Degeneration of the mouse retina upon dysregulated activity of serum response factor.

PURPOSE: Our aim was to generate and phenotypically characterize a transgenic mouse line expressing a constitutively active variant of the transcription regulatory protein serum response factor (SRF), namely the SRF-VP16 protein. This new mouse strain has been registered under the designation Gt(ROSA)26Sor(tm1(SRF-VP16)Antu). We found phenotypic changes upon ectopic expression of SRF-VP16, especially in the mouse retina. METHODS: Using homologous recombination, we integrated an SRF-VP16 conditional (i.e., "flox-STOP" repressed) expression transgene into the Rosa26 locus of murine embryonic stem (ES) cells. These engineered ES cells were used to derive the Gt(ROSA)26Sor(tm1(SRF-VP16)Antu) mouse strain. Semiquantitative real-time PCR was used to determine expression of the SRF-VP16 transgene at the mRNA level, both in young (P20 and P30) and adult (six months old) Gt(ROSA)26Sor(tm1(SRF-VP16)Antu) mice. We also investigated the transcript levels of endogenous Srf and several SRF target genes. Retinal function was tested by electroretinography in both young and adult mice. Morphological abnormalities could be visualized by hematoxylin and eosin staining of sectioned, paraffin-embedded eye tissue samples. Scanning-laser ophthalmoscopy was used to investigate retinal vascularization and degeneration in adult mice. RESULTS: We show that the SRF-VP16 mRNA is expressed to a low but significant degree in the retinas of young and adult animals of the Gt(ROSA)26Sor(tm1(SRF-VP16)Antu) mouse strain, even in the absence of Cre-mediated deletion of the "flox-STOP" cassette. In the retinas of these transgenic mice, endogenous Srf displays elevated transcript levels. Ectopic retinal expression of constitutively active SRF-VP16 is correlated with the malfunction of retinal neurons in both heterozygous and homozygous animals of both age groups (P20 and adult). Additionally, mislamination of retinal cell layers and cellular rosette formations are found in retinas of both heterozygous and homozygous animals of young age. In homozygous individuals, however, the cellular rosettes are more widespread over the fundus. At adult age, retinas both from animals that are heterozygous and homozygous for the floxSTOP/SRF-VP16 transgene display severe degeneration, mainly of the photoreceptor cell layer. Wild-type age-matched littermates, however, do not show any degeneration. The severity of the observed effects correlates with dosage of the transgene. CONCLUSIONS: This is the first report suggesting an influence of the transcription factor SRF on the development and function of the murine retina. Ectopic SRF-VP16 mRNA expression in the retinas of young animals is correlated with photoreceptor layer mislamination and impaired retinal function. At an advanced age of six months, degenerative processes are detected in SRF-VP16 transgenic retinas accompanied by impaired retinal function. The Gt(ROSA)26Sor(tm1(SRF-VP16)Antu) mouse strain represents a genetic SRF gain-of-function mouse model that will complement the current SRF loss-of-function models. It promises to provide new insight into the hitherto poorly defined role of SRF in retinal development and function, including potential contributions to ophthalmologic disorders. Furthermore, using conditional Cre-mediated activation of SRF-VP16, the described mouse strain will enable assessment of the impact of dysregulated SRF activity on the physiologic functions of various other organs.

Tankyrase 2 poly(ADP-ribose) polymerase domain-deleted mice exhibit growth defects but have normal telomere length and capping.

Regulation of telomere length maintenance and capping are a critical cell functions in both normal and tumor cells. Tankyrase 2 (Tnks2) is a poly(ADP-ribose) polymerase (PARP) that has been shown to modify itself and TRF1, a telomere-binding protein. We show here by overexpression studies that tankyrase 2, like its closely related homolog tankyrase 1, can function as a positive regulator of telomere length in human cells, dependent on its catalytic PARP activity. To study the role of Tnks2 in vivo, we generated mice with the Tnks2 PARP domain deleted. These mice are viable and fertile but display a growth retardation phenotype. Telomere analysis by quantitative fluorescence in situ hybridization (FISH), flow-FISH, and restriction fragment analysis showed no change in telomere length or telomere capping in these mice. To determine the requirement for Tnks2 in long-term maintenance of telomeres, we generated embryonic stem cells with the Tnks2 PARP domain deleted and observed no change, even upon prolonged growth, in telomere length or telomere capping. Together, these results suggest that Tnks2 has a role in normal growth and development but is not essential for telomere length maintenance or telomere capping in mice.

A foreign dihydrofolate reductase gene in transgenic mice acts as a dominant mutation.

We have produced 17 lines of transgenic mice by microinjecting a full-length cDNA clone of an altered dihydrofolate reductase (dhfr) gene. The protein specified by this gene carries a point mutation which triples its Km for dihydrofolate and reduces substrate turnover 20-fold relative to the wild-type enzyme. Transgenic mice from different pedigrees, several of which carry a single copy of this gene in different integration sites, manifest an array of similar developmental abnormalities including growth stunting, reduced fertility, pigmentation changes, and skeletal defects. These defects appear in animals heterozygous for the foreign gene. RNA analyses demonstrate significant expression of the cDNA in newborn mice and adult tissues. These findings show that the additional dhfr gene exerts its mutational effects in a dominant fashion, and therefore the data indicate that transgenic mice can serve as models for elucidating mechanisms of dominant mutagenesis.

Adrenocortical function and regulation of the steroid 21-hydroxylase gene in NGFI-B-deficient mice.

The immediate-early gene NGFI-B encodes an orphan nuclear receptor that binds DNA as a monomer and activates transcription through a canonical response element (NBRE). NGFI-B is expressed under basal conditions and in response to external stimuli in many mammalian tissues. In particular, NGFI-B expression is dramatically elevated in the adrenal cortex in response to stress and in Y1 adrenocortical cells in response to adrenocorticotropin. NGFI-B activates transcription through an NBRE of the gene encoding 21-hydroxylase (P450c21) in Y1 cells. Steroidogenic factor 1 (SF-1), a homolog of NGFI-B, also activates the P450c21 promoter. To examine the influence of these factors on P450c21 expression in vivo and the function of the hypothalamic-pituitary-adrenocortical axis as a whole, we generated NGFI-B (-/-) mice. These mice thrive and reproduce normally and maintain normal basal adrenocorticotropin, corticosterone, and P450c21 mRNA levels. In response to increases in adrenocorticotropin, NGFI-B (-/-) and wild-type mice demonstrated equivalent increases in serum corticosterone levels. Furthermore, and in contrast to in vitro results, no increases in P450c21 mRNA levels were observed in response to increases in adrenocorticotropin in NGFI-B (-/-) or wild-type mice. While SF-1 mRNA levels were not increased with increased steroidogenic demand, adrenal expression of Nurr1, a close homolog of NGFI-B, was induced to a greater extent by lipopolysaccharide in NGFI-B (-/-) mice than in wild-type mice. Finally, when the administration of dexamethasone for suppression was stopped, P450c21 mRNA and serum corticosterone levels recovered at the same rate in wild-type and NGFI-B (-/-) mice. Thus, while NGFI-B appears poised to affect the structure and function of the adrenal gland, the gland functions normally in its absence, suggesting that other factors, including Nurr1 and SF-1, are sufficient to drive P450c21 expression in mice and maintain normal steroidogenesis.

Atm knock-in mice harboring an in-frame deletion corresponding to the human ATM 7636del9 common mutation exhibit a variant phenotype.

ATM, the gene mutated in the human immunodeficiency disorder ataxia-telangiectasia (A-T), plays a central role in recognizing ionizing radiation damage in DNA and in controlling several cell cycle checkpoints. We describe here a murine model in which a nine-nucleotide in-frame deletion has been introduced into the Atm gene by homologous recombination followed by removal of the selectable marker cassette by Cre-loxP site-specific, recombination-mediated excision. This mouse, Atm-DeltaSRI, was designed as a model of one of the most common deletion mutations (7636del9) found in A-T patients. The murine Atm deletion results in the loss of three amino acid residues (SRI; 2556-2558) but produces near full-length detectable Atm protein that lacks protein kinase activity. Radiosensitivity was observed in Atm-DeltaSRI mice, whereas the immunological profile of these mice showed greater heterogeneity of T-cell subsets than observed in Atm(-/-) mice. The life span of Atm-DeltaSRI mice was significantly longer than that of Atm(-/-) mice when maintained under nonspecific pathogen-free conditions. This can be accounted for by a lower incidence of thymic lymphomas in Atm-DeltaSRI mice up to 40 weeks, after which time the animals died of other causes. The thymic lymphomas in Atm-DeltaSRI mice were characterized by extensive apoptosis, which appears to be attributable to an increased number of cells expressing Fas ligand. A variety of other tumors including B-cell lymphomas, sarcomas, and carcinomas not seen in Atm(-/-) mice were observed in older Atm-DeltaSRI animals. Thus, expression of mutant protein in Atm-DeltaSRI knock-in mice gives rise to a discernibly different phenotype to Atm(-/-) mice, which may account for the heterogeneity seen in A-T patients with different mutations.

Craf-1 protein kinase is essential for mouse development.

The three mammalian Raf serine/threonine protein kinases mediate the transduction of proliferative and differentiative signals from a variety of cell surface receptors to the nucleus. We report here that Craf-1 is essential for mouse development, as its mutation results in embryonic lethality. Developmental defects are found in mutant placentas as well as in the skin and in the lungs of mutant embryos. Craf-1 mutants also display a generalized growth retardation which is consistent with the ubiquitous expression of Craf-1 and which could be due to the reduced proliferation of mutant cells. Interestingly, the time-point of embryonal death varies depending on the genetic background. This suggests that Craf-1-mediated signaling is affected by genetic background-specific alleles of other genes.

A genetic basis for the "Adonis" phenotype of low adiposity and strong bones.

Toll receptors in Drosophila contribute to host defense and establish the body plan. Mammalian homologues of Toll, the Toll-like receptors (TLRs), are thought to function only in host defense. Here, we report that mice harboring mutations in TLR4 or in CD14, a co-receptor for TLR4, have an "ideal" body plan consisting of increased bone mineral content, density, and size as well as decreased body fat. These mutant mice live long lives, have normal activity and fertility, and show no evidence of infection. Unlike many strains of caged wild-type mice, they do not become obese. Although all mice continue to gain body fat, bone content, and overall weight, the difference in bone content and body fat between mutant and wild-type mice increases with age. Thus, defects in TLR4/CD14 complex generate an "Adonis" phenotype, characterized by this ideal body type, and this function could potentially be exploited for the treatment of osteoporosis and obesity.

Gene expression patterns in calorically restricted mice: partial overlap with long-lived mutant mice.

To gain insight into the pathways by which caloric restriction (CR) slows aging, gene expression levels were assessed for each of 2,352 genes in the livers of 9-month-old CR and control mice. A total of 352 genes were found to be significantly increased or decreased by CR. The distribution of affected genes among functional classes was similar to the distribution of genes within the test set. Surprisingly, a disruption or knockout of the gene for the GH receptor (GHR-KO), which also produces life extension, had a much smaller effect on gene expression, with no more than 10 genes meeting the selection criterion. There was, however, an interaction between the GHR-KO mutation and the CR diet: the effects of CR on gene expression were significantly lower in GHR-KO mice than in control mice. Of the 352 genes altered significantly by CR, 29 had shown a significant and parallel alteration in expression in a previous study of liver gene expression that compared mice of the long-lived Snell dwarf stock (dw/dw) to controls. These 29 genes, altered both by CR and in dwarf mice, provide a list of biochemical features common to both models of delayed aging, and thus merit confirmation and more detailed study.

Diet effects on weight gain and body composition in high growth (hg/hg) mice.

Nongenetic factors such as nutrition modulate the effects of genes responsible for overgrowth in animals. The goal of this study was to examine the importance of genotype x diet interactions on the effects of a major locus that regulates growth in the mouse. We have examined the phenotype of high growth (hg), a partially recessive autosomal locus that increases growth rate and mature body size. C57BL/6J (C57) and congenic C57BL/6J-hg/hg (HG) mice were fed three experimental diets differing in protein and energy content from 3 to 12 wk of age. HG mice grew faster and were, on average, 51% heavier than C57 at 12 wk of age. Feed intake was higher in HG mice but proportional to the increase in body weight. The magnitude of the differences in body size and composition between lines depended on the interaction between genotype and the protein/energy ratio of the diet. In C57, the diets modified the level of fatness without changing adult lean mass. However, in HG the diets differentially affected both linear growth and body composition. In general, HG had higher plasma levels of insulin-like growth factor I at 3 and 12 wk than C57. Plasma insulin did not differ between lines, but leptin was higher for C57 mice fed a high-energy diet. These results show that the effects of hg on growth are modulated by diet composition. Therefore, this mutation could be a valuable model with which to study the genetic and nutritional aspects of overgrowth disorders.

Developmental assessment of hypothalamic tuberoinfundibular dopamine in prolactin-deficient dwarf mice.

Development of the hypophysiotropic hypothalamus in PRL-deficient Ames dwarf (df/df) mice was examined for steady state dopamine (DA) by visualization using formaldehyde-induced catecholamine histofluorescence and by quantification using catecholamine HPLC at selected postnatal ages (7, 14, 21, 30, and 90 days). Phenotypically normal (DF/?) littermate mice were compared with dwarfs by both methods at each age. The studies were designed to investigate whether the known deficiency in hypothalamic tuberoinfundibular DA in adult dwarfs is present neonatally or develops over the postnatal period. The anterior pituitary of each mouse was processed for GH and PRL immunocytochemistry. At 7 days of age, GH immunostaining was robust, and scattered PRL-positive cells were noted in DF/? pituitary. Homogeneously distributed PRL cells increased in number through 30 days of age in normal mice. Neither GH nor PRL immunoreactivity was present in df/df mice at any age. At 7, 14, and 21 days of age, hypothalamic DA tuberoinfundibular histofluorescence was comparable in df/df and DF/? mice. At 90 days of age, tuberoinfundibular histofluorescence in normal mice remained intense, but was virtually undetectable in dwarfs. The developmental change affected only tuberoinfundibular neurons, since DA histofluorescence in nonhypophysiotropic areas, such as substantia nigra (SN), was qualitatively comparable for df/df and DF/? for all ages examined. Norepinephrine (NE) fluorescence in hypothalamus was also comparable for df/df and DF/?. Catecholamine HPLC provided quantitative confirmation of histofluorescence observations. DA and NE levels in both hypothalamus and ventral midbrain, including SN, increased during development in both df/df and DF/? brains. NE levels were not different between dwarf and normal animals at any age in either medial basal hypothalamus (MBH) or SN. The DA concentration in SN was not different between df/df and DF/? at any age examined. MBH DA was comparable in df/df and DF/? mice at 7, 14, and 21 days of age; at 30 and 90 days, MBH DA was markedly lower (P < 0.001) in dwarf than in normal mice. Although MBH DA in dwarfs was comparable to that in normal mice at 21 days, the increase in dwarfs between 14 and 21 days was not statistically significant. Thus, the hypothalamic DA deficit that exists in adult dwarf mice is not present neonatally and represents a failure to increase DA compared with normal mice after 14 days of age. The failure of continued development of hypophysiotropic tuberoinfundibular DA neurons in dwarf mice is correlated chronologically with absent pituitary PRL production.

Human insulin-like growth factor (IGF) binding protein-1 inhibits IGF-I-stimulated body growth but stimulates growth of the kidney in snell dwarf mice.

The actions of insulin-like growth factor-I (IGF-I) are modulated by IGF binding proteins (IGFBPs). The effects of IGFBP-1 in vivo are insufficiently known, with respect to inhibitory or stimulatory actions on IGF-induced growth of specific organs. Therefore, we studied the effects of IGFBP-1 on IGF-I-induced somatic and organ growth in pituitary-deficient Snell dwarf mice. Human GH, IGF-I, IGFBP-1, and a preequilibrated combination of equimolar amounts of IGF-I and IGFBP-1 were administered sc during 4 weeks. Treatment with IGF-I alone induced a significant increase in body length (108% of control) and weight (112%) as well as an increase in weight of the submandibular salivary glands (135%), kidneys (124%), femoral muscles (111%), testes (129%), and spleen (126%) compared with saline-treated controls. IGFBP-1 alone induced a significant increase in weight of the kidneys (152% of control). Coadministration of IGF-I with IGFBP-1 neutralized the stimulating effects of IGF-I on body length and weight as well as on the femoral muscles and testes. In contrast, the weights of the submandibular salivary glands (143%) were not significantly different from those of IGF-I-treated animals, whereas the weights of the kidneys (171%) and spleen (156%) were significantly increased compared with IGF-I-treated mice. The effect of IGFBP-1 plus IGF-I on kidney weight was not significantly greater than the effect of IGFBP-1 alone. Western ligand blotting showed induction of the IGFBP-3 doublet as well as IGFBPs with molecular masses of 24 kDa, most probably IGFBP-4, by human GH, IGF-I alone, and IGF-I in combination with IGFBP-1. Our data show that coadministration of IGFBP-1 inhibits IGF-I-induced body growth of GH-deficient mice but significantly stimulates the growth promoting effects of IGF-I on the kidneys and the spleen. These data warrant further investigation because differences in concentrations of IGFBP-1 occurring in vivo may influence IGF-I-induced anabolic processes.

Enhanced transcription of c-myc proto-oncogene in spleen lymphocytes from lupus-prone mice during the growing process.

The expression of c-myc proto-oncogene in spleen lymphocytes has been studied in lupus-prone mice (MRL/Mp-lpr/lpr), an animal model for the human autoimmune disease systemic lupus erythematosus, during the growing process, in comparison to control mice (MRL/Mp-+/+). By Northern blot assay and nuclear run on transcription assay, we demonstrated the enhancement of c-myc proto-oncogene expression in spleen lymphocytes from lupus-prone mice in comparison to control mice and the level of expression of c-myc proto-oncogene increased during the growing process and deterioration of lupus symptoms, such as production of autoantibodies and lymphoproliferation, in this study.

Olivocerebellar fiber maturation in normal and lurcher mutant mice: defective development in lurcher.

Olivocerebellar fiber maturation was examined in normal and lurcher mutant mice between postnatal day 5 (P5) and P15, using the anterograde transport of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) from the inferior olive. Immunocytochemistry for the Purkinje cell marker PEP-19 was used to demonstrate Purkinje cell development in the same material. In mutant and normal animals, a regional developmental variation is observed such that, when compared at a given age, cortex lining the vermal fissures appears developmentally advanced over cortex in the cerebellar hemispheres. In the primary fissure of the normal animals, the first recognizable Purkinje cell dendrites appear on P6, and the olivocerebellar fibers first enter the climbing stage of their development on P9. In lurcher animals Purkinje cell development proceeds on this schedule, but olivocerebellar fibers are never observed to enter the molecular layer. These afferents maintain dense perisomatic nests around Purkinje cells, even in P13-15 lurchers. Examination of P14 lurchers by transmission electron microscopy indicates that the olivocerebellar fibers form synapses on Purkinje cell somatic spines and that the basket cell axons fail to form their typical perisomal nests around Purkinje cells. In addition, parallel fibers can be observed to synapse on dendritic spines on the Purkinje cell primary dendrites. We interpret these results as indicating a recognition defect between olivocerebellar fibers and Purkinje cell dendrites. An analysis of this defect in lurcher may reveal how the normal transformation of olivocerebellar fibers, from perisomal to dendritic terminals, is achieved.

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.

Gonadal steroids influence neurophysin II distribution in the forebrain of normal and mutant mice.

The distribution of arginine vasopressin-associated neurophysin (neurophysin II) immunoreactivity was investigated in normal and mutant house mice during development and after various gonadal steroid manipulations. During postnatal development of normal mice dense networks of neurophysin II immunoreactivity in the lateral septal nucleus and lateral habenular nucleus appeared earlier in male than in female mice, with an adult pattern of immunoreactivity being attained by 8 weeks and 12 weeks of age, respectively. The neurophysin II immunoreactivity in the male was denser than that in female mice. After gonadectomy of adult normal mice there was a gradual loss of neurophysin II immunoreactivity in the lateral septum and lateral habenula over a period of 15 weeks. In hypogonadal mice, a mutant in which gonadal development is arrested postnatally due to a deficiency in hypothalamic gonadotrophin releasing hormone, no immunoreactive neurophysin II could be detected in the lateral septum or lateral habenula. A pattern of neurophysin II immunoreactivity similar to that in normal control mice was observed in hypogonadal mice which had been implanted for 4 weeks with silicone elastomer capsules containing testosterone or oestradiol-17 beta, but not 5 alpha-dihydrotestosterone or progesterone. Stimulation of gonadal development and endogenous steroid production in hypogonadal mice by third ventricular grafts of preoptic area tissue from normal neonatal animals also produced a normal pattern of neurophysin II immunoreactivity in the lateral septum and lateral habenula. In the androgen-insensitive testicular feminized mouse immunoreactive neurophysin II was undetectable in the lateral septum and lateral habenula. Treatment of testicular feminized mice with oestradiol-17 beta, but not progesterone, produced a normal pattern of neurophysin II immunoreactivity. The main immunohistological findings were confirmed by radioimmunoassay of tissue extracts which showed that the concentration of arginine vasopressin in lateral septum was far greater in normal males than females and was undetectable in hypogonadal mice; no oxytocin could be detected in the septum of normal or hypogonadal mice. These results show that the expression of neurophysin II immunoreactivity in the lateral septum and lateral habenula of the mouse brain is dependent on the presence of aromatizeable androgens or oestrogens.

Meibomian gland changes in the rhino (hrrhhrrh) mouse.

The rhino mouse, a single gene recessive mutation, is characterized by abnormal epidermal differentiation and maturation leading to the loss of hair at 1 month of age as well as follicular and epidermal hyperkeratoses. We evaluated the lids and corneas of nine rhino mice and their normal litter mates at various ages from 3 months to 1 year. Tissue specimens were studied by light microscopy, scanning and transmission electron microscopy as well as immunoperoxidase using a polyclonal rabbit anti-keratin antibody. At 3 months of age there was a thickening and hyperkeratinization of the palpebral epidermis which extended into and included the meibomian gland central duct. Whereas in the skin, hyperkeratinization is followed by follicular hyperkeratosis and dermal cyst formation, in the meibomian gland, ductal hyperkeratinization appeared to lead to loss of well developed acini followed by atrophy of the gland at 1 year as confirmed by immunostaining for keratin proteins. Scanning electron microscopy revealed marked plugging of the meibomian gland orifice with keratinized cells or debris in contrast to the patent orifice of the normal lid. Ocular surface changes included the presence of a whitish exudate covering the surface of the eye and increased numbers of preexfoliative corneal epithelial cells. These findings suggest that the rhino mouse may represents the first naturally occurring disorder of the meibomian gland.

Adrenocortical dysplasia: a mouse model system for adrenocortical insufficiency.

A spontaneous autosomal recessive mutation causing disordered morphogenesis of the adrenal cortex has been identified in DW/J inbred strain mice and named adrenocortical dysplasia (acd). The acd mutant gene has been mapped just proximal to oligosyndactyly (Os) and esterase-1 (Es-1) in the central region of chromosome 8. Both male and female acd/acd mice are characterized by reduced survival, retarded growth, skin hyperpigmentation, poorly developed pelage and focal ureteral blockage leading to hydronephrosis. Morphometric measurements showed that acd/acd cortical cells and nuclei were increased sevenfold in volume; nuclei often showed a variety of inclusions. Cortical cells of acd/acd mice contained large numbers of mitochondria, smooth endoplasmic reticulum and lipid droplets characteristic of steroidogenic cells. While cortical X-zones failed to develop in acd/acd adrenals, medullary cells and nuclei were unaffected by mutant gene action. Resting serum corticosterone levels in female, but not male, mutant mice were significantly lower than in +/? normal littermates, whereas ACTH levels were significantly elevated in mutants of both sexes. Serum aldosterone levels were normal in acd/acd mice. Functional studies of adrenals cultured in vitro revealed that acd/acd adrenals secreted reduced amounts of corticosterone per pair of glands under both basal and ACTH-stimulated conditions. However, correction of the corticosterone secretion data to mg cortical mass in culture showed that the mutant cortical tissue secreted the same amount of glucocorticoid as did their +/? normal littermate glands. We conclude that the acd mutant gene acts in an unknown fashion to cause a fundamental defect in cellular proliferation in the adrenal cortex, leading to compensatory marked hypertrophy of cortical cells and grossly enlarged nuclei. The role of acd action in adrenal cortical development remains to be established.

PKC gamma gene expression is delayed in postnatal central nervous system of mi/mi mice.

In the central nervous system (CNS), the expression of protein kinase C (PKC) genes is strictly controlled by the developmental stage. We have examined the expression of PKC genes (cPKC alpha, beta, gamma, and nPKC delta, epsilon) in the process of the postnatal development in normal (+/+) C57BL/6 and microphthalmic (mi/mi) C57BL/6 mouse brains by Northern blotting and in situ hybridization. By Northern blotting, the expression level of cPKC gamma mRNA in mi/mi mice was significantly lower than that in +/+ littermates at d 9, 13, and 17. By in situ hybridization analysis, cPKC gamma mRNA-positive cells were detected in hippocampal and Purkinje cells in +/+ and mi/mi mice, but the magnitude of the signals in mi/mi mice was lower than that of +/+ mice, and the number of positive cells was smaller, whereas other isozymes (cPKC alpha, beta, and nPKC delta, epsilon) showed no significant difference between normal and mi/mi mice. The neuronal morphometric analysis by anti-P400 antibody revealed the same number and expression level of P400 protein in cerebellar Purkinje cells compared with +/+ mice. These results indicate that the deficiency of mi gene product causes the delayed expression of the cPKC gamma gene.

Development of the inner ear in Splotch mutant mice.

The Splotch mouse, a Pax 3 mutation, represents a model of Waardenburg syndrome I. We show that the homozygous Splotch mutation (Sp(2H)) is associated with severe defects that prevent the formation of the cochlea and vestibulo-cochlear ganglion. To clarify the role of Pax 3 in inner ear formation, we examined the expression of polysialic acid (PSA) associated with neural cell adhesion molecule (NCAM). In accordance with the occurrence of phenotypic abnormalities, PSA NCAM was expressed early in otocyst development in the otic epithelium and the vestibulo-cochlear anlage. During the period of vestibular and cochlear ganglia formation, PSA NCAM expression was decreased. In the late phase of embryonic development, the expression of calcium binding proteins (S100) in the vestibulo-cochlear ganglion was also decreased. Minor differences in S100 immunostaining were found postnatally between the cochleas of heterozygous and wild type animals.

Alteration of cerebral ganglioside metabolism in developing Snell dwarf mice.

The ganglioside metabolism of the Snell dwarf cerebrum was examined on postnatal days 15 and 20, by monitoring the rate of incorporation of radioactivity into each ganglioside species from tritiated N-acetyl-D-mannosamine. It was found that the turnover rate of the GM3 ganglioside was reduced throughout the entire period of development, resulting in retardation of A pathway metabolism which becomes abundant during late cerebral development. In addition, the turnover rate of the GM4 species, which is considered related to myelin formation, was also found to be reduced throughout the entire period of cerebral development.