Early Stages Of Mouse Development Research Articles

Sall1 and Sall4 cooperatively interact with Myocd and SRF to promote cardiomyocyte proliferation by regulating CDK and cyclin genes.

Sall1 and Sall4 (Sall1/4), zinc-finger transcription factors, are expressed in the progenitors of the second heart field (SHF) and in cardiomyocytes during the early stages of mouse development. To understand the function of Sall1/4 in heart development, we generated heart-specific Sall1/4 functionally inhibited mice by forced expression of the truncated form of Sall4 (ΔSall4) in the heart. The ΔSall4-overexpression mice exhibited a hypoplastic right ventricle and outflow tract, both of which were derived from the SHF, and a thinner ventricular wall. We found that the numbers of proliferative SHF progenitors and cardiomyocytes were reduced in ΔSall4-overexpression mice. RNA-sequencing data showed that Sall1/4 act upstream of the cyclin-dependent kinase (CDK) and cyclin genes, and of key transcription factor genes for the development of compact cardiomyocytes, including myocardin (Myocd) and serum response factor (Srf). In addition, ChIP-sequencing and co-immunoprecipitation analyses revealed that Sall4 and Myocd form a transcriptional complex with SRF, and directly bind to the upstream regulatory regions of the CDK and cyclin genes (Cdk1 and Ccnb1). These results suggest that Sall1/4 are critical for the proliferation of cardiac cells via regulation of CDK and cyclin genes that interact with Myocd and SRF.

HMGA Proteins in Stemness and Differentiation of Embryonic and Adult Stem Cells.

HMGA1 and HMGA2 are chromatin architectural proteins that do not have transcriptional activity per se, but are able to modify chromatin structure by interacting with the transcriptional machinery and thus negatively or positively regulate the transcription of several genes. They have been extensively studied in cancer where they are often found to be overexpressed but their functions under physiologic conditions have still not been completely addressed. Hmga1 and Hmga2 are expressed during the early stages of mouse development, whereas they are not detectable in most adult tissues. Hmga overexpression or knockout studies in mouse have pointed to a key function in the development of the embryo and of various tissues. HMGA proteins are expressed in embryonic stem cells and in some adult stem cells and numerous experimental data have indicated that they play a fundamental role in the maintenance of stemness and in the regulation of differentiation. In this review, we discuss available experimental data on HMGA1 and HMGA2 functions in governing embryonic and adult stem cell fate. Moreover, based on the available evidence, we will aim to outline how HMGA expression is regulated in different contexts and how these two proteins contribute to the regulation of gene expression and chromatin architecture in stem cells.

The dynamics of DAXX protein distribution in the nucleus of mouse early embryos

Nuclear distribution of Death-associated protein 6 (Daxx) was studied using fluorescent and electron microscopy in mouse embryos at different stages of development in vivo, from zygote to morula. Daxx was found in association with transcriptionally silent chromatin predominantly with a heterochromatin rim surrounding the nucleolus precursor bodies (NPBs) at all stages studied. At the zygote stage, Daxx was detected only at the periphery of NPBs both in male and female pronuclei. At the late two-cell stage, Daxx was localized not only in the heterochromatin rim at the periphery of NPBs but also in heterochromatin zones not associated with NPBs. At the morula stage, a diffuse distribution of Daxx prevailed. Scarce Daxx-positive zones were detected only in some embryos at the nucleolar periphery. Thus, Daxx is noticeably redistributed during mouse embryo cleavage, and the most conspicuous areas of Daxx concentration are observed at the end of two-cell stage. Daxx is found colocalized with the chromatin-remodeling protein ATRX exclusively in two-cell embryos, but the heterochromatin areas containing either Daxx or ATRX individually are also observed at this stage. However, most zones containing both Daxx and ATRX demonstrated a low FRET-efficiency. This suggest that two molecules are not approached sufficiently close for molecular interactions to occur. Our data suggests that Daxx may function without cooperation with ATRX at least at some stages of early mouse development.

Abstract 359: IWS1 is essential for mouse development

Abstract Iws1 (Interacts with Spt6) was originally identified in Saccharomyces Cerevisiae as a binding partner of Spt6, a histone H3/H4 chaperone.As a transcription factor, Iws1 plays a key role in defining the composition of the RNA polymerase II (RNAPII) elongation complex and in modulating the production of mature mRNA transcripts.Iws1 is phosphorylated, following stimulation with growth factors, by Akt3 and Akt1 at Ser720/Thr721 in human cells (Ser667/Thr668 in the mouse).Preliminary evidence supports a critical protumorigenic role of Iws1 and its phosphorylation in several types of malignancies such as lung cancer (NSCLC), mammary adenocarcinomas and melanomas.For example, it has been shown that, while IWS1 expression in normal human lung is very low, dramatically increases in many NSCLCs. Interestingly the level of IWS1 phosphorylation is variable between tumors and correlates with Akt3 expression.Moreover data from the TCGA database show that Iws1 is expressed at higher levels in tumors than in normal mammary gland specimens and also that basal and HER-2-enriched tumors express the highest levels. The genetic depletion of Iws1 in human mammary adenocarcinoma cell lines inhibits anchorage-independent growth in soft agar and mammosphere formation and growth. Similar experiment revealed that human melanoma cells were extraordinarily sensitive to the knockdown of Iws1. These experiments identify mammary adenocarcinomas and melanomas as tumors potentially addicted to Iws1. However, Iws1 biological functions are poorly characterized and there is no reported in vivo investigation about this RNA-processing factor.To begin to shed some light on the function of this protein at organismal level, we performed a thorough analysis of the expression of Iws1 and generated Iws1-deficient mice.The systematic analysis of expression in mouse tissues shows that Iws1 is ubiquitously expressed. We also report that ablation of Iws1 causes lethality at very early stages of mouse development. In fact, Iws1-deficient mouse embryos die at pre-implantation stage. Overall, these results show that Iws1 is an essential gene for mouse development and suggest a critical function in mammary adenocarcinomas as well as in melanoma. Citation Format: Arturo Orlacchio, Claudia Foray, Tyler Sheetz, Erika Reese, Foued Amari, Aaron E. Stark, Krista La Perle, Ioannis Sanidas, Philip N. Tsichlis, Dario Palmieri, Vincenzo Coppola. IWS1 is essential for mouse development [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 359.

Expression of cancer-testis antigens of the Mage family in mouse oocytes and early embryos

Cancer-testis antigens of the Mage family (Melanoma antigens) are expressed predominantly in the spermatogenic and cancer cells, but some genes of this family are expressed ubiquitously. Expression patterns and functional role of Mage family antigens in the regulation of cellular processes in normal embryonic and definitive cells are virtually unknown. Comparative immunofluorescent analysis of Mage expression in mouse oocytes and early embryos identified the expression of Mage antigens at all stages studied. The greatest intensity of the fluorescent staining was detected in the epiblasts and the extraembryonic structures of the egg cylinder at E6.5 stage. At all studied developmental stages of the mouse oocyte and the early embryo, the localization of Mage antigens was found predominantly in the cytoplasm. Quantitative real-time PCR showed that expression levels of most Mage genes in cells of the epiblast and ectoplacental cone were similar, while the gene expression levels of Mage-a10, Mage-b16, and Mage-b18 were higher in cells of the ectoplacental cone than in epiblast cells. Thus, for the first time, our analysis has shown that the Mage family antigens are expressed at the early stages of mouse development and may be involved in the regulation of earliest events of embryogenesis.

Nuclear distribution of the chromatin-remodeling protein ATRX in mouse early embryogenesis

The nucleus of mammalian embryos differs by transcriptional activity at different stages of early development. Here, we studied nuclear distribution of the chromatin-remodeling protein ATRX in pre-implantation mouse embryos. Immunofluorescent staining revealed the changes of ATRX nuclear distribution at the initial stages of early mouse development. At the stage of early zygote, a diffuse ATRX distribution pattern was prevalent. During the course of zygotic genome activation (ZGA), zones of increased ATRX concentration are observed, and they are most expressed in the nuclei of late 2-cell embryos. In the morula stage, the ATRX distribution becomes diffuse again. In zygotes, the patterns of ATRX distribution differ between male and female pronuclei. At all the stages, ATRX concentrates in the DAPI-positive areas of condensed chromatin. The level of colocalization between ATRX and heterochromatin was found the highest at the late 2-cell stage. When transcription was artificially suppressed, the pattern of intranuclear ATRX distribution was mostly determined by the mechanism of inhibitor action rather than the decreased level of transcriptional activity. Thus, the obvious changes of ATRX distribution occur and partially correlate with the main stages of ZGA during mouse early development, but these changes seem to be determined by other processes of structural and functional rearrangements of blastomere nuclei.

Cell death and morphogenesis during early mouse development: are they interconnected?

Shortly after implantation the embryonic lineage transforms from a coherent ball of cells into polarized cup shaped epithelium. Recently we elucidated a previously unknown apoptosis-independent morphogenic event that reorganizes the pluripotent lineage. Polarization cues from the surrounding basement membrane rearrange the epiblast into a polarized rosette-like structure, where subsequently a central lumen is established. Thus, we provided a new model revising the current concept of apoptosis-dependent epiblast morphogenesis. Cell death however has to be tightly regulated during embryogenesis to ensure developmental success. Here, we follow the stages of early mouse development and take a glimpse at the critical signaling and morphogenic events that determine cells destiny and reshape the embryonic lineage.

An interview with Brigid Hogan

Brigid Hogan is a developmental biologist who has worked extensively on the early stages of mouse development and is now unravelling the mysteries of lung organogenesis. She is the George Barth Geller Professor and Chair of the Department of Cell Biology at Duke University Medical Center. Brigid is also the winner of the 2015 Society for Developmental Biology (SDB) Lifetime Achievement Award.

Wnt Signaling in Mammalian Development: Lessons from Mouse Genetics

Wnts are evolutionarily conserved signaling ligands critical for animal development. Genetic engineering in the mouse has enabled investigators to acquire a detailed activation profile of the β-catenin-dependent canonical Wnt pathway during mouse development, and to manipulate Wnt pathway activities with great spatial and temporal precision. Together, these studies have not only revealed important functions of Wnt signaling at multiple stages of early mouse development, but also elucidated how the Wnt pathway interacts with other pathways to form signaling networks that confer the unique features of mammalian embryogenesis. Additionally, the planar cell polarity pathway has emerged as an essential β-catenin independent noncanonical Wnt pathway that coordinates cell polarity and regulates tissue morphogenesis in various mammalian developmental processes. Importantly, studies of Wnt signaling in mouse development have also revealed important pathogenic mechanisms of several congenital disorders in humans.

Ccbe1 expression marks the cardiac and lymphatic progenitor lineages during early stages of mouse development

The mammalian heart is a complex organ composed of diverse components and various cell types. Heart organogenesis requires the contribution of distinct pools of heart progenitors positioned in separate embryonic regions and subject to particular developmental signals. Moreover, these embryonic heart lineages have different transcriptional profiles expressing specific genes which activate pathways involved in heart lineage specification. Understanding the molecular control of heart organogenesis has major implications for treating congenital and adult heart diseases since specific heart lineages have been associated with particular human cardiovascular malformations. Collagen and calcium-binding EGF-like domain 1 (Ccbe1) was identified in our laboratory using an Affymetrix GeneChip system approach to identify the transcriptome of chick heart/hemangioblast precursor cells. Here, we present a detailed and systematic analysis of the expression of Ccbe1 during early mouse development using whole-mount in situ hybridization (WISH), immunohistochemistry and histological techniques. Ccbe1 mRNA was initially detected in the early cardiac progenitors of the two bilateral cardiogenic fields (E7.0) and in the cardiogenic mesoderm (E7.5 to E8.0). Ccbe1 mRNA was then persistently detected in the pericardium and transiently expressed in the myocardial tissue of the primitive heart tube (E8.25), being later expressed in the proepicardium. By E9.5, the Ccbe1 and Prox1 proteins were found to be expressed in common regions, including the septum transversum and in the proximity of the anterior cardinal vein. Here, it is shown that Ccbe1 is expressed in the FHF, SHF and proepicardium during heart organogenesis (E7.0 to E8.75). Later in development, Ccbe1 expression is localized in the septum transversum and in the vicinity of the anterior cardinal vein, embryonic structures related to hepatic and lymphatic development, respectively.

Granzyme Gis expressed in the two-cell stage mouse embryo and is required for the maternal-zygotic transition

BackgroundDetailed knowledge of the molecular and cellular mechanisms that direct spatial and temporal gene expression in pre-implantation embryos is critical for understanding the control of the maternal-zygotic transition and cell differentiation in early embryonic development. In this study, twenty-three clones, expressed at different stages of early mouse development, were identified using differential display reverse transcription polymerase chain reaction (DDRT-PCR). One of these clones, which is expressed in 2-cell stage embryos at 48 hr post-hCG injection, shows a perfect sequence homology to the gene encoding the granzyme G protein. The granzyme family members are serine proteases that are present in the secretory granules of cytolytic T lymphocytes. However, the pattern of granzyme G expression and its function in early mouse embryos are entirely unknown.ResultsUpon the introduction of an antisense morpholino (2 mM) against granzyme G to knock-down endogenous gene function, all embryos were arrested at the 2- to 4-cell stages of egg cleavage, and the de novo synthesis of zygotic RNAs was decreased. The embryonic survival rate was dramatically decreased at the late 2-cell stage when serine protease-specific inhibitors, 0.1 mM 3,4-dichloroisocoumarin (3,4-DCI), and 2 mM phenyl methanesulphonyl fluoride (PMSF), were added to the in vitro embryonic culture medium. Survival was not affected by the addition of 0.5 mM EDTA, a metalloproteinase inhibitor.ConclusionWe characterized for the first time the expression and function of granzyme G during early stage embryogenesis. Our data suggest that granzyme G is an important factor in early mouse embryonic development and may play a novel role in the elimination of maternal proteins and the triggering of zygotic gene expression during the maternal-zygotic transition.

Genomic imprinting mechanisms in embryonic and extraembryonic mouse tissues

Imprinted genes in mice and humans mainly occur in clusters that are associated with differential DNA methylation of an imprint control element (ICE) and at least one nonprotein-coding RNA (ncRNA). Imprinted gene silencing is achieved by parental-specific insulator activity of the unmethylated ICE mediated by CTCF (CCCTC-binding factor) binding, or by ncRNA expression from a promoter in the unmethylated ICE. In many imprinted clusters, some genes, particularly those located furthest away from the ICE, show imprinted expression only in extraembryonic tissues. Recent research indicates that genes showing imprinted expression only in extraembryonic tissues may be regulated by different epigenetic mechanisms compared with genes showing imprinted expression in extraembryonic tissues and in embryonic/adult tissues. The study of extraembryonic imprinted expression, thus, has the potential to illuminate novel epigenetic strategies, but is complicated by the need to collect tissue from early stages of mouse development, when extraembryonic tissues may be contaminated by maternal cells or be present in limited amounts. Research in this area would be advanced by the development of an in vitro model system in which genetic experiments could be conducted in less time and at a lower cost than with mouse models. Here, we summarize what is known about the mechanisms regulating imprinted expression in mouse extraembryonic tissues and explore the possibilities for developing an in vitro model.

Genome-wide dynamics of replication timing revealed by in vitro models of mouse embryogenesis

Differentiation of mouse embryonic stem cells (mESCs) is accompanied by changes in replication timing. To explore the relationship between replication timing and cell fate transitions, we constructed genome-wide replication-timing profiles of 22 independent mouse cell lines representing 10 stages of early mouse development, and transcription profiles for seven of these stages. Replication profiles were cell-type specific, with 45% of the genome exhibiting significant changes at some point during development that were generally coordinated with changes in transcription. Comparison of early and late epiblast cell culture models revealed a set of early-to-late replication switches completed at a stage equivalent to the post-implantation epiblast, prior to germ layer specification and down-regulation of key pluripotency transcription factors [POU5F1 (also known as OCT4)/NANOG/SOX2] and coinciding with the emergence of compact chromatin near the nuclear periphery. These changes were maintained in all subsequent lineages (lineage-independent) and involved a group of irreversibly down-regulated genes, at least some of which were repositioned closer to the nuclear periphery. Importantly, many genomic regions of partially reprogrammed induced pluripotent stem cells (piPSCs) failed to re-establish ESC-specific replication-timing and transcription programs. These regions were enriched for lineage-independent early-to-late changes, which in female cells included the inactive X chromosome. Together, these results constitute a comprehensive "fate map" of replication-timing changes during early mouse development. Moreover, they support a model in which a distinct set of replication domains undergoes a form of "autosomal Lyonization" in the epiblast that is difficult to reprogram and coincides with an epigenetic commitment to differentiation prior to germ layer specification.

Smad4-dependent pathways control basement membrane deposition and endodermal cell migration at early stages of mouse development.

BackgroundSmad4 mutant embryos arrest shortly after implantation and display a characteristic shortened proximodistal axis, a significantly reduced epiblast, as well as a thickened visceral endoderm layer. Conditional rescue experiments demonstrate that bypassing the primary requirement for Smad4 in the extra-embryonic endoderm allows the epiblast to gastrulate. Smad4-independent TGF-β signals are thus sufficient to promote mesoderm formation and patterning. To further analyse essential Smad4 activities contributed by the extra-embryonic tissues, and characterise Smad4 dependent pathways in the early embryo, here we performed transcriptional profiling of Smad4 null embryonic stem (ES) cells and day 4 embryoid bodies (EBs).ResultsTranscripts from wild-type versus Smad4 null ES cells and day 4 EBs were analysed using Illumina arrays. In addition to several known TGF-β/BMP target genes, we identified numerous Smad4-dependent transcripts that are mis-expressed in the mutants. As expected, mesodermal cell markers were dramatically down-regulated. We also observed an increase in non-canonical potency markers (Pramel7, Tbx3, Zscan4), germ cell markers (Aire, Tuba3a, Dnmt3l) as well as early endoderm markers (Dpp4, H19, Dcn). Additionally, expression of the extracellular matrix (ECM) remodelling enzymes Mmp14 and Mmp9 was decreased in Smad4 mutant ES and EB populations. These changes, in combination with increased levels of laminin alpha1, cause excessive basement membrane deposition. Similarly, in the context of the Smad4 null E6.5 embryos we observed an expanded basement membrane (BM) associated with the thickened endoderm layer.ConclusionSmad4 functional loss results in a dramatic shift in gene expression patterns and in the endodermal cell lineage causes an excess deposition of, or an inability to breakdown and remodel, the underlying BM layer. These structural abnormalities probably disrupt reciprocal signalling between the epiblast and overlying visceral endoderm required for gastrulation.

The effects of in utero irradiation on mutation induction and transgenerational instability in mice

It is well known that the developing embryo is especially sensitive to ionising radiation. However, to date little is known about the long-term effects of in utero exposure on mutation rates during adulthood. To evaluate the effects of in utero irradiation on mutation induction and transgenerational instability, BALB/c pregnant mice (Theiler stage 20, 12 days of gestation) were exposed to 1 Gy of acute X-rays. The in utero exposed 8-week-old males and females were mated to control partners. To evaluate the effects of in utero irradiation on mutation induction in the germline of exposed mice, all parents and offspring were profiled using two mouse-specific expanded simple tandem repeat (ESTR) probes Ms6-hm and Hm-2. The results of our study show that ESTR mutation rates in the germline of in utero irradiated male and female mice remain highly elevated during adulthood. Using single-molecule PCR, the frequency of ESTR mutation was established in DNA samples prepared from sperm, bone marrow and brain taken from the in utero irradiated animals. In all animals, a statistically significant ~2.8-3.7 fold increase in the mean mutation frequency was found in all tissues of the in utero irradiated animals. The results of our study show that the mutagenic effects of in utero irradiation in mice are well manifested during adulthood and therefore suggest that the susceptibility of early stages of mouse development to ionising radiation may be higher than previously thought. To analyse the effects of parental irradiation on transgenerational instability, the frequency of ESTR mutation was established in DNA samples prepared from sperm, bone marrow and brain taken from the first-generation offspring of in utero irradiated male and female mice. The results of our study show that in the offspring of in utero exposed males the frequency of ESTR mutation is considerably elevated across multiple tissues, whereas in the offspring of irradiated females it does not significantly differ from that in controls. A comparison with the results of our previous studies on transgenerational in stability among the offspring of BALB/c male mice irradiated during adulthood showed that that the magnitude of transgenerational effects is not affected by the stage of paternal exposure. This work has therefore established that an instability signal induced in the germline of in utero irradiated males is manifested during adulthood. The potential implications of our findings to for further understanding of the possible mechanisms of transgenerational genomic instability will be discussed.

A role for Xrcc2 in the early stages of mouse development

Xrcc2 is one of a family of five Rad51-like genes with important roles in the repair of DNA damage by homologous recombination (HR) in mammals. We have shown previously that loss of Xrcc2 in mice results in severe but variable developmental defects and embryonic lethality, potentially linked to excessive apoptosis. To look at the causes of lethality, and possibly to allow Xrcc2 −/− mice to survive to birth, we have produced double knockout mice deficient in either the p53 oncoprotein or Ataxia telangiectasia mutated (Atm). Overall we show that the excessive apoptosis observed in Xrcc2 −/− embryos is p53-dependent, and that loss of p53 can restore growth capacity to Xrcc2 −/− fibroblasts in culture, but that it cannot rescue the embryonic lethality. Additionally, although the Xrcc2 −/− Trp53 −/− embryos show a near-normal morphology they remain relatively small in size. Loss of Atm in an Xrcc2 −/− embryo has little effect, suggesting that response to loss of HR capacity is not mediated through the Atm kinase in the early stages of mouse development. Further, as seen by reduced expression of the early developmental marker, Delta-like1, the normal developmental programme is perturbed in Xrcc2 −/− embryonic tissues, particularly during neurogenesis and somitogenesis. Taken together our data suggest that the accumulation of spontaneous damage in HR-deficient embryos has severe consequences for the development and survival of mammals due to the unregulated loss of cells important to the developmental programme.

Secreted modular calcium-binding protein-1 localization during mouse embryogenesis

BM-40 is an extracellular matrix-associated protein and is characterized by an extracellular calcium-binding domain as well as a follistatin-like domain. Secreted modular calcium-binding protein-1 (SMOC-1) is a new member of the BM-40 family. It consists of two thyroglobulin-like domains, a follistatin-like domain and a new domain without known homologues and is expressed ubiquitously in many adult murine tissues. Immunofluorescence studies, as well as immunogold electron microscopy, have confirmed the localization of SMOC-1 in or around basement membranes of adult murine skin, blood vessels, brain, kidney, skeletal muscle, and the zona pellucida surrounding the oocyte. In the present work, light microscopic immunohistochemistry has revealed that SMOC-1 is localized in the early mouse embryo day 7 throughout the entire endodermal basement membrane zone of the embryo proper. SMOC-1 mRNA is synthesized, even in early stages of mouse development, by mesenchymal as well as epithelial cells deriving from all three germ layers. In embryonic stage day 12, and fetal stages day 14, 16, and 18, the protein is present in the basement membrane zones of brain, blood vessels, skin, skeletal muscle, lung, heart, liver, pancreas, intestine, and kidney. This broad and organ-specific distribution suggests multifunctional roles of SMOC-1 during mouse embryogenesis.

Asymmetric distribution of PAR proteins in the mouse embryo begins at the 8-cell stage during compaction

In many organisms, like Caenorhabditis elegans and Drosophila melanogaster, establishment of spatial patterns and definition of cell fate are driven by the segregation of determinants in response to spatial cues, as early as oogenesis or fertilization. In these organisms, a family of conserved proteins, the PAR proteins, is involved in the asymmetric distribution of cytoplasmic determinants and in the control of asymmetric divisions. In the mouse embryo, it is only at the 8-cell stage during compaction that asymmetries, leading to cellular diversification and blastocyst morphogenesis, are first observed. However, it has been suggested that developmentally relevant asymmetries could be established already in the oocyte and during fertilization. This led us to study the PAR proteins during the early stages of mouse development. We observed that the homologues of the different members of the PAR/aPKC complex and PAR1 are expressed in the preimplantation mouse embryo. During the first embryonic cleavages, before compaction, PARD6b and EMK1 are observed on the spindle. The localization of these two proteins becomes asymmetric during compaction, when blastomeres flatten upon each other and polarize. PARD6b is targeted to the apical pole, whereas EMK1 is distributed along the baso-lateral domain. The targeting of EMK1 is dependent upon cell–cell interactions while the apical localization of PARD6b is independent of cell contacts. At the 16-cell stage, aPKCζ colocalizes with PARD6b and a colocalization of the three proteins (PARD6b/PARD3/aPKCζ can occur in blastocysts, only at tight junctions. This choreography suggests that proteins of the PAR family are involved in the setting up of blastomere polarity and blastocyst morphogenesis in the early mammalian embryo although the interactions between the different players differ from previously studied systems. Finally, they reinforce the idea that the first developmentally relevant asymmetries are set up during compaction.

Morpholino oligonucleotide-triggered knockdown reveals a role for maternal E-cadherin during early mouse development

We report that gene silencing via intracytoplasmic microinjections of morpholino-modified antisense oligonucleotides is an effective and reproducible method to study both maternal and zygotic gene functions during early and late stages of mouse preimplantation development. The zygotic expression of the β-geo transgene in the ROSA26 mouse strain could be inhibited until at least the early blastula stages. Thus morpholino-triggered gene inactivation appears to be a useful method to study the functional role of genes in preimplantation development. Using this approach, we have investigated a potential role of maternal expression of Cdh1, the gene encoding the cell-adhesion molecule E-cadherin. Inhibition of translation of maternal E-cadherin mRNA causes a developmental arrest at the two-cell stage. BrUTP incorporation assays indicated that this developmental defect cannot be explained by a general failure in transcriptional activity. This defect is reversible since E-cadherin mRNA can rescue the affected embryos, suggesting that a functional adhesion complex, present at the junction between blastomeres, is a prerequisite for the normal development of the mouse preimplantation embryo. Our study thus reveals a previously unanticipated role of maternal E-cadherin during early stages of mouse development.

Selective loss of dopaminergic neurons in the substantia nigra of Pitx3-deficient aphakia mice

Dopaminergic (DA) neurons in the ventral midbrain nuclei, substantia nigra pars compacta (SNc, A9) and ventral tegmental area (VTA, A10), play important roles in the control of movement, emotion, cognition, and reward related behavior. Although several transcription factors have been shown to be critical for midbrain DA neuron development, there has been no report of factor(s) that differentially regulate individual DA neuronal groups. Based on its highly restricted expression in the SNc and VTA in the brain, we hypothesize that the homeobox transcription factor Pitx3 may critically regulate the development of ventral midbrain DA neurons. In this study, we report that in Pitx3-deficient ak/ak mice, DA neurons in the SNc and the nigrostriatal pathway fail to develop properly, and DA levels are reduced to 10% of the wild type mice in the dorsal striatum. On the contrary, A10 neurons are intact in ak/ak mice and DA levels within their projection areas are not affected. This region-specific defect was already evident in newborn mice, suggesting that the defect had occurred during the early stages of mouse development. Taken together, our results indicate that Pitx3 is the first known transcription factor that may critically and selectively control proper development of A9 DA neurons and the nigrostriatal pathway. This observation is of great importance in understanding the mechanisms of DA neuron development and may also help us to understand the mechanism of selective degeneration of A9 DA neurons in Parkinson’s disease and to devise novel therapeutic approaches for the disorder.