Mehrdad Pedram

Chromosome Instability as a Result of Double-Strand Breaks near Telomeres in Mouse Embryonic Stem Cells

ABSTRACT Telomeres are essential for protecting the ends of chromosomes and preventing chromosome fusion. Telomere loss has been proposed to play an important role in the chromosomal rearrangements associated with tumorigenesis. To determine the relationship between telomere loss and chromosome instability in mammalian cells, we investigated the events resulting from the introduction of a double-strand break near a telomere with I-SceI endonuclease in mouse embryonic stem cells. The inactivation of a selectable marker gene adjacent to a telomere as a result of the I-SceI-induced double-strand break involved either the addition of a telomere at the site of the break or the formation of inverted repeats and large tandem duplications on the end of the chromosome. Nucleotide sequence analysis demonstrated large deletions and little or no complementarity at the recombination sites involved in the formation of the inverted repeats. The formation of inverted repeats was followed by a period of chromosome instability, characterized by amplification of the subtelomeric region, translocation of chromosomal fragments onto the end of the chromosome, and the formation of dicentric chromosomes. Despite this heterogeneity, the rearranged chromosomes eventually acquired telomeres and were stable in most of the cells in the population at the time of analysis. Our observations are consistent with a model in which broken chromosomes that do not regain a telomere undergo sister chromatid fusion involving nonhomologous end joining. Sister chromatid fusion is followed by chromosome instability resulting from breakage-fusion-bridge cycles involving the sister chromatids and rearrangements with other chromosomes. This process results in highly rearranged chromosomes that eventually become stable through the addition of a telomere onto the broken end. We have observed similar events after spontaneous telomere loss in a human tumor cell line, suggesting that chromosome instability resulting from telomere loss plays a role in chromosomal rearrangements associated with tumor cell progression.

Telomere Position Effect and Silencing of Transgenes near Telomeres in the Mouse

ABSTRACT Reversible transcriptional silencing of genes located near telomeres, termed the telomere position effect (TPE), is well characterized in Saccharomyces cerevisiae. TPE has also been observed in human tumor cell lines, but its function remains unknown. To investigate TPE in normal mammalian cells, we developed clones of mouse embryonic stem (ES) cells that contain single-copy marker genes integrated adjacent to different telomeres. Analysis of these telomeric transgenes demonstrated that they were expressed at very low levels compared to the same transgenes integrated at interstitial sites. Similar to the situation in yeast, but in contrast to studies with human tumor cell lines, TPE in mouse ES cells was not reversed with trichostatin A. Prolonged culturing without selection resulted in extensive DNA methylation and complete silencing of telomeric transgenes, which could be reversed by treatment with 5-azacytidine. Thus, complete silencing of the telomeric transgenes appears to involve a two-step process in which the initial repression is reinforced by DNA methylation. Extensive methylation of the telomeric transgenes was also observed in various tissues and embryonic fibroblasts isolated from transgenic mice. In contrast, telomeric transgenes were not silenced in ES cell lines isolated from 3-day-old preimplantation embryos, consistent with the hypothesis that TPE plays a role in the development of the embryo.

Telomeric transgenes are silenced in adult mouse tissues and embryo fibroblasts but are expressed in embryonic stem cells.

In addition to their role in protecting the ends of chromosomes, telomeres also influence the expression of adjacent genes, a process called telomere‐position effect. We previously reported that the neo and HSV‐tk transgenes located adjacent to telomeres in mouse embryonic stem cells are initially expressed at low levels and then become gradually silenced upon passage in culture through a process involving DNA methylation. We also reported extensive DNA methylation in these telomeric transgenes in three different tissues isolated from mice generated from one of these embryonic stem cell clones. In the present study, we demonstrate that embryo fibroblasts isolated from two different mouse strains show extensive DNA methylation and silencing of the telomeric transgenes. Consistent with this observation, we also demonstrate little or no detectable expression of the HSV‐tk telomeric transgene in somatic tissues using whole body imaging. In contrast, both telomeric transgenes are expressed at low levels and have little DNA methylation in embryonic stem cell lines isolated from these same mouse strains. Our results demonstrate that telomere‐position effect in mammalian cells can be observed either as a low level of expression in embryonic stem cells in the preimplantation embryo or as complete silencing and DNA methylation in differentiated cells and somatic tissues. This pattern of expression of the telomeric transgenes demonstrates that subtelomeric regions, like much of the genome, are epigenetically reprogrammed in the preimplantation embryo, a process that has been proposed to be important in early embryonic development.

The anatomy and transcription of a monocistronic expression site for a metacyclic variant surface glycoprotein gene in Trypanosoma brucei.

African trypanosomes evade the immune response of their mammalian hosts by switching the expression of their variant surface glycoprotein genes (vsg). The bloodstream trypanosome clone MVAT4 of Trypanosoma brucei rhodesienseexpresses a metacyclic vsg as a monocistronic RNA from a promoter located 2 kilobases (kb) upstream of its start codon. Determination of 23 kb of sequence at the metacyclic variant antigen type 4 (MVAT) vsg expression site (ES) revealed an ES-associated gene (esag) 1 preceded by an ingiretroposon and an inverted region containing an unrelatedvsg, short stretches of 70-bp repeats and a pseudoesag 3. Nuclear run-on experiments indicate that the 18-kb region upstream of the MVAT4 vsg promoter is transcriptionally silent. However, multiple members of differentesag families are expressed from elsewhere in the genome. The MVAT4 vsg promoter is highly repressed in the procyclic stage, in contrast to the known polycistronic vsg ESs which undergo abortive transcription. Activation of the MVAT4 vsgES occurs in situ without nucleotide sequence changes, although this monocistronic ES undergoes a pattern of base J modifications similar to that reported for the polycistronic ESs. The relative simplicity of the MVAT4 vsg ES and the uncoupled expression of the vsg and esags provide a unique opportunity for investigating the molecular mechanisms responsible for antigenic variation in African trypanosomes.

Leaky Transcription of Variant Surface Glycoprotein Gene Expression Sites in Bloodstream African Trypanosomes

Trypanosoma brucei undergoes antigenic variation by periodically switching the expression of its variant surface glycoprotein (VSG) genes (vsg) among an estimated 20–40 telomere-linked expression sites (ES), only one of which is fully active at a given time. We found that in bloodstream trypanosomes one ES is transcribed at a high level and other ESs are expressed at low levels, resulting in organisms containing one abundant VSG mRNA and several rare VSG RNAs. Some of the rare VSG mRNAs come from monocistronic ESs in which the promoters are situated about 2 kilobases upstream of the vsg, in contrast to the polycistronic ESs in which the promoters are located 45–60 kilobases upstream of the vsg. The monocistronic ES containing the MVAT4 vsg does not include the ES-associated genes (esag) that occur between the promoter and thevsg in polycistronic ESs. However, bloodstream MVAT4 trypanosomes contain the mRNAs for many different ESAGs 6 and 7 (transferrin receptors), suggesting that polycistronic ESs are partially active in this clone. To explain these findings, we propose a model in which both mono- and polycistronic ESs are controlled by a similar mechanism throughout the parasite’s life cycle. Certain VSGs are preferentially expressed in metacyclic versusbloodstream stages as a result of differences in ESAG expression and the proximity of the promoters to the vsg and telomere.

Cell fusion of bone marrow cells and somatic cell reprogramming by embryonic stem cells.

Bone marrow transplantation is a curative treatment for many diseases, including leukemia, autoimmune diseases, and a number of immunodeficiencies. Recently, it was claimed that bone marrow cells transdifferentiate, a much desired property as bone marrow cells are abundant and therefore could be used in regenerative medicine to treat incurable chronic diseases. Using a Cre/loxP system, we studied cell fusion after bone marrow transplantation. Fused cells were chiefly Gr‐1+, a myeloid cell marker, and found predominantly in the bone marrow;in parenchymal tissues. Surprisingly, fused cells were most abundant in the kidney, Peyers patches, and cardiac tissue. In contrast, after cell fusion with embryonic stem cells, bone marrow cells were reprogrammed into new tetraploid pluripotent stem cells that successfully differentiated into beating cardiomyocytes. Together, these data suggest that cell fusion is ubiquitous after cellular transplants and that the subsequent sharing of genetic material between the fusion partners affects cellular survival and function. Fusion between tumor cells and bone marrow cells could have consequences for tumor malignancy.—Bonde, S., Pedram, M., Stultz, R., Zavazava, N. Cell fusion of bone marrow cells and somatic cell reprogramming by embryonic stem cells. FASEB J. 24, 364–373 (2010). www.fasebj.org