Alexandra L. Joyner

Mammalian achaete-scute homolog 1 is required for the early development of olfactory and autonomic neurons

The mouse Mash-1 gene, like its Drosophila homologs of the achaete-scute complex (AS-C), encodes a transcription factor expressed in neural precursors. We created a null allele of this gene by homologous recombination in embryonic stem cells. Mice homozygous for the mutation die at birth with apparent breathing and feeding defects. The brain and spinal cord of the mutants appear normal, but their olfactory epithelium and sympathetic, parasympathetic, and enteric ganglia are severely affected. In the olfactory epithelium, neuronal progenitors die at an early stage, whereas the nonneuronal supporting cells are present. In sympathetic ganglia, the mutation arrests the development of neuronal precursors, preventing the generation of sympathetic neurons, but does not affect glial precursor cells. These observations suggest that Mash-1, like its Drosophila homologs of the AS-C, controls a basic operation in development of neuronal progenitors in distinct neural lineages.

Targeted disruption of the trkB neurotrophin receptor gene results in nervous system lesions and neonatal death

We have generated mice carrying a germline mutation in the tyrosine kinase catalytic domain of the trkB gene. This mutation eliminates expression of gp145trkB, a protein-tyrosine kinase that serves as the signaling receptor for two members of the nerve growth factor family of neurotrophins, brain-derived neurotrophic factor and neurotrophin-4. Mice homozygous for this mutation, trkBTK(-/-), develop to birth. However, these animals do not display feeding activity, and most die by P1. Neuroanatomical examination of trkBTK (-/-) mice revealed neuronal deficiencies in the central (facial motor nucleus and spinal cord) and peripheral (trigeminal and dorsal root ganglia) nervous systems. These findings illustrate the role of the gp145trkB protein-tyrosine kinase receptor in the ontogeny of the mammalian nervous system.

Dynamic expression of the murine Achaete-Scute homologue Mash-1 in the developing nervous system☆

The Drosophila Achaete-Scute Complex genes encode transcriptional regulators belonging to the basic-helix-loop-helix family which control early steps of development of the central and peripheral nervous systems. We have isolated two mouse homologues of Achaete-Scute Complex genes, Mash-1 and Mash-2, by using the conservation of the basic-helix-loop-helix domain in this family. In this article, we analyse the expression of Mash-1 from its onset during neurulation to adult stages by RNA in situ hybridization on whole mounts and sections. As was observed for the rat Mash-1 protein, mouse Mash-1 RNA expression is restricted to cells of the developing central and peripheral nervous systems. We have observed three successive phases in the distribution of Mash-1 transcripts in the developing central nervous system. Initially, between embryonic day 8.5 and 10.5, Mash-1 transcripts are found in restricted domains in the neuroepithelium of the midbrain and ventral forebrain, as well as in the spinal cord. Between embryonic day 10.5 and 12.5, Mash-1 expression pattern changes from a restricted to a widespread one. Mash-1 transcripts are then found at variable levels in the ventricular zone in all regions of the brain. From embryonic day 12.5 to post-natal stages, Mash-1 is also expressed in cells outside of the ventricular zone throughout the brain. In addition, Mash-1 is expressed during development of the olfactory epithelium and neural retina. Overall, its expression pattern suggest that Mash-1 plays a role at early stages of development of specific neural lineages in most regions of the central nervous system and of several lineages in the peripheral nervous system. We have also compared the expression of Mash-1 and mouse Notch because their Drosophila homologues have been shown to interact genetically. The two genes show very similar expression patterns, both spatially and temporally, in the early developing brain and in the retina, suggesting that both genes may participate in the development of the same neural lineages.

A targeted mutation reveals a role for N-myc in branching morphogenesis in the embryonic mouse lung.

The N-myc proto-oncogene encodes a putative transcription factor that has been postulated to be involved in the control of differentiation in a number of lineages at various stages during mammalian embryogenesis. We have generated a leaky mutation in N-myc by gene targeting in embryonic stem cells. In this allele, the neo(r) gene was inserted into the first intron of N-myc, in such a way that alternative splicing around this insertion could result in the generation of a normal N-myc transcript in addition to a mutant transcript. Mice homozygous for this mutation died immediately after birth owing to an inability to oxygenate their blood. Histological examination revealed a marked underdevelopment in the lung airway epithelium, resulting in a decreased respiratory surface area. Analysis of N-myc expression in wild-type and homozygous mutant embryonic lungs suggests that N-myc is required for the proliferation of the lung epithelium in response to local inductive signals emanating from the lung mesenchyme. Homozygous mutant embryos were slightly smaller than normal and also had a marked reduction in spleen size, whereas other tissues that normally express N-myc appeared to be unaffected by the mutation. Molecular analysis revealed that normal N-myc transcripts were found in tissues from homozygous mutant embryos. Different tissues expressed the normal N-myc transcript at different levels relative to those observed in wild-type embryos, with the lowest levels being observed in the lungs. These results illustrate one way in which gene targeting can be used to generate partial loss-of-function mutations and support the importance of generating a series of alleles at a given locus to elucidate the various different functions of a gene during development.

Towards a molecular-genetic analysis of mammalian development

The mouse has been a slower starter than many other organisms in the race to unravel the genetic control of embryonic development. Recent cloning of putative developmental genes combined with new approaches to manipulating the mouse genome seem set, however, to allow the mammalian embryo to move towards the front of the field.

Chromosomal localization of the human homeo box-containing genes, EN1 and EN2

The human homologs of the mouse homeo box-containing genes, En-1 and En-2, which show homology to the Drosophila engrailed gene, have been isolated. The human EN1 gene was mapped to chromosome 2 by analysis of mouse-human somatic cell hybrids. The human EN2 gene was localized to chromosome 7, 7q32-7qter, by analysis of rodent-human somatic cell hybrids and cell lines carrying portions of chromosome 7.

Gene targeting and development of the nervous system

Gene targeting provides a means of directly assaying the function of specific genes during mouse nervous system development. Generation of targeted mutant mice has provided the first evidence of developmental roles for genes whose function was suggested based on their expression, but for which appropriate assay systems were lacking. In other cases, where gene function was known, targeted mutations have revealed in which cell population, and at what developmental stage, particular genes are first indispensable. The existing targeted mutants suggest that an early mechanism of pattern formation in mammals involves regional control of proliferation or survival of neural precursors, and that later general functions, such as the control of differentiation of precursors, may be performed by different genes in distinct neural lineages. As many genes display complex temporal and spatial patterns of expression, analysis of the full range of functions of such genes will require the generation of a series of alleles, including stage- and tissue-specific mutations.

The Engrailed-2 homeobox gene and patterning of spinocerebellar mossy fiber afferents

The mouse Engrailed-2 gene, En-2, appears to be involved in cerebellar pattern formation. Homozygous null mutants for En-2 have abnormal foliation patterns in the posterior half of the cerebellum and there are changes in Purkinje and granule cell gene expression in some posterior folia, possibly reflecting changes in cell identity. We have examined the distribution of spinocerebellar mossy fiber terminals in homozygous En-2hd null mutants to determine if En-2 is involved in regulating the pattern of afferent connectivity in the cerebellum. Spinocerebellar mossy fiber terminals were labeled following WGA-HRP injections in the lumbar region of 5 homozygous En-2hd mutants and 4 heterozygous controls. The distribution of spinocerebellar mossy fiber terminals was consistently altered in lobules VIII and IX of the En-2hd mutants. The principal changes were a reduction in the number of mossy fiber terminal fields in the dorsal aspect of lobule VIII and the dorsal midline field in lobule IX was fused into a single compartment. The results suggest that the deletion of En-2 expression does not transform lobule identity, at least with respect to afferent fiber positional information cues. However, the changes in foliation and afferent connectivity in the En-2 mutant support a broad role for the En-2 gene in cerebellar patterning.

Identification and Targeted Mutation of Developmental Genes in Mouse Embryonic Stem Cells

Publisher Summary This chapter describes the identification and targeted mutation of developmental genes in mouse embryonic stem cells. Embryonic stem (ES) cells are pluripotent cell lines, derived from early embryos that can be maintained in the undifferentiated state in culture. On return to the blastocyst environment, however, these cells can display full embryonic potential, contributing to all somatic tissues of resulting chimeras, and most important, to the germ line. It is, thus, possible to genetically manipulate the ES cells in culture by various means and incorporate the genetic alteration produced in culture into the mouse gene pool. The ability of ES cells has been used to contribute widely to somatic and germ cells in chimeras to devise means of identifying and mutating genes of potential developmental interest.