Mouse arylamine N-acetyltransferase 2 (Nat2) expression during embryogenesis: a potential marker for the developing neuroendocrine system

Arylamine N-acetyltransferase (NAT) genes in humans and in rodents encode polymorphic drug metabolizing enzymes. Human NAT1 (and the murine equivalent mouse Nat2) is found early in embryonic development and is likely to have an endogenous role. We report the detailed expression of the murine gene (Nat2) and encoded protein in mouse embryos, using a transgenic mouse model bearing a lacZ transgene inserted into the coding region of mouse Nat2. In mouse embryos, the transgene was expressed in sensory epithelia, epithelial placodes giving rise to visceral sensory neurons, the developing pituitary gland, sympathetic chain and urogenital ridge. In Nat2^+/+ mice, the presence and activity of Nat2 protein was detected in these tissues and their adult counterparts. Altered expression of the human orthologue in breast tumours, in which there is endocrine signalling, suggests that human NAT1 should be considered as a potential biomarker for neuroendocrine tissues and tumours.     

The mouse Dlx-2 (Tes-1) gene is expressed in spatially restricted domains of the forebrain, face and limbs in midgestation mouse embryos

The pattern of RNA expression of the murine Dlx-2 (Tes-1) homeobox gene is described in embryos ranging in age from E8.5 through E11.5. Dlx-2 is a vertebrate homologue of the Drosophila Distal-less (Dll) gene. Dll expression in the Drosophila embryo is principally limited to the primordia of the brain, head and limbs. Dlx-2 is also expressed principally in the primordia of the forebrain, head and limbs. Within these regions it is expressed in spatially restricted domains. These include two discontinuous regions of the forebrain (basal telencephalon and ventral diencephalon), the branchial arches, facial ectoderm, cranial ganglia and limb ectoderm. Several mouse and human disorders have phenotypes which potentially are the result of mutations in the Dlx genes.     

Two Pax2/5/8-binding sites in Engrailed2 are required for proper initiation of endogenous mid-hindbrain expression

During early brain development mouse Engrailed2 (En2) is expressed in a broad band across most of the mid-hindbrain region. Evidence from gene expression data, promoter analysis in transgenic mice and mutant phenotype analysis in mice and zebrafish has suggested that Pax2, 5 and 8 play a critical role in regulating En2 mid-hindbrain expression. Previously, we identified two Pax2/5/8-binding sites in a 1.0 kb En2 enhancer fragment that is sufficient to directed reporter gene expression to the early mid-hindbrain region and showed that the two Pax2/5/8-binding sites are essential for the mid-hindbrain expression in transgenic mice. In the present study we have examined the functional requirements of these two Pax2/5/8-binding sites in the context of the endogenous En2 gene for directing mid-hindbrain expression. The two Pax2/5/8-binding sites were deleted from the En2 locus and replaced with the bacterial neo gene by homologous recombination in mouse embryonic stem cells. After transmitting the mutation into mice, the neo gene was removed by breeding with transgenic mice expressing cre from a CMV promoter. Embryos homozygous for this En2 Pax2/5/8-binding site deletion mutation had a mild reduction in En2 expression in the presumptive mid-hindbrain region at the 5-7 somite stage, when En2 expression is normally initiated. However, from embryonic day 9.0 onwards, the mutant embryos showed En2 expression indistinguishable from that seen in wild type embryos. Furthermore, the mutants did not show the cerebellar defect seen in mice with a null mutation in En2. This result demonstrates that the two Pax2/5/8-binding sites that were deleted, while being required for mid-hindbrain expression in the context of a 1.0 kb En2 enhancer, are only required for proper initiation of expression of the endogenous En2 gene. Interestingly, a comparison of the lacZ RNA and protein expression patterns directed by the 1.0 kb enhancer fragment revealed that lacZ protein was acting as a lineage marker in the mid-hindbrain region by persisting longer than the mRNA. The transgene expression directed by the 1.0 kb enhancer fragment therefore does not mimic the entire broad domain of En2 expression. Taken together, these two studies demonstrate that DNA binding sites in addition to the two Pax2/5/8-binding sites must be necessary for En2 mid-hindbrain expression.     

Mouse fatty acid transport protein 4 (FATP4): characterization of the gene and functional assessment as a very long chain acyl-CoA synthetase

FATP4 (SLC27A4) is a member of the fatty acid transport protein (FATP) family, a group of evolutionarily conserved proteins that are involved in cellular uptake and metabolism of long and very long chain fatty acids. We cloned and characterized the murine FATP4 gene and its cDNA. From database analysis we identified the human FATP4 genomic sequence. The FATP4 gene was assigned to mouse chromosome 2 band B, syntenic to the region 9q34 encompassing the human gene. The open reading frame was determined to be 1929 bp in length, encoding a polypeptide of 643 amino acids. Within the coding region, the exon-intron structures of the murine FATP4 gene and its human counterpart are identical, revealing a high similarity to the FATP1 gene. The overall amino acid identity between the deduced murine and human FATP4 polypeptides is 92.2%, and between the murine FATP1 and FATP4 polypeptides is 60.3%. Northern analysis showed that FATP4 mRNA was expressed most abundantly in small intestine, brain, kidney, liver, skin and heart. Transfection of FATP4 cDNA into COS1 cells resulted in a 2-fold increase in palmitoyl-CoA synthetase (C16:0) and a 5-fold increase in lignoceroyl-CoA synthetase (C24:0) activity from membrane extracts, indicating that the FATP4 gene encodes an acyl-CoA synthetase with substrate specificity biased towards very long chain fatty acids.     

Targeted c-myc gene expression in mammary glands of transgenic mice induces mammary tumours with constitutive milk protein gene transcription

We investigated the consequences of augmented c-myc gene expression in the mammary gland of transgenic mice. For this purpose we directed the expression of a mouse c-myc transgene to the differentiating mammary epithelial cells by subjecting the protein coding region to the 5' regulatory sequences of the murine whey acidic protein gene (Wap). Analogous to the expression pattern of the endogenous Wap gene, the Wap-myc transgene is abundantly expressed in the mammary gland during lactation. The tissue-specific and hormone-dependent expression of the Wap-myc transgene results in an 80% incidence of mammary adenocarcinomas. As early as two months after the onset of Wap-myc expression, tumours occur in the mammary glands of the transgenic animals. The tumours express not only the Wap-myc transgene, but also the endogenous Wap and beta casein genes. The expression of the milk protein genes becomes independent of the lactogenic hormonal stimuli and persists even in transplanted nude mouse tumours.     

Mouse Mesenchyme forkhead 2 (Mf2): expression, DNA binding and induction by sonic hedgehog during somitogenesis

Cloning and sequencing of mouse Mf2 (mesoderm/mesenchyme forkhead 2) cDNAs revealed an open reading frame encoding a putative protein of 492 amino acids which, after in vitro translation, binds to a DNA consensus sequence. Mf2 is expressed at high levels in the ventral region of newly formed somites, in sclerotomal derivatives, in lateral plate and cephalic mesoderm and in the first and second branchial arches. Other regions of mesodermal expression include the developing tongue, meninges, nose, whiskers, kidney, genital tubercule and limb joints. In the nervous system Mf2 is transcribed in restricted regions of the mid- and forebrain. In several tissues, including the early somite, Mf2 is expressed in cell populations adjacent to regions expressing sonic hedgehog (Shh) and in explant cultures of presomitic mesoderm Mf2 is induced by Shh secreted by COS cells. These results suggest that Mf2, like other murine forkhead genes, has multiple roles in embryogenesis, possibly mediating the response of cells to signaling molecules such as SHH.     

Cloning and chromosomal localization of the human BARX2 homeobox protein gene

The human BARX2 gene encodes a homeodomain-containing protein of 254 amino acids, which binds optimally to the DNA consensus sequence YYTAATGRTTTTY. BARX2 is highly expressed in adult salivary gland and is expressed at lower levels in other tissues, including mammary gland, kidney, and placenta. The BARX2 gene consists of four exons, and is located on human chromosome 11q25. This chromosomal location is within the minimal deletion region for Jacobsen syndrome, a syndrome including craniosynostosis and other developmental abnormalities. This chromosomal location, along with the reported expression of murine barx2 in craniofacial development, suggests that BARX2 may be causally involved in the craniofacial abnormalities in Jacobsen syndrome.     

Deletion of a xenobiotic metabolizing gene in mice affects folate metabolism

The mouse arylamine N-acetyltransferase 2 (Nat2) and its homologue (NAT1) in humans are known to detoxify xenobiotic arylamines and are also thought to play a role in endogenous metabolism. Human NAT1 is highly over-expressed in estrogen receptor positive breast tumours and is implicated in susceptibility to neural tube defects. In vitro assays have suggested an endogenous role for human NAT1 in folate metabolism, but in vivo evidence to support this hypothesis has been lacking. Mouse Nat2 provides a good model to study human NAT1 as it shows similar expression profiles and substrate specificities. We have generated transgenic mice lacking a functional Nat2 gene and compared the urinary levels of acetylated folate metabolite para-aminobenzoylglutamate in Nat2 knockout and Nat2 wild-type mice. These results support an in vivo role for mouse Nat2/human NAT1 in folate metabolism. In addition, effects of the Nat2 deletion on sex ratios and neural tube development are described.     

Ash2l-1/Ash2l-2在小鼠胚胎干细胞中的表达特异性及互补效应

H3K4me3是一种重要的表观遗传修饰,主要由MLL(mixed lineage leukemia)甲基转移酶复合体催化,对小鼠胚胎干细胞(mouse embryonic stem cells, mESCs)自我更新能力的维持具有重要作用。ASH2L是MLL复合体中一个重要的核心亚单位,参与调控mESCs中染色质的开放状态。ASH2L在mESCs中有2个异构体：ASH2L-1(80 kDa)和ASH2L-2(65 kDa),且以ASH2L-2的表达为主;而在小鼠胚胎成纤维细胞(mouse embryonic fibroblast, MEF)中,只有ASH2L-1表达。目前,Ash2l-1和Ash2l-2在mESCs中的作用尚不清楚。本文利用CRISPR/Cas9基因组编辑技术,建立了Ash2l-1 ^-/-和Ash2l-2 ^-/-mESCs。通过碱性磷酸酶染色、免疫荧光染色和qRT-PCR发现,Ash2l-1 ^-/-和Ash2l-2 ^-/-mESCs在碱性磷酸酶、多能性调控转录因子(Oct4、Nanog、Sox2和Klf4)的表达与野生型对照无显著差异。通过拟胚体分化实验,发现Ash2l-1 ^-/-mESCs诱导的拟胚体在Snai2(外胚层标记基因)和Gata4(内胚层标记基因)的表达上显著低于野生型mESCs诱导的拟胚体(P<0.01)。通过Western blotting,发现Ash2l-1 ^-/-mESCs中ASH2L-2的表达显著上调(P<0.01),Ash2l-2 ^-/-mESCs中ASH2L-1的表达显著上调(P<0.01),而Ash2l-1 ^-/-和Ash2l-2 ^-/-mESCs中,基因组H3K4me3的表达与野生型对照并无显著差异。这表明Ash2l-1和Ash2l-2之间存在补偿效应。利用JASPAR和KEGG预测分析发现,Ash2l-1和Ash2l-2启动子区分别具有3个和16个潜在的多能性转录因子结合位点,这些转录因子可能介导实现Ash2l-1和Ash2l-2之间的补偿效应。以上结果表明,Ash2l-1和Ash2l-2之间的补偿效应可能参与mESCs多能性的维持和基因组H3K4me3的调控。     

Expression of p27Kip1 and bcl-2, cigarette smoking, and colorectal cancer risk

Although a positive association between cigarette smoking and colorectal adenoma development is consistently found, the association with colorectal cancer remains controversial. We evaluated the potential roles of p27^Kip1 and bcl-2 protein expressions in conjunction with cigarette smoking exposure and colorectal cancer risk in a hospital-based case-control study. A total of 163 colorectal cancer patients from Roswell Park Cancer Institute and Buffalo General Hospital and 326 healthy controls responded to a standardized questionnaire on colorectal cancer risk factors including detailed information on their history of cigarette smoking; 110 of the patientsfitumours were available for immunohistochemical analysis of p27^Kip1 and bcl-2 protein overexpression. An avidin?biotin immunoperoxidase procedure was used to determine expression after incubation with mouse monoclonal p27^Kip1 and mouse monoclonal bcl-2 antibodies, respectively. A statistically significant trend for total pack-years of smoking was found when p27^Kip1 positive cases were compared with p27^Kip1 negative cases (trend test, p = 0.007). Although a weak inverse association was observed with smoking exposure among p27^Kip1 negative tumour cases in comparison to controls, a significant dose?response association was seen with p27^Kip1 positive tumours. The relative risk of developing a p27^Kip1 positive tumour was estimated to be 1.17 (95% CI 0.54?2.54) for those with less than 20 pack-years, 1.95 (95 % CI 0.95?3.97) for those with 20?39 pack-years, and 2.25 (95% CI 1.14?4.45) for those with greater than 39 pack-years of smoking exposure (trend test, p = 0.009) when compared with controls. When cases with bcl-2 expression were compared with cases without bcl-2 expression, suggestion of a trend was also observed with pack-years smoked (trend test, p = 0.09). In our study of 110 patients with sporadic colorectal cancer and 326 controls, we observed differences in associations between cigarette smoking and expressions in p27^Kip1 and bcl-2. Our data suggest that bcl-2 overexpression (or a bcl-2 dependent pathway) is associated with cigarette smoking in the development of colorectal cancer, whereas a loss of p27^Kip1 expression is not. These associations indicate that there is aetiological heterogeneity in colorectal cancer development, and that they can indirectly allude to where these changes in protein expression occur in the adenoma?carcinoma sequence (i.e. early versus late events).     

Mouse in red: red fluorescent protein expression in mouse ES cells, embryos, and adult animals

Spectral variants of green fluorescent protein are widely used in live samples for a broad range of applications: from visualization of protein interactions, through following gene expression, to marking particular cells in complex tissues. Higher wavelength emissions (such as red) are preferred due to the lower background-autofluorescence in tissues (Miyawaka et al., Nat Cell Biol Suppl S1-7, 2003). Until now, however, red fluorescent proteins (RFP) have displayed toxicity in murine embryos, which has hampered its application in this model. Here we report strong expression of a recently developed RFP variant, DsRed.T3, in mouse ES cells, embryos, and adult mice. Our results show that the red fluorescent wavelength has a superior tissue penetrance compared with spectral variants of lower wavelength. Furthermore, we have generated an ES cell line and a corresponding transgenic mouse line in which red fluorescence is activated upon Cre excision. Finally, we introduced cell type-specifically expressed Cre transgenes into this Cre recombinase reporter cell line, and by using the tetraploid embryo complementation assay, we could directly verify the Cre recombinase specificity on ES cell-derived embryos/animals.     

Chromosome mapping of the genes for murine arylamine N-acetyltransferases (NATs), enzymes involved in the metabolism of carcinogens: identification of a novel upstream noncoding exon for murine Nat2

Arylamine N-acetyltransferases (NATs) catalyse acetylation reactions which can result in either detoxification or activation of arylamine carcinogens. The human NAT loci (NAT1, NAT2, and a pseudogene, NATP) have been mapped to human chromosome 8p22, a region frequently deleted in tumours. There are three functional genes in mice (Nat1, Nat2, and Nat3) encoding for three NAT isoenzymes. Different alleles at the Nat2 locus are responsible for the acetylation polymorphism identified in different mouse strains. We show that Nat3 is close to Nat1 and Nat2, by screening of a P1 artificial chromosome (PAC) library and provide cytogenetic evidence for co-localisation of the three genes in chromosome region 8 B3.1-B3.3. The Nat region of mouse and human is homologous. We also provide sequence information and a restriction map in the vicinity of Nat1 and Nat2 and describe a noncoding exon located 6 kb upstream of the Nat2 coding region.     

The position of integration affects expression of the γ-globin-encoding gene linked to HS3 in transgenic mice

Proper expression of the human β-globin (βGlb) locus is dependent on the presence of a major regulatory element located upstream from the βGlb gene cluster, the locus control region (LCR). The LCR, as well as the individual DNase-I-hypersensitive sites from which it is composed, have been shown to provide position-of-integration-independent expression in transgenic mice. Here, we report that a transgenic founder carrying multiple integrations of a hypersensitive site 3::^Aγ globin gene (HS3::^Aγ) construct produced three types of progeny, one with zero ^Aγ expression in the adult stage, one with minimal ^Aγ expression (1% of ^Aγ-expressing cells) and one with abundant ^Aγ expression (100% ^Aγ-expressing cells). The possibility that these phenotypes were due to parental imprinting or to DNA rearrangements of the transgene or to point mutations of the HS3 core or the ^Aγ promoter were excluded. The pattern of inheritance of the three HS3::^Aγ transgene phenotypes indicate that the transgene has integrated into three different chromosomes. These results provide direct evidence that the HS3 of the LCR is not sufficient to protect the ^Aγ gene from position effects excerted by the surrounding chromatin.     

Genetic analysis implicates a molecular chaperone complex in regulating epigenetic silencing of methylated genomic regions

DNA cytosine methylation confers stable epigenetic silencing in plants and many animals. However, the mechanisms underlying DNA methylation-mediated genomic silencing are not fully understood. We conducted a forward genetic screen for cellular factors required for the silencing of a heavily methylated p35S:NPTII transgene in the Arabidopsis thaliana rdm1-1 mutant background, which led to the identification of a Hsp20 family protein, RDS1 (rdm1-1 suppressor 1). Loss-of-function mutations in RDS1 released the silencing of the p35S::NPTII transgene in rdm1-1 mutant plants, without changing the DNA methylation state of the transgene. Protein interaction analyses suggest that RDS1 exists in a protein complex consisting of the methyl-DNA binding domain proteins MBD5 and MBD6, two other Hsp20 family proteins, RDS2 and IDM3, a Hsp40/DNAJ family protein, and a Hsp70 family protein. Like rds1 mutations, mutations in RDS2, MBD5, or MBD6 release the silencing of the transgene in the rdm1 mutant background. Our results suggest that Hsp20, Hsp40, and Hsp70 proteins may form a complex that is recruited to some genomic regions with DNA methylation by methyl-DNA binding proteins to regulate the state of silencing of these regions.     

地高辛标记Ucp2基因RNA探针的制备和应用

目的:制备用于检测小鼠胚胎早期Ucp2基因表达的地高辛标记的特异性RNA探针。方法:提取小鼠胚胎脑组织总RNA,设计引物,通过RT-PCR方法获取Ucp2基因片段,将其克隆到pGEM-T载体。分别利用Sp6、T7和Ucp2特异性引物,PCR扩增获得转录模板,通过Sp6及T7 RNA聚合酶,获得地高辛标记的正义、反义Ucp2 RNA原位杂交探针。检测标记探针的效价后,通过全胚胎原位杂交分析制备探针的特异性和杂交效果。结果:成功获得Ucp2基因正义、反义探针,反义探针能高效灵敏检测到Ucp2基因在小鼠胚胎Ed9.5、Ed10.5神经系统呈现高表达,而正义探针未能检测到表达信号。结论:成功制备了特异高效的地高辛标记Ucp2 RNA原位杂交探针,为进一步研究Ucp2基因在小鼠胚胎组织中的表达,尤其在神经组织的定位奠定基础。     

Identification of presomitic mesoderm (PSM)-specific Mesp1 enhancer and generation of a PSM-specific Mesp1/Mesp2-null mouse using BAC-based rescue technology

Bacterial artificial chromosome (BAC) modification technology is a powerful method for the identification of enhancer sequences and genetic modifications. Using this method, we have analyzed the Mesp1 and/or Mesp2 enhancers and identified P1-PSME, a PSM-specific enhancer of Mesp1, which contains a T-box binding site similar to the previously identified P2-PSME. Hence, Mesp1 and Mesp2 use different enhancers for their PSM-specific expression. In addition, we find that these two genes also use distinct enhancers for their early mesodermal expression. Based on these results, we generated a PSM-specific Mesp1/Mesp2-null mouse by introducing a BAC clone, from which only early mesodermal Mesp1 expression is possible, into the Mesp1/Mesp2 double knockout (dKO) genetic background. This successfully rescued gastrulation defects due to the lack of the early mesoderm in the dKO mouse and we thereby obtained a PSM-specific Mesp1/Mesp2-null mouse showing a lack of segmented somites.