Structural and functional analysis of a 0.5-Mb chicken region orthologous to the imprinted mammalianAscl2/Mash2–Igf2–H19region

Yokomine, Takaaki; Shirohzu, Hisao; Purbowasito, Wahyu; Toyoda, Atsushi; Iwama, Hisakazu; Ikeo, Kazuho; Hori, Tomohide; Mizuno, Shigeki; Tsudzuki, Masaoki; Matsuda, Yoh Ichi; Hattori, Masahira; Sakaki, Yoshiyuki; Sasaki, Hidetada

doi:10.1101/gr.2609605

Cited by 48 publications

(47 citation statements)

References 69 publications

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“…DNMT1 (DNA methyltransferase 1) is a maintenance methyltransferase, which preferentially recognizes hemimethylated DNA and methylates the newly synthesized strand after DNA replication. Genetic studies in mice clearly showed that both classes of meth- zuki et al, 2005), but not in monotremes (egg-laying mammals such as platypuses and echidnas) (Killian et al, 2000) or birds (such as chicken) (O'Neill et al, 2000;Nolan et al, 2001;Yokomine et al, 2001Yokomine et al, , 2005. Thus, imprinting is restricted to placental mammals, which is consistent with the confl ict theory of imprinting evolution (Moore and Haig, 1991).…”

supporting

confidence: 68%

Evolution of the vertebrate DNMT3 gene family: a possible link between existence of DNMT3L and genomic imprinting

Yokomine

Hata

Tsudzuki

et al. 2006

Cytogenet Genome Res

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DNA methylation plays an essential role in genomic imprinting observed in eutherian mammals and marsupials. In mouse, one of the two de novo DNA methyltransferases, Dnmt3a, and a related protein, Dnmt3L have been shown to be essential for imprint establishment in the parental germline. To gain insights into the evolution of imprinting mechanisms, we have identified and characterized the DNMT3 family genes in other vertebrate species. We cloned cDNAs for chicken DNMT3A and DNMT3B, whose putative protein products shared 81.5% and 48.6% amino acid sequence identity with their mouse orthologues. Using computer-assisted database searches, we also identified DNMT3A and DNMT3B orthologues in fish (fugu and zebrafish) and marsupials (opossum). We found that, while opossums had an orthologue for DNMT3L, chickens and fish did not have this gene. Thus, unlike the other DNMT3 members, DNMT3L was restricted to the species in which imprinting occurs. The acquisition of DNMT3L by a common ancestor of eutherians and marsupials might have been closely related to the evolution of imprinting.

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supporting

confidence: 68%

Evolution of the vertebrate DNMT3 gene family: a possible link between existence of DNMT3L and genomic imprinting

Yokomine

Hata

Tsudzuki

et al. 2006

Cytogenet Genome Res

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“…Comparative mapping suggests these genes cluster on macrochromosomes in regions that preferentially undergo asynchronous DNA replication (Dunzinger et al 2005). Analysis of the chicken region orthologous to the imprinted mammalian ASCL2-H19 region (Yokomine et al 2005) revealed extensive conservation of gene organization, except H19, a critical noncoding imprinted gene. This gene and its regulatory elements were absent from the chicken genome.…”

Section: Comparative Genomicsmentioning

confidence: 99%

Chicken genome: Current status and future opportunities

Burt¹

2005

Genome Res.

144

101

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The chicken genome sequence is important for several reasons. First, the chicken shared a common ancestor with mammals ∼310 million years ago (Mya) at a phylogenetic distance not previously covered by other genome sequences. It therefore fills a gap in our knowledge and understanding of the evolution and conservation of genes, regulatory sequences, genomes, and karyotypes. The chicken is also a major source of protein in the world, with billions of birds used in meat and egg production each year. It is the first livestock species to be sequenced and so leads the way for others. The sequence and the 2.8 million genetic polymorphisms defined in a parallel project are expected to benefit agriculture and cast new light on animal domestication. Also, as the first bird to be sequenced, it is a model for the 9600 avian species thought to exist today. Many of the features of the chicken genome and its biology make it an ideal organism for studies in development and evolution, along with applications in agriculture and medicine.

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“…A surprising number of imprinted gene knockout models exhibit placental defects (19), suggesting gene dosage as another mechanism important in the evolution of the fetoplacental unit. Approximately 0.3% of autosomal genes are imprinted in eutherian mammals, while a subset of these genes are imprinted in marsupials with no evidence of imprinting in other vertebrates (1,31,32,37,39,51,54,56,58). Thus, the emergence of genomic imprinting coincides with the appearance of extraembryonic support, and, as the demands for this support have increased, the number of imprinted genes co-opted by the imprinting mechanism has increased (30), also suggesting the involvement of these unique genes in placental development.…”

mentioning

confidence: 97%

The Imprinted Phlda2 Gene Regulates Extraembryonic Energy Stores

Tunster

Tycko

Roshan

2010

Molecular and Cellular Biology

118

140

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An important difference between placental mammals and marsupials is the maturity of the fetus at birth. Placental mammals achieved this maturity by developing a complex and invasive placenta to support and prolong internal development. The exact genomic modifications that facilitated the evolution of this complex structure are unknown, but the emergence of genomic imprinting within mammalian lineages suggests a role for gene dosage. Here we show that a maximally altered placental structure is achieved by a single extra dose of the imprinted Phlda2 gene characterized by a dramatically reduced junctional zone and a decrease in stored glycogen. In addition, glycogen cells do not migrate into the maternal decidua in a timely fashion, but instead, Tpbpa-positive cells progressively mislocalize into the labyrinth. These defects are linked to a progressive restriction of embryonic growth from embryonic day 16.5. This work has identified a critical role for the imprinted Phlda2 gene in regulating glycogen storage in the eutherian placenta and implies that imprinting has provided a mechanism to boost nutrient supply to the fetus late in gestation, when the fetus is placing the highest demands on maternal resources, to enhance growth.

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Structural and functional analysis of a 0.5-Mb chicken region orthologous to the imprinted mammalianAscl2/Mash2–Igf2–H19region

Cited by 48 publications

References 69 publications

Evolution of the vertebrate DNMT3 gene family: a possible link between existence of <i>DNMT3L</i> and genomic imprinting

Evolution of the vertebrate DNMT3 gene family: a possible link between existence of <i>DNMT3L</i> and genomic imprinting

Chicken genome: Current status and future opportunities

The Imprinted Phlda2 Gene Regulates Extraembryonic Energy Stores

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