A novel zoometric index for assessing body composition in adult rabbits.

Obesity is an emerging problem in domesticated rabbits, and an easy-to-use measure of adipose tissue mass is needed. The current study aimed to develop a zoometric ratio, capable of estimating body condition in rabbits. Body weight (BW), body condition score (BCS), and zoometric measures (distal forelimb length, DFL; vertebral length, VL were measured in 150 pet rabbits. Zoometric formulae were created, combining BW with a zoometric measure, and these were tested for their ability to predict adipose tissue mass judged by BCS. Seventy-five (50 per cent) of the rabbits were in ideal condition (BCS 2.5-3.5), 52 (35 per cent) were overweight (BCS>3.5), and 23 (15 per cent) were underweight (BCS<2.5). Median (range) DFL and VL measurements were 12.1 (8.8-16.4 cm) and 34.0 (26.5-50.5 cm), respectively. In rabbits of medium breed size, the BW/DFL ratio was most strongly associated with BCS (Kendall's τ 0.80, P<0.001). Using BW/DFL limits for optimum body condition (eg, minimum 0.16; maximum 0.21), all underweight and overweight rabbits were correctly classified, while only 2/61 (3 per cent) rabbits with an optimum BCS were incorrectly classified as overweight. This study provides preliminary evidence that the BW/DFL might be a useful indirect measure of adipose tissue mass in rabbits of medium breed size.

Genomic, transcriptional and mutational analysis of the mouse microphthalmia locus.

Mouse microphthalmia transcription factor (Mitf) mutations affect the development of four cell types: melanocytes, mast cells, osteoclasts, and pigmented epithelial cells of the eye. The mutations are phenotypically diverse and can be arranged in an allelic series. In humans, MITF mutations cause Waardenburg syndrome type 2A (WS2A) and Tietz syndrome, autosomal dominant disorders resulting in deafness and hypopigmentation. Mitf mice thus represent an important model system for the study of human disease. Here we report the complete exon/intron structure of the mouse Mitf gene and show it to be similar to the human gene. We also found that the mouse gene is transcriptionally complex and is capable of generating at least 13 different Mitf isoforms. Some of these isoforms are missing important functional domains of the protein, suggesting that they might play an inhibitory role in Mitf function and signal transduction. In addition, we determined the molecular basis for six microphthalmia mutations. Two of the mutations are reported for the first time here (Mitf(mi-enu198) and Mitf(mi-x39)), while the others (Mitf(mi-ws), Mitf(mi-bws), Mitf(mi-ew), and Mitf(mi-di)) have been described but the molecular basis for the mutation not determined. When analyzed in terms of the genomic and transcriptional data presented here, it is apparent that these mutations result from RNA processing or transcriptional defects. Interestingly, three of the mutations (Mitf(mi-x39), Mitf(mi-bws), and Mitf(mi-ws)) produce proteins that are missing important functional domains of the protein identified in in vitro studies, further confirming a biological role for these domains in the whole animal.

The role of micromere signaling in Notch activation and mesoderm specification during sea urchin embryogenesis.

In the sea urchin embryo, the micromeres act as a vegetal signaling center. These cells have been shown to induce endoderm; however, their role in mesoderm development has been less clear. We demonstrate that the micromeres play an important role in the induction of secondary mesenchyme cells (SMCs), possibly by activating the Notch signaling pathway. After removing the micromeres, we observed a significant delay in the formation of all mesodermal cell types examined. In addition, there was a marked reduction in the numbers of pigment cells, blastocoelar cells and cells expressing the SMC1 antigen, a marker for prospective SMCs. The development of skeletogenic cells and muscle cells, however, was not severely affected. Transplantation of micromeres to animal cells resulted in the induction of SMC1-positive cells, pigment cells, blastocoelar cells and muscle cells. The numbers of these cell types were less than those found in sham transplantation control embryos, suggesting that animal cells are less responsive to the micromere-derived signal than vegetal cells. Previous studies have demonstrated a role for Notch signaling in the development of SMCs. We show that the micromere-derived signal is necessary for the downregulation of the Notch protein, which is correlated with its activation, in prospective SMCs. We propose that the micromeres induce adjacent cells to form SMCs, possibly by presenting a ligand for the Notch receptor.

Priming of CD8+ CTL effector cells in mice by immunization with a stress protein-influenza virus nucleoprotein fusion molecule.

Literature is accumulating which suggests the potential for stress proteins to form the basis of a novel vaccine technology. Immunization with mammalian tumor-derived stress proteins and their associated peptides promote anti-tumor immunity. Vaccination with HIV-1 p24 antigen fused to mycobacterial heat shock protein (Hsp) Hsp71 enhances p24-specific immunity, as measured by p24-specific antibody production and in vitro cell proliferation and cytokine induction. An ovalbumin-Hsp71 fusion protein primes ovalbumin-specific CTL activity and resistance to challenge with an ovalbumin-expressing tumor. We have extended these observations by using a mycobacterial Hsp65 fusion molecule to prime CTL specific for a viral antigen. Gene fusion constructs were generated from DNA encoding Mycobacterium bovis strain BCG Hsp65 and individual fragments of influenza virus nucleoprotein (NP) encompassing H-2Kd- and H-2Db-restricted CTL epitopes. The ability of these purified recombinant fusion proteins to prime NP-specific CTL was assessed in mice of appropriate H-2 haplotypes. We observed that adjuvant-free immunization with either fusion protein elicited significant CTL activity when administered at doses of 10-100 micrograms per mouse. An NP fusion protein made with glutathione-S-transferase failed to elicit NP-specific CTL, indicating that the phenomenon requires Hsp65 sequences. A single immunization with the Hsp65-NP fusion protein elicited CTL activity which persisted for a minimum of 4 months post-immunization, at which time it could be boosted by a second immunization. To our knowledge, this is the first report of a member of the Hsp60 family priming for antigen-specific CTL activity when employed as a fusion protein partner.

A new allelic series for the underwhite gene on mouse chromosome 15.

A new allelic series at the underwhite gene is described. Three of the alleles in the series--uw, uwd, and Uwdbr--arose as spontaneous mutations on different genetic backgrounds at The Jackson Laboratory. We report here the visible phenotypes and dominance hierarchy of these alleles, all of which are defined by a reduction of pigmentation in both eye and coat color. Electron microscopic analysis of retinal epithelium suggests that the primary defect is in the melanosome. The degree of severity of melanosome anomalies in the retina correlates with the degree of hypopigmentation in the coat. The perturbed gene and its gene product are unknown. We show that the uw locus is genetically distinct from Myo10, a suggested candidate gene for this mutation.

Specification of first quartet micromeres in Ilyanassa involves inherited factors and position with respect to the inducing D macromere.

In the embryos of the gastropod Ilyanassa obsoleta, the development of several ectodermal structures requires an inductive interaction between the micromeres and the D macromere. The first quartet micromeres (1a, 1b, 1c and 1d) contribute to the head of the larva and descendants of 1a and 1c normally develop the eyes. The eyes do not develop if 1a and 1c are removed at the eight-cell stage. However, regulative eye development may occur if the precursors of 1a and 1c are removed at the two- or four-cell stage. One purpose of this study was to demonstrate which cells of the cleavage-stage embryo have the potential to develop an eye. The results of blastomere deletion experiments suggest that only the first quartet micromeres have this ability. In addition, the 1b micromere was found to be equivalent to 1a and 1c, but 1d was found to have a poorer eye-forming ability. A second purpose of this study was to examine how eye development is normally restricted to the 1a and 1c micromeres. Cell transplantation experiments demonstrate that the proximity of a first quartet micromere relative to the inducing D macromere is important for determining whether or not it will go on to develop an eye. The 1b micromere may not develop an eye during normal development because it is too far from the D macromere. However, the eye-forming ability of the 1d micromere is not influenced by its close position to the D macromere, but is restricted by its polar lobe lineage.

A new spontaneous mouse mutation of Hoxd13 with a polyalanine expansion and phenotype similar to human synpolydactyly.

Human synpolydactyly (SPD) is an inherited congenital limb malformation caused by mutations in the HOXD13 gene. Heterozygotes are typically characterized by 3/4 finger and 4/5 toe syndactyly with associated duplicated digits; hands and feet of homozygotes are very small because of a shortening of the phalanges, metacarpal and metatarsal bones. Here we describe the phenotype and molecular basis of a spontaneous mutation of Hoxd13 in mice that provides a phenotypically and molecularly accurate model for human SPD. The new mutation, named synpolydactyly homolog (spdh), is a 21 bp in-frame duplication within a polyalanine-encoding region at the 5'-end of the Hoxd13 coding sequence. The duplication expands the stretch of alanines from 15 to 22; the same type of expansion occurs in human SPD mutations. spdh/spdh homozygotes exhibit severe malformations of all four feet, including polydactyly, syndactyly and brachydactylia. The phenotype of spdh is much more severe than that exhibited by mice with a genetically engineered, presumably null, disruption of Hoxd13. Thus spdh probably acts in a dominant-negative manner and will be valuable for examining interactions with other Hox genes and their protein products during limb development. Homozygous mice of both sexes also lack preputial glands and males do not breed; therefore, spdh/spdh mice may also be valuable in studies of reproductive physiology and behavior.

Cryopreservation and orthotopic transplantation of mouse ovaries: new approach in gamete banking.

Mouse half ovaries were cryopreserved and orthotopically transplanted into ovariectomized recipients genetically identical to ovary donors except for the coat color gene. Fertility was reestablished in 57% of the female recipients, which became pregnant in an average of 40 days after transplantation of frozen-thawed half ovaries. These experiments demonstrate that ovary cryopreservation can be a very useful option for banking mouse germplasm, or managing subfertile animal colonies, when embryo or sperm freezing cannot be used or is not cost effective.

Birthdate and cell marker analysis of scrambler: a novel mutation affecting cortical development with a reeler-like phenotype.

The reeler mutation in mice produces an especially well characterized disorder, with systematically abnormal migration of cerebral cortical neurons. The reeler gene encodes a large protein, termed Reelin, that in the cortex is synthesized and secreted exclusively in the Cajal-Retzius neurons of the cortical marginal zone (D'Arcangelo et al., 1995). In reeler mutant mice, loss of Reelin protein is associated with a systematic loss of the normal, "inside-out" sequence of neurogenesis in the cortex: neurons are formed in the normal sequence but become localized in the cortex in a somewhat inverted, although relatively disorganized "outside-in" pattern. Here we show that the scrambler mutant mouse exhibits a loss of lamination in the cortex and hippocampus that is indistinguishable from that seen in the reeler mouse. We use BrdU birthdating studies to show that scrambler cortex shows a somewhat inverted "outside-in" sequence of birthdates for cortical neurons that is similar to that previously described in reeler cortex. Finally, we perform staining with the CR-50 monoclonal antibody (Ogawa et al., 1995), which recognizes the Reelin protein (D'Arcangelo et al., 1997). We show that Reelin immunoreactivity is present in the scrambler cortex in a normal pattern, suggesting that Reelin is synthesized and released normally. Our data suggest that scrambler is a mutation in the same gene pathway as the reeler gene (Relnrl) and is most likely downstream of Relnrl.

Cerebellar disorganization characteristic of reeler in scrambler mutant mice despite presence of reelin.

Analysis of the molecular basis of neuronal migration in the mammalian CNS relies critically on the discovery and identification of genetic mutations that affect this process. Here, we report the detailed cerebellar phenotype caused by a new autosomal recessive neurological mouse mutation, scrambler (gene symbol scm). The scrambler mutation results in ataxic mice that exhibit several neuroanatomic defects reminiscent of reeler. The most obvious of these lies in the cerebellum, which is small and lacks foliation. Granule cells, although normally placed in an internal granule cell layer, are greatly reduced in number ( approximately 20% of normal). Purkinje cells are also reduced in number, and the majority are located ectopically in deep cerebellar masses. There is a small population of Purkinje cells ( approximately 5% of the total) that occupy a Purkinje cell layer between the molecular and granule cell layers. Despite this apparent disorganization of Purkinje cells, zebrin-positive and zebrin-negative parasagittal zones can be delineated. The ectopic masses of Purkinje cells are bordered by the extracellular matrix protein tenascin and by processes containing glial fibrillary acidic protein. Antibodies specific for these proteins also identify a novel midline raphe structure in both scrambler and reeler cerebellum that is not present in wild-type mice. Thus, in many respects, the scrambler cerebellum is identical to that of reeler. However, the scrambler locus has been mapped to a site distinct from that of reelin (Reln), the gene responsible for the reeler defect. Here we find that there are normal levels of Reln mRNA in scrambler brain and that reelin protein is secreted normally by scrambler cerebellar cells. These findings imply that the scrambler gene product may function in a molecular pathway critical for neuronal migration that is tightly linked to, but downstream of, reelin.

Genetic and physical maps of the stargazer locus on mouse chromosome 15.

The stargazer mouse mutation causes absence seizures that are more prolonged and frequent than any other petit mal mouse model. Stargazer mice also have an ataxic gait and vestibular problems, including a distinctive head-tossing motion. From the genotyping of a large intersubspecific cross, a panel of 53 recombinant DNAs between D15Mit29 and D15Mit2 has been assembled, and a fine genetic map of the stargazer region has been constructed on mouse Chromosome 15. The stargazer locus has been mapped between D15Mit30 and the parvalbumin gene, and six candidate genes have been excluded by genetic linkage analysis. A physical contig of YACs, BACs, and P1s stretching 1.1 Mb from D15Mit30 to the somatostatin receptor 3 gene is reported, and the DNA interval including the stargazer locus has been narrowed to 150 kb.

Scrambler, a new neurological mutation of the mouse with abnormalities of neuronal migration.

A novel spontaneous neurological mutation, scrambler (scm), appeared in the inbred mouse strain DC/Le (dancer) in 1991. Mice homozygous for this recessive mutation are recognized by an unstable gait and whole-body tremor. The cerebella of 30-day-old scrambler homozygotes are hypoplastic and devoid of folia; however, neither seizures nor abnormal brain wave patterns have been observed. Homozygous scrambler mutants have an ataxic gait which in the male may be a contributory factor in the failure to mate. Female homozygotes mate and breed. Life span is not reduced in either sex. Scrambler is similar to the reeler mutation in phenotype and pathology and, like reeler, probably results from defective neuronal migration. We mapped the scrambler mutation to Chromosome (Chr) 4, proving that it is distinct from the recently cloned reeler gene on Chr 5. We also determined the map position of the agrin gene, Agrn, on Chr 4, and on this basis eliminated it as a candidate for scm. Currently there is no known homology of scrambler with human lissencephalies or other human disorders caused by abnormal neuronal migration.

The neurological mouse mutations jittery and hesitant are allelic and map to the region of mouse chromosome 10 homologous to 19p13.3.

Jittery (ji) is a recessive mouse mutation on Chromosome 10 characterized by progressive ataxic gait, dystonic movements, spontaneus seizures, and death by dehydration/starvation before fertility. Recently, a viable neurological recessive mutation, hesitant, was discovered. It is characterized by hesitant, unco-ordinated movements, exaggerated stepping of the hind limbs, and reduced fertility in males. In a complementation test and by genetic mapping we have shown here that hesitant and jittery are allelic. Using several large intersubspecific backcrosses and intercrosses we have genetically mapped ji near the marker Amh and microsatellite markers D10Mit7, D10Mit21, and D10Mit23. The linked region of mouse Chromosome 10 is homologous to human 19p13.3, to which several human ataxia loci have recently been mapped. By excluding genes that map to human 21q22.3 (Pfkl) and 12q23 (Nfyb), we conclude that jittery is not likely to be a genetic mouse model for human Unverricht-Lundborg progressive myoclonus epilepsy (EPM1) on 21q22.3 nor for spinocerebellar ataxia II (SCA2) on 12q22-q24. The closely linked markers presented here will facilitate positional cloning of the ji gene.

Dense incisors (din): a new mouse mutation on chromosome 16 affecting tooth eruption and body size.

Dense incisors (din) is a new autosomal recessive mutation in the mouse that interferes with complete eruption of the incisors. The initial eruption of incisors through the gingiva does not differ in mutants and normal littermates, but subsequent further eruption of incisors is arrested in mutants. Radiographic examinations show that, because the incisors do not erupt, continued dentin formation gradually occludes the pulp chambers of these teeth creating as dense incisor. The arrested eruption of the incisor results in an anterior open bite. The pleiotropic phenotype of din/din mutant mice also includes small body size, reduced ear pinna size, and coat color dilution. The din mutation was mapped to Chr 16 near the pituitary transcription factor gene Pit1, but din is not a mutation in Pit1.

Mesenchymal dysplasia: a recessive mutation on chromosome 13 of the mouse.

Mesenchymal dysplasia (mes) is a new autosomal recessive mouse mutation that alters normal growth of mesenchyme-derived tissues and provides a new mouse model for studying connective tissue development and defects. Mutants are characterized by preaxial polydactyly of all four feet, a shortened face, wide set eyes, domed head, and a shortened kinky tail. Multiple skeletal defects are seen in alizarin-stained specimens. Histological, areas of mineralization are found in tendons. Mutants also have increased musculature in the shoulders and hips and decreased peritoneal fat. Salivary glands, testes, and kidneys are smaller than in littermates. Mesenchymal dysplasia has been mapped to mouse chromosome (Chr) 13. These mapping crosses also confirmed that the Purkinje cell degeneration (pcd) mutation is on Chr 13.

The stumbler mutation maps to proximal mouse chromosome 2.

The cerebellar mouse mutation stumbler (stu) was mapped to proximal Chromosome (Chr) 2 with a recently developed polymerase chain reaction assay for endogenous retroviruses that vary between mouse strains. The stu locus resides between the markers D2Mit5 and D2Mit7. A number of developmentally or neurologically relevant candidate genes map in this region, including Bmi1, Dbh, Grin1, Notch1, Pax8, Rxra, and Spna2. Knowing the chromosomal localization of stu should simplify maintenance of the stumbler mouse stock and also enable analysis of the cerebellar defect in presymptomatic individuals.

Differential expression of a new dominant agouti allele (Aiapy) is correlated with methylation state and is influenced by parental lineage.

The agouti gene normally confers the wild-type coat color of mice. Dominant mutations at the agouti locus result in a pleiotropic syndrome that is characterized by excessive amounts of yellow pigment in the coat, obesity, a non-insulin-dependent diabetic-like condition, and the propensity to form a variety of tumors. Here, we describe a new dominant mutation at the agouti locus in which an intracisternal A-particle (IAP) has integrated in an antisense orientation immediately 5' of the first coding exon of the gene. This mutation, which we have named Aiapy, results in the ectopic expression of the agouti gene through the utilization of a cryptic promoter within the IAP 5' long terminal repeat (LTR). The coat color of Aiapy/-mice ranges from solid yellow to a pigment pattern that is similar to wild type (pseudoagouti), and the expressivity of this mutant phenotype varies with parental inheritance. Those offspring with a yellow coat ectopically express agouti mRNA at high levels and exhibit marked obesity, whereas pseudoagouti mice express agouti mRNA at a very low level and their weights do not differ from wild-type littermates. Data are presented to show that the differential expressivity of the Aiapy allele is correlated with the methylation status of the inserted IAP 5' LTR. These data further support the hypothesis that in dominant yellow mutations at the agouti locus, it is the ubiquitous expression of the wild-type agouti coding sequence that is responsible for the yellow coat color, obesity, diabetes, and tumorigenesis.

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.