The quantitative architecture of centromeric chromatin

  1. Dani L Bodor
  2. João F Mata
  3. Mikhail Sergeev
  4. Ana Filipa David
  5. Kevan J Salimian
  6. Tanya Panchenko
  7. Don W Cleveland
  8. Ben E Black
  9. Jagesh V Shah
  10. Lars ET Jansen  Is a corresponding author
  1. Instituto Gulbenkian de Ciência, Portugal
  2. Harvard Medical School, United States
  3. Brigham and Women's Hospital, United States
  4. University of Pennsylvania, United States
  5. University of California, San Diego, United States
8 figures

Figures

Figure 1 with 1 supplement
CENP-A levels are regulated by mass-action.

(A) Schematic of gene-targeting strategy that allowed for the creation of CENP-A knockout and fluorescent knock-in alleles. The region encoding the essential CENP-A targeting domain (CATD, Black et al., 2007) is indicated. (B) Quantitative immunoblots of CENP-A, HJURP, and Mis18BP1 in differentially targeted RPE cell lines. α-tubulin is used as a loading control. (C) Immunofluorescence images of same cell lines as in B. CENP-A intensity is represented in a heat map as indicated on the right. The fold difference ± SEM (n is biological replicates) compared to wild-type RPE cells is indicated below. Scale bar: 10 μm. Note that in contrast to quantification of immunoblots, immunofluoresce detection of untagged and tagged CENP-A is directly comparable. (D) Quantification of centromeric CENP-A levels (from C) by immunofluorescence (IF) and total CENP-A levels (n = 4–9 independent experiments as in B) by western blot (WB). All cell lines expressing untagged CENP-A are normalized to CA+/+ while those expressing tagged CENP-A are normalized to the centromeric CAY/− levels measured in C, as indicated by dashed lines. (E) Correlation of centromeric and total cellular CENP-A levels as measured in D. Dashed line represents a predicted directly proportional relationship with indicated correlation coefficients. Throughout, the average ± SEM is indicated. (F) Quantification of centromeric CENP-A levels in synchronized HeLa cells (based on anti-CENP-A staining) within a single cell cycle after transient transfection of indicated proteins. Asterisk indicates statistically significant increase compared to control or indicated transfections (one-tailed t test; p<0.05; n = 3); NS indicates no significant increase. Average ± SEM of three independent experiments is shown.

https://doi.org/10.7554/eLife.02137.003
Figure 1—figure supplement 1
CENP-A expression is the rate limiting factor for centromeric CENP-A levels.

(A) Pedigree of targeted RPE cell lines used in this study. Uninterrupted lines indicate single gene-targeting events, interrupted lines indicate multiple sequential gene-targeting events, and dashed lines indicate stable ectopic protein expression. (BC) Correlation of centromeric CENP-A and total cellular HJURP (B) or Mis18BP1 levels (C). Insets show quantification of total protein levels from Figure 1B; n = 3–5 independent experiments. Dashed lines represent hypothetical directly proportional relationships with indicated correlation coefficients. In the insets, the average ± SEM (n = 3–5) is shown.

https://doi.org/10.7554/eLife.02137.004
Figure 2 with 3 supplements
Human centromeres contain 400 molecules of CENP-A.

(A) Schematic outline of strategy allowing for the quantification of the centromeric fraction of CENP-A compared to the total cellular pool. Scale bars: 5 μm. (B) Quantification of the centromeric fraction of CENP-A in CAY/− cells. Each circle represents one centromere; circles on the same column are individual centromeres from the same cell. Dashed line indicates average of all centromeres. (C) Quantification of the centromeric fraction of CENP-A in indicated cell lines. Each square represents the average centromeric signal from one cell; squares on the same column are individual cells from the same experiment (Exp). Figure 2—figure supplement 2 shows quantification of individual centromeres in CAG/− and CAY/−+OE cells. (D) Representative quantitative immunoblot of purified recombinant CENP-A and endogenous CENP-A from whole cell extracts (WCE). (E) Quantification of D. Solid line represents the best fit linear regression. Dashed line represents the amount of CENP-A from 150,000 cells. (F) Quantification of the total cellular CENP-A copy number. Each diamond represents one replicate experiment; measurement from E is indicated as a gray diamond. (G) Calculation of average CENP-A copy number per centromere (CEN) in wild-type RPE cells. Throughout, the average ± SEM is indicated.

https://doi.org/10.7554/eLife.02137.005
Figure 2—figure supplement 1
Representative fluorescence lifetime imaging (FLIM) micrograph of a CENP-A-YFP expressing cell (left) and quantification of indicated cellular regions (right).
https://doi.org/10.7554/eLife.02137.006
Figure 2—figure supplement 2
Measurements of individual centromeres and CENP-A levels for different cell lines.

(A and B) Graphs as in Figure 2B for CAG/− (A) and CAY/−+OE (B) cells. (C) Graph showing the absolute amount of centromeric CENP-A for indicated cell lines.

https://doi.org/10.7554/eLife.02137.007
Figure 2—figure supplement 3
Transfer efficiency of recombinant and cellular CENP-A.

Immunoblots of recombinant and cellular CENP-A from CA+/+, CAG/−, and CAY/− cells, after protein transfer onto a stack of three membranes. The fraction of CENP-A retained on the first membrane (compared to the total signal from all three membranes) is quantified below. While YFP- or GFP-tagged CENP-A barely passes through the membrane at all, untagged CENP-A from cell extracts or recombinant protein preps is retained equally well on the first membrane.

https://doi.org/10.7554/eLife.02137.008
Figure 3 with 1 supplement
Centromeric CENP-A levels are equivalent between S phase and randomly cycling cells.

(A) Cartoon depicting changes in cell morphology and nuclear levels of hCdt1(30/120)-RFP (in red) throughout the cell cycle (Sakaue-Sawano et al., 2008). Approximate timing of CENP-A expression (Shelby et al., 2000) and centromeric loading (Jansen et al., 2007) are indicated in orange and blue, respectively. The stage at which cells were analyzed to measure the centromeric fraction of CENP-A is indicated in green. (B) An example trace of a cell entering S phase (indicated by a sudden decrease in RFP levels) is shown. The centromeric fraction of CENP-A was measured at this point as outlined in Figure 2A. Peak expression is normalized to 100 and background fluorescence to 0. Micrographs of hCdt-1(30/120)-RFP at indicated timepoints are shown below. (C) As in Figure 2C. Orange squares represent cells that have passed the G1-S transition point, as indicated by decreasing levels of hCdt-1(30/120)-RFP. Gray squares represent randomly cycling cells. No statistically significant differences (NS) were observed between randomly cycling cells and S phase cells.

https://doi.org/10.7554/eLife.02137.009
Figure 3—figure supplement 1
hCdt-1(30/120)-RFP expression allows for accurate determination of cell cycle stages and measurements of centromeric CENP-A ratios.

(A) An example trace of a cell that had entered G1 phase at the beginning of the experiment (as determined by cellular morphology using DIC) is shown. Graph as in Figure 3B. (B) Baculoviral transduction of hCdt-1(30/120)-RFP does not affect measurements of CENP-A-YFP. Centromeric CENP-A ratio measurements of non-transduced cells were compared to measurements of unstaged (i.e., randomly cycling) cells expressing hCdt-1(30/120)-RFP. Graph as in Figure 3C.

https://doi.org/10.7554/eLife.02137.010
Measurement of nuclear CENP-A confirms centromeric copy number.

(A) As in Figure 2B, except that the centromeric fraction compared to total nuclear pool is indicated. Inset shows a representative image of a CAY/−+H2B-RFP cell (scale bar: 2.5 μm). (B) Quantitative immunoblot showing the soluble fraction and a dilution series from the insoluble fraction of CENP-A-YFP in CAY/−+H2B-RFP cells (left). Tubulin is used as a marker for the soluble fraction and H4K20me2 (exclusively found in chromatin, Karachentsev et al., 2007) for the insoluble fraction. Quantification of insoluble fraction of CENP-A is shown to the right. (C) Calculation of the average CENP-A copy number per centromere (CEN) in wild-type RPE cells, based on results from CAY/−+H2B-RFP cells.

https://doi.org/10.7554/eLife.02137.011
Figure 5 with 1 supplement
Independent quantification methods confirm centromeric CENP-A copy number.

(A) Stochastic fluctuation method: cartoon depicting inheritance and random redistribution of parental CENP-A nucleosomes onto sister chromatids during DNA replication. A hypothetical distribution of the absolute difference between the two sister centromeres, as well as the formula for calculating the fluorescence intensity per segregating unit (α) are indicated on the right. (B) Representative image of mitotic CENP-A-YFP expressing cell. CENP-B staining allows for identification of sister centromeres. Blowup to the right represents a single slice of the boxed region showing that CENP-B is located in between the CENP-A spots of sister centromeres. (C) Frequency distribution of the difference between CENP-A-GFP intensity of sister centromeres in CAG/− cells. (D) Quantification of centromeric CENP-A-GFP based on the stochastic fluctuation method. Each circle represents one centromere; circles on the same column are individual centromeres from the same cell. Left y-axis indicates segregating CENP-A-GFP units in CAG/− cells; right y-axis shows the conversion to minimum number of centromeric CENP-A molecules in CA+/+ (WT) cells. (E) Fluorescent standard method: representative fluorescence images of 4kb-LacO, LacI-GFP S. cerevisiae and human CAG/− cells. (F) Quantification of fluorescence signals of LacI-GFP and CENP-A-GFP spots (n = 2 biological replicates). The left y-axis indicates the fluorescence intensity normalized to LacI-GFP; the right y-axis shows the conversion to maximum number of centromeric CENP-A molecules in wild-type cells. (G) Comparison of independent measurements for the centromeric CENP-A copy number (corrected for CA+/+ levels; Stoch. fluctuations = stochastic fluctuation method [Figure 5A]; Integr. fluorescence = integrated fluorescence method [Figure 2A]). Levels from all strategies are corrected for CA+/+ (WT) levels. Throughout, the average ± SEM and scale bars of 2.5 μm are indicated.

https://doi.org/10.7554/eLife.02137.012
Figure 5—figure supplement 1
Stochastic fluctuations of CENP-A segregation allows for copy number measurements.

(AD) Results as in Figure 5C–D for CAY/− (AB) and CAY/−+OE cells (CD). (E) Quantification of segregating units in CAG/− cells based on sister centromeres (dark green) or random centromere pairs (light green; random pairs were assigned independently three times). Asterisks indicate a significant difference from sister centromere result (t test; p<0.0001 in all cases). Each circle represents one centromere pair. Throughout, the average ± SEM is indicated.

https://doi.org/10.7554/eLife.02137.013
Figure 6 with 1 supplement
Reduction of CENP-A leads to a CENP-C, CENP-T, and Hec1 independent increase in micronuclei.

(A) Quantification of centromeric CENP-A (from Figure 1), CENP-C, CENP-T, and Hec1 levels for indicated cell lines; n = 4 independent experiments in each case. Note that cell lines carrying tagged CENP-A have a slight, yet non-significant impairment in recruiting CENP-C, CENP-T, and Hec1. However, this does not correlate with the CENP-A levels themselves. Below, representative images of indicated antibody staining from CA+/+ cells are shown. Representative images from all cell lines can be found in Figure 6—figure supplement 1. (B) Quantification of the fraction of cells containing micronuclei (MN) for indicated cell lines. Asterisk indicates statistically significant increase compared to wild-type (paired t test; p<0.05; n = 3–4 independent experiments [500–3000 cells per experiment per cell line]); NS indicates no significant difference. Throughout, the average ± SEM is indicated and dashed lines represent wild-type levels. Scale bars: 5 μm.

https://doi.org/10.7554/eLife.02137.014
Figure 6—figure supplement 1
Representative images for quantifications in Figure 6B.

Images of indicated cell lines are shown for immunofluorescence staining of (A) CENP-C, (B) CENP-T, and (C) Hec1 (mitotic cells). Scale bars: 5 μm.

https://doi.org/10.7554/eLife.02137.015
Figure 7 with 1 supplement
Centromere and cell specific distribution of CENP-A.

(A, C, E) Representative micrograph of mitotic spreads for LacI-GFP::LacO expressing HCT-116 cells (A); wild-type HCT-116 cells (C); and PDNC-4 cells (E). Blowups show the chromosome containing the integrated Lac-array (A); the Y-chromosome (outline indicated; CENP-B negative) as well as an autosome (CENP-B positive) (C); and the neocentric chromosome 4, containing 2 pairs of ACA spots (staining both CENP-A and CENP-B), but only 1 pair of CENP-A spots (E). (B, D, F) Quantification of CENP-A levels on the centromere of the chromosome containing the Lac-array (CEN-Lac; n = 29; B); the Y-chromosome (CEN-Y; n = 18; D); and neocentric chromosome 4 (NeoCEN-4; n = 39; F) of indicated cell lines compared to all other centromeres within the same cell (Other CENs; n = 1008, 620, and 1592, respectively). Median (line), interquartile distance (box), 3 × interquartile distance or extremes (whiskers), and outliers (spots) are indicated. Figure 7—figure supplement 1 shows results of individual centromeres. Asterisk indicates statistically significant difference (t test; p<0.05); NS indicates no significant difference. (G) Representative images of CENP-A antibody staining in indicated cell types. Images of RPE cells are shown as independent reference. Primary fibrobl. indicates primary human foreskin fibroblasts. (H) Quantification of G. Mean ± SEM for n = 3–4 independent experiments is shown. Left y-axis represents centromeric CENP-A levels normalized to RPE cells; right y-axis shows number of CENP-A molecules per centromere (CEN). (I) Combined results from AH allow for the determination of CENP-A copy numbers on individual chromosomes as indicated. (J) Statistical map of the distribution of 216 CENP-A nucleosomes on the NeoCEN-4 at three different scales. The top 216 peaks are indicated in blue. Y-axis indicates the probability of CENP-A occupancy for each nucleosome. (K) Histogram of the CENP-A nucleosome occupancy. Inset shows the distribution of 216 neocentric CENP-A nucleosomes on the 10% highest occupancy peaks (green) and 90% lowest occupancy peaks (red).

https://doi.org/10.7554/eLife.02137.016
Figure 7—figure supplement 1
Measurements of individual centromeres for graphs in Figure 7A–F.

CENP-A levels are normalized to the average of each individual cell for CEN-Lac in HCT-116 cells (A), CEN-Y in wild-type HCT-116 cells (B), CEN-Y in DLD-1 cells (C), and NeoCEN-4 in PDNC-4 cells (D). Each circle represents one centromere; circles on the same column are individual centromeres from the same cell. Colored circle represents uniquely identified chromosome. Averages ± SEM are indicated. Graph to the right in C as in Figure 7D for DLD-1 cells (n = 26 and 927 for CEN-Y and Other CENs, respectively). Dashed line indicates average of all centromeres.

https://doi.org/10.7554/eLife.02137.017
A quantitative view of human centromeric chromatin.

(A) Distribution of CENP-A. Estimated ratio of CENP-A (red) to H3 (gray) at the centromere and on non-centromeric loci (genome) in interphase cells. Estimations are calculated assuming 2 CENP-A molecules per nucleosome (Sekulic et al., 2010; Tachiwana et al., 2011; Bassett et al., 2012; Hasson et al., 2013; Padeganeh et al., 2013), an average nucleosome positioning distance of 200 base pairs, an average centromere size of 2.5 × 106 base pairs (Sullivan et al., 1996; Lee et al., 1997) of which approximately 40% (1 Mbp) contains CENP-A (Sullivan et al., 2011), a diploid genome size of 6 × 109 base pairs, 200 CENP-A nucleosomes per centromere, and 2.5 × 104 CENP-A nucleosomes outside of centromeres (9.1 × 104 CENP-A molecules per cell [Figure 2F], of which 74% is in chromatin [Figure 4B] and 0.44% in each centromere [Figure 2B]). The fraction of CENP-A on centromeres, non-centromeric chromatin, and unincorporated CENP-A are indicated in green, blue, and black, respectively. CENP-A nucleosomes are represented as though evenly spread throughout the centromeric domain. Alternatively, they could be distributed into one or more clusters within this domain. (B) Mitotic organization of centromeric chromatin. 200 nucleosomes are redistributed to 100 nucleosomes per centromere on replicated sister chromatids (Jansen et al., 2007; Bodor et al., 2013). The exact CENP-A copy number at the centromere depends on the available total pool (mass-action). Excess CENP-A could either lead to an increased CENP-A domain or lead to a higher density of CENP-A within a domain of fixed size. This pool forms an excess to recruit downstream centromere and kinetochore complexes and ultimately provides microtubule binding sites for ∼17 kinetochore microtubules (McEwen et al., 2001). To avoid mitotic errors, a critical amount of CENP-A is required (dashed lines). (C) Graph representing the chance of at least one chromosome in a cell (with 46 chromosomes) reaching critically low levels of CENP-A by random segregation of pre-existing CENP-A nucleosomes. Calculations were performed for varying levels of critical nucleosome numbers at a fixed steady state of 200 (left), or by varying the steady state number at a fixed critical level of 22 (right). Red bars represent identical calculations.

https://doi.org/10.7554/eLife.02137.018

Download links

A two-part list of links to download the article, or parts of the article, in various formats.

Downloads (link to download the article as PDF)

Open citations (links to open the citations from this article in various online reference manager services)

Cite this article (links to download the citations from this article in formats compatible with various reference manager tools)

  1. Dani L Bodor
  2. João F Mata
  3. Mikhail Sergeev
  4. Ana Filipa David
  5. Kevan J Salimian
  6. Tanya Panchenko
  7. Don W Cleveland
  8. Ben E Black
  9. Jagesh V Shah
  10. Lars ET Jansen
(2014)
The quantitative architecture of centromeric chromatin
eLife 3:e02137.
https://doi.org/10.7554/eLife.02137