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The 4q subtelomere harboring the FSHD locus is specifically anchored with peripheral heterochromatin unlike most human telomeres.
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PMID:  15504910     Owner:  NLM     Status:  MEDLINE    
This paper investigates the nuclear localization of human telomeres and, specifically, the 4q35 subtelomere mutated in facioscapulohumeral dystrophy (FSHD). FSHD is a common muscular dystrophy that has been linked to contraction of D4Z4 tandem repeats, widely postulated to affect distant gene expression. Most human telomeres, such as 17q and 17p, avoid the nuclear periphery to reside within the internal, euchromatic compartment. In contrast, 4q35 localizes at the peripheral heterochromatin with 4p more internal, generating a reproducible chromosome orientation that we relate to gene expression profiles. Studies of hybrid and translocation cell lines indicate this localization is inherent to the distal tip of 4q. Investigation of heterozygous FSHD myoblasts demonstrated no significant displacement of the mutant allele from the nuclear periphery. However, consistent association of the pathogenic D4Z4 locus with the heterochromatic compartment supports a potential role in regulating the heterochromatic state and makes a telomere positioning effect more likely. Furthermore, D4Z4 repeats on other chromosomes also frequently organize with the heterochromatic compartment at the nuclear or nucleolar periphery, demonstrating a commonality among chromosomes harboring this subtelomere repeat family.
Rose Tam; Kelly P Smith; Jeanne B Lawrence
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Type:  Journal Article; Research Support, Non-U.S. Gov't; Research Support, U.S. Gov't, P.H.S.    
Journal Detail:
Title:  The Journal of cell biology     Volume:  167     ISSN:  0021-9525     ISO Abbreviation:  J. Cell Biol.     Publication Date:  2004 Oct 
Date Detail:
Created Date:  2004-10-26     Completed Date:  2004-12-06     Revised Date:  2013-06-09    
Medline Journal Info:
Nlm Unique ID:  0375356     Medline TA:  J Cell Biol     Country:  United States    
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Languages:  eng     Pagination:  269-79     Citation Subset:  IM    
Department of Cell Biology, University of Massachusetts Medical School, Worcester, MA 01655, USA.
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MeSH Terms
Cell Line
Cell Nucleus / metabolism
Chromosomes, Human, Pair 17
Chromosomes, Human, Pair 4 / ultrastructure*
Fibroblasts / metabolism
Heterochromatin / chemistry*,  metabolism,  ultrastructure
Image Processing, Computer-Assisted
In Situ Hybridization
Muscles / cytology,  metabolism
Muscular Dystrophy, Facioscapulohumeral / genetics*
Nuclear Proteins
Protein Structure, Tertiary
Proteins / genetics*
Telomere / metabolism,  ultrastructure*
Grant Support
Reg. No./Substance:
0/FRG1 protein, human; 0/Heterochromatin; 0/Nuclear Proteins; 0/Proteins

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Journal ID (nlm-ta): J Cell Biol
ISSN: 0021-9525
ISSN: 1540-8140
Publisher: The Rockefeller University Press
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Copyright © 2004, The Rockefeller University Press
Received Day: 23 Month: 3 Year: 2004
Accepted Day: 2 Month: 9 Year: 2004
Print publication date: Day: 25 Month: 10 Year: 2004
Volume: 167 Issue: 2
First Page: 269 Last Page: 279
ID: 2172553
Publisher Id: 200403128
DOI: 10.1083/jcb.200403128
PubMed Id: 15504910

The 4q subtelomere harboring the FSHD locus is specifically anchored with peripheral heterochromatin unlike most human telomeres
Rose Tam
Kelly P. Smith
Jeanne B. Lawrence
Department of Cell Biology, University of Massachusetts Medical School, Worcester, MA 01655
Correspondence to J.B. Lawrence:


The eukaryotic genome is packaged into large-scale chromatin structures that occupy different subregions of the nucleus associated with either gene activity or gene repression (for reviews see Cockell and Gasser, 1999; Carmo-Fonseca, 2002; Fisher and Merkenschlager, 2002; Parada and Misteli, 2002; Isogai and Tjian, 2003). Euchromatin occupies the internal nucleoplasm, which is further partitioned into several nonchromatin compartments enriched in different nuclear factors with which specific active genes may associate (Shopland et al., 2003). In contrast, heterochromatin forms a compartment of compact DNA at the nuclear periphery, where many inactive genes have been localized not only in yeast (Cockell and Gasser, 1999) but also mammalian (Kosak et al., 2002) nuclei. In human fibroblasts, several inactive loci are found at the nuclear or nucleolar periphery, whereas specific active loci reside internally with SC35 domains (speckles) rich in RNA metabolic factors (Xing et al., 1995), and this organization changes with cell-type gene expression (Moen et al., 2004). Some inactive loci (facultative heterochromatin) associate with constitutive centromeric heterochromatin, which can also be at the nuclear periphery (Brown et al., 1997; Francastel et al., 1999). Studies in yeast indicate that localization at the nuclear periphery contributes to gene repression (Andrulis et al., 1998; Feuerbach et al., 2002; Hediger et al., 2002). Yeast telomeres cluster in the nuclear periphery, which is rich in proteins linked to repression, thus forming a silencing-conducive environment important for the action of silencer elements in telomere position effects (TPEs; de Bruin et al., 2000; Fourel et al., 2002).

Work presented here addresses the organization of human telomeres relative to nuclear compartments and entertains current hypotheses on the mechanism of facioscapulohumeral dystrophy (FSHD). FSHD is an autosomal-dominant myopathy and the third most commonly inherited form of muscular dystrophy (FSH Consortium, 1998; Kissel, 1999). FSHD has been linked to contraction of D4Z4 subtelomeric tandem repeats on chromosome 4q35 below a threshold number of ten (van Deutekom et al., 1993). Although it has been suggested that the 3.3-kb D4Z4 repeat contains an open reading frame for a putative homeobox protein (Gabriels et al., 1999), expression of this has not been established; thus D4Z4 is widely postulated to have a noncoding regulatory function (Bickmore and van der Maarel, 2003). In support of a long-range epigenetic role, contraction of the D4Z4 repeats has been demonstrated to result in inappropriate up-regulation of genes up to a few megabases proximal to the tandem repeats (Gabellini et al., 2002). Although these results link D4Z4 to gene repression, this correlation, and even if the genes in question are up-regulated in FSHD, remains controversial (Bickmore and van der Maarel, 2003; Jiang et al., 2003; Winokur et al., 2003). Nevertheless, a recurrent hypothesis proposed by these recent papers still involves changes in either nuclear organization or chromatin packaging of the 4q subtelomere. Several myopathies linked to defects in the nuclear lamina or envelope proteins continue to fuel interest over the role of heterochromatin at the nuclear periphery in muscular dystrophies (Ostlund and Worman, 2003). Consequently, it is of keen interest to the FSHD field, first, whether the 4q35 locus is normally localized with a defined heterochromatic or euchromatic compartment and, second, if this localization changes in the mutant allele of FSHD patient cells.

Beyond its relevance to FSHD, this work addresses fundamental principles of chromosome organization within mammalian nuclei, particularly as it relates to telomeres and subtelomeric repeats. The nuclear organization of telomeres has been more extensively studied in yeast, where telomeres in general cluster at the nuclear periphery. However, mammalian telomeres distribute more widely or “randomly,” at least in cell types such as HeLa cells (Luderus et al., 1996; Molenaar et al., 2003). If the distribution of telomeres collectively in human cells appears random, this begs the question of whether or not specific chromosome telomeres are reproducibly organized in mammalian nuclei. We further investigate if a chromosome displays a specific orientation relative to nuclear landmarks, and consider this in light of the distribution of gene expression linearly across the chromosome. We next investigate whether this organization is an indirect result of constraints on nuclear structure or, alternatively, an inherent property of that specific chromosomal segment. Finally, the organization of other chromosomes bearing D4Z4 repeats is examined to determine if there is a relationship between this specific subtelomeric repeat family and chromosome organization. The D4Z4 repeat constitutes a family of subtelomeric repeats present on human chromosomes 10q26, 1p12, and the p arm of all five acrocentric chromosomes (Lyle et al., 1995; Winokur et al., 1996). Specific families of subtelomeric repeats on subsets of human chromosomes are characteristic of the human and other genomes (Martin et al., 2002; Mefford and Trask, 2002). However, the potential function of these subtelomeric repeat families is not known, nor is it known if their presence relates to organization of chromosomes within the nucleus.

Human telomeres generally avoid the nuclear periphery, a region rich in heterochromatin

In a preliminary analysis of the FSHD locus organization in lymphocytes, we noted a high percentage of 4q35 signals (45–50%) at the nuclear periphery; in contrast, a U2 snRNA locus probe showed <10% peripheral. Because the random rotation of lymphocytes in suspension complicates analysis and minimizes the apparent frequency of peripheral signals, we focused our work on primary human cells with a defined dorsal/ventral axis in culture. First, heterochromatic and euchromatic nuclear compartments were defined for human fibroblasts, myoblasts, and differentiated muscle. As shown in Fig. 1, late replicating heterochromatic DNA is concentrated around the nuclear periphery, whereas splicing factor (SC35) domains, associated with many active genomic regions (Shopland et al., 2003), are confined to the more internal euchromatic compartment (Fig. 1 A; Carter et al., 1993). These two compartments are also marked differentially by hnRNA, recently shown to distinguish the inactive from the active X chromosomes (Hall et al., 2002; see Materials and methods). The peripheral rim of the nucleus is consistently devoid of hnRNA in both fibroblasts (Fig. 1 B) and muscle (Fig. 1 C). A second region of heterochromatin abuts the nucleolus, consistent with ultrastructural observations (Comings, 1980) and corroborated by the localization of the heterochromatic inactive X to either the nuclear or the nucleolar periphery (Fig. 1, D and E). Thus, in our analysis we considered both the nuclear periphery adjacent to the lamina and the region abutting the nucleolus as common components of the heterochromatic compartment.

To address whether the general distribution of human telomeres in primary myoblasts, muscle, and fibroblasts resembles the clustered peripheral distribution of yeast telomeres or is more internal as in transformed HeLa cells (Luderus et al., 1996), a PNA oligo probe to the TTAGGG repeat was hybridized (Fig. 2 A). Results show the majority (83%) of human telomeres to be in the nucleoplasm, clearly distant from the heterochromatic region encircling the nuclear periphery, as viewed in two dimensions. Although only 17% of telomeres were within 0.6 μm of the nuclear periphery, another 22% position at the nucleolus (largely accounted for by the 10 acrocentric chromosomes carrying rDNA genes). Optical sectioning of cultured muscle confirmed that the vast majority of telomeres are internal and do not abut the nuclear envelope in the X-Y or Z planes (Fig. 2 B). Interestingly, a number of telomeres are tightly juxtaposed to the splicing factor–rich SC35 domains. The ∼60–80 separate telomere signals observed suggests that telomere clustering was limited unlike in yeast, which is consistent with findings in HeLa cells (Nagele et al., 2001; Molenaar et al., 2003).

The 4q35 subtelomere specifically localizes to the heterochromatic compartment, primarily the peripheral nuclear rim

Will the organization of the 4q telomere reflect the broad, largely internal distribution of telomeres or might there be chromosome-specific telomere positioning?

The distribution of the RP11-279 marker specific for 4q35.1 (the distal tip of chromosome 4q) was first examined in diploid human fibroblasts. Signals were deemed peripheral if within ∼0.6 μm from the nuclear edge as seen by DAPI and confirmed by nucleopore or lamin staining (see online supplemental material, available at As shown in Fig. 3 A, the 4q35 signal is located at the outer edge of the nuclear periphery and occasionally with the fibrillarin-stained nucleolus, where the D4Z4-bearing acrocentric chromosomes cluster (see Relationship of D4Z4 repeats on other chromosomes to the heterochromatic compartment). In fibroblasts, 73% of 4q35 signals associate with the heterochromatic compartment (65% nuclear and 8% nucleolar periphery). Given that FSHD is a muscular dystrophy, cultured human skeletal myoblasts and differentiated myotubes were examined, using procedures optimized for analysis of muscle nuclei (Smith et al., 1999). As shown in Fig. 3 (B and I), 87% of myoblast and 92% of myotube signals contacted either the nuclear or nucleolar periphery, with the vast majority (85% in muscle) at the nuclear periphery.

Interestingly, the 4q35 signals consistently reside at the lateral nuclear edge rather than at the dorsal or ventral nuclear surface, rendering localization at or very near the nuclear envelope apparent by two-dimensional analysis of monolayer and confirmed by three-dimensional analysis (Video 2, available at The peripheral compartment around the lateral edge of the nucleus was measured in 10 cells and found to comprise 10.1% of the nuclear volume (Fig. S3, available at This defined organization was not recognized in a previous work in lymphocytes (Winokur et al., 1996), likely because free rotation of suspension cells makes the peripheral locus appear more variably localized. In our analyses of four cell types, including lymphocytes, peripheral localization was detected in many cell lines examined. The trend was most pronounced in muscle.

The demonstration that the FSHD locus is indeed spatially associated with the heterochromatic nuclear compartment indicates that the function of D4Z4 repeats occurs in a nuclear environment typically associated with gene repression. This finding substantially increases the likelihood that this tandem repeat element, deleted in FSHD, is involved in regulation of the heterochromatic state for genes in the region. Moreover, the aforementioned results demonstrate that specific human telomeres are uniquely organized, with the 4q telomere showing an atypical association with the nuclear periphery (Fig. 3 I), which may also have implications for chromosome-specific human TPEs (see Discussion).

A reproducible orientation of 4q versus 4p in the three-dimensional nucleus: correlation with gene expression but not gene density

Is the 4q35 localization specific to this region of the chromosome, or might it also be seen for the 4p telomere and centromere? The 4q35 marker was strongly more peripheral than either the 4p telomere (Fig. 3 C) or the centromere (Fig. 3 D; 78% vs. 9% vs. 28%, respectively). The centromere commonly (48%) abutted the nucleolus (Fig. 3, D and I), and neither the 4q nor 4p telomeres associated with the centromere. The low frequency of peripheral 4p signals demonstrates that chromosome 4 orients with the long arm pointing to the nuclear envelope, whereas centromere and short arm are more internal. In contrast to the predictable arrangement of larger chromosomal segments (4q, 4p, and 4cen), ordering between three loci within the 4q35 subregion was more variable (Fig. 3, E and F), which is consistent with a random walk model (Yokota et al., 1995). Thus, there is a reproducible orientation to this large (∼150-Mb) chromosome arm, even though the path of chromatin folding on a smaller scale is more flexible.

The organizational specificity is further demonstrated by comparison to another individual chromosome, using probes available for 17p and q telomeres. As shown in Fig. 3 G, 85–88% of these telomeres were internal in both fibroblasts and muscle. No consistent orientation of 17p and q arms was noted, although the 17q telomere showed a more consistent (88%) association with the edge of SC35 domains (Fig. 3 H), rich in RNA metabolic factors and associated with high gene activity (Xing et al., 1995; Smith et al., 1999).

Fig. 4 A summarizes our findings for the organization of chromosome 4 and contrasts it with chromosome 17. Results demonstrate that a fundamental aspect of chromosome organization in human cells can involve a defined three-dimensional chromosome orientation for a specific chromosome. This organization shows an interesting relationship with recent data on the profiles of gene density and expression over the chromosome (Fig. 4 B; Versteeg et al., 2003). As considered further in the Discussion, the orientation of chromosome 4 is not simply mirrored by differences in gene density on 4q versus 4p, but shows an intriguing correlation with gene expression.

Distinguishing the normal and mutant alleles in individual nuclei of heterozygous FSHD patient cells

It would be valuable to discriminate the mutant from the normal 4q35 locus in single cells because this distinction was not explored in earlier localization studies (Winokur et al., 1996; Stout et al., 1999). The intensity of FISH signal is proportional to the DNA target size, and direct comparison of normal and mutant alleles in the same cell minimizes technical differences (Johnson et al., 2000). Therefore, we tested a strategy of hybridizing a 4q35 marker with the D4Z4 probe in two different colors to discern the normal from the mutant FHSD alleles in single cells. In the heterozygous SKFSHD5 lymphoblast cell line first tested, the mutant allele carries one D4Z4 repeat, whereas the other allele was within normal range. Both alleles showed a strong 4q35 marker signal, whereas only one associated with a normal bright D4Z4 signal, as seen in both interphase nuclei and metaphase spreads (Fig. 5 A). As shown in the following section, we were able to discern this for other FSHD patient cells that retained more than one copy of D4Z4 (see online supplemental material). Although not our primary purpose here, we suggest that this molecular cytogenetic assay may prove useful in diagnostic assays for FSHD, which are complicated by D4Z4 and 4q homologous sequences on other chromosomes (Kissel, 1999).

Analysis of 4q35 localization in primary muscle cultures from FSHD patients

It was important to investigate muscle cells derived from patients who carry a heterozygous D4Z4 mutation. This was made possible by the generous contribution of muscle biopsy samples from FSHD patients and M. Ehrlich to the Coriell Institute. To facilitate their characterization, we worked in conjunction with the Coriell Institute to characterize the myogenic competence of three primary lines of heterozygous FSHD patient cells and one non4q FSHD line (see online supplemental material).

As discussed earlier in this paper, the 4q35 locus was extremely (87–92%) heterochromatic in normal myoblasts or muscle. In heterozygous FSHD patient cell lines, the frequency of association of the mutant allele with the heterochromatic compartment remained high and was not substantially different from the wild-type allele in any cell line examined. Many mutant signals showed the most extreme peripheral position (e.g., Fig. 5 C, arrowhead), and thus did not appear to have moved significantly inward. This finding was further examined in two ways. First, the peripheral heterochromatic rim was delineated by hybridization to hnRNA in FSHD myoblast nuclei in which the 4q35 locus was simultaneously labeled (Fig. 5 B). This procedure confirmed that in heterozygous cells, both 4q35 alleles could be seen within the peripheral rim depleted of hnRNA signal. Second, measurement of the distance from the 4q35 locus to the nuclear envelope revealed no significant difference between the localization of the peripheral alleles whether they be mutant (0.4 ± 0.1 μm) or wild type (0.4 ± 0.2 μm).

Although the overwhelming majority of mutant alleles positioned with peripheral heterochromatin, each of three mutant myoblast lines did show a slight decrease in the peripheral placement of the mutant allele compared with the normal allele, with 4–7% more mutant alleles in the euchromatic compartment. However, these differences were not statistically significant and were not seen in differentiated myotube nuclei where both alleles were highly peripheral (Fig. 5 D). Similarly, for nuclei in which one allele was internal and the other peripheral, the peripheral allele was not consistently the wild-type allele. Collectively, our results suggest that differences between alleles likely reflect normal biological variation.

Certain types of muscular dystrophy have recently been shown to result from a defect in the nuclear lamina (Ostlund and Worman, 2003), fueling speculation over the organization of heterochromatin at the nuclear rim. Thus, we considered the possibility that in FSHD myoblasts there could be a greater tendency for both normal and mutant 4q35 alleles to detach from the peripheral rim. Importantly, we also examined this for a myoblast line from a patient with an alternate form of “non-4q” FSHD (line GM17725) that does not carry the 4q35 D4Z4 contraction (van Overveld et al., 2003). As shown in Fig. 5 (G–I), the frequency of nonperipheral alleles in normal and mutant myoblasts was essentially equivalent. The non4q FSHD line showed some diminution of peripheral signals; however, this may reflect decreased proliferative capacity of these cells (see Discussion and online supplemental material). Although not our primary focus here, we note that staining for nuclear lamin A (not depicted) and nucleopores did not reveal any obvious defect in the nuclear envelope or lamina in the FSHD muscle cell lines (Fig. 5, H and I).

Peripheral localization is an inherent property of 4q35 and is resistant to perturbation

We explored a fundamental question concerning the nature of the 4q35 localization: a full complement of D4Z4 repeats is not required for peripheral positioning, but is this positioning an inherent property of this telomere? Is this chromosomal region specifically “tethered” or confined indirectly by other constraints of nuclear organization? We investigated this in two ways. First, we determined whether or not 4q35 was similarly oriented in a mouse–human somatic cell hybrid line, carrying a full complement of mouse chromosomes but only human chromosome 4. As shown in Fig. 6 (A and B), even in this foreign environment, 4q35 remains predominantly peripheral (68–73%) and moderately nucleolar (19%); thus, close to ∼90% were with the heterochromatic compartment. Interestingly, 4q35 shows no preferential association with the chromocenters (Fig. 6 B), easily detectable in mouse due to the affinity of their AT-rich centromeres for DAPI (Fig. 6 A). These results indicate that information within 4q alone is likely sufficient for nuclear partitioning of 4q35.

This finding was further tested using a female t(X;4) human lymphocyte translocation cell line, in which a balanced translocation transfers the tip of 4q35 (4q35.2 to the telomere) onto the p arm of the active X chromosome (Fig. 6 D). Hybridization to metaphase chromosomes verified that two probes (RP11-279K24 and a commercial microsatellite probe) bracket the 4q breakpoint and one Xp21.1 probe spans the Xp21 breakpoint, which is consistent with prior characterization of this translocation (Bodrug et al., 1990). In female control cells, the inactive X was distinguished from the active X by the presence of Xist RNA (Clemson et al., 1996) whereas in X;autosome balanced translocations, the intact X is selectively inactivated (Mattei et al., 1982).

As summarized in Fig. 6 C and shown in E– I, swapping the tip of 4q35 for the tip of Xp modifies the nuclear location of loci on each derivative chromosome. Not only can this piece of 4q35 maintain its peripheral organization, it may also increase the propensity of an adjacent locus to situate at the nuclear periphery. Although the active Xp21 locus is itself somewhat peripheral, the Xp21 locus on the translocated active X (carrying 4q35) becomes distinctly more peripheral (49%) compared with the same locus on the intact active X in normal cells (30%). This substantial increase (66%) was evident despite the random rotation of lymphocytes, which underestimates the number of peripheral loci (discussed in Fig. 6). The Xp21 locus on the translocated active X chromosome is as peripheral (slightly more) as on the inactive X, known to be in peripheral heterochromatin. Similarly, swapping 4q35.2 for a piece of X on the derivative chromosome 4 resulted in a less peripheral distribution (37% vs. 56% for normal chromosome 4, a decrease of over 50%). These results indicate that a strong affinity for the nuclear periphery is an inherent property of the distal ∼4 Mb of 4q35 and potentially the 4q subtelomere itself.

Relationship of D4Z4 repeats on other chromosomes to the heterochromatic compartment

The aforementioned results demonstrate that a full complement of D4Z4 repeats is not required for the nuclear localization of 4q35 to the heterochromatic compartment. However, if D4Z4 repeats have some functional relationship to heterochromatin and/or nuclear compartmentalization, other chromosomal loci bearing these repeats may show commonalities in their interphase organization with the nuclear or nucleolar periphery. As depicted in Fig. 7 A, D4Z4 repeats are detected in the subtelomeres of the five acrocentric chromosomes as well as 4q, 10q, and 1q12 (Lyle et al., 1995; Winokur et al., 1996), indicating that D4Z4 comprises a specific family of subtelomeric repeats with unknown function.

Analysis of D4Z4 repeats in fibroblasts (Fig. 7 B) and myoblasts (Fig. 7 C) showed strong commonalities in their interphase organization. Though not invariant, the D4Z4 repeats are found with the nucleolus (61%) or the nuclear periphery (21%) in myoblasts. All five pairs of human acrocentric chromosomes carry D4Z4 repeats very closely linked to rDNA genes, which would be predicted to localize to the nucleolus (Fig. 7 D, arrow). However, even if the nucleolar signals are discounted, D4Z4-containing loci are still four to five times more likely to occupy a peripheral heterochromatic location than are telomeres in general. This distinction is most directly tested by examination of chromosome 10q, which bears neither rDNA repeats nor a huge block of constitutive heterochromatin (as at chromosome 1q12). As shown in Fig. 7 (C and E), 10q localizes to the heterochromatic compartment in myoblasts (82%), either at the nuclear periphery (64%) or the nucleolus (18%). We have found that in certain cell types specific acrocentric chromosomes do not participate in formation of the nucleolus, but instead localize to the extreme nuclear periphery (unpublished data), which is consistent with the idea that these represent alternate but related regions.

Thus, although in general telomeres avoid the nuclear or nucleolar periphery, loci bearing the D4Z4 subtelomeric repeat family exhibit a common affinity for these regions and constitute a distinct organizational subset of telomeres. Fig. 7 A also demonstrates another common feature of their organization: they reside adjacent to blocks of satellite DNA (constitutive heterochromatin) even when at an interstitial site on chromosome 1, as also apparent in the nucleus of Fig. 5 A. The implications of this organization will be further considered in the Discussion.


This paper contributes several new findings regarding basic principles of chromosome organization while also providing insight into potential mechanisms operative in FSHD. The 4q35 locus positions in the heterochromatin-rich compartment in several cell types studied; importantly, this localization is specific to the 4q telomeric region. These results establish that, unlike in yeast, specific human telomeres occupy functionally distinct nuclear domains (e.g., 17q is not only internal, but with SC35 domains rich in RNA metabolic factors). Thus, distinct gene regulatory phenomena may be linked to specific human telomeres. TPEs are well established in yeast telomeres, which more uniformly cluster at the nuclear periphery where repressive chromatin factors accumulate. Studies indicate this organization is important in at least one type of TPE (Andrulis et al., 1998; Feuerbach et al., 2002; Hediger and Gasser, 2002). Our results are consistent with the finding that human telomeres are generally not late replicating (Wright et al., 1999), leading to speculation that TPEs may apply only to specific telomeres. Although TPE has been more difficult to demonstrate in human cells, it has been shown that it can occur (Baur et al., 2001). Our results indicate that the 4q subtelomere specifically would be more subject to any TPE mechanisms that may operate at the nuclear periphery or envelope.

These results further demonstrate a precedent for a reproducible spatial orientation for different parts of an individual human chromosome, with the large 4q arm pointing to the nuclear envelope and the p arm projecting inward. Results indicate that this orientation reflects an inherent tethering of the 4q subtelomere to the nuclear periphery; the positioning resists perturbation even in the foreign environment of a mouse nucleus or when translocated to another chromosome. Tethering of a single chromosomal site has been suggested in Drosophila melanogaster (Marshall et al., 1996). Our results now define a small segment at the tip of human 4q35 that appears to bear some sequence (which is not D4Z4) with an affinity for the peripheral nuclear rim.

As diagrammed in Fig. 4, we find an intriguing correlation between this chromosomal organization and recent SAGE data showing clustered expression along the chromosome, which does not merely reflect gene density (Versteeg et al., 2003; http:/ Although the radial distribution of chromosomes may correlate with overall gene density (Boyle et al., 2001; Cremer and Cremer, 2001; Carmo-Fonseca, 2002), this does not explain the 4q versus 4p organization, which have similar gene densities despite marked differences in nuclear organization. However, the gene expression profile along the chromosome (Fig. 4 B) reveals the 4q subtelomeric region is substantially expression poor compared with 4p. Interestingly, Versteeg et al. (2003) identify chromosome 17q as a region of increased density of gene expression, which correlates well with our finding that 17q associates with SC35 domains. We interpret these results in light of a growing appreciation that the regulation of gene expression is controlled on multiple levels, one of which involves nuclear compartmentalization that can either promote or hinder transcription (Cockell and Gasser, 1999; Isogai and Tjian, 2003).

It has been speculated that the FSHD locus may be associated with heterochromatin and be subject to some form of chromosome position effect (Bickmore and van der Maarel, 2003). However, direct evidence had not been established, and one group, finding chromatin modifications similar to “inactive euchromatin” rather than constitutive heterochromatin, challenged this view (Jiang et al., 2003; Yang et al., 2004). Our findings demonstrate that the 4q35 region is clearly localized to a discrete nuclear “neighborhood” rich in heterochromatin, one of few human telomeres at the nuclear periphery. This close spatial association with heterochromatin, together with other evidence of a link to gene repression (Gabellini et al., 2002) and methylation (van Overveld et al., 2003) supports the hypothesis that D4Z4 at 4q35 is likely involved in regulation of the heterochromatic state.

Having demonstrated 4q35 is with the heterochromatic compartment normally, one mechanism by which D4Z4 deletion could influence gene expression entails relocation of the region away from this repressive compartment. Defects in nuclear organization have been widely speculated for FSHD (Bickmore and van der Maarel, 2003; Winokur et al., 2003). We tested this hypothesis by examining 4q organization in patient fibroblasts, myoblasts, and myotubes. The mutant allele showed no clear and consistent breakdown in 4q organization, demonstrating that a critical number of D4Z4 repeats is not required for tethering 4q35 to the nuclear periphery. Although we cannot completely rule out that more subtle mislocalization or changes in a very small subset of FSHD myoblasts could be significant for disease pathogenesis, small differences between myoblasts lines likely reflect normal biological variation. For example, more senescent cells (normal WI38 and GM17725) may correlate with more internal 4q alleles. It has been shown that senescence affects telomere integrity (Karlseder et al., 2002), and, interestingly, chromosome 4 contains the highest proportion of senescence-responsive genes (Chen et al., 2004).

Gabellini et al. (2002) provided evidence that genes (FRG1, FRG2, and ANT1) up to a few megabases away are up-regulated in FSHD muscle cells, which is consistent with D4Z4 normally functioning to repress gene expression over long distances. The idea that D4Z4 at 4q influences the heterochromatic state is further supported by a recent report that certain sites on the mutant allele are hypomethylated (van Overveld et al., 2003). Given our finding that D4Z4 contraction exhibits its effect on FSHD cells despite remaining in the heterochromatic neighborhood, this tandem repeat likely influences the heterochromatic state on a more local scale. Importantly, yeast studies demonstrate that genes can be expressed from the heterochromatic periphery; however, specific mechanisms are required to regulate expression in this repressive chromatin environment (Hediger and Gasser, 2002). For example, D4Z4 repeats could function akin to a silencer element, possibly at the transition between euchromatin and heterochromatin. In yeast, loss of a silencer element prevents propagation of heterochromatin and silencing that would otherwise occur at telomeres associated with the nuclear envelope (Feuerbach et al., 2002). Although some tandemly repeated sequences can form heterochromatin, protosilencers do not silence on their own. They propagate or maintain a heterochromatic state initiated at a silencer and typically require a specific copy number of tandem repeats for proper function (Fourel et al., 2002), similar to D4Z4 in FSHD.

However, results from Gabellini et al. (2002) have become controversial because two recent papers contest the expression data of these 4q35 genes (Jiang et al., 2003; Winokur et al., 2003). Likewise, an earlier paper concluded that the methylation status did not change in mutant alleles (Tsien et al., 2001) in contrast to recent findings (van Overveld et al., 2003). Cell-to-cell variability and duplicated loci on other chromosomes may obscure expression from 4q; ultimately, the most definitive way to demonstrate a potential cis-effect on gene expression entails examining nuclear RNA directly as it emanates from normal and mutant alleles, as previously demonstrated in Osteogenesis Imperfecta (Johnson et al., 2000).

Clearly some evidence favors a normal role for D4Z4 in maintaining gene repression; however, a given sequence can have a dual role in silencing or insulating from silencing (Kuhn and Geyer, 2003). Although speculative, the possibility merits consideration that D4Z4 can normally insulate neighboring genes from repressive heterochromatin for two reasons. First, this would fit with the recent finding that D4Z4 contraction only results in disease when present on the same chromosome as a polymorphic β satellite sequence (on half of normal alleles and all disease alleles; Lemmers et al., 2002). This would be explained if the presence of the β satellite augmented the heterochromatic signal, requiring the higher number of D4Z4 repeats to “insulate” genes in the vicinity of a stronger repressive signal. Second, we suggest that a role as transition or insulator elements is implied by the singular organization of D4Z4 repeats on human chromosomes, showing a remarkable positioning between β satellite sequences and the very active rDNA genes on all acrocentric chromosomes (Fig. 7 A; Winokur et al., 1996). Similarly, gene expression in1q21 would likely require insulation from the exceptionally large block of heterochromatin in 1q12; D4Z4 repeats lie at the interface of this heterochromatin–euchromatin boundary (Fig. 7 A and Fig. 5 A, nucleus).

These observations point to a possible functional relevance for a subtelomeric repeat family, about which little is known. Notably, we find that other D4Z4-associated loci have an unusual affinity for the nuclear or nucleolar periphery and reside between regions of euchromatin and β satellite DNA. Although the peripheral localization is most striking for 4q35, the strong commonality in nuclear organization of other D4Z4 loci raises the possibility of a common structural and/or functional role (with heterochromatin) for this subtelomeric repeat family.

Finally, our findings support earlier suggestions that telomeres are anchored (Luderus et al., 1996; Weipoltshammer et al., 1999; Nagele et al., 2001) but goes further to indicate that specific telomeres tether to specific intranuclear locations. Given that our results demonstrate tethering of 4q35 and also raise the possibility of a role for D4Z4 as an insulator, it would be interesting to examine the relationship to CTCF, a protein which has recently been reported to have a role in both insulating and tethering of specific sequences to the nuclear matrix and the nucleolar periphery (Yusufzai et al., 2004). This is but one of several important areas for future directions raised by this work.

Materials and methods
Probes, in situ hybridization, and immunolocalization

BACs used in this study, RP11-597P9 (4q35.1), RP11-279K24 (4q35.1), RP11-2H3 (4p16.3), RP11-288G11 (10q26.3), and RP11-509C1 (Xp21.1), were supplied by M. Rocchi (University of Bari, Bari, Italy), as was the plasmid p4n1/4 containing 4 alphoid centromeric sequence. RP11-597P9 is 0.5 Mb distal to RP11-279K24 and 4 Mb proximal to the D4Z4 repeats. Plasmid pLAM containing the 3.3-Kb D4Z4 sequence was a gift of S. Winokur (University of California, Irvine, Irvine, CA; Hewitt et al., 1994).

Conditions for probe labeling by nick-translation and in situ hybridization to PFA-fixed, Triton-extracted cells have been described previously (Tam et al., 2002). In addition to probes nick-translated with biotin or digoxygenin, prelabeled probes to 17p, 17q, and 4q subtelomeres (Vysis Inc.) as well as a 18 bp PNA probe to (TTAGGG)n (Applied Biosystems) were used according to the manufacturer's recommendations. For detection of general nuclear hnRNA, nondenatured cells were hybridized with a probe against human Cot-1 RNA, as described in Hall et al. (2002).

To demarcate nuclear structures, the following antibodies were used: mouse anti-fibrillarin (gift of M. Pollard, Scripps Research Institute, La Jolla, CA), mouse anti-SC35 (Sigma-Aldrich), rabbit anti-lamin (Cell Signaling), and mouse anti-nucleopore (Affinity BioReagents, Inc.). Nuclear contour was also evident by DAPI DNA staining.

Cell lines and culture conditions

Lymphoblastoid FSHD cell lines were provided by S. Winokur and cultured in RPMI, 10% FBS, in a 37°C incubator with 5% CO2. WI38 fibroblasts (American Type Culture Collection) were cultured in DME, 10% FBS. 50MB-1 normal myoblasts were a gift from H. Blau (Stanford University, Stanford, CA). Four FSHD myoblast cell lines (GM17725, GM17731, GM17869A, and GM17899) were obtained from the Coriell Cell Repository, from patient biopsies deposited by M. Ehrlich (Tulane University, New Orleans, LA), and characterized in our lab for myogenesis (see Online supplemental material). Myoblast cell lines were cultured in SKGM media (Clonetics) and for differentiation were shifted to DME (GIBCO BRL), 2% horse serum, upon reaching 80% confluency. A mouse somatic cell hybrid line, GM11687A (Coriell Cell Repository), was cultured in Ham's F12-DME, 10% FBS. A t(X;4) translocation cell line, GM11025 (Coriell Cell Repository), was grown in RPMI, 10% FBS.

Microscopy and image analysis

Single plane images and z-stacks (step size of 100 nm) were acquired using a microscope (model Axiovert 200; Carl Zeiss MicroImaging, Inc.) equipped with a 100× PlanApo objective (NA 1.4). The Chroma 83000 multiband pass dichroic and emission filter set (Chroma Technology Corp.) was used with its excitation filters set up in a wheel to prevent optical shift. Triple-labeled experiments using FITC, Texas red, and Alexa 350 were mounted in Vectashield (Vector Laboratories). Between 50 and 400 cells were examined directly through the microscope over two or more replicas for each experiment, as further specified in the figure legends. Images were captured on a camera (model Orca-ER; Hamamatsu). Z-stacks were processed using constrained iterative deconvolution in Axiovision 4.1 or the remove haze algorithm in Metamorph 4.6, and displayed as maximum value projections.

Online supplemental material

Characterization of four FSHD myoblast cell lines (including Figs. S1 and S2). Fig. S3 shows a description of nuclear volume calculations. Video 1 shows the distribution in three dimensions of total telomeres (red) in relation to nucleopores (green) and nucleoli (blue) in muscle (50MB-1). This video is a though-focal series of 40 planes spaced 100 nm apart, displayed at 10 frames per second. Video 2 shows a three-dimensional organization of 4q35 (red), D4Z4 (green), and fibrillarin (blue) in muscle nuclei (50MB-1). This video is a though-focal series of 50 planes spaced 100 nm apart, displayed at 10 frames per second.

We appreciate the assistance of Dan Perez of the Facioscapulohumeral Muscular Dystrophy (FSH) Society and the efforts of Yigong Polly Xing in initiating this work. We acknowledge John McNeil for assistance with digital imaging and Meg Byron, John Butler, and Carol Johnson for technical assistance. We are grateful to Jeff Jones and Kristie Casey of Athena Diagnostics for determining D4Z4 copy numbers. We would particularly like to thank FSHD patients for providing muscle biopsies and Melanie Ehrlich for contributing this material to the Coriell Institute. We appreciate the assistance of David Moscatello with cells, Mariano Rocchi for probes to 10q, 4q, 4cen, and Xp21, and Sara Winokur for FSHD lymphocytes.

This work was supported by grants from the FSH Society, the Muscular Dystrophy Association, and the National Institutes of Health (grant GM 68138).

Note added in proof. While this paper was in production a paper on a similar topic was published by Masny et al. (Masny, P.S., U. Bengtsson, S.A. Chung, J.H. Martin, B. van Engelen, S.M. van der Maarel, and S.T. Winokur. 2004. Hum. Mol. Genet. 13:1857–1871). Our suggestion that differences between cell lines in frequency of 4q alleles at the nuclear periphery may relate to cellular senescence is supported by our observations that nuclei with herniated or lobulated nuclear envelopes have reduced 4q peripheral association; however, this may be a global effect on chromatin organization. Although our studies are in agreement that normal and mutant alleles show peripheral association, Masny et al. (2004) do not connect this to implications for the cis-regulation of heterochromatin or telomere positions effects. We find it difficult to reconcile the model proposed by Masny et al. (2004) that “disruptive chromatin” at a single 4q allele could directly (without impacting synthesis of a protein) result in mislocalization of Rb or other factors from the entire nuclear periphery and thereby misregulate MyoD genes throughout the genome.

Andrulis, E.D., A.M. Neiman, D.C. Zappulla, and R. Sternglanz. 1998. Perinuclear localization of chromatin facilitates transcriptional silencing. Nature. 394:592–595. (published erratum appears in Nature. 1998. 395:525) [pmid: 9707122]
Baur, J.A., Y. Zou, J.W. Shay, and W.E. Wright. 2001. Telomere position effect in human cells. Science. 292:2075–2077. [pmid: 11408657]
Bickmore, W.A., and S.M. van der Maarel. 2003. Perturbations of chromatin structure in human genetic disease: recent advances. Hum Mol Genet. 12 Spec No 2:R207–R213.
Bodrug, S.E., J.R. Roberson, L. Weiss, P.N. Ray, R.G. Worton, and D.L. Van Dyke. 1990. Prenatal identification of a girl with a t(X;4)(p21;q35) translocation: molecular characterisation, paternal origin, and association with muscular dystrophy. J. Med. Genet. 27:426–432. [pmid: 2395160]
Boyle, S., S. Gilchrist, J.M. Bridger, N.L. Mahy, J.A. Ellis, and W.A. Bickmore. 2001. The spatial organization of human chromosomes within the nuclei of normal and emerin-mutant cells. Hum. Mol. Genet. 10:211–219. [pmid: 11159939]
Brown, K.E., S.S. Guest, S.T. Smale, K. Hahm, M. Merkenschlager, and A.G. Fisher. 1997. Association of transcriptionally silent genes with Ikaros complexes at centromeric heterochromatin. Cell. 91:845–854. [pmid: 9413993]
Carmo-Fonseca, M. 2002. The contribution of nuclear compartmentalization to gene regulation. Cell. 108:513–521. [pmid: 11909522]
Carter, K.C., D. Bowman, W. Carrington, K. Fogarty, J.A. McNeil, F.S. Fay, and J.B. Lawrence. 1993. A three-dimensional view of precursor messenger RNA metabolism within the mammalian nucleus. Science. 259:1330–1335. [pmid: 8446902]
Chen, H.-L., C.-Y. Lu, Y.-H. Hsu, and J.-J. Lin. 2004. Chromosome positional effects of gene expressions after cellular senescence. Biochem. Biophys. Res. Commun. 313:576–586. [pmid: 14697230]
Clemson, C.M., J.A. McNeil, H.F. Willard, and J.B. Lawrence. 1996. XIST RNA paints the inactive X chromosome at interphase: evidence for a novel RNA involved in nuclear/chromosome structure. J. Cell Biol. 132:259–275. [pmid: 8636206]
Cockell, M., and S.M. Gasser. 1999. Nuclear compartments and gene regulation. Curr. Opin. Genet. Dev. 9:199–205. [pmid: 10322139]
Comings, D.E. 1980. Arrangement of chromatin in the nucleus. Hum. Genet. 53:131–143. [pmid: 6987157]
Cremer, T., and C. Cremer. 2001. Chromosome territories, nuclear architecture and gene regulation in mammalian cells. Nat. Rev. Genet. 2:292–301. [pmid: 11283701]
de Bruin, D., S.M. Kantrow, R.A. Liberatore, and V.A. Zakian. 2000. Telomere folding is required for the stable maintenance of telomere position effects in yeast. Mol. Cell. Biol. 20:7991–8000. [pmid: 11027269]
Feuerbach, F., V. Galy, E. Trelles-Sticken, M. Fromont-Racine, A. Jacquier, E. Gilson, J.C. Olivo-Marin, H. Scherthan, and U. Nehrbass. 2002. Nuclear architecture and spatial positioning help establish transcriptional states of telomeres in yeast. Nat. Cell Biol. 4:214–221. [pmid: 11862215]
Fisher, A.G., and M. Merkenschlager. 2002. Gene silencing, cell fate and nuclear organisation. Curr. Opin. Genet. Dev. 12:193–197. [pmid: 11893493]
Fourel, G., E. Lebrun, and E. Gilson. 2002. Protosilencers as building blocks for heterochromatin. Bioessays. 24:828–835. [pmid: 12210519]
Francastel, C., M.C. Walters, M. Groudine, and D.I. Martin. 1999. A functional enhancer suppresses silencing of a transgene and prevents its localization close to centrometric heterochromatin. Cell. 99:259–269. [pmid: 10555142]
FSH Consortium. 1998. Facioscapulohumeral dystrophy: a distinct regional myopathy with a novel molecular pathogenesis. Ann. Neurol. 43:279–282. [pmid: 9506542]
Gabellini, D., M.R. Green, and R. Tupler. 2002. Inappropriate gene activation in FSHD: a repressor complex binds a chromosomal repeat deleted in dystrophic muscle. Cell. 110:339–348. [pmid: 12176321]
Gabriels, J., M.C. Beckers, H. Ding, A. De Vriese, S. Plaisance, S.M. van der Maarel, G.W. Padberg, R.R. Frants, J.E. Hewitt, D. Collen, and A. Belayew. 1999. Nucleotide sequence of the partially deleted D4Z4 locus in a patient with FSHD identifies a putative gene within each 3.3 kb element. Gene. 236:25–32. [pmid: 10433963]
Hall, L.L., M. Byron, K. Sakai, L. Carrel, H.F. Willard, and J.B. Lawrence. 2002. An ectopic human XIST gene can induce chromosome inactivation in postdifferentiation human HT-1080 cells. Proc. Natl. Acad. Sci. USA. 99:8677–8682. [pmid: 12072569]
Hediger, F., and S.M. Gasser. 2002. Nuclear organization and silencing: putting things in their place. Nat. Cell Biol. 4:E53–E55. [pmid: 11875445]
Hediger, F., F.R. Neumann, G. Van Houwe, K. Dubrana, and S.M. Gasser. 2002. Live imaging of telomeres: yKu and Sir proteins define redundant telomere-anchoring pathways in yeast. Curr. Biol. 12:2076–2089. [pmid: 12498682]
Hewitt, J.E., R. Lyle, L.N. Clark, E.M. Valleley, T.J. Wright, C. Wijmenga, J.C. van Deutekom, F. Francis, P.T. Sharpe, M. Hofker, et al. 1994. Analysis of the tandem repeat locus D4Z4 associated with facioscapulohumeral muscular dystrophy. Hum. Mol. Genet. 3:1287–1295. [pmid: 7987304]
Isogai, Y., and R. Tjian. 2003. Targeting genes and transcription factors to segregated nuclear compartments. Curr. Opin. Cell Biol. 15:296–303. [pmid: 12787771]
Jiang, G., F. Yang, P.G. van Overveld, V. Vedanarayanan, S. van der Maarel, and M. Ehrlich. 2003. Testing the position-effect variegation hypothesis for facioscapulohumeral muscular dystrophy by analysis of histone modification and gene expression in subtelomeric 4q. Hum. Mol. Genet. 12:2909–2921. [pmid: 14506132]
Johnson, C.V., D. Primorac, M. McKinstry, J.A. McNeil, D. Rowe, and J.B. Lawrence. 2000. Tracking COL1A1 RNA in osteogenesis imperfecta: splice-defective transcripts initiate transport from the gene but are retained within the SC35 domain. J. Cell Biol. 150:417–432. [pmid: 10931857]
Karlseder, J., A. Smogorzewska, and T. de Lange. 2002. Senescence induced by altered telomere state, not telomere loss. Science. 295:2446–2449. [pmid: 11923537]
Kissel, J.T. 1999. Facioscapulohumeral dystrophy. Semin. Neurol. 19:35–43.
Kosak, S.T., J.A. Skok, K.L. Medina, R. Riblet, M.M. Le Beau, A.G. Fisher, and H. Singh. 2002. Subnuclear compartmentalization of immunoglobulin loci during lymphocyte development. Science. 296:158–162. [pmid: 11935030]
Kuhn, E.J., and P.K. Geyer. 2003. Genomic insulators: connecting properties to mechanism. Curr. Opin. Cell Biol. 15:259–265. [pmid: 12787766]
Lemmers, R.J., P. de Kievit, L. Sandkuijl, G.W. Padberg, G.J. van Ommen, R.R. Frants, and S.M. van der Maarel. 2002. Facioscapulohumeral muscular dystrophy is uniquely associated with one of the two variants of the 4q subtelomere. Nat. Genet. 32:235–236. [pmid: 12355084]
Luderus, M.E., B. van Steensel, L. Chong, O.C. Sibon, F.F. Cremers, and T. de Lange. 1996. Structure, subnuclear distribution, and nuclear matrix association of the mammalian telomeric complex. J. Cell Biol. 135:867–881. [pmid: 8922373]
Lyle, R., T.J. Wright, L.N. Clark, and J.E. Hewitt. 1995. The FSHD-associated repeat, D4Z4, is a member of a dispersed family of homeobox-containing repeats, subsets of which are clustered on the short arms of the acrocentric chromosomes. Genomics. 28:389–397. [pmid: 7490072]
Marshall, W.F., A.F. Dernburg, B. Harmon, D.A. Agard, and J.W. Sedat. 1996. Specific interactions of chromatin with the nuclear envelope: positional determination within the nucleus in Drosophila melanogaster. Mol. Biol. Cell. 7:825–842. [pmid: 8744953]
Martin, C.L., A. Wong, A. Gross, J. Chung, J.A. Fantes, and D.H. Ledbetter. 2002. The evolutionary origin of human subtelomeric homologies—or where the ends begin. Am. J. Hum. Genet. 70:972–984. [pmid: 11875757]
Mattei, M.G., J.F. Mattei, S. Ayme, and F. Giraud. 1982. X-autosome translocations: cytogenetic characteristics and their consequences. Hum. Genet. 61:295–309. [pmid: 7152515]
Mefford, H.C., and B.J. Trask. 2002. The complex structure and dynamic evolution of human subtelomeres. Nat. Rev. Genet. 3:91–102. [pmid: 11836503]
Moen, P.T., Jr., C.V. Johnson, M. Byron, L.S. Shopland, I.L. de la Serna, A.N. Imbalzano, and J.B. Lawrence. 2004. Repositioning of muscle-specific genes relative to the periphery of SC-35 domains during skeletal myogenesis. Mol. Biol. Cell. 15:197–206. [pmid: 14617810]
Molenaar, C., K. Wiesmeijer, N.P. Verwoerd, S. Khazen, R. Eils, H.J. Tanke, and R.W. Dirks. 2003. Visualizing telomere dynamics in living mammalian cells using PNA probes. EMBO J. 22:6631–6641. [pmid: 14657034]
Nagele, R.G., A.Q. Velasco, W.J. Anderson, D.J. McMahon, Z. Thomson, J. Fazekas, K. Wind, and H. Lee. 2001. Telomere associations in interphase nuclei: possible role in maintenance of interphase chromosome topology. J. Cell Sci. 114:377–388. [pmid: 11148139]
Ostlund, C., and H.J. Worman. 2003. Nuclear envelope proteins and neuromuscular diseases. Muscle Nerve. 27:393–406. [pmid: 12661041]
Parada, L., and T. Misteli. 2002. Chromosome positioning in the interphase nucleus. Trends Cell Biol. 12:425–432. [pmid: 12220863]
Shopland, L.S., C.V. Johnson, M. Byron, and J.B. Lawrence. 2003. Clustering of multiple specific genes and gene-rich R-bands around SC-35 domains: evidence for local euchromatic neighborhoods. J. Cell Biol. 162:981–990. [pmid: 12975345]
Smith, K.P., P.T. Moen, K.L. Wydner, J.R. Coleman, and J.B. Lawrence. 1999. Processing of endogenous pre-mRNAs in association with SC-35 domains is gene specific. J. Cell Biol. 144:617–629. [pmid: 10037785]
Stout, K., S. van der Maarel, R.R. Frants, G.W. Padberg, H.H. Ropers, and T. Haaf. 1999. Somatic pairing between subtelomeric chromosome regions: implications for human genetic disease? Chromosome Res. 7:323–329. [pmid: 10515207]
Tam, R., L.S. Shopland, C.V. Johnson, J.A. McNeil, and J.B. Lawrence. 2002. Applications of RNA FISH for Visualizing Gene Expression and Nuclear Architecture. Oxford University Press, New York. 336 pp.
Tsien, F., B. Sun, N.E. Hopkins, V. Vedanarayanan, D. Figlewicz, S. Winokur, and M. Ehrlich. 2001. Methylation of the FSHD syndrome-linked subtelomeric repeat in normal and FSHD cell cultures and tissues. Mol. Genet. Metab. 74:322–331. [pmid: 11708861]
van Deutekom, J.C., C. Wijmenga, E.A. van Tienhoven, A.M. Gruter, J.E. Hewitt, G.W. Padberg, G.J. van Ommen, M.H. Hofker, and R.R. Frants. 1993. FSHD associated DNA rearrangements are due to deletions of integral copies of a 3.2 kb tandemly repeated unit. Hum. Mol. Genet. 2:2037–2042. [pmid: 8111371]
van Overveld, P.G., R.J. Lemmers, L.A. Sandkuijl, L. Enthoven, S.T. Winokur, F. Bakels, G.W. Padberg, G.J. van Ommen, R.R. Frants, and S.M. van der Maarel. 2003. Hypomethylation of D4Z4 in 4q-linked and non-4q-linked facioscapulohumeral muscular dystrophy. Nat. Genet. 35:315–317. [pmid: 14634647]
Versteeg, R., B.D. van Schaik, M.F. van Batenburg, M. Roos, R. Monajemi, H. Caron, H.J. Bussemaker, and A.H. van Kampen. 2003. The human transcriptome map reveals extremes in gene density, intron length, GC content, and repeat pattern for domains of highly and weakly expressed genes. Genome Res. 13:1998–2004. [pmid: 12915492]
Weipoltshammer, K., C. Schofer, M. Almeder, V.V. Philimonenko, K. Frei, F. Wachtler, and P. Hozak. 1999. Intranuclear anchoring of repetitive DNA sequences: centromeres, telomeres, and ribosomal DNA. J. Cell Biol. 147:1409–1418. [pmid: 10613900]
Winokur, S.T., U. Bengtsson, J.C. Vargas, J.J. Wasmuth, M.R. Altherr, B. Weiffenbach, and S.J. Jacobsen. 1996. The evolutionary distribution and structural organization of the homeobox-containing repeat D4Z4 indicates a functional role for the ancestral copy in the FSHD region. Hum. Mol. Genet. 5:1567–1575. (published erratum appears in Hum. Mol. Genet. 1997. 6:502) [pmid: 8894690]
Winokur, S.T., Y.W. Chen, P.S. Masny, J.H. Martin, J.T. Ehmsen, S.J. Tapscott, S.M. van der Maarel, Y. Hayashi, and K.M. Flanigan. 2003. Expression profiling of FSHD muscle supports a defect in specific stages of myogenic differentiation. Hum. Mol. Genet. 12:2895–2907. [pmid: 14519683]
Wright, W.E., V.M. Tesmer, M.L. Liao, and J.W. Shay. 1999. Normal human telomeres are not late replicating. Exp. Cell Res. 251:492–499. [pmid: 10471333]
Xing, Y., C.V. Johnson, P.T. Moen, J.A. McNeil, and J.B. Lawrence. 1995. Nonrandom gene organization: structural arrangements of specific pre-mRNA transcription and splicing with SC-35 domains. J. Cell Biol. 131:1635–1647. [pmid: 8557734]
Yang, F., C. Shao, V. Vedanarayanan, and M. Ehrlich. 2004. Cytogenetic and immuno-FISH analysis of the 4q subtelomeric region, which is associated with facioscapulohumeral muscular dystrophy. Chromosoma. 112:350–359. [pmid: 15138770]
Yokota, H., G. van den Engh, J.E. Hearst, R.K. Sachs, and B.J. Trask. 1995. Evidence for the organization of chromatin in megabase pair-sized loops arranged along a random walk path in the human G0/G1 interphase nucleus. J. Cell Biol. 130:1239–1249. [pmid: 7559748]
Yusufzai, T.M., H. Tagami, Y. Nakatani, and G. Felsenfeld. 2004. CTCF tethers an insulator to subnuclear sites, suggesting shared insulator mechanisms across species. Mol. Cell. 13:291–298. [pmid: 14759373]


[Figure ID: fig1]
Figure 1. 

Heterochromatin forms a compartment at the nuclear and nucleolar periphery in human fibroblasts and muscle cells. (A) Late-replicating DNA (labeled by BrdU; green) concentrates at the nuclear periphery, whereas SC35 domains rich in RNA metabolic factors (red) punctuate the nuclear interior. (B) Heterochromatin, primarily at the nuclear periphery and nucleolus, is delineated as the DAPI region (blue) devoid of hnRNA (red). Inset shows magnification of the periphery. The image was deconvolved to minimize out-of-focus light. (C) This myotube highlights the prominent peripheral heterochromatin compartment in five nuclei as described in B. (D) The inactive X chromosome marked by the accumulation of Xist RNA (green) is localized either at the nucleolus or at the nuclear periphery (E).

[Figure ID: fig2]
Figure 2. 

Interphase telomere distribution. (A) Mammalian telomeres (red) distribute widely (blue, nucleolus; green, SC35 domains) with most avoiding the peripheral heterochromatin compartment. (B) Through focal series montage demonstrating the distribution of telomeres through the nucleus. Sections are 300 nm apart along the Z axis from the coverslip (top left) to the top of the cell (bottom right). The series was captured in wide field and deconvolved using a constrained iterative algorithm. Red, telomeres; green, nucleopores; blue, SC35 domains.

[Figure ID: fig3]
Figure 3. 

The 4q telomere favors the heterochromatic compartment and, in particular, the nuclear periphery. This specific localization is striking when compared to other loci on chromosome 4 and to other telomeres. (A) The 4q35 (red, arrows) is found at either the nuclear periphery or next to the nucleolus as demarcated by fibrillarin (blue) in this fibroblast. (B) 4q35 (red, arrows) localizes within the peripheral rim (DAPI, blue) defined by depletion of hnRNA (green). (C) The peripheral localization of 4q (red) contrasts with the internal localization of 4p (green). Lamin A and nucleoli were detected simultaneously (blue). (D) The centromere of chromosome 4 (green) favors the nucleolus (blue), whereas the 4q telomere (red) is oriented at the periphery. (E) Analysis of three 4q subtelomeric probes reveals no preferred ordering between these three loci with respect to the periphery. RP11-279K24 (red) is more peripheral than RP11-597P9 (green) in one allele in contrast to the loci at the other allele. (F) Likewise, RP11-279K24 (red) is more peripheral than D4Z4 (green) in one allele in contrast to the other. (G) Chromosome 17q (red) and 17p (green) avoid the nuclear periphery and are often in the vicinity of the nucleolus (blue), particularly in myotubes. (H) The 17q (red) telomere frequently colocalizes with SC35 domains (blue) in a myoblast. (I) Quantitative distributions of total or specific telomeres (or centromere) in myoblasts. We analyzed 1,000 total telomeres, >800 4q, 200 4p, 200 4cen, 100 17p, and 100 17q signals.

[Figure ID: fig4]
Figure 4. 

The spatial orientation of chromosomes 4 and 17 correlates with the density of expression along their axes. (A) Model depicting the spatial arrangement of chromosomes 4 and 17. (B) Distribution of gene density and expression for each chromosome (data reproduced with permission from Versteeg et al., 2003).

[Figure ID: fig5]
Figure 5. 

In FSHD patient muscle, truncation of D4Z4 repeats does not significantly alter 4q35 localization to the heterochromatic rim. (A) Cytogenetic preparation of FSHD lymphoblastoid cells demonstrating different intensities of D4Z4 signals (green) at each 4q35 allele (red), permitting the mutant and wild-type alleles to be distinguished. (B) Both 4q35 alleles (green) in a mutant FSHD myoblast remain at the nuclear periphery depleted of hnRNA (red). (C) Localization of wild-type (arrow) and mutant (arrowhead) alleles in a FSHD myoblast using the same probes as in A. DAPI (blue) delineates the nucleus. (D) Quantitation of the localization of mutant (mut) versus wild-type (wt) allele in three FSHD myoblast cell lines (GM 17731, GM17899, and GM17869A) and in a normal myoblast line (50MB-1) before and after differentiation. 100 cells analyzed per sample. Localization of 4q35 (red) in a normal (E) and a FSHD myotube (F) with more intense D4Z4 signal (green) demarcating wild type versus weaker mutant 4q35 allele. Red and green signals from a z-stack were projected onto a single plane of blue signal. In the FSHD myotube, lamin A and fibrillarin were simultaneously detected by Alexa 350. (G) The number of cells (of 100 analyzed) with both 4q35 alleles dissociated from the periphery is rare regardless of D4Z4 copy number and may correlate with the age of the patient (see online supplemental material, available at Typically, both alleles (red) lie just below the nuclear envelope stained for nucleopores (green) in normal muscle (H; blue, nucleoli) and FSHD muscle (I; blue, sc35).

[Figure ID: fig6]
Figure 6. 

Positioning of 4q35 at the nuclear periphery resists perturbation. (A) Human 4q35 locus (green) in the foreign nucleoplasm of a mouse somatic cell hybrid. AT-rich mouse chromocenters (centromeres) are apparent by DAPI (blue). (B) The nuclear and nucleolar periphery are favored over mouse chromocenters as preferred sites for 4q35 localization (100 cells analyzed). (C) Quantitation of nuclear positions of translocated loci 4q35 and Xp21 (analysis of 150 cells per sample). As discussed by Kosak et al. (2002), 50% peripheral by two-dimensional analysis in freely rotated suspension cells corresponds to ∼95% peripheral localization in three-dimensional analysis. (D) Ideogram of the normal and the derivative chromosomes with the relative positions of the probes used in this work. (E) Normal female lymphocyte line and translocation cell line (F) with Xp21 marking the X chromosomes (red) and Xist RNA (green) identifying the inactive X. (G) Translocation cell line with Xp21 (red) on both X chromosomes and a 4q35 marker (green) identifying the derivative X. (H and I) Translocation cell line with 4q35 (green) on both chromosome 4s and D4Z4 (red) identifying the normal 4.

[Figure ID: fig7]
Figure 7. 

Subtelomeres containing D4Z4 repeats tend to localize to the heterochromatic compartment in both fibroblasts and muscle. (A) Ideogram depicting the known positions and rough size of D4Z4 (red) and β satellite repeats (green; Lyle et al., 1995; Lemmers et al., 2002). (B) Both 4q (red) and 10q (green) favor the nuclear or nucleolar periphery (blue) in fibroblasts. (C) 10q (green) near the nuclear or nucleolar periphery (blue) in myoblasts. (D) A maximal intensity projection showing all D4Z4 signals (green) in a three-dimensional stack in muscle (red, 4q). D4Z4 telomeres cluster at the nucleolus (blue, arrow). (E) Quantitative summary showing that the distribution of the D4Z4 subtelomere family is a distinctive subset from that of total telomeres (in myoblasts). We analyzed >800 4q, 100 10q, 100 D4Z4, and 1,000 total telomere signals.

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