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Wehn, A.K., P.H. Gallo, and D.L. Chapman (2009) Generation of transgenic mice expressing Cre recombinase under the control of the Dll1 mesoderm enhancer element. Genesis 47:309-313 To study paraxial mesoderm formation in the mouse, transgenic lines that can beused to either selectively delete or express genes of interest in the paraxialmesoderm are required. We have generated a transgenic mouse line that expressesCre recombinase in the paraxial mesoderm (PAM) beginning at e7.5. A lacZ Crerecombinase reporter line showed that in addition to PAM and its derivatives,lateral plate and intermediate mesoderm derivatives were also exposed to Creactivity, while the node, notochord, and cardiac mesoderm were not. We furtherdemonstrate that 70-75% of the fibroblasts generated from Dll1-msd Cre,ROSA26-rtTA embryos possess Cre recombinase activity. These mice can therefore beused in combination with tet-responsive transgenic lines to generatemesoderm-derived embryonic fibroblasts that inducibly express a gene of interest. Farkas, D.R., and D.L. Chapman (2009) Kinked tail mutation results in notochord defects in heterozygotes and distal visceral endoderm defects in homozygotes. Dev Dyn 238:3237-3247 Proper formation of the anterior-posterior (AP) axis in the developing embryo is critical for the correct patterning and often survival of the organism. In themouse, an initial step in axis establishment is the specification and migrationof the distal visceral endoderm (DVE). We have identified a semi-dominantspontaneous mutation in mouse, named kinked tail (knk), which when heterozygousresults in a kinky tail phenotype due to fusions and dysmorphology of the tailvertebrae. Vertebral fusions appear to be a secondary effect of notochordthickening and branching in the tail region. Homozygosity for knk results inearly embryonic lethality by embryonic day 8.5 due to improper timing of DVEspecification and migration, and subsequent failure to establish the AP axis.Developmental Dynamics, 2009. (c) 2009 Wiley-Liss, Inc. Oginuma, M., Y. Niwa, D.L. Chapman, and Y. Saga (2008) Mesp2 and Tbx6 cooperatively create periodic patterns coupled with the clock machinery during mouse somitogenesis. Development 135:2555-2562 The metameric structures in vertebrates are based on the periodicity of the somites that are formed one by one from the anterior end of the presomitic mesoderm (PSM). The timing and spacing of somitogenesis are regulated by the segmentation clock, which is characterized by the oscillation of several signaling pathways in mice. The temporal information needs to be translated into a spatial pattern in the so-called determination front, at which cells become responsive to the clock signal. The transcription factor Mesp2 plays a crucial role in this process, regulating segmental border formation and rostro-caudal patterning. However, the mechanisms regulating the spatially restricted and periodic expression of Mesp2 have remained elusive. Using high-resolution fluorescent in situ hybridization in conjunction with immunohistochemical analyses, we have found a clear link between Mesp2 transcription and the periodic waves of Notch activity. We also find that Mesp2 transcription is spatially defined by Tbx6: Mesp2 transcription and Tbx6 protein initially share an identical anterior border in the PSM, but once translated, Mesp2 protein leads to the suppression of Tbx6 protein expression post-translationally via rapid degradation mediated by the ubiquitin-proteasome pathway. This reciprocal regulation is the spatial mechanism that successively defines the position of the next anterior border of Mesp2. We further show that FGF signaling provides a spatial cue to position the expression domain of Mesp2. Taken together, we conclude that Mesp2 is the final output signal by which the temporal information from the segmentation clock is translated into segmental patterning during mouse somitogenesis. Chapman, D.L. (2006) Paraxial mesoderm signals are required for intermediate mesoderm formation in the mouse. Dev. Biol. 295:393-394
White, P.H., D.R. Farkas, and D.L. Chapman (2005) Regulation of Tbx6 expression by Notch signaling. Genesis 42:61-70 Somites are the first overt sign of segmentation in the vertebrate embryo and form from bilateral strips of paraxial mesoderm. Paraxial mesoderm arises from the primitive streak; it then migrates laterally and comes to lie on both sides of the neural tube. In the mouse, the T-box transcription factor Tbx6 is required for both somite formation and patterning. Tbx6 expression corresponds both temporally and spatially to somite formation, with expression in the primitive streak and presomitic mesoderm. Its expression in the latter could simply be explained by maintenance following its initial activation in the primitive streak. Alternatively, its expression in the presomitic mesoderm may be contributed by separate regulatory elements possibly under the control of different signals. We have begun to investigate how Tbx6 expression is controlled during development using a transgenic approach to identify the cis-acting regulatory regions. We show that it is possible to separate an element required for presomitic mesoderm expression from that driving expression in the primitive streak. Further, we show that a binding site for the Notch transcription factor RBP-Jk is necessary for Tbx6 presomitic mesoderm enhancer activity, indicating that Notch signaling is upstream of Tbx6 in the pathway directing somite formation and patterning.
White, P.H., and D.L. Chapman (2005) Dll1 is a downstream target of Tbx6 in the paraxial mesoderm. Genesis 42:193-202 Tbx6 is a member of the T-box family of transcription factors. In the mouse, Tbx6 is expressed in the primitive streak, tail bud, and presomitic mesoderm and is essential for the specification of posterior paraxial mesoderm; in its absence, posterior somites are replaced by ectopic neural tubes. Analysis of embryos expressing reduced levels of Tbx6 also revealed that it is required for the correct patterning of the somites as well as their initial specification. As a first step toward identifying downstream targets of Tbx6, we examined the DNA binding properties of Tbx6 and identified a Tbx6 consensus binding site. Previously, we have shown that expression of Dll1, which encodes a Notch ligand, is lost in the Tbx6 mutant and that Tbx6 and Dll1 genetically interact, indicating that Dll1 may be a direct target of Tbx6 in the paraxial mesoderm. We uncovered four putative Tbx6 binding sites within a Dll1 paraxial mesoderm enhancer and show that Tbx6 can bind two of these sites in vitro. Altogether, these results lend further support for Dll1 being a direct target of Tbx6 in the presomitic mesoderm.
Hogan, K.A., C.A. Ambler, D.L. Chapman, and V.L. Bautch (2004) The neural tube patterns vessels developmentally using the VEGF signaling pathway. Development 131:1503-1513 Embryonic blood vessels form in a reproducible pattern that interfaces with other embryonic structures and tissues, but the sources and identities of signals that pattern vessels are not well characterized. We hypothesized that the neural tube provides vascular patterning signal(s) that direct formation of the perineural vascular plexus (PNVP) that encompasses the neural tube at mid-gestation. Both surgically placed ectopic neural tubes and ectopic neural tubes engineered genetically were able to recruit a vascular plexus, showing that the neural tube is the source of a vascular patterning signal. In mouse-quail chimeras with the graft separated from the neural tube by a buffer of host cells, graft-derived vascular cells contributed to the PNVP, indicating that the neural tube signal(s) can act at a distance. Murine neural tube vascular endothelial growth factor A (VEGFA) expression was temporally and spatially correlated with PNVP formation, suggesting it is a component of the neural tube signal. A collagen explant model was developed in which presomitic mesoderm explants formed a vascular plexus in the presence of added VEGFA. Co-cultures between presomitic mesoderm and neural tube also supported vascular plexus formation, indicating that the neural tube could replace the requirement for VEGFA. Moreover, a combination of pharmacological and genetic perturbations showed that VEGFA signaling through FLK1 is a required component of the neural tube vascular patterning signal. Thus, the neural tube is the first structure identified as a midline signaling center for embryonic vascular pattern formation in higher vertebrates, and VEGFA is a necessary component of the neural tube vascular patterning signal. These data suggest a model whereby embryonic structures with little or no capacity for angioblast generation act as a nexus for vessel patterning.
Chapman, D.L., A. Cooper-Morgan, Z. Harrelson, and V.E. Papaioannou (2003) Critical role for Tbx6 in mesoderm specification in the mouse. Mech. Develop. 120:837-847 Tbx6 is a member of the T-box family of transcription factor genes. Two mutant alleles of this gene establish that Tbx6 is involved in both the specification and patterning of the somites along the entire length of the embryo. The null allele, Tbx6tm1Pa, causes abnormal patterning of the cervical somites and improper specification of more posterior paraxial mesoderm, such that it forms ectopic neural tubes. In this study, we use this allele to further investigate the mechanism of action of the Tbx6 gene and investigate possible genetic interactions. We have tested the developmental and differentiation potential of Tbx6tm1Pa/Tbx6tm1Pa cells in ectopic sites, in vitro, and in chimeras in vivo. We have also documented cell proliferation and cell death in mutant tail buds in an attempt to explain the mechanism of tail bud enlargement in the Tbx6 mutant embryos. Our results indicate specific developmental restrictions on the differentiation of posterior cells lacking Tbx6, once they have traversed the primitive streak, but no restrictions in differentiation of anterior somites, or of Tbx6 null embryonic stem (ES) cells. We further demonstrate that Tbx6 null ES cells fail to populate posterior somites in chimeric embryos. To discover whether different T-box proteins interact on the same down stream targets in areas of expression overlap, we have explored potential interactions between Tbx6 and T (Brachyury) in genetic crosses. Our results reveal that the TTbx6Wis mutation is epistatic to the Tbx6tm1Pa mutation and that there is no apparent genetic interaction. However, homozygosity for Tbx6tm1Pa and heterozygosity for Tbx6Wis mutation shows a combinatorial interaction at the phenotypic level.
White, P.H., D.R. Farkas, E.E. McFadden, and D.L. Chapman (2003) Defective somite patterning in mouse embryos with reduced levels of Tbx6. Development 130:1681-1690 During vertebrate embryogenesis, paraxial mesoderm gives rise to somites, which subsequently develop into the dermis, skeletal muscle, ribs and vertebrae of the adult. Mutations that disrupt the patterning of individual somites have dramatic effects on these tissues, including fusions of the ribs and vertebrae. The T-box transcription factor, Tbx6, is expressed in the paraxial mesoderm but is downregulated as somites develop. It is essential for the formation of posterior somites, which are replaced with ectopic neural tubes in Tbx6-null mutant embryos. We show that partial restoration of Tbx6 expression in null mutants rescues somite development, but that rostrocaudal patterning within them is defective, ultimately resulting in rib and vertebral fusions, demonstrating that Tbx6 activity in the paraxial mesoderm is required not simply for somite specification but also for their normal patterning. Somite patterning is dependent upon Notch signaling and we show that Tbx6 genetically interacts with the Notch ligand, delta-like 1 (Dll1). Dll1 expression, which is absent in the Tbx6-null mutant, is restored at reduced levels in the partially rescued mutants, suggesting that Dll1 is a target of Tbx6. We also identify the spontaneous mutation rib-vertebrae as a hypomorphic mutation in Tbx6. The similarity in the phenotypes we describe here and that of some human birth defects, such as spondylocostal dysostosis, raises the possibility that mutations in Tbx6 or components of this pathway may be responsible for these defects.
Maeda, T., D.L. Chapman, and A.F. Stewart (2002) Mammalian vestigial-like 2, a cofactor of TEF-1 and MEF2 transcription factors that promotes skeletal muscle differentiation. J. Biol. Chem. 277:48889-48898 Expression of many skeletal muscle-specific genes depends on TEF-1 (transcription enhancer factor-1) and MEF2 transcription factors. In Drosophila, the TEF-1 homolog Scalloped interacts with the cofactor Vestigial to drive differentiation of the wing and indirect flight muscles. Here, we identify three mammalian vestigial-like genes, Vgl-1, Vgl-2, and Vgl-3, that share homology in a TEF-1 interaction domain. Vgl-1 and Vgl-3 transcripts are enriched in the placenta, whereas Vgl-2 is expressed in the differentiating somites and branchial arches during embryogenesis and is skeletal muscle-specific in the adult. During muscle differentiation, Vgl-2 mRNA levels increase and Vgl-2 protein translocates from the cytoplasm to the nucleus. In situ hybridization revealed co-expression of Vgl-2 with myogenin in the differentiating muscle of embryonic myotomes but not in newly formed somites prior to muscle differentiation. Like Vgl-1, Vgl-2 interacts with TEF-1. In addition, we show that Vgl-2 interacts with MEF2 in a mammalian two-hybrid assay and that Vgl-2 selectively binds to MEF2 in vitro. Co-expression of Vgl-2 with MEF2 markedly co-activates an MEF2-dependent promoter through its MEF2 element. Overexpression of Vgl-2 in MyoD-transfected 10T(1/2) cells markedly increased myosin heavy chain expression, a marker of terminal muscle differentiation. These results identify Vgl-2 as an important new component of the myogenic program.
Xue, Y., X. Wang, Z. Li, N. Gotoh, D.L. Chapman, and E.Y. Skolnik (2001) Mesodermal patterning defect in mice lacking the Ste20 NCK interacting kinase (NIK). Development 128:1559-1572 We have previously shown that the Drosophila Ste20 kinase encoded by misshapen (msn) is an essential gene in Drosophila development. msn function is required to activate the Drosophila c-Jun N-terminal kinase (JNK), basket (Bsk), to promote dorsal closure of the Drosophila embryo. Later in development, msn expression is required in photoreceptors in order for their axons to project normally. A mammalian homolog of msn, the NCK-interacting kinase (NIK) (recently renamed to mitogen-activated protein kinase kinase kinase kinase 4; Map4k4), has been shown to activate JNK and to bind the SH3 domains of the SH2/SH3 adapter NCK. To determine whether NIK also plays an essential role in mammalian development, we created mice deficient in NIK by homologous recombination at the Nik gene. Nik(-)(/)(-) mice die postgastrulation between embryonic day (E) 9.5 and E10.5. The most striking phenotype in Nik(-)(/)(-) embryos is the failure of mesodermal and endodermal cells that arise from the anterior end of the primitive streak (PS) to migrate to their correct location. As a result Nik(- )(/)(- )embryos fail to develop somites or a hindgut and are truncated posteriorly. Interestingly, chimeric analysis demonstrated that NIK has a cell nonautonomous function in stimulating migration of presomitic mesodermal cells away from the PS and a second cell autonomous function in stimulating the differentiation of presomitic mesoderm into dermomyotome. These findings indicate that despite the large number of Ste20 kinases in mammalian cells, members of this family play essential nonredundant function in regulating specific signaling pathways. In addition, these studies provide evidence that the signaling pathways regulated by these kinases are diverse and not limited to the activation of JNK because mesodermal and somite development are not perturbed in JNK1-, and JNK2-deficient mice.
Chapman, D.L., and V.E. Papaioannou (1998) Three neural tubes in mouse embryos bearing mutations in the T-box gene, Tbx6. Nature 391:695-697 Somites, segmented mesodermal units of the vertebrate embryo, are the precursors of adult skeletal muscle, bone and cartilage. During embryogenesis, somite progenitor cells ingress through the primitive streak, move laterally to a paraxial position (alongside the body axis) and segment into epithelial somites. Little is known about how this paraxial mesoderm tissue is specified. We have previously described a mouse T-box gene, Tbx6, which codes for a putative DNA-binding protein. The embryonic pattern of expression of Tbx6 in somite precursor cells suggests that this gene may be involved in the specification of paraxial mesoderm. We now report the creation of a mutation in Tbx6 that profoundly affects the differentiation of paraxial mesoderm. Irregular somites form in the neck region of mutant embryos, whereas more posterior paraxial tissue does not form somites but instead differentiates along a neural pathway, forming neural-tube-like structures that flank the axial neural tube. These paraxial tubes show dorsal/ventral patterning that is characteristic of the neural tube, and have differentiated motor neurons. These results indicate that Tbx6 is needed for cells to choose between a mesodermal and a neuronal differentiation pathway during gastrulation; Tbx6 is essential for the specification of posterior paraxial mesoderm, and in its absence cells destined to form posterior somites differentiate along a neuronal pathway.
Ludwig, T., D.L. Chapman, V.E. Papaionnou, and A. Efstratiadis (1997) Targeted mutations of breast cancer susceptibility gene homologs in mice: lethal phenotypes of Brca1, Brca2, Brca1/p53 and Brca2/p53 nullizygous embryos. Genes Dev. 11:1225-1241 Mutations of the human BRCA1 and BRCA2 genes encoding tumor suppressors have been implicated in inherited predisposition to breast and other cancers. Disruption of the homologous mouse genes Brca1 and Brca2 by targeting showed that they both have indispensable roles during embryogenesis, because nullizygous embryos become developmentally retarded and disorganized, and die early in development. In Brca1 mutants, the onset of abnormalities is earlier by one day and their phenotypic features and time of death are highly variable, whereas the phenotype of Brca2 null embryos is more uniform, and they all survive for at least 8.5 embryonic days. Observations with Brca1/Brca2 double nullizygotes raise the possibility that the two developmental pathways could be linked. Interestingly, the impact of the Brca1 or Brca2 null mutation is less severe in a p53 null background. Roffler-Tarlov, S., J.J. Brown, E. Tarlov, J. Stolarov, D.L. Chapman, M. Alexiou, and V.E. Papaioannou (1996) Programmed cell death in the absence of c-Fos and c-Jun. Development 122:1-9 Programmed cell death, or apoptosis, is a normal process in the development of a variety of embryonic and adult tissues, and is also observed in several pathological conditions. Several recent studies, using both expression and functional assays, have implicated the transcription factor, AP-1, in the regulation of programmed cell death, and specifically implicate the genes c-fos and c-jun, as well as some other family members. If the products of the c-fos and/or c-jun genes are essential components in the cascade of events that leads to programmed cell death in mammalian cells, it follows that cell death would not occur in mice lacking functional copies of these genes. We have made use of null mutations in the c-fos and c-jun genes that were produced by gene targeting (Johnson, R.S., Spiegelman, B.M. and Papaioannou, V.E. (1992). Cell 71, 577-586; Johnson, R.S., Van Lingen, B., Papaioannou, V.E. and Spiegelman, B.M. (1993). Genes Dev. 7, 1309-1317) to investigate this possibility. Cell death was assayed using an in situ apoptosis assay in c-fos null embryos and adults, c-jun null embryos, and c-fos/c-jun double null embryos compared with control mice. The occurrence of cell death in c-fos null mice was also assessed in two experimental conditions that normally lead to neuronal cell death. The first was unilateral section of the sciatic nerve in neonates, which leads to the death of anterior horn cells of the spinal cord on the operated side. The second was a genetic cross combining the weaver mutation, which causes death of cerebellar granule cells, with the c-fos mutation. Our results show that programmed cell death occurs normally in developing embryonic tissues and adult thymus and ovary, regardless of the absence of a functional c-fos gene. Furthermore, absence of c-fos had no effect on neuronal cell death in the spinal cord following sciatic nerve section, or in heterozygous weavers' cerebellae. Finally, the results show that programmed cell death can take place in embryos lacking both Fos and Jun.
Gibson-Brown, J.J., S.I. Agulnik, D.L. Chapman, M. Alexiou, N. Garvey, L.M. Silver, and V.E. Papaioannou (1996) Evidence of a role for T-box genes in the evolution of limb morphogenesis and the specification of forelimb/hindlimb identity. Mech. Develop. 56:93-101 Tetrapod fore-and hindlimbs have evolved from the pectoral and pelvic fins of an ancient vertebrate ancestor. In this ancestor, the pectoral fin appears to have arisen following the rostral homeotic recapitulation of an existing pelvic appendage (Tabin and Laufer (1993), Nature 361, 692-693). Thus the basic appendage outgrowth program is reiterated in both tetrapod fore- and hindlimbs and the pectoral and pelvic fins of extant teleost fishes (Sordino et al. (1995) Nature 375, 678-681). Recently a novel family of putative transcription factors, which includes the T (Brachyury) locus, has been identified and dubbed the "T-box' family. In mice, all of these genes have expression patterns indicative of involvement in embryonic induction (Chapman et al. (1996) Dev. Dyn., in press), and four (Tbx2-Tbx5) are represented as two cognate, linked gene pairs (Agulnik et al., (1996), Genetics, in press). We now report that, whereas Tbx2 and Tbx3 are expressed in similar spatiotemporal patterns in both limbs, Tbx5 and Tbx4 expression is primarily restricted to the developing fore- and hindlimb buds, respectively. These observations suggest that T-box genes have played a role in the evolution of fin and limb morphogenesis, and that Tbx5 and Tbx4 may have been divergently selected to play a role in the differential specification of fore- (pectoral) versus hind- (pelvic) limb (fin) identity.
Agulnik, S.I., N. Garvey, S. Hancock, I. Ruvinsky, D.L. Chapman, I. Agulnik, R. Bollag, V. Papaioannou, and L.M. Silver (1996) Evolution of mouse T-box genes by tandem duplication and cluster dispersion. Genetics 144:249-254 The T-box genes comprise an ancient family of putative transcription factors conserved across species as divergent as Mus musculus and Caenorhabditis elegans. All T-box gene products are characterized by a novel 174-186-amino acid DNA binding domain called the T-box that was first discovered in the polypeptide products of the mouse T locus and the Drosophila melanogaster optomotor-blind gene. Earlier studies allowed the identification of five mouse T-box genes, T, Tbx1-3, and Tbr1, that all map to different chromosomal locations and are expressed in unique temporal and spatial patterns during embryogenesis. Here, we report the discovery of three new members of the mouse T-box gene family, named Tbx4, Tbx5, and Tbx6. Two of these newly discovered genes, Tbx4 and Tbx5, were found to be tightly linked to previously identified T-box genes. Combined results from phylogenetic, linkage, and physical mapping studies provide a picture for the evolution of a T-box subfamily by unequal crossing over to form a two-gene cluster that was duplicated and dispersed to two chromosomal locations. This analysis suggests that Tbx4 and Tbx5 are cognate genes that diverged apart from a common ancestral gene during early vertebrate evolution.
Chapman, D.L., N. Garvey, S. Hancock, M. Alexiou, S. Agulnik, J.J. Gibson-Brown, J. Cebra-Thomas, R.J. Bollag, L.M. Silver, and V.E. Papaioannou (1996) Expression of T-box family genes, Tbx1-Tbx5, during early mouse development. Dev. Dynam. 206:379-390 A novel family of genes, characterized by the presence of a region of homology to the DNA-binding domain of the Brachyury (T) locus product, has recently been identified. The region of homology has been named the T-box, and the new mouse genes that contain the T-box domain have been named T-box 1-6 (Tbx1 through Tbx6). As the basis for further study of the function and evolution of these genes, we have examined the expression of 5 of these genes, Tbx1-Tbx5, across a wide range of embryonic stages from blastocyst through gastrulation and early organogenesis by in situ hybridization of wholemounts and tissue sections. Tbx3 is expressed earliest, in the inner cell mass of the blastocyst. Four of the genes are expressed in different components of the mesoderm or mesoderm/endoderm during gastrulation (Tbx1 and Tbx3-5). All of these genes have highly specific patterns of expression during later embryogenesis, notably in areas undergoing inductive tissue interactions. In several cases there is complementary expression of different genes in 2 interacting tissues, as in the lung epithelium (Tbx1) and lung mesenchyme (Tbx2-5), and in mammary buds (Tbx3) and mammary stroma (Tbx2). Tbx1 shows very little overlap in the sites of expression with the other 4 genes, in contrast to a striking similarity in expression between members of the 2 cognate gene sets, Tbx2/Tbx3 and Tbx4/Tbx5. This is a clear reflection of the evolutionary relationship between the 5 genes since the divergence of Tbx1 occurred long before the relatively recent divergence of Tbx2 and 3 and Tbx4 and 5 from common ancestral genes. These studies are a good indication that the T-box family of genes has important roles in inductive interactions in many stages of mammalian embryogenesis.
Chapman, D.L., I. Agulnik, S. Hancock, L.M. Silver, and V.E. Papaioannou (1996) Tbx6, a mouse T-box gene implicated in paraxial mesoderm formation at gastrulation. Dev. Biol. 180:534-542 The T-box genes constitute an evolutionarily conserved family of putative transcription factors which are expressed in discrete domains during embryogenesis, suggesting that they may play roles in inductive interactions. Members have been identified by virtue of their homology to the prototypical T-box gene, T or Brachyury, which is required for mesoderm formation and axial elongation during embryogenesis. We have previously reported the discovery of six new mouse T-box genes, Tbx1-Tbx6, and described the expression patterns of Tbx1-Tbx5 (Bollag et al., 1994; Agulnik et al., 1996; Chapman et al., 1996; Gibson-Brown et al., 1996). We have obtained cDNA clones encoding the full-length Tbx6 protein from screens of gastrulation-stage mouse cDNA libraries and determined the spatial and temporal distribution of Tbx6 transcripts during embryogenesis. The gene codes for a 1.9-kb transcript with an open reading frame coding for a 540-amino acid protein, with a predicted molecular weight of 59 kDa. Tbx6 maps to chromosome 7 and does not appear to be linked to any known mutation. Unlike other members of the mouse T-box gene family which are expressed in a wide variety of tissues derived from all germ layers, Tbx6 expression is quite restricted. Tbx6 transcripts are first detected in the gastrulation stage embryo in the primitive streak and newly recruited paraxial mesoderm. Later in development, Tbx6 expression is restricted to presomitic, paraxial mesoderm and to the tail bud, which replaces the streak as the source of mesoderm. Expression in the tail bud persists until 12. 5 days postcoitus. Tbx6 expression thus overlaps that of Brachyury in the primitive streak and tail bud, although Brachyury is expressed earlier in the primitive streak. Brachyury is also expressed in a second domain, the node and notochord, that is not shared with Tbx6. The onset of Tbx6 expression is not affected in homozygous null Brachyury mutant embryos at 7.5 days postcoitus. However, Tbx6 expression is extinguished in mutant embryos as soon as the Brachyury phenotype becomes evident at 8.5 days postcoitus, indicating that the continued expression of Tbx6 is directly or indirectly dependent upon Brachyury expression.
Zeitlin, S., J.P. Liu, D.L. Chapman, V.E. Papaioannou, and A. Efstradiadis (1995) Increased apoptosis and early embryonic lethality in mice nullizygous for the Huntington's disease gene homologue. Nat. Genet. 11:155-163 The expansion of CAG triplet repeats in the translated region of the human HD gene, encoding a protein (huntingtin) of unknown function, is a dominant mutation leading to manifestation of Huntington's disease. Targeted disruption of the homologous mouse gene (Hdh), to examine the normal role of huntingtin, shows that this protein is functionally indispensable, since nullizygous embryos become developmentally retarded and disorganized, and die between days 8.5 and 10.5 of gestation. Based on the observation that the level of the regionalized apoptotic cell death in the embryonic ectoderm, a layer expressing the Hdh gene, is much higher than normal in the null mutants, we propose that huntingtin is involved in processes counterbalancing the operation of an apoptotic pathway. Chapman, D.L., and D.J. Wolgemuth (1994) Expression and function of protein kinases during mammalian gametogenesis. Pp in Advances in Developmental Biochemistry, Volume 3., Wassarman, P.M., Ed. JAI Press, Greenwich, CT Chapman, D.L., and D.J. Wolgemuth (1994) Expression of proliferating cell nuclear antigen in the mouse germ line and surrounding somatic cells suggests both proliferation-dependent and -independent modes of function. Int. J. Dev. Biol. 38:491-497 The distribution of proliferating cell nuclear antigen (PCNA) in specific somatic and germ cells of the adult mouse ovary and testis was assessed using immunocytochemical staining and immunoblot analysis and was correlated with cellular proliferation and differentiation. In the adult ovary, immunocytochemical staining for PCNA within follicular cells varied depending on the stage of follicular growth. Since PCNA staining has proven to be a useful indicator of cells involved in DNA synthesis and repair, the pattern of PCNA staining in the ovary was compared to previous studies which used tritiated thymidine labeling as a marker for DNA synthesis. In the testis, PCNA was detected in the mitotically proliferating spermatogonia, but not in spermatocytes which had just entered meiosis. PCNA staining was again observed in spermatogenic cells in later stages of meiotic prophase, in particular zygotene and pachytene spermatocytes. As these cells are undergoing meiotic recombination, the presence of PCNA in these meiotic prophase cells could reflect a second function of PCNA, that of DNA excision repair. Chapman, D.L., and D.J. Wolgemuth (1994) Regulation of M-phase promoting factor activity during development of mouse male germ cells. Dev. Biol. 165:500-506 While the role of M-phase promoting factor (MPF) in controlling meiosis in oocytes has been well documented, very little is known about its function in male germ cells. Previous studies have localized transcripts for cyclin B1, the regulatory subunit of MPF, in male germ cells, with highest levels in postmeiotic, early round spermatids and much reduced levels in the meiotically dividing pachytene spermatocytes. The present study describes the localization of the regulatory and the catalytic subunits of MPF, CycB1 and Cdc2, respectively, to specific cell types within the testis. Immunoblotting revealed that both CycB1 and Cdc2 were present at highest levels in pachytene spermatocytes, with lower levels observed in the postmeiotic compartment. To assay for MPF activity, kinase complexes were isolated from lysates of testicular cells using p13suc1 agarose and antibodies directed against Cdc2 and CycB1. Activity of these kinase complexes was analyzed using histone H1 as an exogenous substrate. Cdc2 and CycB1-associated kinase activities were localized to the meiotically dividing pachytene spermatocytes, but not to postmeiotic spermatids.
Wolgemuth, D.J., J. Don, and D.L. Chapman (1993) Strategies to identify genes regulating the mitotic and meiotic cell cycles of mammalian germ cells. Pp in Meiosis II: Contemporary Approaches to the Study of Meiosis, Hasetine, F.P., Ed. AAAS Press, Washington, DC Chapman, D.L., and D.J. Wolgemuth (1993) Isolation of the murine cyclin B2 cDNA and characterization of the lineage and temporal specificity of expression of the B1 and B2 cyclins during oogenesis, spermatogenesis and early embryogenesis. Development 118:229-240 A cDNA encoding the murine cyclin B2 (cycB2) was isolated from an adult mouse testis cDNA library as part of studies designed to identify cyclins involved in murine germ cell development. This cycB2 cDNA was then used to examine the pattern of cycB2 expression during male and female germ cell development and in early embryogenesis, and to compare this expression with the previously characterized expression of cycB1. A single 1.7 kb cycB2 transcript was detected by northern blot hybridization analysis of total RNA isolated from midgestation embryos and various adult tissues. Northern blot and in situ hybridization analyses revealed that cycB2 expression in the testis was most abundant in the germ cells, specifically in pachytene spermatocytes. This is in contrast to the highest levels of expression of cycB1 being present in early spermatids. In situ analysis of the ovary revealed cycB2 transcripts in both germ cells and somatic cells, specifically in the oocytes and granulosa cells of growing and mature follicles. The pattern of cycB1 and cycB2 expression in ovulated and fertilized eggs was also examined. While the steady state level of cycB1 and cycB2 signal remained constant in oocytes and ovulated eggs, signal of both appeared to decrease following fertilization. In addition, both cycB1 and cycB2 transcripts were detected in the cells of the inner cell mass and the trophectoderm of the blastocyst. These results demonstrate that there are lineage- and developmental-specific differences in the pattern of the B cyclins in mammalian germ cells, in contrast to the co-expression of B cyclins in the early conceptus.
Wolgemuth, D.J., J. Don, D.L. Chapman, and M.A. Winer (1992) Expression of protooncogenes and protein kinases in the testis. Pp in Molecular, Cellular, and Endocrine Events in Male Reproduction: Spermatogenesis, Fertilization, Contraception, , Ed. Springer-Verlag, Berlin Chapman, D.L., and D.J. Wolgemuth (1992) Identification of a mouse B-type cyclin which exhibits developmentally regulated expression in the germ line. Mol. Reprod. Dev. 33:259-269 To begin to examine the function of cyclins in mammalian germ cells, we have screened an adult mouse testis cDNA library for the presence of B-type cyclins. We have isolated cDNAs that encode a murine B-type cyclin, which has been designated cycB1. cycB1 was shown to be expressed in several adult tissues and in the midgestation mouse embryo. In the adult tissues, the highest levels of cycB1 transcripts were seen in the testis and ovary, which contain germ cells at various stages of differentiation. The major transcripts corresponding to cycB1 are 1.7 and 2.5 kb, with the 1.7 kb species being the predominant testicular transcript and the 2.5 kb species more abundant in the ovary. Examination of cDNAs corresponding to the 2.5 kb and 1.7 kb mRNAs revealed that these transcripts encode identical proteins, differing only in the polyadenylation signal used and therefore in the length of their 3' untranslated regions. Northern blot and in situ hybridization analyses revealed that the predominant sites of cycB1 expression in the testis and ovary were in the germinal compartment, particularly in early round spermatids in the testis and growing oocytes in the ovary. Thus cycB1 is expressed in both meiotic and postmeiotic cells. This pattern of cycB1 expression further suggests that cycB1 may have different functions in the two cell types, only one of which correlates with progression of the cell cycle. |
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