Expression of Notch receptors, ligands, and target genes during development of the mouse mammary gland

Notch genes play a critical role in mammary gland growth, development and tumorigenesis. In the present study, we have quantitatively determined the levels and mRNA expression patterns of the Notch receptor genes, their ligands and target genes in the postnatal mouse mammary gland. The steady state levels of Notch3 mRNA are the highest among receptor genes, Jagged1 and Dll3 mRNA levels are the highest among ligand genes and Hey2 mRNA levels are highest among expressed Hes/Hey target genes analyzed during different stages of postnatal mammary gland development. Using an immunohistochemical approach with antibodies specific for each Notch receptor, we show that Notch proteins are temporally regulated in mammary epithelial cells during normal mammary gland development in the FVB/N mouse. The loss of ovarian hormones is associated with changes in the levels of Notch receptor mRNAs (Notch2 higher and Notch3 lower) and ligand mRNAs (Dll1 and Dll4 are higher, whereas Dll3 and Jagged1 are lower) in the mammary gland of ovariectomized mice compared to intact mice. These data define expression of the Notch ligand/receptor system throughout development of the mouse mammary gland and help set the stage for genetic analysis of Notch in this context.     

Presence of new alternative exons in human and mouse Fli-1 genes

The mouse Fli-1 proto-oncogene is activated by proviral integration of four murine leukemia retroviruses and its human counterpart is translocated (11,22) in Ewing tumors. We have identified two alternative exons 1 by RACE analysis from a human neuroectodermal tumor. Exons 1a and 1b are located respectively 1.3 and 2.5 kb upstream from the published exon 1. Translation of these alternative messengers is predicted to generate very similar proteins. The sequence upstream from exon 1b showed functional promoter activity. Exon 1b was not conserved in the mouse but was detected in every analyzed human cell, whereas exon 1a was present only in a subset of them and also in various mouse cell lines. These results suggest that both mouse and human Fli-1 gene expression might be under the control of several independent promoter regions.     

Comparative functional analysis of the cow and mouse myostatin genes reveals novel regulatory elements in their upstream promoter regions

Myostatin is a paracrine/autocrine factor that inhibits muscle growth, and mutations that affect myostatin activity or expression produce dramatic increases in muscle mass in several species. However, at present it is less clear whether differences in myostatin expression or activity exist between species with differing body sizes. Here we demonstrate that mouse muscle expresses far greater levels of myostatin mRNA than cow. In addition, activity of a 1200 bp mouse myostatin promoter construct was significantly greater than that of a 1200 bp cow myostatin promoter construct in C₂C₁₂ myotubes. In contrast, activity of reporter constructs flanked by one or both untranslated regions (UTRs) was not significantly different between the two species. Sequence analysis identified a number of promoter regions which differed between larger species (cow, pig, goat, sheep, human) and smaller (mouse, rat), including a TATA-box sequence, a CACCC box, two AT-rich regions (AT1 and AT2), and a palindromic sequence (PAL). We therefore used mutagenesis to alter the mouse sequence for each of these elements to that of the cow. Mutagenesis of the TATA, CACC, and AT1 sequences of the mouse to those of the cow significantly decreased activity of the mouse myostatin promoter compared to the wild type mouse promoter, while mutation of the AT2 and PAL sequences tended to increase promoter activity. Finally, the cow myostatin promoter was less responsive to FoxO signaling than the mouse myostatin promoter. Together these data support the hypothesis that differences in promoter activity between mouse and cow may contribute to differences in expression of the myostatin gene between these species.     

Comparative sequence analysis of imprinted genes between human and mouse to reveal imprinting signatures

We performed a comparative genomic sequence analysis between human and mouse for 24 imprinted genes on human chromosomes 1, 6, 7, 11, 13, 14, 15, 18, 19, and 20. The MEME program was used to search for motifs within conserved sequences among the imprinted genes and we then used the MAST program to analyze for the presence or absence of motifs in the imprinted genes and 128 nonimprinted genes. Our analysis identified 15 motifs that were significantly enriched in the imprinted genes. We generated a logistic regression model by combining multiple motifs as input variables and the 24 imprinted genes and the 128 nonimprinted genes as a training set. The accuracy, sensitivity, and specificity of our model were 98, 92, and 99%, respectively. The model was further validated by an open test on 12 additional imprinted genes. The motifs identified in this study are novel imprinting signatures, which should improve our understanding of genomic imprinting and the role of genomic imprinting in human diseases.     

Comparative analysis of sequences at the 5' end of the human and mouse apolipoprotein B genes

A comparison was made between the DNA sequences in two regions of the mouse and the human apolipoprotein B genes: the 5'-flanking sequence and the region between the first exon and the second intron. Considerable homology was observed, particularly in the immediate 5' region and in the second intron. Because promoter and enhancer elements have been previously localized to these regions in the human apolipoprotein B gene, it is proposed that regions of conserved base sequence delineate binding regions for regulatory proteins. In some cases, contiguous regions of homology are longer than expected for regions designed as recognition sites for individual nuclear proteins, and may define regions recognizable by a cluster of interacting proteins. Both the human and mouse genes contain repetitive elements and a hypervariable dinucleotide repeat.     

Comparative analysis of sequence characteristics of imprinted genes in human, mouse, and cattle

Genomic imprinting is an epigenetic mechanism that results in monoallelic expression of genes depending on parent-of-origin of the allele. Although the conservation of genomic imprinting among mammalian species has been widely reported for many genes, there is accumulating evidence that some genes escape this conservation. Most known imprinted genes have been identified in the mouse and human, with few imprinted genes reported in cattle. Comparative analysis of genomic imprinting across mammalian species would provide a powerful tool for elucidating the mechanisms regulating the unique expression of imprinted genes. In this study we analyzed the imprinting of 22 genes in human, mouse, and cattle and found that in only 11 was imprinting conserved across the three species. In addition, we analyzed the occurrence of the sequence elements CpG islands, C + G content, tandem repeats, and retrotransposable elements in imprinted and in nonimprinted (control) cattle genes. We found that imprinted genes have a higher G + C content and more CpG islands and tandem repeats. Short interspersed nuclear elements (SINEs) were notably fewer in number in imprinted cattle genes compared to control genes, which is in agreement with previous reports for human and mouse imprinted regions. Long interspersed nuclear elements (LINEs) and long terminal repeats (LTRs) were found to be significantly underrepresented in imprinted genes compared to control genes, contrary to reports on human and mouse. Of considerable significance was the finding of highly conserved tandem repeats in nine of the genes imprinted in all three species. Electronic supplementary material The online version of this article (doi: ) contains supplementary material, which is available to authorized users.     

Comparative analysis of genome maintenance genes in naked mole rat,mouse, and human

Genome maintenance (GM) is an essential defense system against aging and cancer, as both are characterized by increased genome instability. Here, we compared the copy number variation and mutation rate of 518 GM‐associated genes in the naked mole rat (NMR), mouse, and human genomes. GM genes appeared to be strongly conserved, with copy number variation in only four genes. Interestingly, we found NMR to have a higher copy number of CEBPG, a regulator of DNA repair, and TINF2, a protector of telomere integrity. NMR, as well as human, was also found to have a lower rate of germline nucleotide substitution than the mouse. Together, the data suggest that the long‐lived NMR, as well as human, has more robust GM than mouse and identifies new targets for the analysis of the exceptional longevity of the NMR.     

Comparative sequence analysis of the mouse and human Lgn1/SMA interval.

Human chromosome 5q11.2-q13.3 and its ortholog on mouse chromosome 13 contain candidate genes for an inherited human neurodegenerative disorder called spinal muscular atrophy (SMA) and for an inherited mouse susceptibility to infection with Legionella pneumophila (Lgn1). These homologous genomic regions also have unusual repetitive organizations that create practical difficulties in mapping and raise interesting issues about the evolutionary origin of the repeats. In an attempt to analyze this region in detail, and as a way to identify additional candidate genes for these diseases, we have determined the sequence of 179 kb of the mouse Lgn1/SMA interval. We have analyzed this sequence using BLAST searches and various exon prediction programs to identify potential genes. Since these methods can generate false-positive exon declarations, our alignments of the mouse sequence with available human orthologous sequence allowed us to discriminate rapidly among this collection of potential coding regions by indicating which regions were well conserved and were more likely to represent actual coding sequence. As a result of our analysis, we accurately mapped two additional genes in the SMA interval that can be tested for involvement in the pathogenesis of SMA. While no new Lgn1 candidates emerged, we have identified new genetic markers that exclude Smn as an Lgn1 candidate. In addition to providing important resources for studying SMA and Lgn1, our data provide further evidence of the value of sequencing the mouse genome as a means to help with the annotation of the human genomic sequence and vice versa.     

Scalloped and strawberry notch are target genes of Notch signaling in the context of wing margin formation in Drosophila.

The Notch pathway regulates the differentiation of many cell types throughout development of higher metazoa. Different cellular responses are elicited through specific activation of distinct Notch target genes. In the Drosophila wing, for example, the cut gene is activated by Notch signaling along the dorso-ventral boundary but, as we show here, not in other cell types. We identify additional regulatory components, scalloped and strawberry notch, that are targets of the Notch pathway specifically within the wing anlagen. As suggested by physical interactions, these proteins could be co-factors of the cut trans-regulator Vestigial. Additional regulatory input comes from the Wingless pathway. Our data support a model, whereby context specific involvement of distinct co-regulators modulates Notch target gene activation.     

NIPP1 maintains EZH2 phosphorylation and promoter occupancy at proliferation-related target genes

The histone methyltransferase EZH2 regulates cell proliferation and differentiation by silencing Polycomb group target genes. NIPP1, a nuclear regulator of serine/threonine protein phosphatase 1 (PP1), has been implicated in the regulation of EZH2 occupancy at target loci, but the underlying mechanism is not understood. Here, we demonstrate that the phosphorylation of EZH2 by cyclin-dependent kinases at Thr416 creates a docking site for the ForkHead-associated domain of NIPP1. Recruited NIPP1 enables the net phosphorylation of EZH2 by inhibiting its dephosphorylation by PP1. Accordingly, a NIPP1-binding mutant of EZH2 is hypophosphorylated, and the knockdown of NIPP1 results in a reduced phosphorylation of endogenous EZH2. Conversely, the loss of PP1 is associated with a hyperphosphorylation of EZH2. A genome-wide promoter-binding profiling in HeLa cells revealed that the NIPP1-binding mutant shows a deficient association with about a third of the Polycomb target genes, and these are enriched for functions in proliferation. Our data identify PP1 as an EZH2 phosphatase and demonstrate that the phosphorylation-regulated association of EZH2 with proliferation-related targets depends on associated NIPP1.