with RNA polymerase II.

We have analyzed the relationship between the alterations of the DNA structure induced by topological constraint and the template properties of promoters in vitro. A cause-effect relationship has been defined in several instances. Experimental protocols have been developed for the study of the topological properties of RNA polymerase II promoters. The goal of these studies is the definition of the intrinsic structural informations of DNA.