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Myhre syndrome is caused by dominant-negative dysregulation of SMAD4 and other co-factors.
Myhre syndrome is a connective tissue disorder characterized by congenital cardiovascular, craniofacial, respiratory, skeletal, and cutaneous anomalies as well as intellectual disability and progressive fibrosis. It is caused by germline variants in the transcriptional co-regulator SMAD4 that localize at two positions within the SMAD4 protein, I500 and R496, with I500 V/T/M variants more commonly identified in individuals with Myhre syndrome. Here we assess the functional impact of SMAD4-I500V variant, identified in two previously unpublished individuals with Myhre syndrome, and provide novel insights into the molecular mechanism of SMAD4-I500V dysfunction. We show that SMAD4-I500V can dimerize, but its transcriptional activity is severely compromised. Our data show that SMAD4-I500V acts dominant-negatively on SMAD4 and on receptor-regulated SMADs, affecting transcription of target genes. Furthermore, SMAD4-I500V impacts the transcription and function of crucial developmental transcription regulator, NKX2-5. Overall, our data reveal a dominant-negative model of disease for SMAD4-I500V where the function of SMAD4 encoded on the remaining allele, and of co-factors, are perturbed by the continued heterodimerization of the variant, leading to dysregulation of TGF and BMP signaling. Our findings not only provide novel insights into the mechanism of Myhre syndrome pathogenesis but also extend the current knowledge of how pathogenic variants in SMAD proteins cause disease.
Autosomal dominant spondylocostal dysostosis in three generations of a Macedonian family: Negative mutation analysis of DLL3, MESP2, HES7, and LFNG.
The spondylocostal dysostoses (SCDs) are a heterogeneous group of axial skeletal disorders characterized by multiple segmentation defects of the vertebrae (SDV) and abnormality of the thoracic cage with mal-aligned ribs and often a reduction in rib number. The four known monogenic forms of SCD follow autosomal recessive inheritance, have generalized SDV, a broadly symmetrical thoracic cage, and result from mutations in Notch signaling pathway genes-DLL3, MESP2, LFNG, and HES7. Autosomal dominant (AD) SCD has been reported less often, is very variable, and molecular genetic mechanisms remain elusive. Here, we report a three-generation, non-consanguineous family with four affected individuals demonstrating multiple or generalized SDV. Scoliosis was present and the trunk shortened but the ribs were relatively mildly affected. There were no other significant organ abnormalities, no obvious dysmorphic features, neurodevelopment was normal, and all investigations, including mutation analysis of DLL3, MESP2, LFNG, and HES7, were normal. A non-pathogenic variant was detected in LFNG but it did not segregate with the phenotype. This Macedonian kindred adds to knowledge of AD SCD and to our knowledge is the first to be tested for the four Notch pathway genes known to be associated with SCD.
MEF2 proteins, including MEF2A, are expressed in both muscle and non-muscle cells.
The MEF2 proteins are involved in regulation of many muscle specific genes. Although MEF2 RNAs encoding the MEF2A and MEF2D isoforms are ubiquitously expressed, the presence of MEF2 proteins in non-muscle cell types has been controversial. Here we use a well-characterised antibody in conjunction with DNA binding studies to provide evidence that members of the MEF2 family are widely expressed in the nuclei of cultured cells and are competent to bind DNA. The data show that non-muscle MEF2 complexes contain MEF2A, and that another MEF2 protein, probably MEF2D, is also present. These results suggest that MEF2 proteins fulfil functions in addition to muscle-specific gene expression.
Xenopus laevis transgenesis by sperm nuclear injection.
The stable integration of transgenes into embryos of the frog Xenopus laevis is achieved using the procedure described here. Linear DNA containing the transgene is incorporated randomly into sperm nuclei that have had their membranes disrupted with detergent treatment. Microinjection of these nuclei into unfertilized eggs produces viable embryos that can be screened for activity of the transgene. The proportion of embryos that harbor the transgene varies from 10 to 40% of the total number of surviving embryos. Multiple copies of the transgene can integrate as a concatemer into the sperm genome, and more than one site of DNA integration might occur within resulting animals. Germ cell transmission of the transgene is routine and the procedure is well suited to the production of transgenic reporter frog lines. One day should be allocated for the preparation of the sperm nuclei, which are stored as aliquots for future use. The transgenesis reaction and egg injection take one morning.
Regulation of the tinman homologues in Xenopus embryos.
Vertebrate homologues of the Drosophila tinman transcription factor have been implicated in the processes of specification and differentiation of cardiac mesoderm. In Xenopus three members of this family have been isolated to date. Here we show that the XNkx2-3, Xnkx2-5, and XNkx2-10 genes are expressed in increasingly distinctive patterns in endodermal and mesodermal germ layers through early development, suggesting that their protein products (either individually or in different combinations) perform distinct functions. Using amphibian transgenesis, we find that the expression pattern of one of these genes, XNkx2-5, can be reproduced using transgenes containing only 4.3 kb of promoter sequence. Sequence analysis reveals remarkable conservation between the distalmost 300 bp of the Xenopus promoter and a portion of the AR2 element upstream of the mouse and human Nkx2-5 genes. Interestingly, only the 3' half of this evolutionarily conserved sequence element is required for correct transgene expression in frog embryos. Mutation of conserved GATA sites or a motif resembling the dpp-response element in the Drosophila tinman tinD enhancer dramatically reduces the levels of transgene expression. Finally we show that, despite its activity in Xenopus embryos, in transgenic mice the Xenopus Nkx2-5 promoter is able to drive reporter gene expression only in a limited subset of cells expressing the endogenous gene. This intriguing result suggests that despite evolutionary conservation of some cis-regulatory sequences, the regulatory controls on Nkx2-5 expression have diverged between mammals and amphibians.
Early steps in vertebrate cardiogenesis.
Heart formation provides an excellent model for studying the molecular basis of cell determination in vertebrate embryos. By combining molecular assays with the experimental approaches of classic embryology, a model for the cell signalling events that initiate cardiogenesis is emerging. Studies of chick, amphibian, and fish embryos demonstrate the inductive role of dorso-anterior endoderm in specifying the cardiac fate of adjacent mesoderm. A consequence of this signalling is the onset of cardiomyogenesis and several transcription factors--Nkx2-5-related, HAND, GATA and MEF-2 families--contribute to these events.
Mutation of HES7 in a large extended family with spondylocostal dysostosis and dextrocardia with situs inversus.
Spondylocostal dysotosis (SCD) is a rare developmental congenital abnormality of the axial skeleton. Mutation of genes in the Notch signaling pathway cause SCD types 1-5. Dextrocardia with situs inversus is a rare congenital malformation in which the thoracic and abdominal organs are mirror images of normal. Such laterality defects are associated with gene mutations in the Nodal signaling pathway or cilia assembly or function. We investigated two distantly related individuals with a rare combination of severe segmental defects of the vertebrae (SDV) and dextrocardia with situs inversus. We found that both individuals were homozygous for the same mutation in HES7, and that this mutation caused a significant reduction of HES7 protein function; HES7 mutation causes SCD4. Two other individuals with SDV from two unrelated families were found to be homozygous for the same mutation. Interestingly, although the penetrance of the vertebral defects was complete, only 3/7 had dextrocardia with situs inversus, suggesting randomization of left-right patterning. Two of the affected individuals presented with neural tube malformations including myelomeningocele, spina bifida occulta and/or Chiari II malformation. Such neural tube phenotypes are shared with the originally identified SCD4 patient, but have not been reported in the other forms of SCD. In conclusion, it appears that mutation of HES7 is uniquely associated with defects in vertebral, heart and neural tube formation, and this observation will help provide a discriminatory diagnostic guide in patients with SCD, as well as inform molecular genetic testing.
Cited2 is required in trophoblasts for correct placental capillary patterning.
CITED2 is a transcriptional co-factor with important roles in many organs of the developing mammalian embryo. Complete deletion of this gene causes severe malformation of the placenta, and results in significantly reduced embryonic growth and death from E14.5. The placenta is a complex organ originating from cells derived from three lineages: the maternal decidua, the trophectoderm, and the extra-embryonic mesoderm. Cited2 is expressed in many of these cell types, but its exact role in the formation of the placenta is unknown. Here we use a conditional deletion approach to remove Cited2 from overlapping subsets of trophectoderm and extra-embryonic mesoderm. We find that Cited2 in sinusoidal trophoblast giant cells and syncytiotrophoblasts is likely to have a non-cell autonomous role in patterning of the pericytes associated with the embryonic capillaries. This function is likely to be mediated by PDGF signaling. Furthermore, we also identify that loss of Cited2 in syncytiotrophoblasts results in the subcellular mislocalization of one of the major lactate transporters in the placenta, SLC16A3 (MCT4). We hypothesize that the embryonic growth retardation observed in Cited2 null embryos is due in part to a disorganized embryonic capillary network, and in part due to abnormalities of the nutrient transport functions of the feto-maternal interface.
The mouse notches up another success: understanding the causes of human vertebral malformation.
The defining characteristic of all vertebrates is a spine composed of a regular sequence of vertebrae. In humans, congenital spinal defects occur with an incidence of 0.5-1 per 1,000 live births and arise when the formation of vertebral precursors in the embryo is disrupted. These precursors (somites) form in a process (somitogenesis) in which each somite is progressively separated from an unsegmented precursor tissue. In the past decade the underlying genetic mechanisms driving this complex process have been dissected using animal models, revealing that it requires the coordinated action of at least 300 genes. Deletion of many of these genes in the mouse produces phenotypes with similar vertebral defects to those observed in human congenital abnormalities. This review highlights the role that such mouse models have played in the identification of the genetic causes of the malsegmentation syndrome spondylocostal dysostosis.
Antigenic and genetic characterization of current influenza strains.
Annually the influenza centre receives more than 1000 virus isolates from around the world to monitor the changing pattern of viruses causing influenza throughout the year. These are characterized antigenically using both polyclonal and monoclonal antibodies and selected viruses are subjected to closer scrutiny by nucleotide sequence analyses of their HA genes. This information is used in making the annual recommendation of vaccine composition. As in the last 15 years, influenza A viruses of both H3N2 and H1N1 subtypes and influenza B viruses have been isolated during the recent influenza season. Outbreaks in the northern hemisphere were largely caused by influenza B viruses which are similar to the B/Panama/45/90 reference strain. The proportion of influenza A increased later in the season and was predominantly of the H3N2 subtype, viruses similar to the recent A/Beijing/32/92 variant being most prevalent. The observed changes taking place will be discussed in the context of recent trends.
Gene-environment interaction demonstrates the vulnerability of the embryonic heart.
Mammalian embryos develop in a low oxygen environment. The transcription factor hypoxia inducible factor 1a (HIF1α) is a key element in the cellular response to hypoxia. Complete deletion of Hif1α from the mouse conceptus causes extensive placental, vascular and heart defects, resulting in embryonic lethality. However the precise role of Hif1α in each of these organ systems remains unknown. To further investigate, we conditionally-deleted Hif1α from mesoderm, vasculature and heart individually. Surprisingly, deletion from these tissues did not recapitulate the same severe heart phenotype or embryonic lethality. Placental insufficiency, such as occurs in the complete Hif1α null, results in elevated cellular hypoxia in mouse embryos. We hypothesized that subjecting the Hif1α conditional null embryos to increased hypoxic stress might exacerbate the effects of tissue-specific Hif1α deletion. We tested this hypothesis using a model system mimicking placental insufficiency. We found that the majority of embryos lacking Hif1α in the heart died when exposed to non-physiological hypoxia. This was a heart-specific phenomenon, as HIF1α protein accumulated predominantly in the myocardium of hypoxia-stressed embryos. Our study demonstrates the vulnerability of the heart to lowered oxygen levels, and that under such conditions of non-physiological hypoxia the embryo absolutely requires Hif1α to continue normal development. Importantly, these findings extend our understanding of the roles of Hif1α in cardiovascular development.
Two novel missense mutations in HAIRY-AND-ENHANCER-OF-SPLIT-7 in a family with spondylocostal dysostosis.
Spondylocostal dysostosis (SCD) is an inherited disorder with abnormal vertebral segmentation that results in extensive hemivertebrae, truncal shortening and abnormally aligned ribs. It arises during embryonic development by a disruption of formation of somites (the precursor tissue of the vertebrae, ribs and associated tendons and muscles). Four genes causing a subset of autosomal recessive forms of this disease have been identified: DLL3 (SCDO1: MIM 277300), MESP2 (SCDO2: MIM 608681), LFNG (SCDO3: MIM609813) and HES7 (SCDO4). These genes are all essential components of the Notch signalling pathway, which has multiple roles in development and disease. Previously, only a single SCD-causative missense mutation was described in HES7. In this study, we have identified two new missense mutations in the HES7 gene in a single family, with only individuals carrying both mutant alleles being affected by SCD. In vitro functional analysis revealed that one of the mutant HES7 proteins was unable to repress gene expression by DNA binding or protein heterodimerization.
Disruption of the somitic molecular clock causes abnormal vertebral segmentation.
Somites are the precursors of the vertebral column. They segment from the presomitic mesoderm (PSM) that is caudally located and newly generated from the tailbud. Somites form in synchrony on either side of the embryonic midline in a reiterative manner. A molecular clock that operates in the PSM drives this reiterative process. Genetic manipulation in mouse, chick and zebrafish has revealed that the molecular clock controls the activity of the Notch and WNT signaling pathways in the PSM. Disruption of the molecular clock impacts on somite formation causing abnormal vertebral segmentation (AVS). A number of dysmorphic syndromes manifest AVS defects. Interaction between developmental biologists and clinicians has lead to groundbreaking research in this area with the identification that spondylocostal dysostosis (SCD) is caused by mutation in Delta-like 3 (DLL3), Mesoderm posterior 2 (MESP2), and Lunatic fringe (LFNG); three genes that are components of the Notch signaling pathway. This review describes our current understanding of the somitic molecular clock and highlights how key findings in developmental biology can impact on clinical practice.
Loss of Cited2 affects trophoblast formation and vascularization of the mouse placenta.
Cited2 is widely expressed in the developing embryo and in extraembryonic tissues including the placenta. Gene expression can be induced by a number of factors; most notably by the hypoxia inducible transcription factor, HIF1, under low oxygen conditions. Cited2 encodes for a transcriptional co-factor that in vitro can act as both a positive and negative regulator of transcription. This function is due to its interaction with CBP/p300 and appears to depend on whether Cited2 enables CBP/p300 to interact with the basic transcriptional machinery, or if its binding prevents such an interaction from occurring. Here, we report a novel function for Cited2 in placenta formation, following gene deletion in mouse. In the absence of Cited2 the placenta and embryo are significantly small from 12.5 and 14.5 dpc respectively, and death occurs in utero. Cited2 null placentas have fewer differentiated trophoblast cell types; specifically there is a reduction in trophoblast giant cells, spongiotrophoblasts and glycogen cells. In addition, the fetal vasculature of the placenta is disorganised and there are fewer anastomosing capillaries. Given that Cited2 is expressed in both trophoblasts and the fetal vasculature, the observed defects fit well with the sites of gene expression. We conclude that Cited2 is required for normal placental development and vascularisation, and hence for embryo viability.
Mutated MESP2 causes spondylocostal dysostosis in humans.
Spondylocostal dysostosis (SCD) is a term given to a heterogeneous group of disorders characterized by abnormal vertebral segmentation (AVS). We have previously identified mutations in the Delta-like 3 (DLL3) gene as a major cause of autosomal recessive spondylocostal dysostosis. DLL3 encodes a ligand for the Notch receptor and, when mutated, defective somitogenesis occurs resulting in a consistent and distinctive pattern of AVS affecting the entire spine. From our study cohort of cases of AVS, we have identified individuals and families with abnormal segmentation of the entire spine but no mutations in DLL3, and, in some of these, linkage to the DLL3 locus at 19q13.1 has been excluded. Within this group, the radiological phenotype differs mildly from that of DLL3 mutation-positive SCD and is variable, suggesting further heterogeneity. Using a genomewide scanning strategy in one consanguineous family with two affected children, we demonstrated linkage to 15q21.3-15q26.1 and furthermore identified a 4-bp duplication mutation in the human MESP2 gene that codes for a basic helix-loop-helix transcription factor. No MESP2 mutations were found in a further 7 patients with related radiological phenotypes in whom abnormal segmentation affected all vertebrae, nor in a further 12 patients with diverse phenotypes.
Renal developmental defects resulting from in utero hypoxia are associated with suppression of ureteric β-catenin signaling.
Gestational stressors, including glucocorticoids and protein restriction, can affect kidney development and hence final nephron number. Since hypoxia is a common insult during pregnancy, we studied the influence of oxygen tension on kidney development in models designed to represent a pathological hypoxic insult. In vivo mouse models of moderate, transient, midgestational (12% O₂, 48 h, 12.5 dpc) or severe, acute, early-gestational (5.5-7.5% O₂, 8 h, 9.5-10.5 dpc) hypoxia were developed. The embryo itself is known to mature under hypoxic conditions with embryonic tissue levels of oxygen estimated to be 5%-8% (physiological hypoxia) when the mother is exposed to ambient normoxia. Both in vivo models generated phenotypes seen in patients with congenital anomalies of the kidney and urinary tract (CAKUT). Severe, acute, early hypoxia resulted in duplex kidney, while moderate, transient, midgestational hypoxia permanently reduced ureteric branching and nephron formation. Both models displayed hypoxia-induced reductions in β-catenin signaling within the ureteric tree and suppression of the downstream target gene, Ccnd1. Thus, we show a link between gestational hypoxia and CAKUT, the phenotype of which varies with timing, duration, and severity of the hypoxic insult.
Cyclical expression of the Notch/Wnt regulator Nrarp requires modulation by Dll3 in somitogenesis.
Delta-like 3 (Dll3) is a divergent ligand and modulator of the Notch signaling pathway only identified so far in mammals. Null mutations of Dll3 disrupt cycling expression of Notch targets Hes1, Hes5, and Lfng, but not of Hes7. Compared with Dll1 or Notch1, the effects of Dll3 mutations are less severe for gene expression in the presomitic mesoderm, yet severe segmentation phenotypes and vertebral defects result in both human and mouse. Reasoning that Dll3 specifically disrupts key regulators of somite cycling, we carried out functional analysis to identify targets accounting for the segmental phenotype. Using microdissected embryonic tissue from somitic and presomitic mesodermal tissue, we identified new genes enriched in these tissues, including Limch1, Rhpn2, and A130022J15Rik. Surprisingly, we only identified a small number of genes disrupted by the Dll3 mutation. These include Uncx, a somite gene required for rib and vertebral patterning, and Nrarp, a regulator of Notch/Wnt signaling in zebrafish and a cycling gene in mouse. To determine the effects of Dll3 mutation on Nrarp, we characterized the cycling expression of this gene from early (8.5 dpc) to late (10.5 dpc) somitogenesis. Nrarp displays a distinct pattern of cycling phases when compared to Lfng and Axin2 (a Wnt pathway gene) at 9.5 dpc but appears to be in phase with Lfng by 10.5 dpc. Nrarp cycling appears to require Dll3 but not Lfng modulation. In Dll3 null embryos, Nrarp displayed static patterns. However, in Lfng null embryos, Nrarp appeared static at 8.5 dpc but resumed cycling expression by 9.5 and dynamic expression at 10.5 dpc stages. By contrast, in Wnt3a null embryos, Nrarp expression was completely absent in the presomitic mesoderm. Towards identifying the role of Dll3 in regulating somitogenesis, Nrarp emerges as a potentially important regulator that requires Dll3 but not Lfng for normal function.
SmcHD1, containing a structural-maintenance-of-chromosomes hinge domain, has a critical role in X inactivation.
X-chromosome inactivation is the mammalian dosage compensation mechanism by which transcription of X-linked genes is equalized between females and males. In an N-ethyl-N-nitrosourea (ENU) mutagenesis screen on mice for modifiers of epigenetic reprogramming, we identified the MommeD1 (modifier of murine metastable epialleles) mutation as a semidominant suppressor of variegation. MommeD1 shows homozygous female-specific mid-gestation lethality and hypomethylation of the X-linked gene Hprt1, suggestive of a defect in X inactivation. Here we report that the causative point mutation lies in a previously uncharacterized gene, Smchd1 (structural maintenance of chromosomes hinge domain containing 1). We find that SmcHD1 is not required for correct Xist expression, but localizes to the inactive X and has a role in the maintenance of X inactivation and the hypermethylation of CpG islands associated with the inactive X. This finding links a group of proteins normally associated with structural aspects of chromosome biology with epigenetic gene silencing.
Distinct enhancers regulate skeletal and cardiac muscle-specific expression programs of the cardiac alpha-actin gene in Xenopus embryos.
During vertebrate embryonic development, cardiac and skeletal muscle originates from distinct precursor populations. Despite the profound structural and functional differences in the striated muscle tissue they eventually form, such progenitors share many features such as components of contractile apparatus. In vertebrate embryos, the alpha-cardiac actin gene encodes a major component of the myofibril in both skeletal and cardiac muscle. Here, we show that expression of Xenopus cardiac alpha-actin in the myotomes and developing heart tube of the tadpole requires distinct enhancers within its proximal promoter. Using transgenic embryos, we find that mutations in the promoter-proximal CArG box and 5 bp downstream of it specifically eliminate expression of a GFP transgene within the developing heart, while high levels of expression in somitic muscle are maintained. This sequence is insufficient on its own to limit expression solely to the myocardium, such restriction requiring multiple elements within the proximal promoter. Two additional enhancers are active in skeletal muscle of the embryo, either one of which has to interact with the proximal CArG box for correct expression to be established. Transgenic reporters containing multimerised copies of CArG box 1 faithfully detect most sites of SRF expression in the developing embryo as do equivalent reporters containing the SRF binding site from the c-fos promoter. Significantly, while these motifs possess a different A/T core within the CC(A/T)(6)GG consensus and show no similarity in flanking sequence, each can interact with a myotome-specific distal enhancer of cardiac alpha-actin promoter, to confer appropriate cardiac alpha-actin-specific regulation of transgene expression. Together, these results suggest that the role of CArG box 1 in the cardiac alpha-actin gene promoter is to act solely as a high-affinity SRF binding site.
A mechanism for gene-environment interaction in the etiology of congenital scoliosis.
Congenital scoliosis, a lateral curvature of the spine caused by vertebral defects, occurs in approximately 1 in 1,000 live births. Here we demonstrate that haploinsufficiency of Notch signaling pathway genes in humans can cause this congenital abnormality. We also show that in a mouse model, the combination of this genetic risk factor with an environmental condition (short-term gestational hypoxia) significantly increases the penetrance and severity of vertebral defects. We demonstrate that hypoxia disrupts FGF signaling, leading to a temporary failure of embryonic somitogenesis. Our results potentially provide a mechanism for the genesis of a host of common sporadic congenital abnormalities through gene-environment interaction.