Disordered vertebral and rib morphology in pudgy mice. Structural relationships to human scoliosis.

Normal and abnormal vertebral development have been studied over the past 200 years at increasing levels of resolution as techniques for biological investigation have improved. Disordered development of the axial skeleton from the early embryonic period on leads to structurally malformed vertebrae and intervertebral discs and ribs causing the severe deformities of scoliosis, kyphosis, and kyphoscoliosis. Developmental malformation of the axial skeleton therefore has led to considerable biological and clinical interest. This work will detail our studies on the structural deformities of the vertebral column and adjacent ribs in the pudgy mouse [1] caused by mutations in the delta-like 3 (Dll3) gene of the Notch family [2]. While gene abnormalities in the pudgy mouse have been outlined, there has been no in-depth assessment of the histopathology of the pudgy vertebral and rib abnormalities that this study will provide. In addition, although congenital scoliosis has been recognized as a clinical problem since the mid-nineteenth century (1800s) [3] and accurately defined by radiography since the early twentieth century (1900s) [4-6], there have been few detailed histopathologic studies of human cases. We will also relate our histopathologic findings in the pudgy mouse to the histopathology of human vertebral and rib malformations in clinical cases of congenital scoliosis, one of which we defined in detail previously [7].

La modificación genética dirigida en ratones es premiada con el Nobel de Fisiología o Medicina de 2007 / Gene targeting in mice awarded with the 2007 Nobel Prize in Physiology or Medicine

El Premio Nobel de Fisiología o Medicina 2007 ha sido otorgado, merecidamente,a los investigadores norteamericanos Mario Capecchi y Oliver Smithies, yal científico británico Sir Martin Evans, por sus contribuciones pioneras y diseñoexperimental conducentes a la obtención de los primeros ratones mutantes conuna modificación genética dirigida, con la inactivación específica de un gen, dejandointacto el resto del genoma. Martin Evans describió, en 1981, la extraordinariaplasticidad de las células troncales embrionales pluripotentes de la masa internacelular del blastocisto, lo que permitía mantenerlas en cultivo indefinidamente,modificarlas genéticamente y reintroducirlas en un nuevo blastocisto, sin que perdieranla posibilidad de convertirse en cualquiera de los tipos celulares que pueblanun organismo adulto, incluyendo la línea germinal. Mario Capecchi exploró,en los años ochenta, las estrategias que permitieron modificar, de forma selectiva,una determinada secuencia genética mediante el procedimiento de recombinaciónhomóloga y estableció en 1988 el método general de selección doble positiva-negativa.Finalmente, Oliver Smithies, en 1989, fue el primer investigador que integrólas evidencias experimentales de sus dos colegas, modificó un gen (lo inactivó) encélulas troncales embrionales pluripotentes en cultivo, obtuvo después un ratónquimérico y, finalmente, mediante cruces, un animal que, en todas sus células, eraportador de la mutación inicial del gen seleccionado

The Nobel Prize in Physiology or Medicine for 2007 has been awarded jointly,well deserved, to the American scientists Mario Capecchi and Oliver Smithies,and to the British scientist Sir Martin Evans, for their pioneer contributions andexperimental design resulting in the obtention of the first knockout mice with agene targeted event, with the specific inactivation of a gene, leaving the rest of thegenome intact. Martin Evans described, in 1981, the extraordinary plasticity ofpluripotent embryonic stem cells, from the inner cell mass of the blastocyst, thusallowing their maintenance in culture indefinitely, their genetic manipulation and,eventually, their reintroduction in a new blastocyst, without loosing their capacityto differentiate to any of the cellular types found in an adult organism, includingthe germ line. Mario Capecchi explored, in the 80s, the strategies that allowed himto selectively alter a given genetic sequence, using the homologous recombinationprocedure, and established, in 1988, the general method of positive-negative doubleselection. Finally, Oliver Smithies, in 1989, modified a first gene (inactivated) inembryonic stem cells in culture, later obtained a chimera and eventually, througha number of crosses, an animal that, in all of its cells, was carrying the initialmutation of the selected gene

An ENU-induced mutation in the Ankrd11 gene results in an osteopenia-like phenotype in the mouse mutant Yoda.

The mechanisms that regulate bone mass are important in a variety of complex diseases such as osteopenia and osteoporosis. Regulation of bone mass is a polygenic trait and is also influenced by various environmental and lifestyle factors, making analysis of the genetic basis difficult. As an effort toward identifying novel genes involved in regulation of bone mass, N-ethyl-N-nitrosourea (ENU) mutagenesis in mice has been utilized. Here we describe a mouse mutant termed Yoda that was identified in an ENU mutagenesis screen for dominantly acting mutations. Mice heterozygous for the Yoda mutation exhibit craniofacial abnormalities: shortened snouts, wider skulls, and deformed nasal bones, underlined by altered morphology of frontonasal sutures and failure of interfrontal suture to close. A major feature of the mutant is reduced bone mineral density. Homozygosity for the mutation results in embryonic lethality. Positional cloning of the locus identified a missense mutation in a highly conserved region of the ankyrin repeat domain 11 gene (Ankrd11). This gene has not been previously associated with bone metabolism and, thus, identifies a novel genetic regulator of bone homeostasis.

microMRI-HREM pipeline for high-throughput, high-resolution phenotyping of murine embryos.

Rapid and precise phenotyping analysis of large numbers of wild-type and mutant mouse embryos is essential for characterizing the genetic and epigenetic factors regulating embryogenesis. We present a novel methodology that permits precise high-throughput screening of the phenotype of embryos with both targeted and randomly generated mutations. To demonstrate the potential of this methodology we show embryo phenotyping results produced in a large-scale ENU-mutagenesis study. In essence this represents an analysis pipeline, which starts with simultaneous micro-magentic resonance imaging (microMRI) screening (voxel size: 25.4 x 25.4 x 24.4 microm) of 32 embryos in one run. Embryos with an indistinct phenotype are then cut into parts and suspect organs and structures are analysed with HREM (high-resolution episcopic microscopy). HREM is an imaging technique that employs 'positive' eosin staining and episcopic imaging for generating three-dimensional (3D) high-resolution (voxel size: 1.07 x 1.07 x 2 microm) digital data of near histological contrast and quality. The results show that our method guarantees the rapid availability of comprehensive phenotype information for high numbers of embryos in, if necessary, histological quality and detail. The combination of high-throughput microMRI with HREM provides an alternative screening pipeline with advantages over existing 3D phenotype screening methods as well as traditional histology. Thus, the microMRI-HREM phenotype analysis pipeline recommends itself as a routine tool for analysing the phenotype of transgenic and mutant embryos.

Canalization and developmental stability in the Brachyrrhine mouse.

The semi-dominant Br mutation affects presphenoid growth, producing the facial retrognathism and globular neurocranial vault that characterize heterozygotes. We analysed the impact of this mutation on skull shape, comparing heterozygotes to wildtype mice, to determine if the effects are skull-wide or confined to the sphenoid region targeted by the mutation. In addition, we examined patterns of variability of shape for the skull as a whole and for three regions (basicranium, face and neurocranium). We found that the Br mice differed significantly from wildtype mice in skull shape in all three regions as well as in the shape of the skull as a whole. However, the significant increases in variance and fluctuating asymmetry were found only in the basicranium of mutant mice. These results suggest that the mutation has a significant effect on the underlying developmental architecture of the skull, which produces an increase in phenotypic variability that is localized to the anatomical region in which the mean phenotype is most dramatically affected. These results suggest that the same developmental mechanisms that produce the change in phenotypic mean also produce the change in variance.

Raf-1 sets the threshold of Fas sensitivity by modulating Rok-alpha signaling.

Ablation of the Raf-1 protein causes fetal liver apoptosis, embryonic lethality, and selective hypersensitivity to Fas-induced cell death. Furthermore, Raf-1-deficient cells show defective migration as a result of the deregulation of the Rho effector kinase Rok-alpha. In this study, we show that the kinase-independent modulation of Rok-alpha signaling is also the basis of the antiapoptotic function of Raf-1. Fas activation stimulates the formation of Raf-1-Rok-alpha complexes, and Rok-alpha signaling is up-regulated in Raf-1-deficient cells. This leads to increased clustering and membrane expression of Fas, which is rescued both by kinase-dead Raf-1 and by interfering with Rok-alpha or its substrate ezrin. Increased Fas clustering and membrane expression are also evident in the livers of Raf-1-deficient embryos, and genetically reducing Fas expression counteracts fetal liver apoptosis, embryonic lethality, and the apoptotic defects of embryonic fibroblasts. Thus, Raf-1 has an essential function in regulating Fas expression and setting the threshold of Fas sensitivity during embryonic life.

Examination of the Lunatic fringe and Uncx4.1 expression by whole-mount in situ hybridization in the embryo of the CKH-Jsr (jumbled spine and ribs) mouse.

The CKH-Jsr (jumbled spine and ribs) mouse was found as a spontaneous mutant with malformation of vertebrae, that is, a short trunk and kinky tail. We examined Lunatic Fringe (Lfng) and Uncx4.1 expression in the presomitic mesoderm (PSM) and somites of Jsr-mutant (CKH-Jsr/+) embryos to elucidate pathogenesis of the Jsr mutation. Expression pattern of Lfng in the PSM of Jsr-mutant embryos was similar to that of the normal (C57BL/6) embryos. However, expression pattern of Uncx4.1 in the somites of Jsr-mutant embryos was impaired to be irregular and mosaic, suggesting that the anterior-posterior (A-P) polarity is disordered in the Jsr mutant. These results indicate that the Jsr mutation disrupts the A-P polarity of somites during the somitogenesis without altering Lfng expression pattern in the PSM.

The G-netics of dark skin.

Several mutant strains of mice have dark skin pigmentation due to an aberrant accumulation of pigment-producing melanocytes in the dermal layer of the skin. A new study shows that three such strains carry activating mutations in the genes encoding the G-protein subunits Galphaq or Galpha11, resulting in more pigment cell precursors and an excess of dermally retained pigment cells at birth.

Vertebrate floor-plate specification: variations on common themes.

Situated at the ventral-most part of the vertebrate neural tube, the floor plate (FP) is an important signalling centre that controls the regional differentiation of neurons in the nervous system. It secretes guidance molecules that direct ventrally navigating axons crucial for the correct wiring of neuronal circuits. Although the function of the FP is well-conserved from fish to humans, discrepancies exists with respect to both the signalling system involved in FP induction, and the origin of the FP in various vertebrate species. Recent findings from the embryos of zebrafish, chicken and mouse provide insights that reconcile previous results and suggest common themes in vertebrate FP specification.

Frontonasal dysplasia in 3H1 Br/Br mice.

The adult Brachyrrhine (3H1 Br/+) mouse displays severe midfacial retrognathia, with a "pugnose" external appearance, but information concerning craniofacial morphology of the homozygote (3H1 Br/Br) mutant is lacking. This study characterized craniofacial phenotype and genotypic features of the homozygous condition. Segregation analysis was performed by phenotypic scoring of offspring from 3H1 Br/+ reciprocal matings. Whole-mount staining was undertaken to determine the presence or absence of cranial base structures in newborn and adult mice, while features of cranial base chondrification were examined using light microscopy and type II collagen immunohistochemistry. Karyotype analysis was performed to determine whether gross chromosomal aberrations were present. Finally, microsatellite mapping analysis was undertaken to provide further resolution of the Br locus. Results showed that Br was inherited as an autosomal semidominant feature. 3H1 Br/Br mice consistently lacked a presphenoid (with its lateral projections, including a preoptic root, postoptic root, and lesser wing). Karyotyping did not reveal major gross aberrations; however, microsatellite analysis localized Br to distal mouse chromosome 17 in the vicinity of D17Mit155. These results indicated that 3H1 Br/Br mice show characteristic features of frontonasal dysplasia, including median facial clefting and bifid cranium, as well sphenoidal malformations. Furthermore, this mutant should serve as a useful model for examining mechanisms of frontonasal dysplasia.

Early development and degeneration of vestibular hair cells in bronx waltzer mutant mice.

In bronx waltzer mouse mutants, inner hair cells die at an early stage in their development, from around 17.5 days of gestation onwards. In contrast, outer hair cells appear to develop normally. Vestibular hair cells also degenerate, but the earliest signs of vestibular abnormalities have not yet been described. We looked at prenatal and early postnatal stages of vestibular development by scanning electron microscopy in the mutants, and established that vestibular hair cells (types I and II) never reach beyond the middle stages of differentiation (at least up to P2) and instead show signs of degeneration. Thus, it appears that the bronx waltzer gene product is required for the continued survival and differentiation of inner and vestibular hair cells past a set point in their development.

Syk expression in endothelial cells and their morphologic defects in embryonic Syk-deficient mice.

Mice deficient in the Syk tyrosine kinase showed severe petechiae in utero and died shortly after birth. The mechanism of this bleeding, however, remains unknown. Here it is shown that this bleeding is caused by morphologic defects of Syk-deficient endothelial cells during embryogenesis. Immunoblot and reverse transcriptase-polymerase chain reaction Northern blot analysis indicated that Syk is expressed in several endothelial cell lines. Immunocytochemical analysis also confirmed that Syk is expressed in the normal embryonic endothelial cells and is absent in Syk-deficient mice. Furthermore, electron microscopic analysis of Syk-deficient mice revealed an abnormal morphogenesis and a decreased number of endothelial cells. The results indicate a critical role for Syk in endothelial cell function and in maintaining vascular integrity in vivo.

Special considerations in the evaluation of the hematology and hemostasis of mutant mice.

The study of mutant mice with altered or deficient hematopoietic or hemostatic gene products provides a challenge to the researcher, particularly when genetic alterations lead to lethal phenotypes. The following review provides a framework for understanding murine hematopoiesis, based on work with mutant mice, and details experimental approaches used to evaluate these animals. Mice with deficiencies in hemostatic and fibrinolytic system proteins are discussed, and the investigation of their phenotypes is reviewed.

Evidence for intrinsic development of olfactory structures in Pax-6 mutant mice.

It has been reported that the arrival of primary olfactory axons is required to induce the development of the olfactory bulb (OB). On the other hand, the Sey(Neu)/Sey(Neu) mutant mouse (Small eye) has been previously described as a model for the absence of olfactory bulbs, owing to the lack of olfactory epithelium (OE). In the present report, we take advantage of this mutant and study a neural structure in the rostral pole of the telencephalon that phenotypically resembles the prospective OB. We named this formation olfactory bulb-like structure (OBLS). We also report the occurrence, in the mutants, of small epithelial vesicles in the malformed craneofacial pits, resembling an atrophic OE, although a mature olfactory nerve was not identified. Axonal tracing, birthdating, immunohistochemistry, and in situ hybridization using antibodies and probes expressed in the olfactory system, indicated that two distinct structures observed in the OBLS correspond to the main and accessory olfactory bulbs of the control mouse. We propose that the OBLS has developed independently of the external influences exerted by the olfactory nerve. The presence of a prospective OB in the mutants, without intervening olfactory fibers, suggests that intrinsic factors could define brain territories even in absence of the proper afferent innervation. The intrinsic mechanisms and environmental cues in the telencephalon could be sufficient to promote axonogenesis in the projection neurons of the OB and guide their axons in a lateral prospective tract, in the absence of olfactory axons.

Persistent hyperplastic tunica vasculosa lentis and persistent hyperplastic primary vitreous in transgenic line TgN3261Rpw.

Persistent hyperplastic tunica vasculosa lentis and persistent hyperplastic primary vitreous are congenital ocular anomalies that can lead to cataract formation. A line of insertional mutant mice, TgN3261Rpw, generated at the Oak Ridge National Laboratory in a large-scale insertional mutagenesis program was found to have a low incidence (8/243; 3.29%) of multiple developmental ocular abnormalities. The ocular abnormalities include persistent hyperplastic primary vitreous, persistent hyperplastic tunica vasculosa lentis, failure of cleavage of the anterior segment, retrolental fibrovascular membrane, posterior polar cataract, and detached retina. This transgenic mouse line provides an ontogenetic model because of the high degree of similarity of this entity in humans, dogs, and mice.

Embryonic hematopoiesis defect in the tattered-Hokkaido (Tdho) mouse.

BACKGROUND AND PURPOSE: The Tdho allele is an X-linked dominant, embryonic male-lethal mouse mutation that occurs between embryonic day (E) 12.5 and E14.5. The lethal cause and responsible gene have not been identified until now. The cause of lethality in Tdho male embryos was examined with respect to the defect of hematopoiesis. METHODS: Suppression subtractive hybridization and Northern blot analysis were performed on E12.5 male Tdho and normal mouse embryos. In addition, histochemical examinations and blood cell counts of normal and mutant E12.5 embryos were carried out. RESULTS: Diminished expression of embryonic globin genes (zeta and epsilon globins) in the blood of E12.5 Tdho male embryos were documented by use of Northern blot analysis and subtractive hybridization. Increased apoptosis of yolk sac-derived erythrocytes was found in E12.5 Tdho male embryos. Furthermore, diminished numbers of anucleated erythrocytes were observed in E12.5 mutant embryos. CONCLUSIONS: A defect of embryonic hematopoiesis in Tdho mice was suggested as one of the possible causes of embryo lethality.

Pads and flexion creases on the plantar surface of hammertoe mutant mouse (Hm).

The purpose of the present work was to determine the effects of the hereditary malformation of Hammertoe mutant mice (gene symbol Hm) on the surrounding morphological structures and, specifically, on the volar pads, i.e., the sites of the epidermal ridge patterns (dermatoglyphics). The hindlimbs of the wild-type (+/+) Hammertoe mice show no anomalies and their major pad and flexion crease configurations correspond to those of normal mice. The heterozygous (Hm/+) and homozygous (Hm/Hm) mice display a fusion of the interdigital tissues involving all digits with the exception of digit I. In Hm/Hm mice, this webbing extends to the distal phalanx and the markedly flexed digits form a shape resembling a hammer. In Hm/+ mice, the interdigital webbing does not extend as far and the digits show moderate flexion compared to those of Hm/Hm mice. Both Hm/Hm and Hm/+ have a rudimentary extra digit in the postaxial area of the hindlimbs. The ventral volar skin of the flexed digits is incompletely developed. The more posterior digits show the more severe camptodactyly. These aberrant configurations are related to the abnormal occurrence of the programmed cell death (PCD) in the interdigital zones II-IV and the proximal part of the postaxial margin during hindlimb development. They are limited to the pads on the plantar surface of the postaxial area; the preaxial area is not affected. As a result of a severe camptodactyly of digit V, its volar skin is shifted into the distal portion of the hypothenar area. This shifting affects the number, size, and location of the pads, especially of the hypothenar pad, resulting in varying pad configurations, such as a displacement of the distal and proximal components of the hypothenar pad, or a fusion of the two components of the hypothenar pad, leading to a reduced final pad number. These pad modifications are induced by the postaxial plantar surface shifting proximally and are not affected by the presence of an extra rudimentary digit. The pad modifications in Hammertoe mice with webbed digits and postaxial polydactyly resemble closely those of the previously studied mice with genetic preaxial polydactyly.

Genetic analysis of the exed region in mouse.

The extraembryonic ectoderm development (exed) mutant phenotype was described in mice homozygous for the c(6H) deletion, a radiation-induced deletion in the tyrosinase region of mouse Chromosome 7. These mutants fail to gastrulate and die around embryonic day 8.0. Several genes including, for example, embryonic ectoderm development (eed), are deleted in the c(6H) mutants; however, the portion of the chromosome responsible for the more severe exed phenotype is localized to a 20-kb region called the "exed-critical region." To understand the genetics behind the exed phenotype, we analyzed this region in two ways. First, to determine whether the 20-kb exed-critical region alone causes the mutant phenotype, we removed it from a wild-type chromosome. The resulting mice homozygous for this deletion were viable and fertile, indicating that the 20-kb exed-critical region by itself is not sufficient to cause the phenotype when deleted. We then sequenced the 20-kb exed-critical region and no expressed exons were found. Several short matches to GenBank Expressed Sequence Tag (EST) databases were identified; however, none of these ESTs mapped to the region. Taken together, these results indicate that the exed phenotype may either be a position effect on a distal gene caused by the c(6H) breakpoint or the result of composite effects of nullizygosity of multiple genes in the deletion homozygotes.

Targeted disruption of mouse Yin Yang 1 transcription factor results in peri-implantation lethality.

Yin Yang 1 (YY1) is a zinc finger-containing transcription factor and a target of viral oncoproteins. To determine the biological role of YY1 in mammalian development, we generated mice deficient for YY1 by gene targeting. Homozygosity for the mutated YY1 allele results in embryonic lethality in the mouse. YY1 mutants undergo implantation and induce uterine decidualization but rapidly degenerate around the time of implantation. A subset of YY1 heterozygote embryos are developmentally retarded and exhibit neurulation defects, suggesting that YY1 may have additional roles during later stages of mouse embryogenesis. Our studies demonstrate an essential function for YY1 in the development of the mouse embryo.