Manipulating the mouse genome: implications for neurobiology

Placental expression and chromosomal localization of the human Gcm 1 gene

Although gcm was first recognized for its role in specifying glial cell fate in Drosophila melanogaster, its mammalian counterparts are expressed predominantly in non-neural tissues. Here we demonstrate expression of the mouse and human GCM 1 proteins in placenta. We have prepared a highly specific antibody that recognizes the GCM 1 protein and have used it to assess the temporal and spatial expression profile of the protein. In both mouse and human placenta, the protein is associated with cells that are involved with exchange between maternal and fetal blood supplies: the labyrinthine cells of the mouse placenta and the syncytio- and cytotrophoblasts of the human placenta. Using the full-length hGcm 1 cDNA as a probe, we have mapped the gene on human chromosome 6p12 by fluorescent in situ hybridization.

Evidence that lysosomal storage of proteolipids is a cell autonomous process in the motor neuron degeneration (mnd) mouse, a model of neuronal ceroid lipofuscinosis

The motor neuron degeneration (mnd) mouse has been documented to accumulate proteolipid and thus is a model of neuronal ceroid lipofuscinosis [Dunn, W.A., Raizada, M.K., Vogt, E.S. and Brown, E.A., Int. J. Dev. Neurosci., 12 (1994) 185-196; Faust, J.R., Rodman, J.S., Daniel, P.F., Dice, J.F. and Bronson, R.T., J. Biol. Chem., 269 (1994) 10150-10155]. While accumulation of proteolipid in the hippocampus of chimeric mice composed of mnd and +/+ cells was found to be proportional to the contribution of mnd in the brain, accumulation within individual cells was the same for cells from chimeric and age-matched mnd mice. Bone marrow transplantation was used to altering the milieu of circulating factors to determine whether this might modify the disease phenotype in mnd mice. Transplantation of bone marrow in neonatal or young mice did not reduce the age-associated accumulation of proteolipid within hippocampal neurons. The results of these experiments indicate that mnd results in a cell autonomous defect.

New Methods in the Molecular Genetic Study and Treatment of Hearing Loss

In genetics, both discovery and methodology are advancing at an accelerating rate. As a result, the role of clinicians, and in this case clinical audiologists, must be re-examined from time to time to assure the sort of cooperation that will maximize results for both the investigators and the patients. This article will briefly review the current state of molecular genetic methodology and relate the assumptions inherent in such methods to the character of the clinical data needed from the audiologist inthese cases. The basic assumption of most molecular biologic investigations of ear disease is that a binary (yes or no) diagnosis can be made by the audiologists and physicians as to the disease status of each member of an affected family. The binary assumption gives rise to a number of clinical diagnosis issues not easily understood by molecular biologists, and these issues are discussed in order to facilitate progress in genetic cases.

Clonal architecture of the mouse retina

The study of chimeric retinas has yielded insight on the early development of retina. The close match in chimerism ratios between right and left retinas is significant and supports the idea that both retinas originate from a common population of progenitors. We are able to estimate numbers of progenitor cells that contribute to the formation of the retina and the approximate time at which this small group is isolated from surrounding prosencephalic cell fields. These cells undergo at least five rounds of division before the first retinal neurons are generated. The mouse retina is not build from the center outward. There is simultaneous expansion and differentiation in all parts of the retina and as a result clones are not arranged in wedges. Instead the mouse retina is a patchwork of clones that do not differ greatly in size from center to periphery. The most consistent radial feature in mouse retina is a raphe left at the line of fusion of the margins of the ventral fissure. Processes that shape the clonal patchwork are both passive and active, intrinsic and extrinsic. Certain features of the clonal architecture of the retina, such as the size differences of clones are primarily passive responses to extrinsic forces on progenitor cells and their progeny. The fifteen-fold range in the size of cohorts is not due to intrinsic differences in the proliferative capacity of individual progenitor cells, but is due to the extent of cell movement and mixing at early stages of development. In contrast, active or intrinsic processes are illustrated by the partial (and still controversial) restriction of retinal progenitors, the possible clonal differences between ganglion cells with crossed and uncrossed projections, and the consistent differences in ratios of albino and pigmented genotypes in peripheral and central retina.

Molecular genetic analysis of glucocorticoid signaling during mouse development

Glucocorticoids are important in a number of developmental processes in mammals around birth. The pathway of gluconeogenesis is activated in liver shortly after birth due to the combined effects of glucocorticoids and glucagon. We have defined the essential cis-regulatory elements directing hormone-dependent liver-specific expression of the gene for tyrosine aminotransferase, a key gluconeogenic enzyme. The hormone response elements synergize with cell-type specific elements. In the case of glucocorticoids, the glucocorticoid-dependent enhancer is composed of the glucocorticoid response element and binding sites for liver cell-enriched transcription factors, in particular hepatocyte nuclear factor-3. The dependence of the respective enhancer motifs on each other restricts the hormonal activation of the tyrosine aminotransferase gene in liver in response to a hormonal signal. To further understand the role of glucocorticoid signaling via the type II glucocorticoid receptor (GR) in the perinatal period and earlier during development, we have studied the expression of the mouse GR gene. Expression of the gene is controlled by at least three promoters, one of which is only active in T-lymphocytes. Expression of GR mRNA has been detected as early as day 9.5 of mouse development. To specifically address the role of glucocorticoid signaling via the GR during development, we have disrupted the GR gene by homologous recombination in mouse embryonic stem cells. The majority of GR mutants die shortly after birth and analysis so far has revealed defects in lung, liver, and adrenal function.

Drastic and selective hyperinnervation of central serotonergic neurons in a lethal neurodevelopmental mouse mutant, Anorexia (anx)

The autosomal recessive lethal anorexia mutation in mice (anx/anx) causes starvation in preweanlings. In addition, this murine neurodevelopmental mutant shows other distinct phenotypic characteristics and dysfunctional behaviors. Previous studies strongly suggested that the mutation results in elevated serotonergic stimulation, because these traits are characteristic of such overstimulation and because brain serotonin is believed to have an inhibitory effect on feeding behavior. In this report, we show extensive serotonergic hyperinnervation in normal target fields (hippocampus, cortex, olfactory bulb and cerebellum) of mutant mice. Despite the extensive hyperinnervation, the normal laminar organization of the brain was retained. The specificity of the mutation to the serotonergic system was confirmed by demonstration of normal catecholaminergic innervation in the central nervous system (CNS), and this specificity was especially striking in a common target field, the cerebellum. Serotonergic hyperinnervation in these mutant preweanling mice may represent the underlying etiology of increased serotonergic stimulation which leads to anorexic starvation, abnormal behavior, and premature death.

Molecules and cognition: the latterday lessons of levels, language, and lac. Evolutionary overview of brain structure and function in some vertebrates and invertebrates

The characteristics of the nervous systems of a number of organisms in different phyla are examined at the recombinant DNA, protein, neuroanatomic, neurophysiological, and cognitive levels. Among the invertebrates, special attention is paid to the advantages as well as the shortcomings of the fly Drosophila melanogaster, the worm Caenorhabditis elegans, the honey bee Apis mellifera, the sea hare Aplysia californica, the octopus Octopus vulgaris, and the squid Loligo pealei. Among vertebrates, the focus is on Homo sapiens, the mouse Mus musculus, the rat Rattus norvegicus, the cat Felis catus, the macaque monkey Macaca fascicularis, the barn owl Tyto alba, and the zebrafish Brachydanio rerio. Vertebrate nervous systems have also been compared in fossil vs. extant organisms. I conclude that complex nervous systems arose in the Early Cambrian via a big bang that was underpinned by a modular method of construction involving massive pleiotropy of gene circuits. This rapidity of construction had enormous implications for the degrees of freedom that were subsequently available to evolving nervous systems. I also conclude that at the level of neuronal populations and interactions of neuropiles there is no model system between phyla except at the basic macromolecular level. Further, I argue that to achieve a significant understanding of the functions of extant nervous systems we need to concentrate on fewer organisms in greater depth and manipulate genomes via transgenic technologies to understand the behavioral outputs that are possible from an organism. Finally, I analyze the concepts of "perceptual categorization" and "information processing" and the difficulties involved in the extrapolation of computer analogies to sophisticated nervous systems.

Retroviral infection coupled with tissue transplantation limits gene transfer in the chicken embryo

Gene transfer into early embryos is a powerful methodology for unraveling the molecular bases of developmental processes. One can attempt to minimize widespread effects of an exogenous gene by using tissue- or region-specific promoters in the few instances where they are available. We have developed a method that bypasses the requirement for specific targeting sequences to achieve regionally restricted gene transfer. Intraspecific chimeras have been created by transplantation of restricted portions of a chicken embryo from a donor strain to a host strain. The donor cells are infectable with a recombinant retroviral vector that carries the exogenous gene, whereas the host cells are not. We have demonstrated the feasibility of this approach using a histochemically distinct reporter gene, human placental alkaline phosphatase. The expression of retrovirally transduced alkaline phosphatase was limited to a transplanted hemiprosencephalon (forebrain and eye) in embryonic chickens. This technique can be applied to many other organ systems during avian embryogenesis to test the function(s) of molecules that are normally controlled through spatial and/or temporal regulation, such as many of the growth factor receptors or homeobox-containing proteins.

Aggregation chimeras demonstrate that the primary defect responsible for aganglionic megacolon in lethal spotted mice is not neuroblast autonomous

The lethal spotted (ls) mouse has been used as a model for the human disorder Hirschsprung's disease, because as in the latter condition, ls/ls homozygotes are born without ganglion cells in their terminal colons and, without surgical intervention, die early as a consequence of intestinal obstruction. Previous studies have led to the conclusion that hereditary aganglionosis in ls/ls mice occurs because neural crest-derived enteric neuroblasts fail to colonize the distal large intestine during embryogenesis, perhaps due to a primary defect in non-neuroblastic mesenchyme rather than migrating neuroblasts themselves. In this investigation, the latter issue was addressed directly, in vivo, by comparing the distributions of ls/ls and wild-type neurons in aggregation chimeras. Expression of a transgene, D beta H-nlacZ, in enteric neurons derived from the vagal neural crest, was used as a marker for ls/ls enteric neurons in chimeric mice. In these animals, when greater than 20% of the cells were wild-type, the ls/ls phenotype was rescued; such mice were neither spotted nor aganglionic. In addition, these ‘rescued’ mice had mixtures of ls/ls and wild-type neurons throughout their gastrointestinal systems including distal rectum. In contrast, mice with smaller relative numbers of wild-type cells exhibited the classic ls/ls phenotype. The aganglionic terminal bowel of the latter mice contained neither ls/ls nor wild-type neurons. These results confirm that the primary defect in ls/ls embryos is not autonomous to enteric neuroblasts, but instead exists in the non-neuroblastic mesenchyme of the large intestine.

Authentic and artifactual detection of the E. coli lacZ gene product in the rat brain by histochemical methods

The accurate detection of a marker gene is fundamental to the assessment of any gene delivery protocol. The use of E. coli lacZ as such a marker gene has become common in studies on gene transfer to the central nervous system. The straightforward histochemical assay that is available to detect the gene product, beta-galactosidase; has made it an attractive system. However, using standard protocols, we have found dramatic non-E. coli lacZ staining in cells with neuronal, glial and endothelial morphology in the normal, adult rat brain. This false staining is primarily in the brainstem, but is evident in cortical and subcortical regions as well. This endogenous reactivity is independent of substrate concentration within the range tested, but is exquisitely sensitive to even small fluctuations in pH. In light of these findings, one must carefully examine any findings of E. coli lacZ gene expression in the rat brain based solely on histochemical analysis of tissue sections.

Disrupted cerebellar cortical development and progressive degeneration of Purkinje cells in SV40 T antigen transgenic mice

SV40 T antigen (Tag) expression directed to cerebellar Purkinje cells resulted in the generation of three transgenic mouse lines that displayed ataxia, a neurological phenotype characteristic of cerebellar dysfunction. Onset of symptoms and cerebellar pathology, characterized by specific Purkinje cell degeneration, appeared to be directly dependent upon transgene copy number. The SV5 line (containing > 30 transgene copies), exhibited embryonic transgene expression that caused selective death of immature Purkinje cells and a subsequent block in cerebellar development and ataxia at 2 weeks. The developmental effect of the disruption of Purkinje cells in SV5 mice suggests that a normal complement of these cells is required for early development of the cerebellar cortex, especially granule cell proliferation and migration from external to internal layers. Transgene expression in a second line, SV4 (10 copies), was detectable during the second postnatal week. Death of mature Purkinje cells in the SV4 line resulted in onset of ataxia at 9 weeks. Ataxia in a third line, SV6 (2 copies), was detected after 15 weeks. The distinct cerebellar phenotypes of the SV4-6 lines correlate with specific Tag-induced Purkinje cell ablation as opposed to tumorigenesis.

Neurotransmitter-stimulated immediate-early gene responses are organized through differential post-synaptic receptor mechanisms

The products of the cellular immediate-early genes (IEGs) are thought to act as messengers in the coupling of trans-synaptic stimuli with altered neuronal gene expression. However, the manner in which neurotransmission specifies particular responses through the IEGs is undefined. In this report, mRNA and transcription analysis of a precisely-timed, physiological IEG response illustrates how an IEG signal may be organized through differential neurotransmitter receptor activation. The nocturnal pattern of IEG expression in the rat pineal gland has been shown to be differentially regulated through post-synaptic adrenergic receptors. Induction of the c-fos gene is primarily mediated through alpha 1-receptors, whereas the coordinately regulated jun-B gene exhibits dual regulation through alpha 1- and beta-receptors. A simultaneous repression of c-jun expression is partly mediated through a beta-receptor mechanism. In vitro analysis of IEGs in cultured pineal glands has confirmed the receptor-specific link between adrenergic neurotransmission and IEG induction. The pineal is a unique neuroendocrine model in which the characteristics and function of the IEG third messenger system may be defined.

The use of human repetitive DNA to target selectable markers into only the human chromosome of a human-hamster hybrid cell line (AL)

We used the plasmid BLUR-8 that contains an 800-base pair (bp) sequence of human repetitive Alu DNA in a cotransfection protocol to target the plasmids pSV2neo or EBO-pcD-leu-2 (hygro) into a single site of the sole human chromosome, number 11, of a Chinese hamster-human hybrid cell line (AL). The neo and hygro plasmids confer resistance to the antibiotics G418 and hygromycin, respectively. Of the 33 cotransfected clones with single-site insertions, 1/13 without BLUR-8 and 6/20 with BLUR-8 were only in human chromosome 11. A frequency of insertion of 1/13 is not different than expected by chance (rho = 0.3512). On the other hand, the probability that 6/20 insertions, as seen with BLUR-8, occurred by chance is low (rho = 0.0003). We suggest that the human DNA sequences contained in BLUR-8 targeted insertions into only the human chromosome.

Structure of clonal and polyclonal cell arrays in chimeric mouse retina

One of the most striking results of recent cell-lineage studies of vertebrate retina is the marked variability in the size and types of clones marked by retroviral transfection and dye injection of embryonic progenitor cells. Is this variability due to microenvironmental modulation of cell determination, to lineage restriction, or to experimental perturbation of the progenitor cells? We have taken advantage of species-specific DNA probes to mark groups of lineage-related cells in experimental mouse chimeras. This method of marking cells has two distinct advantages over previous methods: direct manipulation of progenitor cells is avoided, and clones are established at an earlier stage of retinal development. The most notable feature of retinal cohorts in chimeras is their structural uniformity--each is a solid radial array that contains the same ratio of major cell types as the retina itself. This is true even of the smallest monoclonal cohorts, which contain fewer than 200 cells. Our results provides compelling empirical support for the hypothesis that the murine retina is made up of hundreds of relatively homogeneous radial units, each derived from single retinal precursor cells. This finding is inconsistent with micro-environmental modulation of clone structure early in development. We raise the possibility that the heterogeneity among clones marked by dye injection and transfection is due to progressive lineage restriction or to experimental perturbation of the retinal progenitor cells.

The molecular biology of retinoic acid receptors: orphan from good family seeks home

A variety of c-DNAs coding for nuclear retinoic acid receptors (RARs) have recently been cloned. These receptors are members of the steroid/thyroid receptor superfamily and are believed to act as ligand-inducible transactivating factors; retinoic acid induces changes in receptor configuration that allows DNA binding and increased gene transcription from specific genes to occur. The retinoic acid receptor family itself may consist of up to 20 separate receptors each with a specific distribution and ligand binding characteristics. The RAR-gamma in the adult is found almost exclusively in the skin but other receptors which are found in a variety of other tissues are also present in skin. Associations of cutaneous disease states with receptor mutants have not yet been reported although some cases of leukaemia may be secondary to retinoic acid receptor gene rearrangements. A variety of approaches to identify the biological function of these receptors based on recombinant DNA technology are already underway.

The major laminin receptor of mouse embryonic stem cells is a novel isoform of the alpha 6 beta 1 integrin

Laminin is the first extracellular matrix protein expressed in the developing mouse embryo. It is known to influence morphogenesis and affect cell migration and polarization. Several laminin receptors are included in the integrin family of extracellular matrix receptors. Ligand binding by integrin heterodimers results in signal transduction events controlling cell motility. We report that the major laminin receptor on murine embryonic stem (ES) cells is the integrin heterodimer alpha 6 beta 1, an important receptor for laminin in neurons, lymphocytes, macrophages, fibroblasts, platelets and other cell types. However, the cytoplasmic domain of the ES cell alpha 6 (alpha 6 B) differs totally from the reported cytoplasmic domain amino acid sequence of alpha 6 (alpha 6 A). Comparisons of alpha 6 cDNAs from ES cells and other cells suggest that the alpha 6 A and alpha 6 B cytoplasmic domains derive from alternative mRNA splicing. Anti-peptide antibodies to alpha 6 A are unreactive with ES cells, but react with mouse melanoma cells and embryonic fibroblasts. When ES cells are cultured under conditions that permit their differentiation, they become positive for alpha 6 A, concurrent with the morphologic appearance of differentiated cell types. Thus, expression of the alpha 6 B beta 1 laminin receptor may be favored in undifferentiated, totipotent cells, while the expression of alpha 6 A beta 1 receptor occurs in committed lineages. While the functions of integrin alpha chain cytoplasmic domains are not understood, it is possible that they contribute to transferring signals to the cell interior, e.g., by delivering cytoskeleton organizing signals in response to integrin engagement with extracellular matrix ligands. It is therefore reasonable to propose that the cellular responses to laminin may vary, according to what alpha subunit isoform (alpha 6 A or alpha 6 B) is expressed as part of the alpha 6 beta 1 laminin receptor. The switch from alpha 6 B to alpha 6 A, if confirmed in early embryos, could then be of striking potential relevance to the developmental role of laminin.

Mechanisms of complex transcriptional regulation: implications for brain development

The large number of transcription factors, their diverse sequence-specific interactions with DNA sites and with other transcription factors, and their ability to be modified in response to a variety of environmental cues and intracellular signals provide combinatorial codes for highly complex and yet highly organized patterns of gene expression likely to underlie the determination of diversity of neuronal phenotypes. Subtle differences in the combinations of transcription factors are likely to have profound consequences for cell phenotype, similar to the mechanism involved in the specification of cell types in yeast (reviewed in Herskowitz, 1989). Although our current understanding of transcriptional regulation in the brain comes largely from phenomenological studies, recent technical progress on two fronts promises a bright future. Homologous recombination technology in embryonic stem cells (reviewed in Capecchi, 1989; Rossant, 1990) allows the disruption of particular genes in transgenic mice and definition of the roles of identified transcription factors in mammalian neurogenesis. A second technological advance, targeted tumorigenesis, has provided neuronal model cell lines (Mellon et al., 1990; reviewed in Cepko, 1988; McKay et al., 1988) that mimic certain neuronal differentiation pathways. These combined genetic, cell biological, and biochemical approaches will greatly facilitate the study of neural development and function.

Neuroantibodies: molecular cloning of a monoclonal antibody against substance P for expression in the central nervous system

We present a strategy to study functional and/or developmental processes occurring in the nervous system, as well as in other systems, of mice. This strategy is based on the local expression of specific monoclonal antibodies (mAbs) by cells of the nervous system. As an application of this strategy, we report the cloning of the anti-substance P rat mAb NC1/34HL. Functional substance P-binding antibodies were reconstituted from the cloned variable domains by using vectors for expression in myeloma cells. With these and other vectors a general system for the cloning and expression of mAbs under a series of promoters (of the rat VGF8a gene, the neurofilament light-chain gene, and the methallothionein gene) has been created. The activity of these plasmids was confirmed by expressing the recombinant NC1/34HL mAb in GH3 pituitary cells, PC12 pheochromocytoma cells, and COS cells. DNA from the described constructs can be used to target the expression of the NC1/34HL mAb to the central nervous system of transgenic mice. This procedure will allow us to perturb substance P activity in a controlled way in order to dissect its multiple roles.

The B30 ganglioside is a cell surface marker for neural crest-derived neurons in the developing mouse

We have previously reported the isolation of a monoclonal antibody, mAb B30, that recognizes two minor gangliosides specifically expressed in a small subset of neurons in the developing mouse central nervous system (Stainier and Gilbert, 1989). B30 labels mesencephalic trigeminal neurons shortly after differentiation until about 2 weeks after birth. Postnatally, it also labels two specific monolayers of cerebellar neurons. In this study, we have characterized the B30 immunoreactivity in the developing peripheral nervous system of the mouse. We report that B30 is a marker for neural crest-derived neurons and have used it to follow the neuronal differentiation of neural crest cells in a serum-free chemically defined culture system. Within hours after plating, neural crest cells migrate away from the neural tube explant on a fibronectin or laminin substrate and by 24 hr, up to 15% of them have differentiated into morphologically identifable neurons. In vitro as in vivo, undifferentiated mouse neural crest cells express the GD3 ganglioside which is recognized by mAb B33, and neural crest-derived neurons can be labeled by mAbs B33, B30, and also E1.9, a specific neuronal cytoskeletal marker. We also show the unique biochemical specificity of mAb B30 and provide experimental evidence for the role of the B30 ganglioside in the cellular adhesion process.

Gene targeting in murine embryonic stem cells: introduction of specific alterations into the mammalian genome

The ability to create targeted mutations in the mouse will have an impact on many areas of research in mammalian biology. Mutations are generated in embryonic stem (ES) cells by homologous recombination between exogenously added DNA and the endogenous chromosomal sequences. These cells are then used to generate chimeric intermediates that pass the mutant allele through the germ line, initiating a strain of mice that carry the desired mutation. This review focuses on the selection of a starting ES cell line, introduction of DNA into ES cells, construction of gene targeting vectors, and selection/enrichment schemes for the isolation of targeted cell lines. The generation of mice that carry the targeted allele is briefly outlined.

Sequence of a novel carbonic anhydrase-related polypeptide and its exclusive presence in Purkinje cells

I isolated a mouse cDNA clone encoding a novel polypeptide which has strong homology with carbonic anhydrase. Unlike the other carbonic anhydrases, it has an additional N-terminal domain with a glutamic acid stretch and an arginine substitutes one of the three histidine residues which bind zinc ion. In the central nervous system, carbonic anhydrase is known to be expressed only in glia cells, but this gene is expressed in neuron, but only in Purkinje cells.

Animal models of Lesch-Nyhan syndrome

In humans, deficiency of the enzyme hypoxanthine-guanine phosphoribosyltransferase (HPRT) is associated with a disorder known as Lesch-Nyhan syndrome which includes severe neurobehavioral abnormalities. Several animal models which have been developed to examine the neurobiologic substrates of this disorder have suggested a role for abnormal function in purine/dopamine neurotransmission, but the relationship between HPRT-deficiency and these abnormalities remains unknown. Recently, HPRT-deficient mice have been produced which appear to have similar, though more subtle changes in brain dopamine function. These mice will be useful in elucidating the relationship between HPRT-deficiency and the neurological deficits observed in patients with this disorder.