哺乳动物印记域DLK1-DIO3的研究进展

DLK1-DIO3印记域定位于人14号染色体、小鼠12号染色体及绵羊18号染色体远端, 在真哺乳亚纲动物中印记保守。该印记域包含3个编码蛋白的父系表达基因Dlk1、Rtl1和Dio3以及若干大小不同的母系表达印记非编码RNA, 如miRNAs、snoRNAs 和大型非编码RNA Gtl2等。人和小鼠该印记域内印记基因剂量的改变将导致严重的表型异常甚至胚胎致死, 暗示正常的发育需要域内印记基因的正常表达。文章重点论述了哺乳动物DLK1-DIO3印记域的印记调控机制和域内印记基因及其功能的研究进展。     

Genomic imprinting at the mammalian Dlk1-Dio3 domain

Genomic imprinting causes genes to be expressed or repressed depending on their parental origin. The majority of imprinted genes identified to date map in clusters and much of our knowledge of the mechanisms, function and evolution of imprinting have emerged from their analysis. The cluster of imprinted genes delineated by the delta-like homolog 1 gene and the type III iodothyronine deiodinase gene (Dlk1-Dio3) is located on distal mouse chromosome 12 and human chromosome 14. Its developmental importance is exemplified by severe phenotypes associated with altered dosage of these genes in mice and humans. The domain contains three imprinted protein-coding genes, Dlk1, Rtl1 and Dio3, expressed from the paternally inherited chromosome and several imprinted large and small noncoding RNA genes expressed from the maternally inherited homolog. Here, we discuss the function and regulation of imprinting at this domain.     

Aberrant regulation of imprinted gene expression in Gtl2lacZ mice

The imprinted region on mouse distal chromosome 12 covers about 1 Mb and contains at least three paternally expressed genes (Pegs: Peg9/Dlk1, Peg11/Rtl1, and Dio3) and four maternally expressed genes (Megs: Meg3/Gtl2, antiPeg11/antiRlt1, Meg8/Rian, and Meg9/Mirg). Gtl2(lacZ) (Gene trap locus 2) mice have a transgene (TG) insertion 2.3 kb upstream from the Meg3/Gtl2 promoter and show about 40% growth retardation when the TG-inserted allele is paternally derived. Quantitative RT-PCR experiments showed that the expression levels of Pegs in this region were reduced below 50%. These results are consistent with the observed phenotype in Gtl2lacZ mice, because at least two Pegs(Peg9/Dlk1 and Dio3) have growth-promoting effects. The aberrant induction of Megs from silent paternal alleles was also observed in association with changes in the DNA methylation level of a differentially methylated region (DMR) located around Meg3/Gtl2 exon 1. Interestingly, a 60 approximately 80% reduction in all Megs was observed when the TG was maternally derived, although the pups showed no apparent growth or morphological abnormalities. Therefore, the paternal or maternal inheritance of the TG results in the down-regulation in cis of either Pegs or Megs, respectively, suggesting that the TG insertion influences the mechanism regulating the entire imprinted region.     

Activation of paternally expressed imprinted genes in newly derived germline-competent mouse parthenogenetic embryonic stem cell lines

Parthenogenetic embryonic stem （pES） cells provide a valuable in vitro model system for studying the molecular mechanisms that underlie genomic imprinting. However, the pluripotency of pES cells and the expression profiles of paternally expressed imprinted genes have not been fully explored. In this study, three mouse pES cell lines were established and the differentiation potential of these cells in extended culture was evaluated. The undifferentiated cells had a normal karyotype and homozygous genome, and expressed ES-cell-specific molecular markers. The cells remained undifferentiated after more than 50 passages and exhibited pluripotent differentiation capacity. All three lines of the established ES cells produced teratomas; two lines of ES cells produced chimeras and germline transmission. Furthermore, activation of the paternally expressed imprinted genes Snrpn, U2afl-rsl, Peg3, Impact, Zfp127, Dlkl and Mest in these cells was detected. Some paternally expressed imprinted genes were found to be expressed in the blastocyst stage of parthenogenetically activated embryos in vitro and their expression level increased with extended pES cell culture. Furthermore, our data show that the activation of these paternally expressed imprinted genes in pES cells was associated with a change in the methylation of the related differentially methylated regions. These findings provide direct evidence for the pluripotency of pES cells and demonstrate the association between the DNA methylation pattern and the activa- tion of paternally expressed imprinted genes in pES cells. Thus, the established ES cell lines provide a valuable model for studying epigenetic regulation in mammalian development.     

Mice lacking paternally expressed Pref-1/Dlk1 display growth retardation and accelerated adiposity

Preadipocyte factor 1 (Pref-1/Dlk1) inhibits in vitro adipocyte differentiation and has been recently reported to be a paternally expressed imprinted gene at human chromosome 14q32. Studies on human chromosome 14 deletions and maternal uniparental disomy (mUPD) 14 suggest that misexpression of a yet-to-be-identified imprinted gene or genes present on chromosome 14 causes congenital disorders. We generated Pref-1 knockout mice to assess the role of Pref-1 in growth and in vivo adipogenesis and to determine the contribution of Pref-1 in mUPD. Pref-1-null mice display growth retardation, obesity, blepharophimosis, skeletal malformation, and increased serum lipid metabolites. Furthermore, the phenotypes observed in Pref-1-null mice are present in heterozygotes that harbor a paternally inherited, but not in those with a maternally inherited pref-1-null allele. Our results demonstrate that Pref-1 is indeed paternally expressed and is important for normal development and for homeostasis of adipose tissue mass. We also suggest that Pref-1 is responsible for most of the symptoms observed in mouse mUPD12 and human mUPD14. Pref-1-null mice may be a model for obesity and other pathologies of human mUPD14.     

The novel gene EGFL9/Dlk2, highly homologous to Dlk1, functions as a modulator of adipogenesis

The Dlk1 gene appears to function as a regulator of adipogenesis. Adult Dlk1-deficient mice are obese, but adipose tissue still develops in transgenic mice overexpressing an Fc-dlk1 fusion protein, and neither type of genetically modified mice displays serious abnormalities. It was therefore possible that one yet unidentified gene might either compensate or antagonize for the absence or for overexpression, respectively, of Dlk1 in those animals. In database searches, we found a novel gene, EGFL9, encoding for a protein whose structural features are virtually identical to those of dlk1, suggesting it may function in a similar way. As dlk1 does, the protein encoded by EGFL9/Dlk2 affects adipogenesis of 3T3-L1 preadipocytes and mesenchymal C3H10T1/2 cells; however, it does so in an opposite way to that of dlk1. In addition, expression levels of both genes appear to be inversely correlated in both cell lines. Moreover, enforced changes in the expression of one gene affect the expression levels of the other. Our data suggest that adipogenesis may be modulated by the coordinated expression of Dlk1 and EGFL9/Dlk2.     

DLK1 is a somato-dendritic protein expressed in hypothalamic arginine-vasopressin and oxytocin neurons

Delta-Like 1 Homolog, Dlk1, is a paternally imprinted gene encoding a transmembrane protein involved in the differentiation of several cell types. After birth, Dlk1 expression decreases substantially in all tissues except endocrine glands. Dlk1 deletion in mice results in pre-natal and post-natal growth deficiency, mild obesity, facial abnormalities, and abnormal skeletal development, suggesting involvement of Dlk1 in perinatal survival, normal growth and homeostasis of fat deposition. A neuroendocrine function has also been suggested for DLK1 but never characterised. To evaluate the neuroendocrine function of DLK1, we first characterised Dlk1 expression in mouse hypothalamus and then studied post-natal variations of the hypothalamic expression. Western Blot analysis of adult mouse hypothalamus protein extracts showed that Dlk1 was expressed almost exclusively as a soluble protein produced by cleavage of the extracellular domain. Immunohistochemistry showed neuronal DLK1 expression in the suprachiasmatic (SCN), supraoptic (SON), paraventricular (PVN), arcuate (ARC), dorsomedial (DMN) and lateral hypothalamic (LH) nuclei. DLK1 was expressed in the dendrites and perikarya of arginine-vasopressin neurons in PVN, SCN and SON and in oxytocin neurons in PVN and SON. These findings suggest a role for DLK1 in the post-natal development of hypothalamic functions, most notably those regulated by the arginine-vasopressin and oxytocin systems.     

An imprinted gene network that controls mammalian somatic growth is down-regulated during postnatal growth deceleration in multiple organs

In mammals, somatic growth is rapid in early postnatal life but decelerates with age and eventually halts, thus determining the adult body size of the species. This growth deceleration, which reflects declining proliferation, occurs simultaneously in multiple organs yet appears not to be coordinated by a systemic mechanism. We, therefore, hypothesized that growth deceleration results from a growth-limiting genetic program that is common to multiple tissues. Here, we identified a set of 11 imprinted genes that show down-regulation of mRNA expression with age in multiple organs. For these genes, Igf2, H19, Plagl1, Mest, Peg3, Dlk1, Gtl2, Grb10, Ndn, Cdkn1c, and SLC38a4, the declines show a temporal pattern similar to the decline in growth rate. All 11 genes have been implicated in the control of cell proliferation or somatic growth. Thus, our findings suggest that the declining expression of these genes contributes to coordinate growth deceleration in multiple tissues. We next hypothesized that the coordinate decline in expression of these imprinted genes is caused by altered methylation and consequent silencing of the expressed allele. Contrary to this hypothesis, the methylation status of the promoter regions of Mest, Peg3, and Plagl1 did not change with age. Our findings suggest that a set of growth-regulating imprinted genes is expressed at high levels in multiple tissues in early postnatal life, contributing to rapid somatic growth, but that these genes are subsequently downregulated in multiple tissues simultaneously, contributing to coordinate growth deceleration and cessation, thus imposing a fundamental limit on adult body size.     

Restoration of Dlk1 and Rtl1 Is Necessary but Insufficient to Rescue Lethality in Intergenic Differentially Methylated Region (IG-DMR)-deficient Mice

In the Dlk1-Dio3 imprinted domain, an intergenic differentially methylated region (IG-DMR) regulates the parental allele-specific expression of imprinted genes. The maternally inherited deletion of IG-DMR (IG-DMR^(−/+)) results in perinatal lethality because of the overexpression of paternally expressed genes and repression of maternally expressed noncoding RNAs (ncRNAs), including Gtl2. To better understand the possible contribution of paternally expressed genes to the lethality, we attempted to rescue the lethality of IG-DMR^(−/+) mutants by restoring the paternally expressed genes. Because the paternally inherited Gtl2 deletion (Gtl2^(+/−)) induced a decrease in the expression of paternally expressed genes, we crossed female IG-DMR heterozygous mice and male Gtl2 heterozygous mutant mice. The resultant IG-DMR^(−/+)/Gtl2^(+/−) double mutant mice had normal expression levels of paternally expressed genes, and none of them showed perinatal lethality; however, most mice showed postnatal lethality with decreased expression of the maternally expressed ncRNAs. Thus, we inferred that paternally expressed genes are necessary for perinatal survivability and that maternally expressed ncRNAs are involved in postnatal lethality.     

The imprinted gene Delta like non-canonical Notch ligand 1 (Dlk1) is conserved in mammals,and serves a growth modulatory role during tissue development and regeneration through Notch dependent and independent mechanisms

Delta like non-canonical Notch ligand 1 (Dlk1) is an imprinted gene, mainly known for its involvement in adipogenesis, although it has been associated with many other stem cells/progenitors and is known to be widely expressed during organism development and tissue regeneration. In a systematic manner, we have outlined the overall expression pattern of Dlk1 in both man and mouse, and found Dlk1 to be expressed in tissues from all three germ layers. Yet, Dlk1 expression decreases along with increased differentiation as gestation proceeds and in most tissues Dlk1 is absent around birth. Thus, in adults, expression of Dlk1 is restricted to a few tissues and progenitor cells, but is re-expressed during disease and regeneration. Although diffferences exist, we found an overall conservation of Dlk1 expression between mouse and man, and conclude in that sense that the mouse is an appropiate model to study Dlk1. In agreement with the observed Dlk1 expression pattern, we found that the majority of published Dlk1 studies, report Dlk1 to have an inhibitory effect on both cell proliferation and differentiation, but the levels of the different DLK1 isoforms may be critical and have an impact on the overall outcome. This may also be an issue during tissue regeneration where several studies have reported Dlk1′s impact during skeletal muscle and liver regeneration without establishing the exact role. Likewise, the underlying mechanism of Dlk1 action is unknown, and seems to depend on both Notch dependent and independent pathways. However, from our data it is intriguing to speculate that the actual role of DLK1 may be to function as a checkpoint to slow down proliferation while forcing cells into the process of differentiation, and thus switch the cell/organ to a state of growth and hypertrophy. This may fit well with its reported impact on growth restiction and body size. Thus, our study which for the first time summarizes reported knowledge on Dlk1 in tissue development and regeneration as well as on the Dlk1 mechanism may provide novel insight to the general role of this remarkable imprinted gene in controlling cell growth, from which new hypotheses can be made in the field of stem cell biology and regenerative medicine.     

Localizing transcriptional regulatory elements at the mouse Dlk1 locus

Much effort has focused recently on determining the mechanisms that control the allele-specific expression of genes subject to genomic imprinting, yet imprinting regulation is only one aspect of configuring appropriate expression of these genes. Imprinting control mechanisms must interact with those regulating the tissue-specific expression pattern of each imprinted gene in a cluster. Proper expression of the imprinted Delta-like 1 (Dlk1)-Maternally expressed gene 3 (Meg3) gene pair is required for normal fetal development in mammals, yet the mechanisms that control tissue-specific expression of these genes are unknown. We have used a combination of in vivo and in vitro expression assays to localize cis-regulatory elements that may regulate Dlk1 expression in the mouse embryo. A bacterial artificial chromosome transgene encompassing the Dlk1 gene and 77 kb of flanking sequence conferred expression in most endogenous Dlk1-expressing tissues. In combination with previous transgenic data, these experiments localize the majority of Dlk1 cis-regulatory elements to a 41 kb region upstream of the gene. Cross-species sequence conservation was used to further define potential regulatory elements, several of which functioned as enhancers in a luciferase expression assay. Two of these elements were able to drive expression of a lacZ reporter transgene in Dlk1-expressing tissues in the mouse embryo. The sequence proximal to Dlk1 therefore contains at least two discrete regions that may regulate tissue-specificity of Dlk1 expression.     

印记基因Dlk1在小鼠胚胎发育中的表达分析

目的:研究印记基因Dlk1在小鼠胚胎发育过程中的动态表达模式,以揭示Dlk1与胚胎发育的关系。方法:通过半定量PCR和定量PCR分析Dlk1在小鼠胚胎发育E8.5～E19.5的基因表达模式,并选取Dlk1表达量最高的时期进行胚胎切片原位杂交和组织定量PCR分析。结果:在小鼠胚胎发育E8.5～E15.5时,Dlk1的表达逐渐升高,在E15.5时表达量达到最高;E15.5～E19.5时,Dlk1表达有所下降,但仍然维持较高水平。E15.5切片原位杂交显示,垂体、肺脏、软骨、舌和背侧肌肉组织中Dlk1表达较高,组织定量PCR实验进一步证实了原文杂交的结果。结论:Dlk1在小鼠胚胎发育中后期持续表达,并呈现一定的组织特异性,对胚胎发育可能起重要的调节作用。     

Alternative splicing and imprinting control of the Meg3/Gtl2-Dlk1 locus in mouse embryos

The distal part of the mouse Chr 12 contains a cluster of reciprocally imprinted genes. Recently we found a grandparental origin-dependent, transmission-ratio distortion (TRD) in this region. The TRD resulted from postimplantation loss of embryos that inherited the distal Chr 12 alleles from the maternal grandfather. These data suggested that imprinting of one or more genes in this region was not uniformly well established or maintained in all the embryos. To elucidate the mechanism underlying such a variation, we examined the expression of two genes from the distal Chr 12 imprinted region, the maternally expressed gene 3/gene-trap locus 2 ( Meg3/ Gtl2), and the delta-like homolog 1 ( Dlk1) gene. We demonstrated that the Meg3/ Gtl2 gene had two major mRNA forms. One form, Meg3-proximal ( Meg3p), contained exons 1-3. The second form, Meg3-distal ( Meg3d) did not contain exons 1-3 and was present in oocytes and in 1- and 2-cell embryos. We observed cross-dependent and splice form-specific relaxation of imprinting of the Dlk1 and Meg3d, but not Meg3p. Expression patterns of Dlk1 and Meg3/ Gtl2 in embryos from crosses between different mouse strains suggest that 1). imprinting of the Dlk1 and Meg3/ Gtl2 genes is not strictly coordi- nated; 2). parental origin-dependent expression of these genes is under control of a strain-specific, cis-acting modifier located in a 1.5-Mb region that includes the Meg3/ Gtl2-Dlk1 locus. Biallelic expression of Dlk1 and Meg3d did not affect embryo viability and, therefore, cannot be responsible for the lethal phenotypes in UPD12 embryos or for the transmission-ratio distortion.