M6P/IGF2R imprinting first appeared approximately 150 million years ago following the divergence of prototherian from therian mammals. Although M6P/IGF2R is clearly imprinted in opossums and rodents, its imprint status in humans remains ambiguous. It is also still unknown if M6P/IGF2R imprinting was an ancestral mammalian epigenotype or if it evolved convergently. We report herein that M6P/IGF2R is imprinted in Artiodactyla, as it is in Rodentia and Marsupialia, but that it is not imprinted in Scandentia, Dermoptera and Primates, including ringtail lemurs and humans. These results are most parsimonious with a single ancestral origin of M6P/IGF2R imprinting followed by a lineage-specific disappearance of M6P/IGF2R imprinting in Euarchonta. The absence of M6P/IGF2R imprinting in extant primates, due to its disappearance from the primate lineage over 75 million years ago, demonstrates that imprinting at this locus does not predispose to human disease. Moreover, the divergent evolution of M6P/IGF2R imprinting predicts that the success of in vitro embryo procedures such as cloning may be species dependent.
IGF2 (insulin-like growth factor 2) and M6P/IGF2R (mannose 6-phosphate/insulin-like growth factor 2 receptor) are imprinted in marsupials and eutherians but not in birds. These results along with the absence of M6P/IGF2R imprinting in the egg-laying monotremes indicate that the parental imprinting of fetal growth-regulatory genes may be unique to viviparous mammals. In this investigation, we have cloned IGF2 from two monotreme mammals, the platypus and echidna, to further investigate the origin of imprinting. We report herein that like M6P/IGF2R, IGF2 is not imprinted in monotremes. Thus, although IGF2 encodes for a highly conserved growth factor in chordates, it is only imprinted in therian mammals. These findings support a concurrent origin of IGF2 and M6P/IGF2R imprinting in the late Jurassic/early Cretaceous period. The absence of imprinting in monotremes, despite apparent interparental conflicts over maternal-offspring exchange, argues that a fortuitous congruency of genetic and epigenetic events may have limited the phylogenetic breadth of genomic imprinting to therian mammals. J. Exp. Zool. (Mol. Dev. Evol.) 291:205-212, 2001.
Placental development and imprinting co-evolved with parental conflict over resource distribution to mammalian offspring. The imprinted genes, IGF2 and IGF2R, code for the growth promoter insulin-like growth factor 2 and its binding inhibitor, mannose 6-phosphate/IGF2 receptor, respectively. M6P/IGF2R of birds and fish do not recognize IGF2. In monotremes that lack imprinting, IGF2 specifically bound M6P/IGF2R via a hydrophobic CD loop. We show that the DNA coding the CD loop in monotremes functions as an exon splice enhancer (ESE) and that structural evolution of binding site loops (AB, HI, FG) improved therian IGF2 affinity. We propose that evolution of this ESE led to the fortuitous acquisition of M6P/IGF2R IGF2 binding that drew IGF2R into parental conflict prior to imprinting, that may have accelerated subsequent affinity maturation. † The sequence of molecular evolutionary events that established placental viviparity, genomic imprinting and parental conflict in mammals remain poorly understood (1) . Genomic imprinting occurs when expression of one allele of a diploid gene is silenced depending on the parent-of-origin, e.g. either from the father or the mother. Parental conflict over the distribution of resources to offspring has been supported by the observation of reciprocal imprinting of genes coding for the growth promoter Insulin-like growth factor 2 (IGF2), and the cation-independent mannose 6-phosphate/ IGF2 receptor (M6P/IGF2R or IGF2R) (2) . IGF2 and IGF2R are two of the approximately 80 genes imprinted in mammals, and two of the five genes (with INS, MEST/PEG1 and PEG10) imprinted in marsupials. So far, no evidence supports the existence of imprinting in monotremes despite the presence of a chorio-vitelline placenta (3, 4). On the basis of functional data, IGF2R transports M6P modified acid hydrolases to the pre-lysosomes (5). Of the 15 extra-cellular domains of IGF2R, domain 11 binds IGF2 in therians, and internalizes the ligand for degradation, whereas M6P bind to domains 3, 5 and 9 (5). Igf2 rescues placental dependent embryonic lethality associated with laboratory created murine parthenogenesis, implicating IGF2 supply as a regulator of placental development (6). Disruption of the maternal Igf2r allele results in Igf2 dependent overgrowth and fatality, supporting that IGF2R antagonizes the function of IGF2 (7,8). The structure of the unbound human domain 11 shows that the IGF2 binding site composed of defined loops (AB, CD, FG and HI, Fig. 1A and Fig. S1) but how this domain 11 evolved to bind IGF2, and the relationship to imprinting co-evolution, remain unknown (9-12).We established a high resolution structure of the human IGF2R:IGF2 complex and then compared this to other phylogenetically informative vertebrates. We adopted an NMR approach as the side chain amino acid interactions across the binding interface were not resolved in our 4.1Å resolution co-crystal structures (9). Wild-type human domain 11 and IGF2 failed to form a stable association in initial NMR studies. However, we ...
The underlying mechanism of the callipyge muscular hypertrophy phenotype in sheep (Ovis aries) is not presently understood. This phenotype, characterized by increased glycolytic type II muscle proportion and cell size accompanied by decreased adiposity, is not visibly detectable until approximately three to eight weeks after birth. The muscular hypertrophy results from a single nucleotide change located at the telomeric end of ovine Chromosome 18, in the region between the imprinted MATERNALLY EXPRESSED GENE 3 (MEG3) and DELTA, DROSOPHILA, HOMOLOG-LIKE 1 (DLK1) genes. The callipyge phenotype is evident only when the mutation is paternally inherited by a heterozygous individual. We have examined the pre-and postnatal expression of MEG3 and DLK1 in sheep of all four possible genotypes in affected and unaffected muscles as well as in liver. Here we show that the callipyge phenotype correlates with abnormally high DLK1 expression during the postnatal period in the affected sheep and that this elevation is specific to the hypertrophy-responsive fast-twitch muscles. These results are the first to show anomalous gene expression that coincides with both the temporal and spatial distribution of the callipyge phenotype. They suggest that the effect of the callipyge mutation is to interfere with the normal postnatal downregulation of DLK1 expression.
Genomic imprinting is a method of gene regulation whereby a gene is expressed in a parent-of-origin-dependent fashion; however, it is hypothesized that imprinting should not occur in oviparous taxa such as birds. Therefore, we examined the allelic expression of two genes in the chicken that are reciprocally imprinted in most mammals, mannose 6-phosphate/insulin-like growth factor 2 receptor (M6P/IGF2R) and insulin-like growth factor 2 (IGF2). Single nucleotide polymorphisms were identified in these genes, and cDNA was prepared from several tissues of embryos heterozygous for these polymorphisms. Both alleles of M6P/IGF2R and IGF2 were expressed in all tissues examined by RT-PCR. Since the expression of these genes was independent of the parent from which they were inherited, we conclude that neither M6P/IGF2R nor IGF2 are imprinted in the chicken.
The mannose 6-phosphate/insulin-like growth factor 2 receptor (M6P/IGF2R) encodes a multifunctional protein involved in lysosomal enzyme trafficking, fetal organogenesis, tumor suppression, and T cell-mediated immunity. M6P/IGF2R is an imprinted gene in mice with expression only from the maternal allele. Complete knockout of this gene causes neonatal lethality, thus preventing analysis of its multifunctional role postnatally. To help elucidate the biological functions of M6P/IGF2R in adulthood, we generated both complete and tissue-specific M6P/IGF2R knockout mice using the Cre/loxP system. We confirm that complete M6P/IGF2R knockout results in fetal overgrowth and neonatal lethality. In contrast, tissue-specific inactivation of this gene in either the liver or skeletal and cardiac muscle gives rise to viable animals with no obvious phenotype. The successful creation of viable tissue-specific M6P/IGF2R knockout mouse models will now allow for detailed analysis of receptor function in a number of cellular processes including brain development, carcinogenesis, lysosomal trafficking, and T cell-mediated immunity. Both the 275-kd cation-independent mannose 6-phosphate/insulin-like growth factor II receptor (M6P/IGF2R) and the 46-kd cation-dependent mannose 6-phosphate receptor (M6PR) function in the intracellular trafficking of lysosomal enzymes.
Insulin-like growth factor (IGF) signalling is required for early dorso-anterior development of the zebrafish embryo
The insulin-like growth factor (IGF) signalling pathway has been highly conserved in animal evolution and, in mammals and Xenopus, plays a key role in embryonic growth and development, with the IGF-1 receptor (IGF-1R) being a crucial regulator of the signalling cascade. Here we report the first functional role for the IGF pathway in zebrafish. Expression of mRNA coding for a dominant negative IGF-1R resulted in embryos that were small in size compared to controls and had disrupted head and CNS development. At its most extreme, this phenotype was characterized by a complete loss of head and eye structures, an absence of notochord and the presence of abnormal somites. In contrast, up-regulation of IGF signalling following injection of IGF-1 mRNA, resulted in a greatly expanded development of anterior structures at the expense of trunk and tail. IGF-1R knockdown caused a significant decrease in the expression of Otx2, Rx3, FGF8, Pax6.2 and Ntl, while excess IGF signalling expanded Otx2 expression in presumptive forebrain tissue and widened the Ntl expression domain in the developing notochord. The observation that IGF-1R knockdown reduced expression of two key organizer genes (chordin and goosecoid ) suggests that IGF signalling plays a role in regulating zebrafish organizer activity. This is supported by the expression of IGF-1, IGF-2 and IGF-1R in shield-stage zebrafish embryos and the demonstration that IGF signalling influences expression of BMP2b, a gene that plays an important role in zebrafish pattern formation. Our data is consistent with a common pathway for integration of IGF, FGF8 and anti-BMPs in early vertebrate development.
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