Sabrina Venditti

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.

Linkage reduction allows reconstitution of nucleosomes on DNA microdomains

We have established an experimental system for reconstitution of an individual nucleosome on a closed DNA microdomain (operationally defined as a DNA domain of a size so small as to be unable to establish titratable superhelical turns). The microdomain (185 base-pairs (bp), composed of 128 bp encompassing the central part of the Saccharomyces cerevisiae ADH II promoter plus 57 bp of a polylinker) was obtained by ligation under conditions that produced three circularized forms characterized by different linkage numbers. These linkomers were tested for nucleosome reconstitution with S. cerevisiae histones. It was observed that only microcircles with linkage reduction (delta Lk = 1 or 2) could form a nucleosome, as defined by protection of a 145(+/- 2) bp DNA fragment from micrococcal nuclease, relaxed forms (open or closed circles) could not.

Increased cerebellar volume and BDNF level following quadrato motor training.

Using whole-brain structural measures coupled to analysis of salivary brain-derived neurotrophic factor (BDNF), we demonstrate sensory motor training-induced plasticity, including cerebellar gray matter volume increment and increased BDNF level. The increase of cerebellar volume was positively correlated with the increase of BDNF level.

Effects of DNA topology in the interaction with histone octamers and DNA topoisomerase I

Several simple proteins and complex protein systems exist which do not recognize a defined sequence but--rather--a specific DNA conformation. We describe experiments and principles for two of these systems: nucleosomes and eukaryotic DNA topoisomerase I. Evidences are summarized that describe the effects of negative DNA supercoiling on nucleosome formation and the influence of DNA intrinsic curvature on their localization. The function of the DNA rotational information in nucleosome positioning and in the selection of multiple alternative positions on the same helical phase are described. This function suggests a novel genetic regulatory mechanism, based on nucleosome mobility and on the correlation between in vitro and in vivo positions. We observe that the same rules that determine the in vitro localization apply to the in vivo nucleosome positioning, as determined by a technique that relies on the use of nystatin and on the import of active enzymes in living yeast cells. The sensitivity of DNA topoisomerase I to the topological condition of the DNA substrate is reviewed and discussed taking into account recent experiments that describe the effect of the DNA tridimensional context on the reaction. These topics are discussed in the following order: (i) Proteins that look for a consensus DNA conformation; (ii) Nucleosomes; (iii) Negative supercoiling and nucleosomes; (iv) DNA curvature/bending and nucleosomes; (v) Multiple positioning; (vi) Multiple nucleosomes offer a contribution to the solution of the linking number paradox; (vii) Rotational versus translational information; (viii) A regulatory mechanism; (ix) DNA topoisomerase I; (x) DNA topoisomerase I and DNA supercoiling: a regulation by topological feedback; (xi) DNA topoisomerase I and DNA curvature; (xii) The in-and-out problem in the accessibility of DNA information; (xiii) The integrating function of the free energy of supercoiling.

Imbalance in dosage of the genes for the heterochromatin components Sir3p and histone H4 results in changes in the length and sequence organization of yeast telomeres

Abstract Telomeric heterochromatin plays an essential role in telomere function, including the regulation of telomere length. We observe that in Saccharomyces cerevisiae an imbalance in the dosage of genes for two protein components of heterochromatin (namely Sir3p and histone H4) causes modifications in telomere length and telomere sequence organization. The effects of Sir3p/H4 imbalance were analyzed in yeast strains in which the wild-type SIR3 gene (normally a single-copy gene) was either absent or present in 20–30 copies, and both histone H4 genes (HHF1 and HHF2) were present or HHF1 was deleted, thus covering a wide range of viable gene-dosage combinations. Modifications of telomeres and of subtelomeric regions were identified by analyzing both the overall telomere population and by focusing on two single telomeric regions: the left telomere of chromosome III (LIII) and the right telomere of chromosome XI (RXI). The modifications induced by alteration of the Sir3p/H4 ratio consist of a reduction in the length and an increase in the instability of the terminal block of (C1–3A)n repeats and in susceptibility to insertion of Y′ elements into this repeat element. Restoration of the wild-type gene ratio (by removal of the extra copies of SIR3 or by complementation with the missing second copy of HHF) restored the original telomere organization, both with respect to the length of the (C1–3A)n repeat stretch and the absence of Y′ elements. This behavior shows that the stability of the wild-type sequence organization requires maintenance of the normal structure of telomeric heterochromatin.

[9] Mapping of yeast nucleosomes in Vivo

Publisher Summary The localization of nucleosomes in yeast chromatin has so far been analyzed on isolated chromatin or nuclei because intact cells and spheroplasts are impermeable to macromolecules, thus, preventing the penetration of enzymes normally used in vivo or in vitro as analytical tools (deoxyribonuclease I, micrococcal nuclease, exonuclease III, and restriction endonucleases). The use of nystatin as a permeabilizing agent has opened the possibility of the enzymatic treatment of chromatin in living cells and the development of new analytical approaches to chromatin analysis. Permeabilization with nystatin allows mapping in the spheroplasts of nucleosomes located on large chromosomal segments by the traditional indirect end-labeling procedure. The resulting picture is not substantially different from that conventionally obtained with isolated chromatin. In this case, the advantage is the fact that the risks of protein rearrangements and/or modifications are kept to a minimum.

Telomere-based neo-Darwinian selection of yeast clonal subpopulations.

Abstract In Saccharomyces cerevisiae, imbalance of the genes coding for the heterochromatin components Sir3p and histone H4 (namely, overdosage of SIR3 and lack of one of the two genes coding for H4) causes modifications in telomere length and telomere sequence organization, favoring the insertion of Y′ elements into a stably shortened (C1–3A)n repeat tract. We report here that the newly inserted Y′ elements are unstable and are lost with high frequency, generating clonal subpopulations with short telomeres, as revealed by the analysis of a specific telomere (LIII) and of the overall population of telomeres. Moreover, the growth rates of the subpopulations with and without Y′ elements on LIII are different, the Y′-less individuals reproducing 20% more slowly than individuals bearing Y′ elements. When grown together with Y′-bearing individuals, the subpopulations with the normal LIII telomere (which are viable and genetically stable if grown alone) are rapidly competed out. Hence, genetic imbalance for the structural components of heterochromatin results in a complex and rapidly changing mixture of subpopulations in such cultures. Thus, in situations where subpopulations are allowed to compete, heterochromatin-based differential growth rates result in neo-Darwinian clonal selection.

Sir2 is involved in the transcriptional modulation of NHP6A in Saccharomyces cerevisiae

The Sir proteins, namely Sir2, 3 and 4, have roles related to heterochromatin, but genome-wide studies have revealed their presence at many euchromatic loci, although the functional meaning of this is still not clear. Nhp6a is an abundant HMG-like protein in yeast, which has a role in transcription by modulating chromatin structure and nucleosome number. Although much is known about its structure and function, information regarding its regulation is scarce. NHP6A, among other genes, emerges in ChIP-on chip studies of global Sir proteins binding, suggesting it could be regulated by SIR. We have investigated NHP6A expression in sir deletion mutants as well as in SIR2 overexpressing conditions. In addition, we have asked if the Sir2 deacetylation activity is involved by using conditions that either inhibit (treatment with nicotinamide) or enhance (calorie restriction conditions) Sir2 activity. We have found that, consistent with previous microarray studies, NHP6A expression undergoes a slight increase in sir mutant strains, but is strongly repressed when SIR2 is overexpressed. In a sir3 mutant strain the gene continues to be transcribed, even in SIR2 overexpressing conditions. In addition, treating the cells with nicotinamide counteracts the SIR2 overexpressing effect. Finally, conditions that are known to potentiate Sir2 deacetylation activity seem to mimic the effect of SIR2 overexpression on NHP6A. Our results suggest that Sir2 is involved in the regulation of NHP6A promoter, acting more as a specific repressor, rather than a long-range silencer. This effect is specific, and the Sir2 deacetylase activity is required for the Sir2 mediated repression of NHP6A. Moreover, the presence of the SIR complex seems required for Sir2 to silence NHP6A.