Department of Cell Biology, University of Texas Southwestern Medical Center, 5323 Harry Hines Boulevard, Dallas, TX 75390, USA.
Department of Cell Biology, University of Texas Southwestern Medical Center, 5323 Harry Hines Boulevard, Dallas, TX 75390, USA.
Differentiation. 2018 Jan-Feb;99:1-9. doi: 10.1016/j.diff.2017.11.005. Epub 2017 Nov 22.
The human cellular reverse transcriptase, telomerase, is very tightly regulated in large long-lived species. Telomerase is expressed during early human fetal development, is turned off in most adult tissues, and then becomes reactivated in almost all human cancers. However, the exact mechanism regulating these switches in expression are not known. We recently described a phenomenon where genes are regulated by telomere length dependent loops (telomere position effects over long distances; TPE-OLD). The hTERT gene is ~ 1.2Mb from the human chromosome 5p end. We observed that when telomeres are long hTERT gene expression is repressed and a probe next to the 5p telomere and the hTERT locus are spatially co-localized. When telomeres are short at least one of the hTERT alleles is spatially separated from the telomere, developing more active histone marks and changes in DNA methylation in the hTERT promoter region. These findings have implications for how cells turn off telomerase when telomeres are long during fetal development and how cancer cells reactivate telomerase in cells that have short telomeres. In addition to TPE-OLD, in proliferating stem cells such as activated T-lymphocytes, telomerase can be reversibly activated and silenced by telomere looping. In telomerase positive cancer cells that are induced to differentiate and downregulate telomerase, telomere looping correlates with silencing of the hTERT gene. These studies and others support a role of telomeres in regulating gene expression via telomere looping that may involve interactions with internal telomeric sequences (ITS). In addition to telomere looping, TPE-OLD may be one mechanism of how cells time changes in physiology without initiating a DNA damage response.
人类细胞的逆转录酶,端粒酶,在大型长寿物种中受到非常严格的调控。端粒酶在人类胚胎早期发育过程中表达,在大多数成人组织中关闭,然后在几乎所有人类癌症中重新激活。然而,调节这些表达开关的确切机制尚不清楚。我们最近描述了一种现象,即基因受端粒长度依赖的循环(端粒位置效应长距离;TPE-OLD)调节。hTERT 基因距离人类染色体 5p 端约 1.2Mb。我们观察到,当端粒较长时,hTERT 基因表达受到抑制,并且靠近 5p 端粒的探针与 hTERT 基因座在空间上共定位。当端粒较短时,至少一个 hTERT 等位基因与端粒在空间上分离,导致 hTERT 启动子区域的组蛋白标记更加活跃,DNA 甲基化发生变化。这些发现对于细胞在胎儿发育过程中端粒较长时如何关闭端粒酶以及癌细胞在端粒较短的细胞中如何重新激活端粒酶具有重要意义。除了 TPE-OLD 之外,在增殖的干细胞中,如激活的 T 淋巴细胞,端粒酶可以通过端粒环化可逆地激活和沉默。在端粒酶阳性的癌细胞中,诱导其分化并下调端粒酶时,端粒环化与 hTERT 基因的沉默相关。这些研究和其他研究支持端粒通过端粒环化调节基因表达的作用,这可能涉及与内部端粒序列(ITS)的相互作用。除了端粒环化,TPE-OLD 可能是细胞在不引发 DNA 损伤反应的情况下调节生理变化的一种机制。
