Mechanics and spiral formation in the rat cornea.

During the maturation of some mammals such as mice and rats, corneal epithelial cells tend to develop into patterns such as spirals over time. A better understanding of these patterns can help to understand how the organ develops and may give insight into some of the diseases affecting corneal development. In this paper, a framework for explaining the development of the epithelial cells forming spiral patterns due to the effect of tensile and shear strains is proposed. Using chimeric animals, made by combining embryonic cells from genetically distinguishable strains, we can observe the development of patterns in the cornea. Aggregates of cell progeny from one strain or the other called patches form as organs and tissue develop. The boundaries of these patches are fitted with logarithmic spirals on confocal images of adult rat corneas. To compare with observed patterns, we develop a three-dimensional large strain finite element model for the rat cornea under intraocular pressure to examine the strain distribution on the cornea surface. The model includes the effects of oriented and dispersed fibrils families throughout the cornea and a nearly incompressible matrix. Tracing the directions of critical strain vectors on the cornea surface leads to spiral-like curves that are compared to the observed logarithmic spirals. Good agreement between the observed and numerical curves supports the proposed assumption that shear and tensile strains facilitate sliding of epithelial cells to develop spiral patterns.

GLI1 localization in the germinal epithelial cells alternates between cytoplasm and nucleus: upregulation in transgenic mice blocks spermatogenesis in pachytene.

The zinc finger transcription factor GLI1 is the mediator of signaling by members of the Hedgehog (Hh) family. Male mice in which Desert hedgehog (Dhh), an Hh homologue expressed in Sertoli cells of the testis, was knocked out are sterile, suggesting that the Dhh/GLI1 pathway plays a role in spermatogenesis. Using an antiserum raised against human GLI1, we found that during the first round of spermatogenesis, GLI1 expression is initially cytoplasmic, then shifts to the nuclei of Sertoli and germ cells, and finally shifts back to the cytoplasm. In the adult mouse testis, GLI1 expression localized to the nuclei of germ cells, beginning with pachytene cells and persisting through round spermatids. Localization of GLI1 in elongating spermatids shifted from the nucleus to the cytoplasm and became associated with microtubules. We also examined a line of transgenic mice that overexpressed human GLI1. Male mice in this line were sterile. Spermatogenesis was blocked at the pachytene stage, and a subset of the morphologically indistinguishable pachytene cells underwent apoptosis. Patched-2, which is a Dhh receptor, and Fused, another component of the signal transduction pathway, are expressed in Leydig cells and in primary and secondary spermatocytes. Expression of GLI1 in the same cell types as Patched-2 and Fused and the disruption of spermatogenesis by GLI1 overexpression suggest that GLI1 is the mediator of the Dhh signal in the testis, and that it may be a regulator of spermatogenesis.

Nodal regulates trophoblast differentiation and placental development.

Nodal has been thought to be an embryo-specific factor that regulates development, but nodal is also expressed in the mouse placenta beginning at midgestation, specifically in the spongiotrophoblasts. In an insertional null nodal mutant, not only is embryonic development disrupted, but mouse placental development is also grossly altered with the loss of the diploid spongiotrophoblasts and labyrinth and an expansion of the polyploid giant cell layer. A hypomorphic mutation in nodal results in an expansion of the giant cell and spongiotrophoblast layers, and a decrease in labyrinthine development. Expression of nodal in trophoblast cell cultures is sufficient to inhibit trophoblast giant cell differentiation, demonstrating that nodal can act directly on trophoblasts. The mechanism of nodal action includes the inhibition of junB gene transcription. These results suggest that nodal may be involved in redirecting trophoblast fate towards the midgestational expansion of the labyrinth region while maintaining the thin layer of trophoblast giant cells and the underlying layer of spongiotrophoblasts that form the boundary between the maternal and extraembryonic compartments.

Developmental pathways: Sonic hedgehog-Patched-GLI.

Developmental pathways are networks of genes that act coordinately to establish the body plan. Disruptions of genes in one pathway can have effects in related pathways and may result in serious dysmorphogenesis or cancer. Environmental exposures can be associated with poor pregnancy outcomes, including dysmorphic offspring or children with a variety of diseases. An important goal of environmental science should be reduction of these poor outcomes. This will require an understanding of the genes affected by specific exposures and the consequence of alterations in these genes or their products, which in turn will require an understanding of the pathways critical in development. The ligand Sonic hedgehog, the receptors Patched and Smoothened, and the GLI family of transcription factors represent one such pathway. This pathway illustrates several operating principles important in the consideration of developmental consequences of environmental exposures to toxins.

Expression of lymphomagenic oncogenes in T-cell lymphomas of HPV 16 transgenic mice.

We have previously established that a dimer repeat of the complete HPV 16 genome is sufficient to cause multiple organ malignancies, either carcinomas or T-cell lymphomas, in transgenic mice. Here, we report the expression of oncogenes supporting the notion that these tumors arose via multiple oncogenic pathways. In these mice, the transgenic HPV 16 genome cosegregated with the tumor phenotype. E6/E7 expression was observed in both carcinomas and T-cell lymphomas, while E2 expression was observed only in T-cell lymphomas. Some of the T-cell lymphomas revealed E2 expression alone, implying that oncogenic pathways of HPV other than the one involving E6/E7 existed in these transgenic mice. To establish that this is the case, expression of genes downstream from E6/E7 and oncogenes involved in T-cell lymphoma formation were analyzed. p53 mutations were observed in two of five tumors that lacked E6 expression. High levels of c-myc gene expression were observed in five of six tumors with E7 expression, suggesting that a pathway involving E7, inactivation of Rb, and activation of c-myc is important in tumorigenesis of HPV 16 in these transgenic animals. High levels of expression of the c-Pim gene were also noted in two of three c-myc-expressing T-cell lymphomas, suggesting cooperation between these two proto-oncogenes. Activation of Hox-11, Tal2/SCL-2, and Rbtn1/Ttg1 expression, which are highly associated with human T-cell acute lymphoblastic leukemia (T-ALL), was observed in three of three T-cell lymphomas with E2 expression but not E6/E7 expression, showing that pathways to tumor formation not involving E6/E7 exist in these transgenic animals. At least two oncogenic pathways to tumors in HPV 16 transgenic mice exist, one involving E6/E7 and c-myc and the other involving E2 and lymphomagenic oncogenes.

Characterization of the promoter region and genomic organization of GLI, a member of the Sonic hedgehog-Patched signaling pathway.

GLI is the prototype for the Gli-Kruppel gene family characterized by a consensus C2-H2 zinc finger domain and is believed to function as a transcription activator in the vertebrate Sonic hedgehog-Patched signal transduction pathway. Understanding GLI gene regulation may be of importance to understanding causes of human birth defects and cancer. To begin to understand the regulation of this developmentally important gene we have cloned the human GLI gene and functionally characterized its 5' flanking region. The GLI gene is composed of 12 exons and 11 introns and in the zinc finger coding region shares a highly conserved splicing pattern with several other Gli family members in both vertebrates and C. elegans. A major transcription initiation site was identified upstream of the GLI translation start site along with three minor transcription initiation sites. The region surrounding the transcription initiation sites lacks TATA and CCAAT consensus sequences, has a high GC content, includes a CpG island, and contains several GC boxes. A 487bp segment surrounding the transcription initiation sites increased expression of a luciferase reporter gene 15-fold in Tera-1 cells and was defined as the core promoter region of human GLI. In transgenic mice this region directed beta-galactosidase expression to the central nervous system on embryonic days 10.5-12.5 and to sites of endochondral ossification on embryonic days 12.5 and 13.5 in a pattern comparable to the endogenous expression pattern of mouse gli within these tissues. The previously identified gastrointestinal expression of gli was not driven by this region and may require elements outside of the core promoter. Sequence analysis of the 5' flanking region of the mouse gli gene and the full-length mouse gli cDNA demonstrated high homology with human GLI, suggesting conservation of GLI regulation and function.

GLI activates transcription through a herpes simplex viral protein 16-like activation domain.

Three proteins have been identified in mammals, GLI, GLI2, and GLI3, which share a highly conserved zinc finger domain with Drosophila Cubitus interruptus and are believed to function as transcription factors in the vertebrate Sonic hedgehog-Patched signaling pathway. To understand the role GLI plays in the Sonic hedgehog-Patched pathway and mechanisms of GLI-induced transcriptional regulation, we have characterized its transcriptional regulatory properties and contributions of specific domains to transcriptional regulation. We have demonstrated that GLI activates expression of reporter constructs in HeLa cells in a concentration-dependent manner through the GLI consensus binding motif and that a GAL4 binding domain-GLI fusion protein activates reporter expression through the GAL4 DNA binding site. GLI-induced transcriptional activation requires the carboxyl-terminal amino acids 1020-1091, which includes an 18-amino acid region highly similar to the alpha-helical herpes simplex viral protein 16 activation domain, including the consensus recognition element for the human TFIID TATA box-binding protein-associated factor TAFII31 and conservation of all three amino acid residues believed to contact directly chemically complementary residues in TAFII31. The presence of this region in the GLI activation domain provides a mechanism for GLI-induced transcriptional regulation.

Cloning and developmental expression of the murine homolog of the acute leukemia proto-oncogene AF4.

AF4 is the 4q21 gene involved in the acute lymphoblastic leukemia associated t(4;11)(q21;q23) where it forms a fusion gene with MLL. In order to gain insight into AF4's role in leukemogenesis we have studied its functional domains and expression pattern during murine development. We have cloned the murine homolog, Af4. We have demonstrated that 5' half of Af4 encodes a region with transcriptional transactivation activity which is disrupted by the t(4;11) in human leukemias. We have also localized the murine AF4 protein to the nucleus supporting a role for AF4 in transcription. The developmental expression pattern of Af4 was determined in situ hybridization and suggests Af4 plays an important role in the development of the hematopoietic, cardiovascular, skeletal and central nervous systems. A repeating pattern of Af4 expression in development is down-regulation with differentiation of a tissue. Among the cell types where this pattern of down-regulation is noted are B-lymphocytes. These findings raise the possibility that the disruption of normal AF4 function by the translocation may contribute to leukemogenesis.

Conservation of the C.elegans tra-2 3'UTR translational control.

The Caenorhabditis elegans sex-determination gene, tra-2, is translationally regulated by two 28 nt elements (DREs) located in the 3'UTR that bind a factor called DRF. This regulation requires the laf-1 gene activity. We demonstrate that the nematode Caenorhabditis briggsae tra-2 gene and the human oncogene GLI are translationally regulated by elements that are functionally equivalent to DREs. Here, we rename the DREs to TGEs (tra-2 and GLI elements). Similarly to the C.elegans tra-2 TGEs, the C.briggsae tra-2 and GLI TGEs repress translation of a reporter transgene in a laf-1 dependent manner. Furthermore, they regulate poly(A) tail length and bind DRF. We also find that the C.elegans TGEs control translation and poly(A) tail length in C.briggsae and rodent cells. Moreover, these same organisms contain a factor that specifically associates with the C.elegans TGEs. These findings are consistent with the TGE control being present in C.briggsae and rodent cells. Three lines of evidence indicate that C.briggsae tra-2 and GLI are translationally controlled in vivo by TGEs. First, like C.elegans tra-2 TGEs, the C.briggsae tra-2 and GLI TGEs control translation and poly(A) tail lengths in C.briggsae and rodent cells, respectively. Second, the same factor in C.briggsae and mammalian cells that binds to the C.elegans tra-2 TGEs binds the C.briggsae tra-2 and GLI TGEs. Third, deletion of the GLI TGE increases GLI's ability to transform cells. These findings suggest that TGE control is conserved and regulates the expression of other mRNAs.

Transgenic technology: an overview of approaches useful in surgical research.

Advances in transgenic science have created powerful tools for the investigation of both genetic and protein regulatory systems. Recently, transgenic animals have been utilized in several vascular and transplantation research laboratories. The ability to specifically mutate genes important in oncologic and cardiovascular research is leading to a greater understanding of the role of gene and protein regulatory systems in cancer and cardiovascular disease. The expanding use of transgenic animals will undoubtedly increase our insight into complex problems in surgical research. This review briefly describes the various techniques utilized to create transgenic animals including: transgene design, gene-transfer utilizing transfection, microinjection and retroviral infection, as well as the use of embryonic stem cells, and methods for screening transgenic offspring.

Expression of human GLI in mice results in failure to thrive, early death, and patchy Hirschsprung-like gastrointestinal dilatation.

BACKGROUND: GLI is an oncodevelopmental gene in the vertebrate hedgehog/patched signaling pathway that is spatiotemporally regulated during development and is amplified in a subset of human cancers. GLI is the prototype for the Gli-Kruppel family of transcription factors, which includes the Drosophila segment polarity gene ci, the C. elegans sex-determining gene tra-1, and human and mouse GLI3, all of which contain a conserved domain of five C2-H2 zinc fingers. GLI3 mutations have been implicated in the mouse mutant extra toes, as well as in human Greig cephalopolydactaly syndrome and the autosomal dominant form of Pallister-Hall syndrome. As such, GLI and the vertebrate hedgehog/patched signaling pathway appear to play important roles in both normal development and neoplasia. MATERIALS AND METHODS: Since it is not known whether aberrant GLI expression is similarly linked to developmental disorders, we developed gain-of-function transgenic mice which express human GLI ectopically. RESULTS: Affected transgenic mice exhibit a phenotype of failure to thrive, early death, and Hirschsprung-like patches of gastrointestinal dilatation. The colons of affected mice have greatly attenuated smooth muscle layers and abnormal overlying epithelium. The density of myenteric plexuses is reduced in the colonic walls. The severity of the phenotype is related to the level of transgene expression. CONCLUSIONS: The transgenic mouse model supports a role for GLI in gastrointestinal development. As part of the vertebrate hedgehog/patched signaling pathway, GLI is essential to mesoderm and CNS ectoderm development and transgenic GLI expression affects neuronal, muscular, and epithelial cell differentiation in the gut. Expression of human GLI in mice results in impairment of enteric neuronal development and a Hirschsprung-like phenotype.

The HPV 16 genome induces carcinomas and T-cell lymphomas in transgenic mice.

Human papillomavirus type 16 is highly associated with cervical carcinoma. Here we report families of transgenic mice produced by the microinjection of a dimer repeat sequence of the human papillomavirus type 16 genome. Thirty-two transgenic animals in four families developed multiple organ malignancies that appeared in middle age without other intervention. The tumor phenotype of poorly differentiated carcinomas or malignant lymphomas and the transgene cosegregate in these lineages. The tumors arise in the subcutaneous compartment, thoracic cavity, or abdomen; are widely metastatic; and grow rapidly in nude mice. No cervical lesions were identified in six females examined. No rearrangements in transgene E6/E7, E2, and E1 regions were found in tumor tissues, and the truncated E2 region, which was thought to play an important role in human cervical carcinogenesis, was not needed for tumorigenesis in these animals. The transgenic mice produce RNA from the E6/E7 open reading frames, which has been identified in both the carcinomas and the lymphomas, but RNA from the E2 open reading frame is present only in malignant T-cell lymphomas and not in carcinomas, hyperplastic lymphoid tissue, or normal lymphoid tissue.

Overexpression of human glutathione S-transferase pi protects NIH 3T3 cells against (+/-)anti BPDE cytotoxicity but not tumor formation.

In order to explore the protective function of human glutathione S-transferase pi (GST-pi) in vitro and in vivo, transfected NIH 3T3 clones were examined in cytotoxicity assays using the carcinogen (+/-)anti-benzo(a)pyrene 7,8-diol-9,10-epoxide (BPDE) or inoculated into nude mice and treated with the carcinogen benzo(a)pyrene (BP) to induce tumor formation. The human GST-pi cDNA under the control of the murine alpha 2(I)collagen promoter was transfected into NIH 3T3 cells and G418 resistant clones were analyzed by Southern, northern, western, and two-dimensional analysis. Clone A2 stably expressed human GST-pi and has 2.5-fold greater activity toward the substrate 1-chloro-2,4-dinitrobenzene and a 1.7-fold increase in LD50 for BPDE in vitro when compared to control-transfected clone G3. This increase in protection, however, did not prevent the formation of BP-induced tumors in vivo.

An upstream region of the enoyl-coenzyme A hydratase/3-hydroxyacyl-coenzyme A dehydrogenase gene directs luciferase expression in liver in response to peroxisome proliferators in transgenic mice.

Peroxisome proliferators, which are structurally diverse nonmutagenic agents, induce hepatocarcinogenesis in rats and mice. Exposure to these xenobiotics leads to a rapid and coordinated transcriptional activation of the genes for the peroxisomal beta-oxidation enzyme system pathway in the liver. We have previously identified a peroxisome proliferator-responsive element in the 5'-flanking region of the rat peroxisomal hydratase/dehydrogenase (PBE) gene, the second enzyme in the beta-oxidation pathway. The peroxisome proliferator-responsive element in the PBE gene was shown to direct the induction of a luciferase reporter gene in vitro. We have now used this 3.2-kilobase 5'-flanking region of the PBE gene fused to the coding region of luciferase to generate transgenic mice. Three independent lines of transgenic mice expressed luciferase in response to ciprofibrate, a peroxisome proliferator. The induction of luciferase is specific to the liver; this agrees with the tissue-specific induction of PBE. Two other hypolipidemic drugs, nafenopin and Wy-14,643, were also capable of inducing luciferase activity in the liver. This study suggests that the PBE upstream element can be used to direct and modulate the expression of cloned genes by changing the levels of peroxisome proliferators. Also, the PBE-luciferase transgenic mouse should be an excellent model system for screening xenobiotics for potential peroxisome proliferator property.

Pluripotent embryonic stem cells from the rat are capable of producing chimeras.

Embryonic stem cells have been enormously important in the production of targeted mutations in mice used in the study of gene function and biological aspects of disease states. The use of these cells for mouse studies is now wide-spread but the production of animals from similar cell lines derived from other species has not been previously reported. We demonstrate here the derivation of diploid rat embryonic stem cells (RESC-01). RESC-01 cells are SSEA-1 and alkaline phosphatase positive, grow best on primary rat embryonic fibroblasts, and can differentiate extensively in vivo. RESC-01 cells form cystic embryoid bodies capable of rhythmic contractions. Rat blastocysts injected with RESC-01 cells form chimeras. The results indicate that the successful in vitro propagation and chimera production with embryonic stem cells is not limited to the mouse. The long-term culture of rat ES cells will provide an important resource for the study of normal physiology and disease models where rat is the species of choice.

Exploring pathogenetic mechanisms using transgenic animals.

Molecular technologies for the permanent germ-line transformation of animals are now well established and routine. These new strains of animals, called transgenic, offer an unprecedented opportunity to gain a basic understanding of human genetic disorders. In this brief review we discuss the role of transgenic animals in the creation of new models of human disease and their experimental use in biomedical research. Models are now available for the study of the genetic processes involved in the pathogenesis of neoplasia, diabetes, atherosclerosis, and developmental abnormalities. Many others are available and new ones are being produced at a great rate. Principles of gene replacement therapy are amenable to analysis with transgenic animals and the information gained will be important for the development of rational therapy.

gli, a zinc finger transcription factor and oncogene, is expressed during normal mouse development.

The oncogene GLI is amplified and expressed in some cases of human malignant glioma and undifferentiated childhood sarcoma and is the prototype for a gene family characterized by a highly conserved set of five tandem zinc fingers and a consensus cysteine-histidine link. This zinc finger motif has been shown to bind DNA with sequence specificity and may mediate transcriptional regulation. Since GLI is expressed in embryonal carcinoma cell lines but not in most normal adult tissues and shows significant sequence similarity within its zinc finger domain to cubitus interruptus dominant (ciD), a Drosophila segmentation gene known to be important in the morphogenesis of the posterior portion of each larval segment, we established the temporal and tissue expression patterns of the mouse homologue of human GLI in day 10 through 18 mouse embryos with Northern blotting, reverse transcriptase coupled PCR, and in situ hybridization. gli transcripts were demonstrated on days 10 through 18 of mouse embryonic development as well as in normal adult uterus, brain, testis, and limb. Tissue expression of gli during gestation was demonstrated in Meckel's precartilage mesenchyme, the basis occipitus, rib mesenchymal condensations, primordial vertebral bodies, digital mesenchymal condensations in forefoot and hindfoot plates, the ependymal layer of the spinal cord, and the mesoderm of the gastrointestinal tract. Expression persisted throughout gestation in developing bone and cartilage of the extremities, the ribs, and the vertebral bodies, as well as the gastrointestinal tract mesoderm. These findings support a role for gli family genes in normal craniofacial and digital development in mammals first suggested by the demonstration of translocation breakpoints within the GLI3 gene in families with the Greig cephalopolysyndactylyl syndrome and subsequently by reduced gli3 expression in the mouse mutant extra toes. It is surprising that a single gene would be expressed in such a wide range of mesenchymal structures.

Distribution of expression of cell adhesion molecules in the mid to late gestational mouse fetus.

The control of murine morphogenesis appears to be regulated in part by the expression of the primary cell adhesion molecules, such as the neural cell adhesion molecules (N-CAM). Here we show that the epithelial cell adhesion molecules appear in intestinal epithelium, liver and cartilage, but were absent from intestinal submucosa and neural tissues. N-CAMs on the other hand were present in intestinal submucosa and neural tissues, but absent from intestinal epithelium, liver, and cartilage. Both epithelial cell adhesion molecules and N-CAM were present in intestinal primordium at gestation times (days 12 and 13) when intestinal epithelium and submucosa are not morphologically distinguishable. On day 14 of gestation, when the intestinal epithelium and submucosa are morphologically distinguishable, epithelial cell adhesion molecules are present in intestinal epithelium but not submucosa while N-CAM has the reciprocal pattern of expression. Immunoblots with antibodies to N-CAM revealed two bands of 110-220 and 60 kD which followed specific patterns of expression. As defined by densitometry, the intensity of the larger protein increased from day 12 to 18 in neural tissue groups, but diminished in late gestational intestine and intact fetus and was replaced by a more discrete region of 110-150 kD, suggesting that embryonic to adult conversion of isoform ('E to A conversion') had occurred at this nonneural site.