Allotypes of mouse complement component C6 in inbred strains and some wild populations.

This collaborative work was undertaken to resolve discrepancies in reports of the number of forms of complement component C6 present in the circulation of mice from various inbred strains. Plasma C6 was analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and by isoelectric focusing (IEF), and C6 band patterns were developed by electroblotting and immunoprobing. Results of C6 allotyping of mice from 36 strains confirmed that while 20 strains (prototype strain BALB/c) possessed only one relative mass (Mr) for which typed C6A1 on IEF, the other 16 strains all possessed more than one C6 Mr form. Moreover, IEF analysis demonstrated additional polymorphic differences; among these 16 strains, 11 typed C6A1B1 like the prototype strain CBA, the AKR and RF/J strains typed C6A2B2, and the Japanese MOM strain as well as the C57BR/cdJ and C57L/J strains possessed two forms with IEF mobilities intermediate between C6A1B1 and C6A2B2. These will now be referred to as C6A3B3. Thus, a total of four different mouse C6 haplotypes have been identified. Testing C6 allotypes in a limited number of wild mice revealed that haplotypes found in inbred strains of Western or Eastern origin tend to reflect haplotypes of the wild mice from Europe or Japan, respectively.

Fructose bisphosphatase isozymes of the mouse. I. Inheritance.

Electrophoretically detectable polymorphisms of fructose bisphosphatase (EC 3.1.3.11) have been found in the mouse. One polymorphism, found among inbred strains of Mus musculus and feral animals, affects the isozymes found in the muscle and in most other tissues examined but is not expressed in kidney, liver, or testis. These tissues have other electrophoretically distinct isozymes which are monomorphic in Mus musculus but are present as a different electromorph in the sympatric species Mus spretus. Breeding data have established that the genetic control of the muscle enzyme is expressed by an autosomal structural locus Fbp-1 which is distinct from that expressing the liver, kidney, and testis enzyme, Fbp-2. The organ-specific expression of the two loci suggests possible functional differences between the two products.

Close linkage between mouse genes determining the two forms of complement component C6 and component C7, and cis action of a C6 regulatory gene.

Two forms of mouse complement component C6, with molecular weights (Mrs) of 90 and 100 kilodaltons (kd), are present in the sera from certain inbred strains such as the CBA strain; other strains, such as the BALB/c and DBA/2 strains, have only the 90 kd C6A form. The present work was undertaken to determine whether the two Mr forms were the products of genes coding at separate loci. We screened sera from mice from a number of inbred strains by isoelectric focusing and found one strain, AKR, exhibiting allotypic structural variations of C6 forms. To distinguish the various types, we designated the 90 kd types from CBA and AKR mice C6A1 and C6A2, respectively, and the corresponding 100 kd types C6B1 and C6B2, respectively. Mice possessing only one Mr form were all typed as C6A1. Results of breeding experiments strongly suggested that the two Mr forms of C6 are coded for at two closely linked loci. Sera from a number of inbred strains were also screened for a complement C7 polymorphism by means of isoelectric focusing and functional overlay. C7 from all strains, excepting the AKR strain, produced identical C7 band patterns. AKR C7 produced a unique band pattern, and results of breeding experiments with AKR and BALB/c mice showed the C6 and C7 loci to be closely linked. In addition, we identified a regulatory gene for C6 production. The gene apparently requires androgen to facilitate C6 production in the majority of strains. In these strains C6 activity is virtually absent from female sera. However, we observed moderate levels of C6 activity in sera from IS/Cam females, indicating that, in this strain, male physiological androgen levels are not necessary for C6 production. IS/Cam possess one form of circulating C6 which appears identical with BALB/c C6A1, and therefore IS/Cam mice differ from AKR mice at both the C6 structural and regulatory loci. These two strains were thus suitable for use in breeding experiments to determine the manner of action of the regulatory gene. Results showed that it acted in a cis manner.

A tiger mouse and relatives. Variants caused by an activated transposable element?

In a laboratory-bred population of wild Peruvian house mice, one male had an excessive rate of non-pairing of the X and Y chromosomes. After crossing him with laboratory stock mice, a mouse of very unusual phenotype appeared from a yellow (AyA) mother. He was yellow with black dorsal stripes; hence Tiger. He was mated to many females, and inbred F2 and F3 generations were raised. There were no more tiger phenotypes, but his F1 contained an excess of black-and-tans over yellows, showing him to be a gonosomic mosaic Ayat/atat; the homozygous cell line probably arose from the heterozygous one. The mitotic karyotype was normal. Some of Tiger's mates were of known allozyme types and their progeny were scored. The allozyme segregations were normal, except at the Es-3 locus (esterase-3), for which Tiger was typed as homozygous. Several unusual events among Tiger's close relatives included a mutation to an unstable pattern mutant, three probable translocations, and several cases of somatic defect. All unusual mice derived from Tiger's yellow mother, whose genome was one-quarter Peruvian. Yellow is associated with an ecotropic murine leukemia virus. The Peru genome is characterized by a high occurrence of mutation and aberrant karyotypes. It is suggested that something from the Peru genome in Tiger's mother caused instability of the DNA sequence associated with yellow, with related disturbance at different locations thereafter. The nature of this instability, and of the Peru genome, is discussed.

Xylose dehydrogenase-1, a new gene on mouse chromosome 7.

We report a new enzyme xylose dehydrogenase, the structural locus for which is on chromosome 7 of the mouse, closely linked to Tam-1. Three alleles have been detected in both laboratory strains and wild populations. Two of these determine proteins differing in electrophoretic mobility and the third is a "null." This easily scored variation may prove useful both for gene mapping and in population genetics.

Kidney esterases of Mus musculus: further polymorphism of esterase-6, esterase-9, and a new esterase, esterase-20.

The comparison of results obtained by different separation and staining techniques permits the definition of esterase-6 in comparison with esterase-9 and a new esterase, esterase-20. Alleles of Es-6 affect the product's ability to aggregate. Esterase-20 may be an aggregated product of Es-9. The close linkage of Es-6 and Es-9 is confirmed. Homology of esterase-6 with esterases from other mammalian species is also suggested.

Mesothelial cysts of the spleen with squamous metaplasia.

Epidermoid cyst (metaplastic mesodermal cyst) is the most common true cyst of the spleen. The pathogenesis is unknown. The lesion is usually asymptomatic and has a characteristic gross morphology. Two splenic epidermoid cysts which were mesothelial-lined and showed focal squamous metaplasia were observed. Examination of one adult spleen and ten fetal spleens showed similar mesothelial linings of their capsules. It is believed that the epithelial-lined splenic cysts are the result of invagination of capsular surface mesothelium with subsequent cystic expansion and metaplastic changes. The use of the term "mesothelial cyst with squamous metaplasia" as a more accurate term than "epidermoid" or "metaplastic mesodermal cyst" is suggested.

Polymorphism of kidney pyruvate kinase in the mouse is determined by a gene, Pk-3, on chromosome 9.

An electrophoretically detectable variant of pyruvate kinase (EC 2.7.1.40) has been found in the house mouse Mus musculus. The variant was seen in all tissues examined except liver and red cells. The gene (Pk-3) determining this electrophoretic variation is inherited as an autosomal codominant located on chromosome 9. Our data confirm that the genetic determination of pyruvate kinase in liver and red cells is separate from that in other tissues. In addition, our results indicate that the muscle (M1) and kidney (M2) pyruvate kinase isozymes share at least one genetic determinant and may in fact be determined by the same structural gene.

Esterases of Mus musculus: substrate and inhibition characteristics, new isozymes, and homologies with man.

A wide range of fluorogenic and naphthol esters has been tested as substrates for mouse esterases. New esterases have been identified in liver and kidney extracts with palmityl, oleyl, and elaidyl esters. From substrate, inhibition, and molecular weight studies, three homologies between human and mouse esterases are suggested. A new allele at Es-6 is also described.

Polymorphism of esterase 11 in Mus musculus, a further esterase locus on chromosome 8.

A further esterase, esterase 11, which exhibits a polymorphism detectable by electrophoresis, has been observed in the house mouse, Mus musculus. In 15 inbred strains and two outbred strains, the ES-11A phenotype has been found, composed of two bands of enzyme activity of greater anodal electrophoretic mobility than the two bands of the ES-11B phenotype found in one inbred strain, one wild stock, and 101 wild mice. In F1 hybrids (IS/Cam X C57BL/Gr), the phenotype shown corresponds to a mixture of the two parental phenotypes. In backcrosses, ES-11 segregates as an autosomal gene, designated Es-11, closely linked to Es-2 and Es-5 on chromosome 8.

Polymorphism of esterase-10 in Mus musculus.

An esterase, esterase-10, in the house mouse, Mus musculus, is specific for esters of 4-methylumbelliferone and exhibits a polymorphism detectable by electrophoresis. Fifteen inbred strains and two outbred strains have been examined for this polymorphism, and two phenotypes, ES-10A and ES-10B, have been observed. Each phenotype manifests itself as a single band of enzyme activity, but under the electrophoretic conditions used the ES-10A phenotype has less anodal electrophoretic mobility than the ES-10B phenotype. In F1 hybrids (C3H/He/LacxC57BL/Gr) a third phenotype was observed, ES-10AB, consisting of three bands of enzyme activity, two of which correspond to the parental forms and the third with intermediate mobility. The triple-band pattern in the F1 hybrids indicates that esterase-10 is a dimeric enzyme protein.