474 resultados para patterning
Resumo:
Lmx1b encodes a LIM-homeodomain transcription factor required for dorso-ventral (D-V) patterning in the mesenchyme of the vertebrate limb. In the absence of Lmx1b function, limbs exhibit a bi-ventral pattern indicating that Lmx1b is required for cells to adopt a dorsal cell fate. However, how Lmx1b specifies dorsal cell fates in the mesenchyme of the distal limb is unknown. Lmx1b is initially expressed throughout the dorsal and ventral limb bud mesenchyme, then becomes dorsally restricted around E10.5. At this stage, there is a sharp boundary between Lmx1b expressing and Lmx1b non-expressing cells. How the dorso-ventral Lmx1b expression boundary is formed and maintained is currently unknown. One mechanism that may contribute to establishing and/or maintaining the Lmx1b expression boundary is if the dorsal mesenchyme is a lineage-based compartment, where different groups of non-mingling cells are separated. Compartment formation has been proposed to rely on compartment-specific selector gene activity which functions to restrict cells to a compartment and specifies the identity of cells within that compartment. Based on the evidence that the dorsal limb identity relies on the expression of Lmx1b in the dorsal half of the limb mesenchyme, we hypothesized that Lmx1b might function as a dorsal limb bud mesenchyme selector gene to set up a dorsal compartment. To test this hypothesis, we developed an inducible CreERT2/ loxP based fate mapping approach that permanently marks Lmx1b wild-type and mutant cells and examined the distribution of their descendents in the developing limb. Our data is the first to show that dorso-ventral lineage compartments exist in the limb bud mesenchyme. Furthermore, Lmx1b is required for maintenance of the dorso-ventral compartment lineage boundary. The behavior of Lmx1b mutant cells that cross into the ventral mesenchyme, as well as previous chimera analysis in which mutant cells spread evenly in the ventral limb and form patches in the dorsal side, suggest that cell affinity differences prevent intermingling of dorsal and ventral cells. ^
Resumo:
Classical ablation studies have shown that neural crest cells (NCC) are critical for thymus organogenesis, though their role in this process has never been determined. We have used a mouse model deficient in NCC near the thymus rudiment to investigate the role of NCC in thymus organogenesis. Splotch mice exhibit a lack of NCC migration due to mutation in the gene encoding the transcription factor Pax 3. Homozygous mutants, designated Pax3Sp/Sp, display a range of phenotypes including spina bifida, cardiac outflow tract deformities, and craniofacial deformities. Pax3Sp/Sp, mice have also been reported to have hypoplastic and abnormal thymi, which is consistent with the expected result based on the classical ablation studies. However, in contrast to the dogma, we find that the thymus lobes in Pax3Sp/Sp, mice are even larger in size than those of littermate controls, although they fail to migrate and are therefore ectopic. Differentiation of the thymic epithelial compartments occurs normally, including the ability to import hematopoietic precursors, until the embryos die at embryonic day E13.0. We also investigated the patterning of the third pharyngeal pouch which gives rise to both the thymus and the parathyroid. Using RNA probes to detect expression of transcription factors exclusively expressed in the ventral, thymus- or dorsal, parathyroidfated domains of the E11.5 third pouch, we show that the parathyroid domain is restricted and the thymus-fated domain is expanded in Pax3Sp/Sp, embryos. Furthermore, mixing of the boundary between these domains occurs at E12.0. These results necessitate reconsideration of the previously accepted role for NCC in thymus organogenesis. NCC are not required for outgrowth of the thymus up to E13.0, and most strikingly, we have discovered a novel role for NCC in establishing parathyroid versus thymus fate boundaries in the third pharyngeal pouch. ^
Resumo:
The Notch signaling pathway plays a central role in metazoan growth and patterning, and its deregulation leads to many human diseases, including cancer. It is therefore important to understand the modes of Notch signaling regulation. Recent discoveries have demonstrated that mutations in conserved endosomal pathway components such as Erupted and Vps25 can ectopically activate Notch signaling in Drosophila. Mutations in the tumor suppressor lethal giant discs (lgd) display similar but even stronger and more specific Notch activation than in the erupted and vps25 mutant animals. This Notch activation in lgd mutant tissues causes hyperplastic overgrowth of the Drosophila imaginal discs, and the eventual lethality of the animal. However, the gene that encodes Lgd, and its function in the Notch pathway have not yet been identified. ^ I have found that Lgd is a novel, conserved C2 domain protein that regulates Notch trafficking. Lgd cell-autonomously restricts Notch signaling in the Drosophila wing disc to the target cells in the D/V boundary. The function of Lgd lies at or upstream of Notch S3 activation, but Lgd doesn't affect the binding affinities between Notch and Delta. Lgd is also not required for cis-inhibition of Notch signaling by ligands. Notch accumulates on the early endosome in lgd mutant cells and signals in a ligand-independent manner, a result that has previously been seen in endosomal pathway mutants. Interestingly, Notch activation in lgd mutant cells is dependent on the endosomal protein Hrs, and Lgd activity appears to be downstream of Hrs function in endocytosis. Taken together, my data identify Lgd as a novel tumor suppressor protein that regulates Notch signaling by targeting Notch for degradation or recycling. ^
Resumo:
Divergence of anterior-posterior (AP) limb pattern and differences in vertebral column morphology are the two main examples of mammalian evolution. The Hox genes (homeobox containing gene) have been implicated in driving evolution of these structures. However, regarding Hox genes, how they contribute to the generation of mammalian morphological diversities, is still unclear. Implementing comparative gene expression and phenotypic rescue studies for different mammalian Hox genes could aid in unraveling this mystery. In the first part of this thesis, the expression pattern of Hoxd13 gene, a key Hox gene in the establishment of the limb AP pattern, was examined in developing limbs of bats and mice. Bat forelimbs exhibit a pronounced asymmetric AP pattern and offer a good model to study the molecular mechanisms that contribute to the variety of mammalian limbs. The data showed that the expression domain of bat Hoxd13 was shifted prior to the asymmetric limb plate expansion, whereas its domain in mice was much more symmetric. This finding reveals a correlation between the divergence of Hoxd13 expression and the AP patterning difference in limb development. The second part of this thesis details a phenotypic rescue approach by human HOXB1-9 transgenes in mice with Hoxb1-9 deletion, The mouse mutants displayed homeosis in cervical and anterior thoracic vertebrae. The human transgenes entirely rescued the mouse mutants, suggesting that these human HOX genes have similar functions to their mouse orthologues in anterior axial skeletal patterning. The anterior expressing human HOXB transgenes such as HOXB1-3 were expressed in the mouse embryonic trunk in a similar manner as their murine orthologues. However, the anterior boundary of human HOXB9 expression domain was more posterior than that of the mouse Hoxb9 by 2-3 somites. These data provide the molecular support for the hypothesis that Hox genes are responsible for maintaining similar anterior axial skeletal architectures cervical and anterior thoracic regions, but different architectures in lumbar and posterior thoracic regions between humans and mice. ^
Resumo:
The underlying genetic defects of a congenital disease Nail-Patella Syndrome are loss-of-function mutations in the LMX1B gene. Lmx1b encodes a LIM-homeodomain transcription factor that is expressed specifically in the dorsal limb bud mesenchyme. Gain- and loss-of-function experiments suggest that Lmx1b is both necessary and sufficient to specify dorsal limb patterning. However, how Lmx1b coordinates patterning of the dorsal tissues in the limb, including muscle, skeleton and connective tissues, remains unknown. One possibility is that each tissue specifies its own pattern cell-autonomously, i.e., Lmx1b is expressed in tissues in which it functions and different tissues do not communicate with each other. Another possibility is that tissues that express Lmx1b interact with adjacent tissues and provide patterning information thereby directing the development of tissues non-cell-autonomously. Previous results showed that Lmx1b is expressed in limb connective tissue and skeleton, but is not expressed in muscle tissue. Moreover, muscles and muscle connective tissue are closely associated during development. Therefore, we hypothesize that Lmx1b controls limb muscle dorsal-ventral (DV) patterning through muscle connective tissue, but regulates skeleton and tendon/ligament development cell-autonomously. ^ To test this hypothesis, we first examined when and where the limb dorsal-ventral asymmetry is established during development. Subsequently, conditional knockout and overexpression experiments were performed to delete or activate Lmx1b in different tissues within the limb. Our results show that deletion of Lmx1b from whole limb mesenchyme results in all dorsal tissues, including muscle, tendon/ligament and skeleton, transforming into ventral structures. Skeleton-specific knockout of Lmx1b led to the dorsal duplication of distal sesamoid and metacarpal bones, but did not affect the pattern formation of other tissues, suggesting that Lmx1b controls skeleton development cell-autonomously. In addition, this skeleton-specific pattern alteration only occurs in distal limb tissues, not proximal limb tissues, indicating different regulatory mechanisms operate along the limb proximal-distal axis. Moreover, skeleton-specific ectopic expression of Lmx1b reveals a complementary skeletal-specific dorsalized phenotype. This result supports a cell-autonomous role for Lmx1b in dorsal-ventral skeletal patterning. This study enriched our understanding of limb development, and the insights from this research may also be applicable for the development of other organs. ^
Resumo:
Cell differentiation and pattern formation are fundamental processes in animal development that are under intense investigation. The mouse retina is a good model to study these processes because it has seven distinct cell types, and three well-laminated nuclear layers that form during embryonic and postnatal life. β-catenin functions as both the nuclear effector for the canonical Wnt pathway and a cell adhesion molecule, and is required for the development of various organs. To study the function of β-catenin in retinal development, I used a Cre-loxP system to conditionally ablate β-catenin in the developing retina. Deletion of β-catenin led to disrupted laminar structure but did not affect the differentiation of any of the seven cell types. Eliminating β-catenin did not reduce progenitor cell proliferation, although enhanced apoptosis was observed. Further analysis showed that disruption of cell adhesion was the major cause of the observed patterning defects. Overexpression of β-catenin during retinal development also disrupted the normal retinal lamination and caused a transdifferentiation of neurons into pigmented cells. The results indicate that β-catenin functions as a cell adhesion molecule but not as a Wnt pathway component during retinal neurogenesis, and is essential for lamination but not cell differentiation. The results further imply that retinal lamination and cell differentiation are genetically separable processes. ^ Sonic hedgehog (shh) is expressed in retinal ganglion cells under the control of transcription factor Pou4f2 during retinal development. Previous studies identified a phylogenetically conserved region in the first intron of shh containing a Pou4f2 binding site. Transgenic reporter mice in which reporter gene expression was driven by this region showed that this element can direct gene expression specifically in the retina, but expression was not limited to the ganglion cells. From these data I hypothesized that this element is required for shh expression in the retina but is not sufficient for specific ganglion cell expression. To further test this hypothesis, I created a conditional allele by flanking this region with two loxP sites. Lines carrying this allele will be crossed with retinal-specific Cre lines to remove this element in the retina. My hypothesis predicts that alteration in shh expression and subsequent retinal defects will occur in the retinas of these mice. ^
Resumo:
Clubfoot is a common, complex birth defect affecting 4,000 newborns in the United States and 135,000 world-wide each year. The clubfoot deformity is characterized by inward and rigid downward displacement of one or both feet, along with persistent calf muscle hypoplasia. Despite strong evidence for a genetic liability, there is a limited understanding of the genetic and environmental factors contributing to the etiology of clubfoot. The studies described in this dissertation were performed to identify variants and/or genes associated with clubfoot. Genome-wide linkage scan performed on ten multiplex clubfoot families identified seven new chromosomal regions that provide new areas to search for clubfoot genes. Troponin C (TNNC2) the strongest candidate gene, located in 20q12-q13.11, is involved in muscle contraction. Exon sequencing of TNNC2 did not identify any novel coding variants. Interrogation of fifteen muscle contraction genes found strong associations with SNPs located in potential regulatory regions of TPM1 (rs4075583 and rs3805965), TPM2 (rs2025126 and rs2145925) and TNNC2 (rs383112 and rs437122). In previous studies, a strong association was found with rs3801776 located in the basal promoter of HOXA9, a gene also involved in muscle development and patterning. Altogether, this data suggests that SNPs located in potential regulatory regions of genes involved in muscle development and function could alter transcription factor binding leading to changes in gene expression. Functional analysis of 3801776/HOXA9, rs2025126/TPM2 and rs2145925/TPM2 showed altered protein binding, which significantly influenced promoter activity. Although the ancestral allele (G) of rs4075583/TPM1 creates a DNA-protein complex, it did not affect TPM1 promoter activity. However and importantly, in the context of a haplotype, rs4075583/G significantly decreased TPM1 promoter activity. These results suggest dysregulation of multiple skeletal muscle genes, TPM1, TPM2, TNNC2 and HOXA9, working in concert may contribute to clubfoot. However, specific allelic combinations involving these four regulatory SNPs did not confer a significantly higher risk for clubfoot. Other combinations of these variants are being evaluated. Moreover, these variants may interact with yet to be discovered variants in other genes to confer a higher clubfoot risk. Collectively, we show novel evidence for the role of skeletal muscle genes in clubfoot indicating that there are multiple genetic factors contributing to this complex birth defect.
Resumo:
The central paradigm linking disadvantaged social status and mental health has been the social stress model (Horwitz, 1999), the assumption being that individuals residing in lower social status groups are subjected to greater levels of stress not experienced by individuals from higher status groups. A further assumption is that such individuals have fewer resources to cope with stress, in turn leading to higher levels of psychological disorder, including depression (Pearlin, 1989). Despite these key assumptions, there is a dearth of literature comparing the social patterning of stress exposure (Hatch & Dohrenwend, 2007; Meyer, Schwartz, & Frost, 2008; Kessler, Mickelson, & Williams, 1999; Turner & Avison, 2003; Turner & Lloyd, 1999; Turner, Wheaton, & Lloyd, 1995), and the distribution and contribution of protective factors, posited to play a role in the low rates of depression found among African- and Latino-Americans (Alegria et al., 2007; Breslau, Aguilar-Gaxiola, Kendler, Su, Williams, & Kessler, 2006; Breslau, Borges, Hagar, Tancredi, Gilman, 2009; Gavin, Walton, Chae, Alegria, Jackson, & Takeuchi, 2010; Williams, & Neighbors, 2006). Thus, this study sought to describe both the distribution and contribution of risk and protective factors in relation to depression among a sample of African-, European-, and Latina-American mothers of adolescents, including testing a hypothesized mechanism through which social support, an important protective factor specific to women and depression, operates. ^ Despite the finding that the levels of depression were not statistically different across all three groups of women, surprising results were found in describing the distribution of both risk and protective factors, in that results reported among all women who were mothers when analyzed masked differences within each ethnic group when SES was assessed, a point made explicit by Williams (2002) regarding racial and ethnic variations in women's health. In the final analysis, while perceived social support was found to partially mediate the effect of social isolation on depression, among African-Americans, the direct effect of social isolation and depression was lower among this group of women, as was the indirect effect of social isolation and perceived social support when compared to European- and Latina-American mothers. Or, put differently, higher levels of social isolation were not found to be as associated with more depression or lower social support among African-American mothers when compared to their European- and Latina-American counterparts. ^ Women in American society occupy a number of roles, i.e., that of being female, married or single, mother, homemaker or employee. In addition, to these roles, ethnicity and SES also come into play, such that the intersection of all these roles and the social contexts that they occupy are equally important and must be taken into consideration when making predictions drawn from the social stress model. Based on these findings, it appears that the assumptions of the social stress model need to be revisited to include the variety of roles that intersect among individuals from differing social groups. More specifically, among women who are mothers and occupy a myriad of other roles, i.e., that of being female, married or single, African- or Latina-American, mother, homemaker or employee, the intersection of all the roles and the social contexts that women occupy are equally important and must be taken into consideration when looking at both the types and distribution of stressors across women. Predictions based on simple, mutually exclusive categories of social groups may lead to erroneous assumptions and misleading results.^
Resumo:
A fundamental task in developmental biology is to understand the molecular mechanisms governing early embryogenesis. The aim of this study was to understand the developmental role of a putative basic helix-loop-helix (b-HLH) transcription factor, twist, during mouse embryogenesis.^ twist was originally identified in Drosophila as one of the zygotic genes, including snail, that were required for dorsal-ventral patterning. In Drosophila embryogenesis, twist is expressed in the cells of the ventral midline destined to form mesoderm. In embryos lacking twist expression, their ventral cells fail to form a ventral furrow and subsequently no mesoderm is formed.^ During mouse embryogenesis, twist is expressed after initial mesoderm formation in both mesoderm and cranial neural crest cell derivatives. To study the role of twist in vivo, twist-null embryos were generated by gene targeting. Embryos homozygous for the twist mutation die at midgestation. The most prominent phenotype in the present study was a failure of the cranial neural tube to close (exencephaly). twist-null embryos also showed defects in head mesenchyme, branchial arches, somites, and limb buds.^ To understand whether twist functions cell-autonomously and to investigate how twist-null cells interact with wild-type cells in vivo, twist chimeras composed of both twist-null and wild-type cells marked by the expression of the lacZgene were generated. Chimeric analysis revealed a correlation between the incidence of exencephaly and the contribution of the underlying twist-null head mesenchyme, thus strongly suggesting that twist-expressing head mesenchyme is required for the closure of the cranial neural tube. These studies have identified twist as a critical regulator for the mesenchymal fate determination within the cranial neural crest lineage. Most strikingly, twist-null head mesenchyme cells were always segregated from wild-type cells, indicating that the twist mutation altered the adhesive specificity of these cells. Furthermore, these results also indicated that twist functions cell-autonomously in the head, arch, and limb mesenchyme but non-cell-autonomously in the somites. Taken together, these studies have established the essential role of twist during mouse embryogenesis. ^
Resumo:
This thesis is centered on applying molecular genetics to study pattern formation during animal development. More specifically, this thesis describes the functional studies of a LIM-homeodomain gene called lmx1b during murine embryogenesis. Lmx1b expression is restricted to the mid-hindbrain junction as well as to the dorsal mesenchyme of the limb, suggesting important functions during mid-hindbrain and limb development. To test these possibilities, lmx1b homozygous mutant mice were generated and their limb and CNS phenotypes examined. Lmx1b homozygous mutant mice exhibit a large reduction of mid-hindbrain structures, and that their limbs are symmetrical along the dorsal-ventral axis as the result of a dorsal to ventral transformation. Taken together, these studies define essential functions for lmx1b in mid-hindbrain patteming and in dorsal limb cell fate determination. However, the molecular mechanisms which accounts for these phenotypes are unknown, and whether lmx1b has same or distinctive functions during the mid-hindbrain and limb development is also unclear. ^ Recently, insight into molecular mechanisms of mid-hindbrain patterning and limb development has resulted from the identification of several factors with restricted expression patterns within these regions. These include the secreted factors wnt-1, fgf-8, wnt-7a and the transcription factors pax-2, and en-1. Targeted disruption of any of these genes in mice suggests that these genes might be involved in similar regulatory pathways. Analysis of the expression of these genes in lmx1b mutants demonstrates that lmxlb is not required for the initiation, but is required to maintain their expression at the mid-hindbrain junction. Thus, lmxlb is not required for specifying mid-hindbrain cell fates, rather, it functions to ensure the establishment or maintenance of a proper organizing center at the mid-hindbrain junction. Interestingly, lmxlb functions cell non-autonomously in chimera analysis, which indicates that lmx1b might regulate the expression of secreted factors such as wnt-1 and/or fgf-8 in the organizing center. In contrast, lmx1b functions cell autonomously in the dorsal limb to govern dorsal ventral limb development and its expression is regulated by with wnt-7a and en-1. However, single and double mutant analysis suggest that all three genes have partially overlapping functions as well as independent functions. The results point toward a complicated network of cross-talks among all three limb axes. ^
Resumo:
One way developing embryos regulate the expression of their genes is by localizing mRNAs to specific subcellular regions. In the oocyte of the frog, Xenopus laevis, many RNAs are localized specifically to the animal or the vegetal halves of the oocyte. The localization of these RNAs contributes to the primary polarity of the oocyte, the asymmetry that is the basis for patterning and lineage specification in the embryo. I have screened a cDNA library for clones containing the Xlsirt repeat, an element known to target RNAs to the vegetal cortex of the oocyte. I have identified seventeen cDNA clones that contain this element. One of these cDNAs encodes the RNA binding protein Hermes. The Hermes mRNA is localized to the vegetal cortex of the oocyte. Additionally, Hermes protein is also vegetally localized in the oocyte and is found in subcellular structures known to contain localized mRNAs. This suggests that Hermes might interact with localized RNAs. While Hermes protein is present in oocytes, it disappears at germinal vesicle breakdown during maturation. We therefore believe that the time period during which Hermes functions is during oogenesis or maturation prior to the time of Hermes degradation. To determine Hermes function, an antisense depletion strategy was used that involved injecting morpholino oligos (HE-MO) into oocytes. Injection of these morpholinos causes the level of Hennes protein to drop prematurely during maturation. Embryos produced from these oocytes exhibit cleavage defects that are most prevalent in the vegetal blastomeres. The phenotype can be partially rescued by injection of a heterologous Hermes mRNA and is therefore specific to Hermes. The Hermes expression and depletion results are consistent with a model in which Hermes interacts with one or more vegetally localized mRNAs in the oocyte and during the early stages of maturation. The interaction is required for cleavage of the vegetal blastomeres. Therefore, it is likely that at least one mRNA that interacts with Hermes is a cell cycle regulator. ^
