Molecular Markers for the agouti Coat Color Locus of the Mouse

The agouti (a) coat color locus of the mouse acts within the microenvironment of the hair follicle to control the relative amount and distribution of yellow and black pigment in the coat hairs. Over 18 different mutations with complex dominance relationships have been described at this locus. The lethal yellow (Ay) mutation is the top dominant of this series and is uniquely associated with an endogenous provirus, Emv-15, in three highly inbred strains. However, we report here that it is unlikely that the provirus itself causes the Ay-associated alteration in coat color, since one strain of mice (YBR-Ay/a) lacks the provirus but still retains a yellow coat color. Using single-copy mouse DNA sequences from the regions flanking Emv-15 we have detected three patterns of restriction fragment length polymorphisms (RFLPs) within this region that can be used as molecular markers for different agouti locus alleles: a wild-type agouti (A) pattern, a pattern which generally cosegregates with the nonagouti (a) mutation, and a pattern which is specific to Emv-15. We have used these RFLPs and a panel of 28 recombinant inbred mouse strains to determine the genetic linkage of these sequences with the agouti locus and have found complete concordance between the two (95% confidence limit of 0.00 to 3.79 centimorgans). We have also physically mapped these sequences by in situ hybridization to band H1 of chromosome 2, thus directly confirming previous assignments of the location of the agouti locus.     

Physical and Genetic Characterization of a 75-Kilobase Deletion Associated with A(l), a Recessive Lethal Allele at the Mouse Agouti Locus

The agouti locus (A) of the mouse determines the timing and type of pigment deposition in the growing hair bulb, and several alleles at this locus are lethal when homozygous. Apparent instances of intragenic recombination and complementation between different recessive lethal alleles have suggested that the locus has a complex structure. We have begun to investigate the molecular basis of agouti gene action and recessive lethality by using a series of genetically linked DNA probes and pulsed field gel electrophoresis to detect structural alterations in radiation-induced agouti mutations. Hybridization probes from the Src and Emv-15 loci do not reveal molecular alterations in DNA corresponding to the ae, ax, and al alleles, but a probe from the parotid secretory protein gene (Psp) detects a 75-kilobase (kb) deletion in DNA containing the non-agouti lethal allele (al). The deletion is defined by a 75-kb reduction in the size of BssHII, NotI, NruI and SacII high molecular weight restriction fragments detected with the Psp probe and is located between 25 kb and 575 kb from Psp coding sequences. Because the genetic distance between A and Emv-15 is much less than A and Psp, there may be a preferred site of recombination close to Psp, or suppression of recombination between A and Emv-15. The al deletion has allowed us to determine the genotype of mice heterozygous for different recessive lethal alleles. We find that three different recessive lethal complementation groups are present at the agouti locus, two of which are contained within the al deletion.     

Allelic Variation within the Emv-15 Locus Defines Genomic Sequences Closely Linked to the agouti Locus on Mouse Chromosome 2

Gene(s) at the agouti locus act within the microenvironment of the hair follicle to switch pigment synthesis in the melanocyte between eumelanin (black or brown pigment) and phaeomelanin (yellow pigment). Many phenotypic variants of this locus have been described. The mechanism(s) of gene action causing such variation in coat-color phenotype is not known. The close linkage of an endogenous ecotropic murine leukemia provirus, Emv-15, to the lethal yellow mutation of the agouti locus provides a means to molecularly access genes at or near the agouti locus. We have identified and used a unique mouse sequence flanking the Emv-15 provirus to define three alleles of the Emv-15 locus. We found a correlation between the presence of specific Emv-15 alleles and the origins of specific agouti locus mutations, confirming close linkage. However, we found some exceptions which suggest that the Emv-15 locus is closely linked to, but genetically separable from, the agouti locus.     

Effects of the lethal yellow (Ay) mutation in mouse aggregation chimeras

The Ay allele is a recessive lethal mutation at the mouse agouti locus, which results in embryonic death around the time of implantation. In the heterozygous state, Ay produces several dominant pleiotropic effects, including an increase in weight gain and body length, a susceptibility to hepatic, pulmonary and mammary tumors, and a suppression of the agouti phenotype, which results in a yellow coat color. To investigate the cellular action of Ay with regard to its effects upon embryonic viability and adult-onset obesity, we generated a series of aggregation chimeras using embryos that differ in their agouti locus genotype. Embryos derived from Ay/a x Ay/a matings were aggregated with those derived from A/A x A/A matings, and genotypic identification of the resultant chimeras was accomplished using a molecular probe at the Emv-15 locus that distinguishes among the three different alleles, Ay, A, and a. Among 50 chimeras, 25 analyzed as liveborns and 25 as 9.5 day embryos, 29 were a/a in equilibrium A/A and 21 were Ay/a in equilibrium A/A. The absence of Ay/Ay in equilibrium A/A chimeras demonstrates that Ay/Ay cells cannot be rescued in a chimeric environment, and the relative deficiency of Ay/a in equilibrium A/A chimeras suggests that, under certain conditions, Ay heterozygosity may partially affect cell viability or proliferation. In the 25 liveborn chimeras, Ay/a in equilibrium A/A animals became obese as adults and a/a in equilibrium A/A animals did not. There was no correlation between genotypic proportions and rate of weight gain, which shows that, with regard to its effects on weight gain, Ay heterozygosity is cell non-autonomous.     

Recombinant Inbred Strain and Interspecific Backcross Analysis of Molecular Markers Flanking the Murine Agouti Coat Color Locus

Recombinant inbred strain and interspecific backcross mice were used to create a molecular genetic linkage map of the distal portion of mouse chromosome 2. The orientation and distance of the Ada, Emv-13, Emv-15, Hck-1, Il-1a, Pck-1, Psp, Src-1 and Svp-1 loci from the beta 2-microglobulin locus and the agouti locus were established. Our mapping results have provided the identification of molecular markers both proximal and distal to the agouti locus. The recombinants obtained provide valuable resources for determining the direction of chromosome walking experiments designed to clone sequences at the agouti locus. Comparisons between the mouse and human genome maps suggest that the human homolog of the agouti locus resides on human chromosome 20q. Three loci not present on mouse chromosome 2 were also identified and were provisionally named Psp-2, Hck-2 and Hck-3. The Psp-2 locus maps to mouse chromosome 14. The Hck-2 locus maps near the centromere of mouse chromosome 4 and may identify the Lyn locus. The Hck-3 locus maps near the distal end of mouse chromosome 4 and may identify the Lck locus.     

Molecular characterization of the mouse agouti locus.

The agouti (a) locus acts within the microenvironment of the hair follicle to regulate coat color pigmentation in the mouse. We have characterized a gene encoding a novel 131 amino acid protein that we propose is the one gene associated with the agouti locus. This gene is normally expressed in a manner consistent with a locus function, and, more importantly, its structure and expression are affected by a number of representative alleles in the agouti dominance hierarchy. In addition, we found that the pleiotropic effects associated with the lethal yellow (Ay) mutation, which include pronounced obesity, diabetes, and the development of neoplasms, are accompanied by deregulated overexpression of the agouti gene in numerous tissues of the adult animal.     

The long-range restriction map surrounding the mouse agouti locus reveals a disparity between physical and genetic distances

Isolation of a gene based on its location, which depends on aligning physical landmarks with the genetic map, can yield basic information about genome structure and organization. As a first step toward isolating the mouse agouti (A) locus, we have begun to define the physical position of this gene relative to genetically linked DNA probes from the Psp, Emv-15, and Src loci. Using a combination of pulsed-field gel techniques that include partial digestion with rare-cutting restriction enzymes and analysis of polymorphic sites present in certain inbred strains, we have constructed long-range restriction maps for each of the probes that span a total of more than 3000 kb. The Src and Emv-15 probes are less than 600 kb apart, but are separated from the Psp probe by at least 1500 kb. By determining the position of a 75-kb deletion that inactivates agouti function, we have localized the A locus to within 500 kb of the Psp probe, but more than 600 kb away from the Emv-15 probe. These physical distances contrast with the known recombination frequencies, 3 +/- 3 cM for A-Psp and less than 0.3 cM for A-Emv-15, and suggest that recombination between A and Emv-15 may be suppressed.     

Chromosomal assignment of two endogenous ecotropic murine leukemia virus proviruses of the AKR/J mouse strain.

The AKR/J mouse strain is genetically fixed for three different ecotropic murine leukemia virus genomes, designated Akv-1, Akv-3, and Akv-4 (Emv-11, Emv-13, and Emv-14). With recombinant inbred strains and crosses with linkage-testing stocks, Akv-3 and Akv-4 were placed on the mouse chromosome map. Akv-3, which encodes a replication-defective provirus, maps near the agouti coat color locus, a, on chromosome 2. Akv-4, which is replication competent, maps near the neurological mutant gene locus trembler, Tr, on chromosome 11. Akv-1 and Akv-2 (Emv-12), an ecotropic provirus carried by AKR/N but not AKR/J, have previously been mapped to chromosome 7 and 16, respectively. Thus, the four Akv proviruses mapped to date are on four different chromosomes. Akv-3 is the second ecotropic murine leukemia virus provirus to be mapped near the agouti locus. The results are discussed in relation to possible nonrandomness of viral integration.     

Differentiation of hairbulb pigment cell melanosomes in compound agouti and albino locus mouse mutants (Ay, a, c2J; C57BL/6J)

Our objective was to determine using electron microscopy how nonagouti (a), lethal yellow (Ay), and albino (c2J) genes affect the program of mouse hairbulb melanosome differentiation; 1,921 hairbulb melanosomes from four genotypes (a/a C/C = B,Ay/a C/C = Y, a/a c2J/c2J = BA, and Ay/a c2J/c2J = YA) were scored for developmental stage, length, and width. Qualitative and quantitative electron microscopy revealed the following. An albino locus-induced diminution of melanosome size suggests that the albino locus is involved in structural features of melanosomes not directly related to the synthesis and deployment of tyrosinase. Ratio data on melanosome length-to-width confirm that the agouti locus determines melanosome shape, either spherical or elliptical; melanization is not required for melanosomes to achieve their agouti-locus-determined shapes. YA (Ay/a c2J/c2J) melanosomes, characterized by poorly organized matrices, absence of active tyrosinase, unusually large membrane invaginations, and significantly smaller dimensions than those of BA (a/a c2J/c2J), showed additive effects of both Ay and c2J alleles. These data suggest that the albino locus plays a structural as well as functional (tyrosinase) role in the differentiation of mouse hairbulb melanosomes. The agouti locus, even in the absence of melanization, directs melanosome shape either via synthesis and deployment of agouti-locus-encoded matrix proteins or by other structural factors. The additive effects of Ay and c2J alleles in compound YA mutants document the importance of specific interactions both functional and structural between agouti and albino loci.     

Heterogeneity of Lethals in a "Simple" Lethal Complementation Group

Of 24 ethyl methanesulphonate-induced, recessive-lethal mutations in the region 9E1-9F13 of the X chromosome of Drosophila melanogaster, eight fall into a typically homogeneous lethal complementation group associated with the raspberry (ras) locus. Mutations in this group have previously been shown to be pleiotropic, affecting not only ras but also two other genetic entities, gua 1 and pur 1, which yield auxotrophic mutations.--The eight new mutations have been characterized phenotypically in double heterozygotes with gua 1, pur 1 and ras mutations. Despite their homogeneity in lethal complementation tests, the mutations prove quite diverse. For example, two mutations have little or no effect on eye color in double heterozygotes with ras2. The differences between the lethals are allele-specific and cannot be explained as a trivial outcome of a hypomorphic series.--Taken alone, the lethal complementation studies mask the complexity of the locus and the diversity of its recessive lethal alleles. By extension, we argue that the general use of lethal saturation studies provides an unduly simplified image of genetic organization. We suggest that the reason why recessive lethal mutations rarely present complex complementation patterns is that complex loci tend to produce mutations that affect several subfunctions.     

Tyrosinase activity (TH, DO, PAGE-defined isozymes) and melanin production in regenerating hairbulb melanocytes of lethal yellow (Ay/a), black (a/a), agouti (AwJ/AwJ/) and albino (a/a/c2J/c2J) mice (C57BL/6J)

We compared tyrosinase activity (TH, DO, and native PAGE-defined isozymes) and melanin production in particulate and soluble fractions of hairbulb melanocytes of lethal yellow (Ay/a C/C), nonagouti black (a/a C/C), and albino (a/a c2J/c2J) of 3-, 6-, 9-, and 12-day regenerating hairbulbs. With respect to tyrosine hydroxylase (TH) and dopa oxidase (DO) activities, Ay/a melanocytes possessed only 25-35% of the activity of a/a; there were no genotype differences in either the subcellular distribution of activity in soluble and particulate fractions or in the relative increases of activity over the 12-day developmental period. TH data on wild-type agouti (AwJ/AwJ) mice over the 3-11 day regeneration interval showed an activity intermediate between that of a/a and Ay/a; the rate of TH increase reflected black and yellow phases of the agouti hair cycle. Analyses of the number and densities of dopa-sensitive bands following native PAGE of 3-, 6-, 9-, and 12-day hairbulb fractions of a/a and Ay/a mice suggested stage-dependent patterns. A comparison of rates and amounts of melanin production in 3-, 6-, 9-, and 12-day fractions showed consistent melanin production in Ay/a to be 10-20% that of a/a; however, fold increases in melanin production over the four stages were similar between genotypes. Overall, tyrosinase activity data support the notion that agouti locus modification of tyrosinase activity is a graded or quantitative rather than a qualitative phenomenon.     

Quantitative trait loci that regulate plasma lipid concentration in hereditary obese KK and KK-Ay mice

To identify quantitative trait loci (QTLs) responsible for regulating plasma lipid concentration associated with obesity, linkage analysis was carried out on the 190 F2 progeny of a cross between C57BL/6J female and KK-Ay (Ay allele at the agouti locus congenic) male. In F2 a/a (agouti locus genotype) mice, two QTLs were identified on chromosome 1 and a QTL on chromosome 3 for total-cholesterol. A QTL for HDL-cholesterol was identified on chromosome 1 and a QTL for NEFA on chromosome 9. In F2 Ay/a mice, two QTLs for HDL-cholesterol were found on chromosome 1. Loci for other lipids with suggestive linkage were also identified. In both F2 mice, one QTL on chromosome 1 for total- and HDL-cholesterol was mapped near D1Mit150, in the vicinity of the apolipoprotein A-II (Apoa2) locus. Seven nucleotide substitutions out of 309 nucleotide apolipoprotein A-II cDNA sequences were identified between KK and C57BL/6J. The Ay allele may be an indication of the plasma lipid levels, but its influence was less apparent than in the case of weight control. The loci for lipids were not on identical chromosomes with those previously identified for obesity, suggesting that hyperlipidemia in KK does not coincidentally occur with obesity.     

Molecular cloning and mapping of the ecotropic leukemia provirus Emv-23 provides molecular access to the albino-deletion complex in mouse chromosome 7

Genetic analysis of radiation-induced deletion mutations involving the chromosome 7 albino (c) locus has expanded the functional map of this 6 to 11-cM region of the mouse genome. To generate one of many points of molecular access necessary for intensifying the analysis of the genes and phenotypes associated with this particular complex of deletions, we have cloned an endogenous ecotropic leukemia provirus (Emv-23), known to be closely linked to c, along with its flanking chromosome 7 sequences. A unique-sequence probe (23.3), derived from a region immediately 5' to the proviral integration site, was found to map less than 0.5 cM from c in a standard backcross analysis. Southern blot analysis of DNAs from animals carrying homozygous or overlapping albino deletions demonstrated that the 23.3 probe was deleted in several relatively small c-region deletions. The deletion mapping of the 23.3 probe places the Emv-23 locus between c and Mod-2, just proximal to a region important for male fertility and juvenile fitness. Mapping of this locus also provides a refinement of the genetic/deletion map for several mutations within this deletion complex.     

Absence of Linkage Between Human Obesity and the Mouse Agouti Homologous Region (20q11.2) or Other Markers Spanning Chromosome 20q

XU, WEIZHEN, DANIELLE R REED, YUAN DING AND R ARLEN PRICE. Absence of linkage between human obesity and the mouse agouti homologous region (20q11.2) or other markers spanning chromosome 20q. Obes Res. Mutant alleles of the agouti gene cause obesity in the mouse and the homologous gene in humans has been mapped to chromosome 20q11.2. An allelic variant of the agouti gene could account for obesity in humans and we tested this hypothesis by genotyping 210 sibling pairs from 45 families segregating an obesity phenotype. Using sibling pair linear regression analysis, evidence for linkage between obesity and markers flanking the agouti locus and other markers spanning chromosome 20q was assessed. We found no correlation between identity-by-descent at these markers and obesity differences within pairs. In the mouse, obesity caused by mutations of the agouti gene develops later in life, so a subset of families with adult-onset obesity were also tested for linkage, with negative results. Although it is not possible to exclude alleles of the agouti gene as a contributor to obesity in humans, the absence of positive linkage in this study suggests that either the agouti gene has small effects or the allele frequency is low.     

The Unusual Spectrum of Mutations Induced by Hybrid Dysgenesis at the Triplo-Lethal Locus of Drosophila Melanogaster

The Triplo-lethal locus (Tpl) is unique in its dosage sensitivity; no other locus in Drosophila has been identified that is lethal when present in three doses. Tpl is also haplo-lethal, and its function is still a mystery. Previous workers have found it nearly impossible to mutationally inactive Tpl other than by completely deleting the chromosomal region in which Tpl resides (83DE). We have utilized P-M hybrid dysgenesis in an effort to obtain new mutations of Tpl. We recovered 19 new duplications of Tpl, 15 hypomorphic mutations of Tpl (a previously rare class of mutation), and no null mutations. Surprisingly, 14 of the 15 hypomorphic alleles have no detectable P element sequences at the locus. The difficulty in recovering null mutations in Tpl suggests that it may be a complex locus, perhaps consisting of several genes with redundant functions. The relative ease with which we recovered hypomorphic alleles is in sharp contrast to previous attempts by others to mutagenize Tpl. A higher mutation rate with hybrid dysgenesis than with radiation or chemicals also suggests a peculiar genetic organization for the locus.     

Molecular Genetic Characterization of Six Recessive Viable Alleles of the Mouse Agouti Locus

The agouti locus on mouse chromosome 2 encodes a secreted cysteine-rich protein of 131 amino acids that acts as a molecular switch to instruct the melanocyte to make either yellow pigment (phaeomelanin) or black pigment (eumelanin). Mutations that up-regulate agouti expression are dominant to those causing decreased expression and result in yellow coat color. Other associated effects are obesity, diabetes, and increased susceptibility to tumors. To try to define important functional domains of the agouti protein, we have analyzed the molecular defects present in a series of recessive viable agouti mutations. In total, six alleles (a(mJ), a(u), a(da), a(16H), a(18H), a(e)) were examined at both the RNA and DNA level. Two of the alleles, a(16H) and a(e), result from mutations in the agouti coding region. Four alleles (a(mJ), a(u), a(18H), and a(da)) appear to represent regulatory mutations that down-regulate agouti expression. Interestingly, one of these mutations, a(18H), also appears to cause an immunological defect in the homozygous condition. This immunological defect is somewhat analogous to that observed in motheaten (me) mutant mice. Short and long-range restriction enzyme analyses of homozygous a(18H) DNA are consistent with the hypothesis that a(18H) results from a paracentric inversion where one end of the inversion maps in the 5' regulatory region of agouti and the other end in or near a gene that is required for normal immunological function. Cloning the breakpoints of this putative inversion should allow us to identify the gene that confers this interesting immunological disorder.     

Molecular Genetics of the Brown (B)-Locus Region of Mouse Chromosome 4. I. Origin and Molecular Mapping of Radiation- and Chemical-Induced Lethal Brown Deletions

Over a period of many years, germ-cell mutagenesis experiments using the mouse specific-locus test have generated numerous radiation- and chemical-induced alleles of the brown (b; Tyrp1) locus in mouse chromosome 4. We describe here the origin, maintenance and initial molecular characterization of 28 b mutations that are prenatally lethal when homozygous. Each of these mutations is deleted for Tyrp1 sequences, and each of 25 mutations tested further is deleted for at least one other locus defined by molecular clones previously found to be closely linked to b by interspecific backcross analysis. A panel of DNAs from mice carrying a lethal b mutation and a Mus spretus chromosome 4 was used in the fine structure mapping of these molecularly defined loci. The deletional nature of each of these prenatally lethal mutations is consistent with the hypothesis that the null phenotype at b has an effect only on the quality (color) of eumelanin produced in melanocytes. The resulting deletion map provides a framework on which to build future molecular-genetic and biological analyses of this region of mouse chromosome 4.     

Effects of dehydroepiandrosterone on obesity and glucose-6-phosphate dehydrogenase activity in the lethal yellow mouse (strain 129/Sv-Ay/Aw)

We investigated the anti-obesity effects of the adrenal androgen, dehydroepiandrosterone (DHEA), on genetically predisposed obese lethal yellow mice (Ay/Aw). Secondly, we tested the hypothesis that DHEA promotes its anti-obesity effects by decreasing the activity of glucose-6-phosphate dehydrogenase (G6PDH). We subjected four genotype-sex combinations of yellow and agouti (control) mice to four dietary treatments and determined weight changes, food consumption, and G6PDH activity. Although G6PDH activities of yellow mice were considerably decreased in the 0.4% DHEA treatment group, they were elevated in the 0.0 and 0.1% DHEA treatment groups. In contrast, G6PDH activities of DHEA-treated control agouti mice remained relatively constant. These studies confirm that DHEA prevents the Ay gene from promoting excess fat deposition via some mechanism(s) other than reduced dietary intake. However, the overall absence of agreement between weight change (gain or loss) and G6PDH activity suggests that the anti-obesity activity of DHEA is not mediated via G6PDH. Since yellow obese (Ay/Aw) mice were found to be more susceptible to DHEA's effects than their agouti (Aw/Aw) littermates, Ay appears to induce an altered metabolism in Ay/Aw mice which is more susceptible to the effects of DHEA than the normal metabolism of Aw/Aw mice.     

Genetic Characterization of the Region between 86f1,2 and 87b15 on Chromosome 3 of DROSOPHILA MELANOGASTER

The region between 86F1,2 and 87B15 on chromosome 3 of Drosophila melanogaster, which contains about 27 polytene chromosome bands including the 87A7 heat-shock locus, has been screened for EMS-induced visible and lethal mutations. We have recovered 268 lethal mutations that fall into 25 complementation groups. Cytogenetic localization of the complementation groups by deficiency mapping is consistent with the notion that each band encodes a single genetic function. We have also screened for mutations at the 87A7 heat shock locus, using a chromosome that has only one copy of the gene encoding the 70,000 dalton heat-shock protein (hsp70). No lethal or visible mutations at 87A7 were identified from 10,719 mutagenized chromosomes, and no female-sterile mutations at 87A7 were recovered from the 1,520 chromosomes whose progeny were tested for female fertility. We found no evidence that a functional hsp70 gene is required for development under laboratory conditions.     

The Triplo-Lethal Locus of Drosophila: Reexamination of Mutants and Discovery of a Second-Site Suppressor

In the genome of Drosophila melanogaster there is a single locus, Triplo-lethal (Tpl), that causes lethality when present in either one or three copies in an otherwise diploid animal. Previous attempts to mutagenize Tpl produced alleles that were viable over a chromosome bearing a duplication of Tpl, but were not lethal in combination with a wild-type chromosome, as deficiencies for Tpl are. These mutations were interpreted as hypomorphic alleles of Tpl. In this work, we show that these alleles are not mutations at Tpl; rather, they are dominant mutations in a tightly linked, but cytologically distant, locus that we have named Suppressor-of-Tpl (Su(Tpl)). Su(Tpl) mutations suppress the lethality associated with three copies of the Triplo-lethal locus and are recessive lethal. We have mapped Su(Tpl) to the approximate map position 3-46.5, within the cytological region 76B-76D.