Effects of fatty (fa) allele and high-fat diet on adipose tissue leptin and lipid metabolism.

Leptin is an adipocyte-secreted hormone that binds hypothalamic receptors and potently decreases food intake. Leptin receptor defects in homozygous mutant Zucker fatty ( fa/fa) rats lead to massive obesity, hyperphagia, decreased energy expenditure, and insulin resistance, while the phenotype of heterozygous ( Fa/fa) lean rats lies between lean ( Fa/Fa) and obese ( fa/fa) rats. Whether heterezygotes exhibit specific changes in lipid metabolism in a diet-responsive manner is not clear. Thus, the specific aim of this study was to test whether the presence of one fa allele modulates lipid metabolism and leptin, and whether these effects are exacerbated by high-fat diet. We demonstrate that the presence of one fa allele significantly increases lipogenesis in adipose tissue assessed by glycerol-3-phosphate dehydrogenase (GPDH) and fatty acid synthase (FAS) activities. FAS is more responsive to high-fat diets than GPDH in Fa/fa rats. Adipose tissue leptin levels are significantly higher in fat pads of Fa/fa compared to Fa/Fa rats. Moreover, Fa/fa rats fed high-fat diet show an additional two-fold increase in leptin levels compared to wild type rats on the same diet. Collectively, these results indicate that the presence of one fa allele increase adipocyte lipogenic enzyme activities, which results in hyperleptinemia concurrent with increased adiposity.

A developmental switch affecting growth of fatty rats.

Fatty (fa/fa) rats accumulate more adipose mass than their littermates soon after birth, but they first appear obese during the fourth week of life. We analyzed the effects of fa genotype on growth of pups housed with their dams through 4 wk of age. The fa genotype effects on daily gain were undetectable from 7 to 22 days of age but became highly significant (P = 10(-18)) at 23 days of age. When litters were reduced to 4 pups, fa genotype effects on daily gain also became detectable at 23 days of age. The fa genotype effects on daily gain, stomach contents weight, liver weight, and plasma insulin of rats killed from 20 to 24 days of age displayed a marked genotype by age interaction, becoming highly significant at 23 days of age. These changes occur without the environmental changes induced by separating pups from their dams. These observations suggest that a developmental switch triggers hyperphagia and rapidly increases growth rate of fatty rats after 22 days of age.

Eradication of infection with Helicobacter spp. by use of neonatal transfer.

BACKGROUND AND PURPOSE: Efficient methods for detection and elimination of Helicobacter spp. infections are needed to facilitate the development of Helicobacter-free mouse colonies. We developed an inexpensive, high-throughput method for preparation of fecal DNA for Helicobacter polymerase chain reaction (PCR) assays. METHODS: Fecal DNA was prepared by heating fecal pellets to 95 degrees C for 10 minutes in an alkaline solution, then adjusting the pH by addition of Tris buffer. This solution is used for PCR assays without purification of DNA. We then tested fostering as a method of generating Helicobacter-free mice. Litters born to Helicobacter-positive dams were transferred to Helicobacter-negative foster dams on the first day of life. RESULTS: Fostered pups tested Helicobacter negative up to 89 days of age, whereas pups raised by Helicobacter-positive dams were all test positive by 19 days of age. CONCLUSION: These simple methods provide an efficient system for the development of Helicobacter-free mouse colonies.

Misty (m) affects growth traits.

The misty (m) coat color mutation is commonly maintained in linkage disequilibrium with the obesity mutation diabetes (Leprdb) to serve as a marker for Leprdb genotype. Comparisons among Leprdb genotypes are made under the untested assumption that m has no effects on traits under investigation. We tested this assumption in a population segregating m in the absence of db. Analysis of growth curves revealed that m/m mice are smaller than M/M mice by the 2nd wk of life and remain smaller through the 5th wk of life. Analysis of variance of three traits measured at 35 days of age revealed that m/m mice are 8% shorter than M/M mice, weigh 15% less, and have 21% less inguinal adipose mass. These results indicate that m affects growth traits. Therefore, when m and Leprdb segregate in the same cross, interpretation of their effects is confounded by linkage. More accurate estimates of Leprdb genotype effects can be made by removing m from populations segregating Leprdb and using a direct assay to measure Leprdb genotype.

ELISA detection of restriction site polymorphisms in the pig ryanodine receptor locus.

We compare two strategies for ELISA detection of restriction site polymorphisms (EDRSP) that are suitable for high-throughput genotyping of the pig ryanodine receptor point mutation (RYR1(hal)). In both procedures, target DNA is amplified by PCR with one primer that is 5' biotinylated and a second primer that is 5' fluoresceinylated. PCR products are captured in duplicate wells on a streptavidin-coated, 96-well plate. The duplicates may be treated in two ways. In a single restriction enzyme assay, one duplicate is exposed to a restriction enzyme that cuts one allele specifically, and the second duplicate is exposed to no restriction enzyme. In a dual restriction enzyme assay, the second replicate is exposed to a second restriction enzyme that cuts the alternate allele specifically. Thereafter, the two procedures are similar; anti-fluorescein antibodies conjugated to peroxidase are allowed to bind to the fluoresceinylated ends, the plate is washed, and a substrate is converted to a colored end product. The ratio of the absorbances in the two wells is used to classify subjects by genotype. When the dual restriction enzyme assay is run, three genotype groups are easily distinguishable. When the single restriction enzyme assay is run, heterozygotes generate values that may overlap with those of the homozygotes that are not cut by the restriction enzyme. Dual restriction enzyme assays are more accurate than single restriction enzyme assays; however, single restriction enzyme assays are sufficient for identifying pigs that carry RYR1(hal).

Dietary fat and sex modify heterozygote effects of the rat fatty (fa) allele.

Rats carrying one copy of the obesity gene fa may exhibit intermediate phenotypes between lean (+/+) and homozygous mutants (fa/fa). Previous data suggested to us that fa heterozygotes may be more sensitive than wild-type rats to high fat diets. To test this hypothesis, we generated +/+ and fa/+ rats and fed them diets containing 12% or 48% energy as fat for 7 wk. Energy efficiency was significantly greater in males than in females and in high fat-fed vs. low fat-fed rats. Perirenal fat pad weights were significantly greater in males than in females, in high fat-vs. low fat-fed rats and in fa/+ vs. +/+ rats. Adipose and soleus plasma membrane calcium-ATPase concentrations were significantly lower in rats fed the high fat diet. This protein was also lower in soleus of fa/+ rats compared with +/+ rats. There were significant diet x genotype interactions such that the high fat diet had the greatest effect on fat pads and calcium-ATPase in fa/+ rats. The results of the present study show heterozygote effects of the fa allele and suggest that these effects may be modulated by both sex-related factors and dietary manipulation.

A rat homolog of the mouse deafness mutant jerker (je).

An autosomal recessive deafness mutant was discovered in our colony of Zucker (ZUC) rats. These mutants behave like shaker-waltzer deafness mutants, and their inner ear pathology classifies them among neuroepithelial degeneration type of deafness mutants. To determine whether this rat deafness mutation (-) defines a unique locus or one that has been previously described, we mapped its chromosomal location. F2 progeny of (Pbrc:ZUC x BN/Crl) A/a B/b H/h +/- F1 rats were scored for coat color and behavioral phenotypes. Segregation analysis indicated that the deafness locus might be loosely linked with B on rat Chromosome (Chr) 5 (RNO5). Therefore, 40 -/- rats were scored for BN and ZUC alleles at four additional loci, D5Mit11, D5Mit13, Oprd1, and Gnb1, known to map to RNO5 or its homolog, mouse Chr 4 (MMU4). Linkage analysis established the gene order (cM distance) as D5Mit11-(19.3)-B-(17.9)-D5Mit13-(19. 2)-Oprd1-(21.5) - (1.2) Gnb1, placing the deafness locus on distal RNO5. The position of the deafness locus on RNO5 is similar to that ofjerker (je) on MMU4; the phenotypes and patterns of inheritance of the deafness mutation and je are also similar. It seems likely that the mutation affects the rat homolog of je. The rat deafness locus should, therefore, be named jerker and assigned the gene symbol Je.

Quantitative analysis of abnormal spontaneous behavior and clinical assessment of the stargazer rat.

A new mutant derived from the Zucker rat strain called stargazer (homozygous stg/stg) displays abnormal behavior that is characterized by pronounced arching of the neck ("stargazing"), rapid circling, and conspicuous hyperactivity. Results of serologic assays performed by two independent diagnostic laboratories have indicated that the abnormal behavior in the stargazer is not the result of a viral or bacterial infection. In this report, different groups of stargazer rats and their normal-behaving littermates (heterozygous stg/+) were assessed with regard to spontaneous behaviors, heart rate, blood pressure, and plasma biochemical profiles. Besides frequent stargazing, the predominant behavioral feature of the stargazers was extreme hyperactivity; they had sevenfold greater activity than the normal littermates (P < 0.05), expressed in the form of rapid ambulation and tail-chasing. The stargazers had significantly greater daily calorie and water consumption, despite being significantly smaller in body weight than the littermates (P < 0.05 for all). However, urine output was not different between the two groups. Heart rate and blood pressure also were not different. Stargazers had significantly lower total triglycerides concentration and lower aminotransferase activity than littermates (P < 0.05 for both), a finding probably related to their smaller body size. It is concluded that stargazer rats are extremely hyperactive but normotensive; heterozygous littermates are behaviorally normal, despite being carriers of the stg gene; and routine diagnostic blood testing revealed no important differences between the stargazers and their unaffected littermates.

Codominant effects of the fatty (fa) gene during early development of obesity.

Expression of a single copy of the rat obesity fatty (fa) gene may affect energy balance. To test this hypothesis, the effects of zero, one, and two copies of fa on early growth were evaluated, using a molecular genetic method for counting fa alleles inherited by 7- and 14-day-old F2 offspring of a BN/Crl x Crl:ZUC-fa F1 intercross. Litter and sex effects were controlled by multiple-regression analysis, allowing genotype effects on the weights of body, inguinal adipose pads, interscapular brown adipose tissue, and liver to be isolated. At 7 days of age, the fa copy number had linear effects on body and inguinal adipose pads weight. At 14 days of age, the fa copy number had linear effects on body, inguinal adipose pads, and interscapular brown adipose tissue weights and an additional quadratic effect on inguinal adipose pads weight. Thus fa has codominant effects on growth during the first week of life. The recessive effects of fa on growth appear during the second week of life.

Genetic map of rat chromosome 5 including the fatty (fa) locus.

Thirteen loci, including the obesity gene fatty (fa), were incorporated into a linkage map of rat Chromosome (Chr) 5. These loci were mapped in obese (fa/fa) progeny of a cross between BN x 13M-fal+F1 animals. Obese rats were scored for BN and 13M alleles at four loci (Ifna, D1S85h, C8b, and Lck1) by restriction fragment length polymorphisms and at eight additional loci (Glut1, Sv4j2, R251, R735, R980, R252, R371, and R1138) by simple sequence length polymorphisms (SSLP). The resulting map spans 67.3 cM of Chr5, presenting nine previously unmapped loci and one locus (Lck1) previously assigned to Chr 5 by use of somatic cell hybrid lines. Seven of the eight SSLP loci are newly identified; the SSLP linkage group alone spans 56.8 cM. The order of the loci is Sv4j2-R251-R735-R980-R1138-Ifna-fa-+ ++D1S85h-C8b-(Glut1-R252-R371)-Lck1. One locus, D1S85h, was found to lie only 0.4 cM from fa, close enough to serve as a reliable marker for the prediction of phenotype from genotype, and will be useful also for studies on the development of obesity in the fatty rat.

Stargazer (stg), new deafness mutant in the Zucker rat.

We describe a new deafness mutant found in the Zucker rat. The mutant phenotype appears to be caused by an autosomal recessive gene, tentatively named stargazer, gene symbol stg. The phenotype is characterized by stargazing, head tossing, drawing back, circling, and hyperactivity, all of which are apparent by the third week of life. Although the affected animals sire or bear normal-sized litters, mortality is high for litters of affected dams, apparently due to trampling or neglect by the hyperactive dams. Affected animals are unable to swim and, when lifted by the tail, they are likely to curl ventrally, rather than extending their paws downward. These behaviors are consistent with a disorder of the vestibular system. Auditory evoked potential recordings were attempted as a hearing test. The failure of audible clicks up to 90 decibels to stimulate the auditory tract indicates that stargazers are profoundly deaf. These disruptions of vestibular and auditory systems suggest that the stargazer phenotype may be caused by disordered development of the inner ear. Histologic examination of the inner ear revealed progressive degeneration of cells in the acoustic ganglion and of hair cells. The stargazer rat may be useful as a model for hereditary deafness or hyperactivity.

Dietary obesity linked to genetic loci on chromosomes 9 and 15 in a polygenic mouse model.

Loci linked to sensitivity to dietary obesity were identified by Quantitative Trait Locus (QTL) analysis of two mapping populations derived from a cross between AKR/J and SWR/J mice. AKR/J mice are sensitive to dietary obesity when fed a high fat diet while SWR/J mice are resistant. Intercrosses between these strains segregate the phenotype of sensitivity to dietary obesity. Using an F2 mapping population of 931 male mice we found significant linkage with a QTL on chromosome 9 (Likelihood of the Odds [LOD] ratio of 4.85) and another QTL on chromosome 15 (LOD = 3.93). The presence of a QTL on chromosome 15 was confirmed in a separate mapping population of 375 male F1 x SWR/J mice (LOD = 3.82). These two loci are designated dietary obese 2 (Do2) and dietary obese 3 (Do3) for the chromosome 9 and 15 loci, respectively. Both of these chromosomal regions contain candidate genes which may contribute to variation in the phenotype. These loci also exert a significant control over individual adipose depot weights.

Utility of a C-jun microsatellite marker in determining gene dosage for fatty (fa).

The Zucker fatty (fa) mutation provides a genetic model for obesity and non-insulin dependent diabetes mellitus. The molecular pathogenesis of the metabolic phenotype of these animals is not known. Detailed molecular maps of the region surrounding the fa locus on rat chromosome 5 can be used for positional cloning experiments as well as to permit genotyping of animals from appropriate crosses before the confounding metabolic effects of obesity have occurred. We describe the development of a polymerase chain reaction (PCR) assay for a polymorphic simple sequence repeat (SSR) in the promoter region of the protooncogene c-Jun. This assay was used to position c-Jun 4.5cM proximal to the fa locus in 111 F2 progeny of a 13MBN fa/+ F1 intercross. Concurrent use of the c-Jun SSR with a previously described assay for a microsatellite in the glucose transporter, Glut1, permits rapid and accurate assessment of genotypes at the fa locus in animals of any age using minimal amounts of DNA. A strategy is described which minimizes the error rate in assigning genotype at the fatty locus for backcross and intercross progeny.

A molecular genetic method for genotyping fatty (fa/fa) rats.

After three decades of physiological research, the precise nature of the genetic lesion in Zucker fatty (fa/fa) rats remains unknown. Several methods have been used to identify preobese rats to detect the earliest phenotypic effects of the fa mutation. Most of these methods have used phenotypic characteristics that are not reliable until the second week of life, when increased adiposity is already evident. We have used a restriction fragment length polymorphism (RFLP) for a human genomic DNA probe (VC85) that is tightly linked to the fa locus on rat chromosome 5 to genotype the F2 progeny of a Zucker (13M) x Brown Norway (BN) fa/+ F1 intercross. Sixty-four rats, comprising five litters, were killed at 5-6 wk of age. DNA was isolated either from tail at age 4-7 days (36 rats) or from organs at the time of death (28 rats). Adiposity was scored using inguinal fat pad weight as a percentage of body weight. RFLP analysis was > 99% accurate in identifying obese (fa/fa) rats. This molecular genetic method can be used to genotype fatty rats from an appropriate genetic cross at any age, even prenatally. Moreover, this method can distinguish heterozygous from homozygous littermates, enabling an analysis of gene dosage effects.

The Zucker fatty (fa) gene is not a mutation of corticotropin-releasing factor.

Corticotropin-releasing factor (CRF) appears to regulate several physiological systems that display prominent abnormalities in Zucker fatty (fa/fa) rats, including the hypothalamic-pituitary-adrenal axis, the autonomic nervous system, and feeding behavior. Moreover, central administration of CRF ameliorates the obese phenotype. In light of these observations, the gene for CRF is a plausible candidate for the defective gene in the Zucker fatty rat. We report here the use of molecular genetic linkage analysis to test the hypothesis that fa is a mutant allele of the CRF gene. A restriction fragment length polymorphism for CRF between Zucker (13M) and Brown Norway (BN) DNA allowed us to examine segregation of 13M and BN CRF alleles relative to fa in 58 obese (fa/fa) F2 progeny of a 13MBN fa/+F1 intercross. If fa = CRF, all animals homozygous for the fatty mutation should be homozygous for the 13M CRF allele. However, only 10/58 fa/fa animals were homozygous for the 13M CRF allele, indicating that fa and CRF are not allelic. Thus, although CRF may be important in the physiology of Zucker rat obesity, fa is not a CRF mutation. Using a mouse C57BL/6J Spretus F1 x C57BL DBA/2J F1 intercross, we were able to demonstrate that the mouse CRF gene is linked to the carbonic anhydrase II (Car-2) gene on mouse chromosome 3, in a region of synteny-homology with rat chromosome 2. Thus the rat CRF gene is probably located on chromosome 2.

Rat obesity gene fatty (fa) maps to chromosome 5: evidence for homology with the mouse gene diabetes (db).

The autosomal recessive mutations fa (rat) and db (mouse) cause obesity syndromes that develop early and ultimately become severe. Although both fa/fa rats and db/db mice have been studied extensively as models of human obesity and diabetes, the molecular bases of these phenotypes remain unknown. We have mapped fa in 50 fa/fa (obese) offspring of a (13M x Brown Norway) F1 fa/+ intercross relative to two molecular markers, Ifa and Glut-1, which flank db on mouse chromosome 4 and which are located on rat chromosome 5. Ifa and Glut-1 are linked to fa, with a gene order, Ifa-fa-Glut-1, that is identical to that for the region around db in the mouse genome. These results place fa on rat chromosome 5 and suggest that db and fa are mutations in homologous genes.