Telomeric localization of TRF2, a novel human telobox protein.

Natural chromosomal ends are stabilized by proteins that bind duplex telomeric DNA repeats. In human cells, the TTAGGG Repeat Factor 1 (TRF1) was identified by two independent studies, one screening for factors that bind duplex telomeric DNA and the other screening for proteins containing a particular Myb motif called the telobox, which is required for telomeric repeat recognition (Fig. 1a; refs 3-5). A second human open reading frame, orf2, contains a telobox sequence and encodes a polypeptide that specifically recognizes mammalian telomeric repeat DNA in vitro. We show that two proteins of 65 and 69 kD, expressed in HeLa cells, contain the orf2 telobox sequence. These proteins are collectively termed TRF2. Affinity-purified antibodies specific for anti-TRF2 label the telomeres of intact human chromosomes, strengthening the correlation between occurrence of telobox and telomere-repeat recognition in vivo.

Telomeres and the functional architecture of the nucleus.

The single molecule of DNA that constitutes a eukaryotic chromosome begins and ends with a stretch of repetitive DNA known as a telomere. These sequences appear to be necessary to preserve the integrity of the genetic material through the cell cycle. Telomeric DNA is organized into regions of non-nucleosomal chromatin called the telosome, which can interact with other telosomes and with the nuclear envelope. This review focuses on cytological evidence for these interactions and on recent insights into the molecular organization of the telomeric complex.

The positioning and dynamics of origins of replication in the budding yeast nucleus.

We have analyzed the subnuclear position of early- and late-firing origins of DNA replication in intact yeast cells using fluorescence in situ hybridization and green fluorescent protein (GFP)-tagged chromosomal domains. In both cases, origin position was determined with respect to the nuclear envelope, as identified by nuclear pore staining or a NUP49-GFP fusion protein. We find that in G1 phase nontelomeric late-firing origins are enriched in a zone immediately adjacent to the nuclear envelope, although this localization does not necessarily persist in S phase. In contrast, early firing origins are randomly localized within the nucleus throughout the cell cycle. If a late-firing telomere-proximal origin is excised from its chromosomal context in G1 phase, it remains late-firing but moves rapidly away from the telomere with which it was associated, suggesting that the positioning of yeast chromosomal domains is highly dynamic. This is confirmed by time-lapse microscopy of GFP-tagged origins in vivo. We propose that sequences flanking late-firing origins help target them to the periphery of the G1-phase nucleus, where a modified chromatin structure can be established. The modified chromatin structure, which would in turn retard origin firing, is both autonomous and mobile within the nucleus.

The clustering of telomeres and colocalization with Rap1, Sir3, and Sir4 proteins in wild-type Saccharomyces cerevisiae.

We have developed a novel technique for combined immunofluorescence/in situ hybridization on fixed budding yeast cells that maintains the three-dimensional structure of the nucleus as monitored by focal sections of cells labeled with fluorescent probes and by staining with a nuclear pore antibody. Within the resolution of these immunodetection techniques, we show that proteins encoded by the SIR3, SIR4, and RAP1 genes colocalize in a statistically significant manner with Y' telomere-associated DNA sequences. In wild-type cells the Y' in situ hybridization signals can be resolved by light microscopy into fewer than ten foci per diploid nucleus. This suggests that telomeres are clustered in vegetatively growing cells, and that proteins essential for telomeric silencing are concentrated at their sites of action, i.e., at telomeres and/or subtelomeric regions. As observed for Rap1, the Sir4p staining is diffuse in a sir3- strain, and similarly, Sir3p staining is no longer punctate in a sir4- strain, although the derivatized Y' probe continues to label discrete sites in these strains. Nonetheless, the Y' FISH is altered in a qualitative manner in sir3 and sir4 mutant strains, consistent with the previously reported phenotypes of shortened telomeric repeats and loss of telomeric silencing.

The carboxy termini of Sir4 and Rap1 affect Sir3 localization: evidence for a multicomponent complex required for yeast telomeric silencing.

The Silent Information Regulatory proteins, Sir3 and Sir4, and the telomeric repeat-binding protein RAP1 are required for the chromatin-mediated gene repression observed at yeast telomeric regions. All three proteins are localized by immunofluorescence staining to foci near the nuclear periphery suggesting a relationship between subnuclear localization and silencing. We present several lines of immunological and biochemical evidence that Sir3, Sir4, and RAP1 interact in intact yeast cells. First, immunolocalization of Sir3 to foci at the yeast nuclear periphery is lost in rap1 mutants carrying deletions for either the terminal 28 or 165 amino acids of RAP1. Second, the perinuclear localization of both Sir3 and RAP1 is disrupted by overproduction of the COOH terminus of Sir4. Third, overproduction of the Sir4 COOH terminus alters the solubility properties of both Sir3 and full-length Sir4. Finally, we demonstrate that RAP1 and Sir4 coprecipitate in immune complexes using either anti-RAP1 or anti-Sir4 antibodies. We propose that the integrity of a tertiary complex between Sir4, Sir3, and RAP1 is involved in both the maintenance of telomeric repression and the clustering of telomeres in foci near the nuclear periphery.

Localization of RAP1 and topoisomerase II in nuclei and meiotic chromosomes of yeast.

Topoisomerase II (topoII) and RAP1 (Repressor Activator Protein 1) are two abundant nuclear proteins with proposed structural roles in the higher-order organization of chromosomes. Both proteins co-fractionate as components of nuclear scaffolds from vegetatively growing yeast cells, and both proteins are present as components of pachytene chromosome, co-fractionating with an insoluble subfraction of meiotic nuclei. Immunolocalization using antibodies specific for topoII shows staining of an axial core of the yeast meiotic chromosome, extending the length of the synaptonemal complex. RAP1, on the other hand, is located at the ends of the paired bivalent chromosomes, consistent with its ability to bind telomeric sequences in vitro. In interphase nuclei, again in contrast to anti-topoII, anti-RAP1 gives a distinctly punctate staining that is located primarily at the nuclear periphery. Approximately 16 brightly staining foci can be identified in a diploid nucleus stained with anti-RAP1 antibodies, suggesting that telomeres are grouped together, perhaps through interaction with the nuclear envelope.

Chromosome dynamics in the yeast interphase nucleus.

Little is known about the dynamics of chromosomes in interphase nuclei. By tagging four chromosomal regions with a green fluorescent protein fusion to lac repressor, we monitored the movement and subnuclear position of specific sites in the yeast genome, sampling at short time intervals. We found that early and late origins of replication are highly mobile in G1 phase, frequently moving at or faster than 0.5 micrometers/10 seconds, in an energy-dependent fashion. The rapid diffusive movement of chromatin detected in G1 becomes constrained in S phase through a mechanism dependent on active DNA replication. In contrast, telomeres and centromeres provide replication-independent constraint on chromatin movement in both G1 and S phases.

Exclusion of CD45 from the T-cell receptor signaling area in antigen-stimulated T lymphocytes.

T lymphocytes are activated by the engagement of their antigen receptors (TCRs) with complexes of peptide and major histocompatibility complex (MHC) molecules displayed on the cell surface of antigen-presenting cells (APCs) [1]. An unresolved question of antigen recognition by T cells is how TCR triggering actually occurs at the cell-cell contact area. We visualized T-cell-APC contact sites using confocal microscopy and three-dimensional reconstruction of z-sections. We show the rapid formation of a specialized signaling domain at the T-cell-APC contact site that is characterized by a broad and sustained area of tyrosine phosphorylation. The T-lymphocyte cell-surface molecule CD2 is rapidly recruited into this signaling domain, whereas TCRs progressively percolate from the entire T-cell surface into the phosphorylation area. Remarkably, the highly expressed phosphatase CD45 is excluded from the signaling domain. Our results indicate that physiological TCR triggering at the T-cell-APC contact site is the result of a localized alteration in the balance between cellular kinases and phosphatases. We therefore provide experimental evidence to support current models of T-cell activation based on CD45 exclusion from the TCR signaling area [2] [3] [4].

MAP kinase signaling induces nuclear reorganization in budding yeast.

BACKGROUND: During the mating pheromone response in budding yeast, activation of a mitogen-activated protein kinase (MAP kinase) cascade results in well-characterized changes in cytoskeletal organization and gene expression. Spatial reorganization of genes within the nucleus has been documented during cell-type differentiation in mammalian cells, but no information was previously available on the morphology of the yeast nucleus during the major transcriptional reprogramming that accompanies zygote formation. RESULTS: We find that in response to mating pheromone, budding yeast nuclei assume an unusual dumbbell shape, reflecting a spatial separation of chromosomal and nucleolar domains. Within the chromosomal domain, telomeric foci persist and maintain their associated complement of Sir proteins. The nucleolus, on the other hand, assumes a novel cup-shaped morphology and a position distal to the mating projection tip. Although microtubules are required for this orientation with respect to the projection tip, neither microtubules nor actin polymerization are necessary for the observed changes in nuclear shape. We find that activation of the pheromone-response MAP kinase pathway by ectopic expression of STE4 or STE11 leads to identical nuclear and nucleolar reorganization in the absence of pheromone. Mutation of downstream effector MAP kinases Fus3p and Kss1p, or of the transcriptional regulator Ste12p, blocks nuclear shape changes, whereas overexpression of Ste12p promotes dumbbell-shaped nuclei in the absence of pheromone. CONCLUSIONS: Nuclear remodeling occurs when the MAP kinase cascade is activated by yeast pheromone, but it is independent of the cytoskeletal reorganization regulated by the same signaling pathway. Activation of the Ste12p transcription factor is necessary, and may be sufficient, for the changes in nuclear structure that coincide with developmentally significant changes in gene expression.

Mutation of yeast Ku genes disrupts the subnuclear organization of telomeres.

The mammalian Ku70 and Ku86 proteins form a heterodimer that binds to the ends of double-stranded DNA in vitro and is required for repair of radiation-induced strand breaks and V(D)J recombination [1,2]. Deletion of the Saccharomyces cerevisiae genes HDF1 and HDF2--encoding yKu70p and yKu80p, respectively--enhances radiation sensitivity in a rad52 background [3,4]. In addition to repair defects, the length of the TG-rich repeat on yeast telomere ends shortens dramatically [5,6]. We have shown previously that in yeast interphase nuclei, telomeres are clustered in a limited number of foci near the nuclear periphery [7], but the elements that mediate this localization remained unknown. We report here that deletion of the genes encoding yKu70p or its partner yKu80p altered the positioning of telomeric DNA in the yeast nucleus. These are the first mutants shown to affect the subnuclear localization of telomeres. Strains deficient for either yKu70p or yKu80p lost telomeric silencing, although they maintained repression at the silent mating-type loci. In addition, the telomere-associated silencing factors Sir3p and Sir4p and the TG-repeat-binding protein Rap1p lost their punctate pattern of staining and became dispersed throughout the nucleoplasm. Our results implicate the yeast Ku proteins directly in aspects of telomere organization, which in turn affects the repression of telomere-proximal genes.

Correlative SIM-STORM Microscopy.

The ability to specifically label subcellular structures or even proteins of interest in combination with the ability to look at live specimens turned fluorescence light microscopy into an invaluable tool. However, conventional light microscopy is diffraction limited, which restricts the lateral resolution to around 200 nm laterally and 600-800 nm axially. In 2014, the Nobel Prize in Chemistry was awarded to Eric Betzig, Stefan W. Hell, and William E. Moerner for the development of super-resolved fluorescent microscopy techniques. Since then, it has become evident that imaging techniques that enable the visualization of structures below the diffraction limit are essential for the field of life sciences. However, each one of these approaches has inherent advantages and limitations. Here, we describe an imaging workflow suitable for combining structured illumination microscopy (SIM) with direct stochastic optical reconstruction microscopy (dSTORM) data. This is invaluable, since it allows us to put highly resolved dSTORM data into its cellular context.

Identification of high affinity Tbf1p-binding sites within the budding yeast genome.

The yeast TBF1 gene is essential for mitotic growth and encodes a protein that binds the human telomere repeats in vitro, although its cellular function is unknown. The sequence of the DNA-binding domain of Tbf1p is more closely related to that of the human telomeric proteins TRF1 and TRF2 than to any yeast protein sequence, yet the functional homologue of TRF1 and TRF2 is thought to be Rap1p. In this study we show that the Tbf1p DNA-binding domain can target the Gal4 transactivation domain to a (TTAGGG)(n) sequence inserted in the yeast genome, supporting the model that Tbf1p binds this sub-telomeric repeat motif in vivo. Immunofluorescence of Tbf1p shows a spotty pattern throughout the interphase nucleus and along synapsed chromosomes in meiosis, suggesting that Tbf1p binds internal chromosomal sites in addition to sub-telomeric regions. PCR-assisted binding site selection was used to define a consensus for high affinity Tbf1p-binding sites. Compilation of 50 selected oligonucleotides identified the consensus TAGGGTTGG. Five potential Tbf1p-binding sites resulting from a search of the total yeast genome were tested directly in gel shift assays and shown to bind Tbf1p efficiently in vitro, thus confirming this as a valid consensus for Tbf1p recognition.

Metaphase chromosome structure. Involvement of topoisomerase II.

SCI is a prominent, 170,000 Mr, non-histone protein of HeLa metaphase chromosomes. This protein binds DNA and was previously identified as one of the major structural components of the residual scaffold structure obtained by differential protein extraction from isolated chromosomes. The metaphase scaffold maintains chromosomal DNA in an organized, looped conformation. We have prepared a polyclonal antibody against the SC1 protein. Immunolocalization studies by both fluorescence and electron microscopy allowed identification of the scaffold structure in gently expanded chromosomes. The micrographs show an immunopositive reaction going through the kinetochore along a central, axial region that extends the length of each chromatid. Some micrographs of histone-depleted chromosomes provide evidence of the substructural organization of the scaffold; the scaffold appears to consist of an assembly of foci, which in places form a zig-zag or coiled arrangement. We present several lines of evidence that establish the identity of SC1 as topoisomerase II. Considering the enzymic nature of this protein, it is remarkable that it represents 1% to 2% of the total mitotic chromosomal protein. About 60% to 80% of topoisomerase II partitions into the scaffold structure as prepared from isolated chromosomes, and we find approximately three copies per average 70,000-base loop. This supports the proposed structural role of the scaffold in the organization of the mitotic chromosome. The dual enzymic and apparent structural function of topoisomerase II (SC1) and its location at or near the base of chromatin loops allows speculation as to its involvement in the long-range control of chromatin structure.

Aromatase and 17beta-hydroxysteroid dehydrogenase inhibition by flavonoids.

A method for estimating in the same assay both aromatase and 17beta-hydroxysteroid dehydrogenase activities in human placental microsomes using radiolabelled [1,2,6,7-3H]4-androstene-3,17-dione was proposed. In this assay, estrone (E1) and estradiol (E2) produced were separated by HPLC and estimated using a radioactive flow detector. Using this method, the inhibitory effect of various flavonoids, including flavone, flavanone and isoflavone, on the human placental aromatase and 17beta-hydroxysteroid dehydrogenase was studied. Flavonoids were shown to be potent inhibitors of both aromatase and 17beta-hydroxysteroid dehydrogenase activities. We found that 7-hydroxyflavone and apigenin are the most effective aromatase and 17beta-hydroxysteroid dehydrogenase inhibitors, respectively. Experiments showed that a hydroxyl group in position 7 was essential for anti-17beta-hydroxysteroid dehydrogenase activity. However, flavonoids with 7-methoxy or 8-hydroxyl groups on the A ring showed only anti-aromatase activity. Structure-activity relationships were discussed.

Nuclear organization and silencing: trafficking of Sir proteins.

In budding yeast genes integrated near telomeres succumb to a variegated pattern of gene repression that requires the silent information regulatory proteins Sir2p, Sir3p and Sir4p, which form a nucleosome-binding complex. Immunolocalization shows that the Sir proteins co-localize with the telomeric repeat binding protein Rap1p and with telomeric DNA in a limited number of foci near the periphery of interphase nuclei. All conditions tested so far that disrupt telomere proximal repression result in a dispersed staining pattern for Sir2p, Sir3p and Sir4p. Although the focal organization is clearly not sufficient for establishing repression, genetic studies suggest that the high local concentration of Sir proteins at telomeric foci facilitates the formation of repressed chromatin. In addition to its telomeric localization, Sir2p is shown by immunostaining and cross-linking to bind a subdomain of the nucleolus. In strains lacking an intact Sir4p, Sir3p also becomes concentrated in the nucleolus by a pathway requiring SIR2 and UTH4. This unexpected localization correlates with observed effects of sir mutations on rDNA stability and longevity, defining a new site of action for silent information regulatory factors. We report a novel WD40 repeat-containing factor, Sif2p, that binds specifically to the Sir4p N-terminus. Like Sir1p and Uth4p, Sif2p antagonizes telomeric silencing by regulating an equilibrium between alternative assembly pathways at different subnuclear loci.

[Undesirable events during the perioperative period and communication deficiencies]. / Évènements indésirables et problèmes de communication en périopératoire.

In recent decades, anaesthesia and surgery have undergone major scientific and technical developments. However, these improvements have not solved a recurring problem, communication deficiencies within teams in charge of surgical patients. Current figures show that 21% to 65% of accidents and errors in patient management during the perioperative period are related to communication problems. These problems occur when gaps arise in the continuity and coordination of care within teams. Some of the contributing factors to these gaps are emergency status of patients, staff shifts and handovers following patient transfers. To minimize the impact of these phenomena, it is important to improve standardization of information flow within operating theatres and to improve teamwork between anaesthetists and surgeons. This can be done through crew resource management training programs or simulation. This should ultimately contribute to minimise medical error and improve the overall quality of care provided to patients in operating theatres and during all the perioperative period.

The composition and morphology of yeast nuclear scaffolds.

The yeast nuclear scaffold has been shown to bind with high affinity to genomic sequences that permit autonomous DNA replication of plasmids (ARS elements). We describe here conditions for the isolation of a histone-free nuclear substructure, the nuclear scaffold, from Saccharomyces cerevisiae. We examine the protein composition of this structure,and the conditions under which topoisomerase II, the nuclear factor RAP-1 and RNA polymerase II co-fractionate with the scaffold. We find that exposure of nuclei to a combined metal and heat treatment (0.5mM Cu(2) +, 37 degree centigrade prior to detergent extraction is required for effective stabilization of these proteins with the scaffold. Electron microscopy of the residual nuclei extracted with non-ionic detergents shows the absence of a typical peripheral lamina structure.

Nuclear scaffold attachment stimulates, but is not essential for ARS activity in Saccharomyces cerevisiae: analysis of the Drosophila ftz SAR.

Nuclei isolated from eukaryotic cells can be depleted of histones and most soluble nuclear proteins to isolate a structural framework called the nuclear scaffold. This structure maintains specific interactions with genomic DNA at sites known as scaffold attached regions (SARs), which are thought to be the bases of DNA loops. In both Saccharomyces cerevisiae and Schizosaccharomyces pombe, genomic ARS elements are recovered as SARs. In addition, SARs from Drosophila melanogaster bind to yeast nuclear scaffolds in vitro and a subclass of these promotes autonomous replication of plasmids in yeast. In the present report, we present fine mapping studies of the Drosophila ftz SAR, which has both SAR and ARS activities in yeast. The data establish a close relationship between the sequences involved in ARS activity and scaffold binding: ARS elements that can bind the nuclear scaffold in vitro promote more efficient plasmid replication in vivo, but scaffold association is not a strict prerequisite for ARS function. Efficient interaction with nuclear scaffolds from both yeast and Drosophila requires a minimal length of SAR DNA that contains reiteration of a narrow minor groove structure of the double helix.

RAP1 stimulates single- to double-strand association of yeast telomeric DNA: implications for telomere-telomere interactions.

Repressor Activator Protein 1 (RAP1) of Saccharomyces cerevisiae is an abundant nuclear protein implicated in telomere length maintenance, transactivation, and in the establishment of silent chromatin domains. The RAP1 binding site 5' of the yeast HIS4 gene is also a region of hyperrecombination in meiosis. We report here that as RAP1 binds its recognition consensus, it appears to untwist double-stranded DNA, which we detect as the introduction of a negative supercoil in circularization assays. Coincident with the RAP1-dependent untwisting, we observe stimulation of the association of a single-stranded yeast telomeric sequence with its homologous double-stranded sequence in a supercoiled plasmid. This unusual distortion of the DNA double helix by RAP1 may contribute to the RAP1-dependent enhancement of recombination rates and promote non-duplex strand interactions at telomeres.