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. 2014 May 20:3:e02203.
doi: 10.7554/eLife.02203.

Imaging the fate of histone Cse4 reveals de novo replacement in S phase and subsequent stable residence at centromeres

Jan Wisniewski  1 Bassam Hajj  2 Jiji Chen  2 Gaku Mizuguchi  3 Hua Xiao  4 Debbie Wei  4 Maxime Dahan  2 Carl Wu  5
Affiliations

Imaging the fate of histone Cse4 reveals de novo replacement in S phase and subsequent stable residence at centromeres

Jan Wisniewski et al. Elife. .

Abstract

The budding yeast centromere contains Cse4, a specialized histone H3 variant. Fluorescence pulse-chase analysis of an internally tagged Cse4 reveals that it is replaced with newly synthesized molecules in S phase, remaining stably associated with centromeres thereafter. In contrast, C-terminally-tagged Cse4 is functionally impaired, showing slow cell growth, cell lethality at elevated temperatures, and extra-centromeric nuclear accumulation. Recent studies using such strains gave conflicting findings regarding the centromeric abundance and cell cycle dynamics of Cse4. Our findings indicate that internally tagged Cse4 is a better reporter of the biology of this histone variant. Furthermore, the size of centromeric Cse4 clusters was precisely mapped with a new 3D-PALM method, revealing substantial compaction during anaphase. Cse4-specific chaperone Scm3 displays steady-state, stoichiometric co-localization with Cse4 at centromeres throughout the cell cycle, while undergoing exchange with a nuclear pool. These findings suggest that a stable Cse4 nucleosome is maintained by dynamic chaperone-in-residence Scm3.DOI: http://dx.doi.org/10.7554/eLife.02203.001.

Keywords: 3D-PALM; Cse4 histone variant; Scm3 chaperone; centromeric nucleosome; fluorescence pulse-chase; multifocus microscopy.

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Conflict of interest statement

The authors declare that no competing interests exist.

Figures

Figure 1.
Figure 1.. Internal tagging of Cse4 confers exclusive centromeric localization and preserves wild type phenotype.
(A) Alternative tag locations at Leu81 (internal XbaI site) or at the C-terminus of Cse4 are indicated by green triangles. Unstructured N-terminal tail (aa1-135) is depicted in grey while region corresponding to the known 3D structure of mammalian CENP-A (aa134-226) is shown as solid black and red (loops and α-helices of histone-fold domain). Functionally important END region (aa28-60) and C-terminal CENP–C interaction region QFI (aa227-228) are highlighted in blue and yellow. (B) Schematic position of fluorescent protein tags in relation to the overall nucleosome structure. Monomeric GFP tag is shown in green while Cse4 histone-fold domains are highlighted in red inside nucleosome core. Unstructured N-terminal tails of Cse4 are depicted as dashed lines for illustrative purposes. (CE) Distribution of tagged Cse4 in live cells containing Cse4 tagged internally with GFP (C) or tdEos (D), or the C-terminal GFP fusion (E). Cell cycle stages are indicated in DIC panels. In addition to G1, S, and G2, individual stages of mitosis are identified as: M—metaphase, A—anaphase, T—telophase. Fluorescence images are shown as negatives to reveal residual intracellular autofluorescence and the diffuse nuclear presence of C-terminally tagged Cse4. (F) Viability test of strains containing wild-type or tagged Cse4. 10 μl of 10-fold serial dilutions of equivalent log-phase cultures were spotted on YPD plates and incubated overnight at 38°C or for 36 hr at 24°C. DOI: http://dx.doi.org/10.7554/eLife.02203.003
Figure 1—figure supplement 1.
Figure 1—figure supplement 1.. Fluorescence of centromeric clusters containing C-terminally tagged Cse4 is slightly elevated but does not double in anaphase.
(A) Representative examples of metaphase and telophase cells (outlined) shown at the same brightness scale. Clusters in surrounding cells may be out of focus. (B) Intensity of individual centromeric clusters in metaphase (M) and telophase (T) was measured by photometry (5 s exposure). Minimum/1st quartile/median/3rd quartile, and maximum values are displayed for each group of 20 measurements. Prior to measurement, clusters were separated from lower frequency components of the image (diffuse fluorescence present in nuclei and intracellular autofluorescence) by processing the image with wavelet function and adding together scales 1+2+3 (1, 2 and 4 pixels across) (see Figure 7—figure supplement 1). DOI: http://dx.doi.org/10.7554/eLife.02203.004
Figure 1—figure supplement 2.
Figure 1—figure supplement 2.. Internally tagged Cse4 accumulates at levels comparable to wild-type protein.
(A) Whole-cell lysates of cells containing wild-type or tagged Cse4 were probed with affinity-purified anti-Cse4 antibody. Arrows indicate bands corresponding to wild-type Cse4 (27 kDa) and Cse4 fused to GFP (57 kDa) or tdEos (87 kDa). A control blot probed for histone H4 is shown below. (B) Anti-Cse4 antibody was used to estimate the level of endogenous wild-type Cse4 (present in WT lysate) by comparison to indicated amounts of purified recombinant H6-Cse4 introduced into a lysate of the strain carrying Cse4-GFPinternal. The * denotes a common background band used to normalize different lysates; see below. The presence of the Histidine-tag visibly retards the electrophoretic mobility of recombinant Cse4 and Cse4-GFP. (C and D) A similar analysis of Cse4 internally tagged with GFP (C) or tdEos (D). In these cases, purified proteins were introduced into WT lysate. (E) Plot of band intensity (panel B) for recombinant Cse4 (black dots) to estimate the endogenous Cse4 level (red dot). (F and G) Estimates of endogenous levels of internally tagged Cse4 (panels C and D). Insets show the intensity of the common background band used to compare Cse4-GFPinternal and Cse4-tdEosinternal lysates to WT lysate. The resulting normalization factor is given in red. After normalization (protein fmoles/normalization factor), we obtained a 1:1 ratio for both Cse4:Cse4-GFPinternal and Cse4:Cse4-tdEosinternal. DOI: http://dx.doi.org/10.7554/eLife.02203.005
Figure 2.
Figure 2.. Pre-existing Cse4 is removed and exchanged for new Cse4 molecules at G1/S transition.
(A) Relevant fluorescence states of a tdEos-tagged protein molecule are depicted schematically after its synthesis and folding, fluorophore maturation and irreversible photoconversion. Excitation and emission peak wavelengths are indicated (see Figure 6—figure supplement 1 for additional details). (B) Pulse-chase experimental scheme. After initial photoconversion (pulse at t0), red-fluorescent Cse4 is followed into later stages of the cell cycle (chase until tx). (CE) Cells containing Cse4-tdEos were imaged immediately after pulse (C) and following 40 min chase (D). At the end, additional photoconversion (2ndPC) was used to confirm sufficient Z-stack range (E). Three cells that crossed G1/S boundary are outlined in magenta while all other cells are outlined in grey, based on DIC images. (F) An example of a telophase cell followed until mother cell entered S phase, while the bud-derived daughter remained in G1. (G) An example of S phase cell followed into telophase. DOI: http://dx.doi.org/10.7554/eLife.02203.006
Figure 3.
Figure 3.. Cell cycle-dependent increase in centromere cluster intensity is a result of fluorophore maturation.
(A) Relative intensity of centromeric clusters in asynchronously growing cells as the function of cell cycle stage and approximate time since entry into S phase. Values were corrected per 16 centromeres, to account for the presence of replicated (32) centromeres in a single ‘dot’ in S and G2. ∼7500 and ∼11,000 photons were detected during 5 s exposure for G1 clusters containing Cse4 with internal GFP or tdEos, respectively—other results were normalized against those values. Standard deviation of each sample is indicated. (B) Schematic of the experiment to measure maturation rate of fluorophores present on Cse4-tdEos. Following α-factor synchronization, cycloheximide (CHX, 0.2 mg/ml) was added 10 min after entry into S phase. (C) Images of S phase cells at different sampling points (tx) after bud emergence. Cells which entered S phase prior to addition of cycloheximide are outlined. (D) Relative fluorescence of Cse4-tdEos centromere clusters in S phase in the absence of protein synthesis. Plateau value (average of points representing tx >100 min, ∼1750 photons detected during 1 s exposure) was used for normalization and standard deviations are indicated. DOI: http://dx.doi.org/10.7554/eLife.02203.007
Figure 4.
Figure 4.. Removal of pre-existing Cse4 is associated with DNA replication.
(A) Experimental scheme to assess role of DNA replication on the removal of pre-existing Cse4. α-factor synchronized cells were released into control medium or one with 0.2 M hydroxyurea (HU). Cse4-tdEos was photoconverted prior to bud emergence and then followed after sizable buds became evident. (B) Examples of cells released from α-factor block directly into control or hydroxyurea (+HU) containing medium. Time of photoconversion and observation after chase is indicated. Only cells on which buds appeared during the observation period are outlined. DOI: http://dx.doi.org/10.7554/eLife.02203.008
Figure 5.
Figure 5.. There is no additional Cse4 deposition in anaphase.
(A) Scheme of the experimental test for Cse4 deposition in anaphase. All operations were carried on a selected metaphase cell in the specified order. 3D diffraction-limited spot, generated with a galvano-controlled MicroPoint 551 nm dye laser system, was used for targeted photobleaching. (B) An example of the metaphase cell subjected to a targeted photobleaching of photoconverted Cse4-tdEos centromeric cluster. Images were acquired at stages indicated in panel A. DOI: http://dx.doi.org/10.7554/eLife.02203.009
Figure 6.
Figure 6.. Centromeric clusters become more compact during anaphase.
(A) An example of MFM-PALM image with nine simultaneously acquired Z-planes. Gold Nanorods are indicated (blue circles) and distance above the glass surface is listed for other tiles. Anaphase cell outline (red) is based on a separate bright-field MFM image. Two single-molecule events of Cse4-tdEos are visible inside the cell. (B) A time-trace representation of the number of tdEos fluorophore detections per frame during single MFM-PALM acquisition series. Events lasting >1 frame were considered to represent the same fluorophore. (C) A projection of all 73 independent single-fluorophore detections in the above image series. Image volume is indicated and Z position of individual localizations is color-coded. Each event is depicted as a dot 50 nm across (increased from average 20 nm lateral precision to facilitate visualization at this image scale). Number of events concentrated at each of the two centromeric clusters is listed. See Video 1. ViSP software (El Beheiry and Dahan, 2013) was used for projections in CE. (D) A representative example of a 3D distribution of Cse4-tdEos molecules on the G1 centromere cluster. Each event (total of 21 independent detections) is depicted as a 20 nm dot, corresponding to the average lateral localization precision. Total volume of 1 μm3 is shown, with color-coded Z distance. See Video 2. (E) A representative late anaphase centromere cluster depicted as above. Total of 24 independent detections are plotted. See Video 3. (F) Compilation of detections from 10 G1 clusters, center-aligned and projected onto XY plane. Grey circle depicts cross-section of a sphere (∼450 nm across) sufficient to contain majority of detected Cse4-tdEos molecules. (G) Compilation of total detections from 10 late anaphase and telophase clusters projected onto XY plane (center-aligned, long axis rotated horizontally). Grey ellipse depicts cross-section of an ellipsoid (∼350 nm equatorial diameter and ∼200 nm polar distance) sufficient to contain majority of detected Cse4-tdEos molecules. In both cases, distribution in Z is comparable to that along X-axis (not shown). DOI: http://dx.doi.org/10.7554/eLife.02203.010
Figure 6—figure supplement 1.
Figure 6—figure supplement 1.. tdEos fluorophore undergoes transitions between multiple fluorescent and dark states.
Different states of tdEos fluorophore (and mEos variants, including mIRIS [Wiedenmann et al., 2011]) are shown schematically. Newly synthesized non-fluorescent tdEos undergoes fast folding followed by slow maturation into green emitting state (λexcem = 506 nm/516 nm, respectively) (Nienhaus et al., 2006). Green tdEos can undergo irreversible photobleaching as well as conversion to a long-term reversible dark state, from which it is ‘rescued’ by 405 nm illumination (JW personal communication). 405 nm light also induces irreversible photoconversion from green- to red-emitting form (Nienhaus et al., 2006). Interestingly, PFA fixation also results in the conversion of some fluorophores into the red-emitting state (JW, personal communication). Red tdEos may be bleached irreversibly or enter a reversible dark state as well—again subject to rescue by 405 nm illumination (Annibale et al., 2010). In addition, both fluorescent forms undergo short-term ‘blinking’ (not depicted in the figure). DOI: http://dx.doi.org/10.7554/eLife.02203.011
Figure 7.
Figure 7.. Two Cse4 molecules are present on each centromere.
(A) Comparison of Cse4-GFP centromere clusters with TetR-GFP bound to arrays of 7, 14 or 21 tetO, displayed within the same brightness range. Representative telophase cells are outlined. Clusters in surrounding cells may be out of focus. (B) Fluorescence intensity of tetO arrays and centromeric clusters was measured in telophase cells (2 s exposure). Minimum/1st quartile/median/3rd quartile and maximum values are displayed for each group of 50 measurements. Prior to measurement, clusters were separated from lower frequency components of the image (diffuse fluorescence in nuclei and intracellular autofluorescence) by processing the image with wavelet function and adding together scales 1, 2 and 3 (1, 2 and 4 pixels FWHM). DOI: http://dx.doi.org/10.7554/eLife.02203.015
Figure 7—figure supplement 1.
Figure 7—figure supplement 1.. Wavelet filtering allows precise separation of cluster signal from nuclear and cellular background.
(A) Images of the representative telophase cells (outlined) are shown for Cse4-GFPinternal strain or strains containing integrated tetO arrays (7, 14, 21 or 112 repeats) and TetR-GFP under constitutive low level expression from mutated URA3 promoter. Image containing extracted small-scale structures (sum of wavelet scales 1, 2, and 3) is presented together with the larger structures, representing background (including cells and nuclei; sum of remaining wavelet scales and residual). Simple arithmetic addition of all scales (1 through 8) and residual returns the image indistinguishable from the original (within the precision of the 32-bit floating-point format). (B) An example of intensity profile (in ADUs) across cell, nucleus and cluster present in a telophase cell from the strain containing 21x tetO and TetR-GFP. Scales 1+2+3 accurately separate cluster signal from background (represented by higher scales). (C) Similar example of intensity profile and effects of wavelet filtering for a telophase cell containing Cse4-GFPinternal. DOI: http://dx.doi.org/10.7554/eLife.02203.016
Figure 8.
Figure 8.. Scm3 dynamically interacts with centromeres at levels equivalent to Cse4.
(A) Scm3-tdEos fluorescence recovery after targeted photobleaching. The experiment was performed essentially as shown in Figure 5A, except that recovery was monitored by repetitive imaging, without additional photoconversion. In this example, images were acquired only when indicated. Arrowhead indicates targeted centromere cluster. (B) Pulse-chase demonstrates overall stability and cell-cycle persistence of Scm3-tdEos. Photoconverted Scm3 molecules were followed after approximately one and two cell cycles (2.5 and 4 hr, respectively). Fluorescent images are displayed with the same intensity range. (C) Fluorescence intensity of centromeric clusters containing Scm3-tdEos (black circles) or Cse4-tdEosinternal (open circles) in late anaphase/telophase. Average and standard deviation are shown as a function of excitation time to illustrate photostability of photoconverted tdEos. ∼10,000 photons were initially detected in 5 s exposure in both cases. Representative images of individual cells containing Cse4-tdEosinternal or Scm3-tdEos are shown at the same brightness scale. DOI: http://dx.doi.org/10.7554/eLife.02203.017
Figure 8—figure supplement 1.
Figure 8—figure supplement 1.. Scm3-tdEos is present on centromeres and in the nucleus at every stage of the cell cycle.
(A) Distribution of Scm3-tdEos in live cells. Cell cycle stages are indicated in DIC panels and red fluorescence, after photoconversion, is shown as in Figure 1. (B) Majority of Scm3 is dispersed throughout nucleus. Average ratio of fluorescence present at centromeres (±standard deviation) through the cell cycle is indicated. (C) Scm3-tdEos is not displaced from centromeres in S phase but its signal diminishes, probably due to exchange with new, less mature molecules. DOI: http://dx.doi.org/10.7554/eLife.02203.018
Figure 8—figure supplement 2.
Figure 8—figure supplement 2.. Similar amounts of Cse4 and Scm3 molecules reside at centromeres.
(A) Average intensity (photons/s, ±standard deviation) of centromeric clusters containing Cse4-GFPinternal or Scm3-GFP (n = 8), measured during continuous excitation. (B) Sample images of cells containing Cse4-GFP or Scm3-GFP are shown at the same brightness scale. DOI: http://dx.doi.org/10.7554/eLife.02203.019
Figure 9.
Figure 9.. Model of Cse4 replacement and re-establishment of point centromere during cell cycle (see text for details).
DOI: http://dx.doi.org/10.7554/eLife.02203.021
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