Histidine decarboxylase phenotypes of inbred mouse strains: A regulatory locus (Hdc) determines kidney enzyme concentration

Mouse kidney histidine decarboxylase (HDC) provides a model system to study genetic control of a hormone-regulated enzyme (inducible by estrogen and thyroxine; repressible by testosterone). Five major HDC phenotypes scored on the basis of (i) enzyme activity and (ii) the difference in activity between the sexes (females usually higher than males) have been discovered by screening 38 strains of mice. One genetic difference between high-activity strains (DBA/2 and C3H/He) and low-activity strains (C57BL/6 and C57BL/10) has been examined in detail. The phenotypic difference segregates as a single gene in both conventional crosses and between recombinant inbred (RI) strains. Immunoprecipitation has shown that the activity difference is due to an alteration in the number of enzyme molecules. The phenotypic difference between high and low strains can therefore be attributed to different alleles of a single regulatory locus, Hdc; the alleleHdc ^d determines low HDC concentration, and the allele Hdc ^d high concentration. Hdc has been mapped to chromosome 2 using data from both comparisons of strain distribution patterns of previously mapped loci within RI strains and a conventional three-point cross. The probable gene order is B2m-pa-Hdc, with map distances of 3.1±1.7 and 2.0±1.4 cM, respectively.This work was supported by an MRC project grant to Grahame Bulfield, an SERC research studentship to S. A. M. Martin, and NIH Research Grant GM 18684 from the National Institute of General Medical Sciences to B. A. Taylor. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory animal care.     

A regulatory locus,Hdc-e,determines the response of mouse kidney histidine decarboxylase to estrogen

Levels of histidine decarboxylase (HDC; EC 4.1.1.22) activity in female mouse kidney are modulated by estrogen (administered as implanted pellets). In some inbred strains HDC activity is induced by estrogen, while in others the enzyme is repressed. Immunoprecipitation with an anti-fetal rat HDC antiserum has shown that induction and repression of HDC levels are due to changes in enzyme concentration. Segregation analysis has identified a single additively inherited regulatory locus, Hdc-e, which determines the response to estrogen. The allele Hdc-eb (C57BL/10) determines induction, and the allele Hdc-ed (DBA/2) determines repression. Preliminary evidence indicates cosegregation of Hdc-e alleles with alleles of another regulatory locus, Hdc-c (determining kidney HDC concentration), and therefore putative linkage of Hdc-e with the HDC gene complex on chromosome 2. This is the first report of a mammalian regulatory gene controlling two opposite mechanisms, induction and repression in response to a single effector.     

Histamine deficiency delays ischaemic skeletal muscle regeneration via inducing aberrant inflammatory responses and repressing myoblast proliferation

Histidine decarboxylase (HDC) catalyses the formation of histamine from L‐histidine. Histamine is a biogenic amine involved in many physiological and pathological processes, but its role in the regeneration of skeletal muscles has not been thoroughly clarified. Here, using a murine model of hindlimb ischaemia, we show that histamine deficiency in Hdc knockout (Hdc^?/?) mice significantly reduces blood perfusion and impairs muscle regeneration. Using Hdc‐EGFP transgenic mice, we demonstrate that HDC is expressed predominately in CD11b⁺Gr‐1⁺ myeloid cells but not in skeletal muscles and endothelial cells. Large amounts of HDC‐expressing CD11b⁺ myeloid cells are rapidly recruited to injured and inflamed muscles. Hdc^?/? enhances inflammatory responses and inhibits macrophage differentiation. Mechanically, we demonstrate that histamine deficiency decreases IGF‐1 (insulin‐like growth factor 1) levels and diminishes myoblast proliferation via H3R/PI3K/AKT‐dependent signalling. These results indicate a novel role for HDC‐expressing CD11b⁺ myeloid cells and histamine in myoblast proliferation and skeletal muscle regeneration.     

Characterizations of candidate genes for IDD susceptibility from the diabetes-prone NOD mouse strain

The nucleotide sequences of the NOD and C57BL/6J alleles of Glut-2, Sod-2, and Il-2 were determined by RT-PCR sequencing. Each of these loci is located in intervals that strongly correlated with susceptibility to diabetes in an (NOD/Uf x C57BL/6J)F₁ x NOD/Uf backcross. No significant variations in the alleles of Glut-2 at 16 cM on Chromosome (Chr) 3 or Sod-2 at 8 cM on Chr 17 were detected. However, the Il-2 allele in NOD at 20 cM on Chr 3 was found to differ from that in C57BL/6J by a complex mutation involving the contraction of a simple sequence repeat (SSR). Il-2 in NOD differs from the allele in C57BL/6J via a complex mutation involving a deletion of four CAG codons from the SSR together with a length-compensatory four-codon duplication of a segment 5 from the SSR. Two nonsynonymous mutations in the coding region 5 to the SSR were also detected. Only these two allelic forms of Il-2 were detected in a survey of 13 standard inbred lines and 4 wild mouse strains. We propose to designate these alleles as Il-2 ^a (for alleles such as C57BL/6J that contain 12 CAG repeats) and Il-2 ^b (for alleles such as NOD), which occurred in a variety of standard inbred strains and in all four wild Mus musculus domesticus tested. The distribution of these Il-2 alleles among inbred strains correlated with the detection of Chr 3 as an interval effecting diabetes susceptibility in three separate genetic crosses. However, functional characterizations of the quantity and functional characteristics of Il-2 produced by Il-2 ^a and Il-2 ^b failed to reveal any allele-specific variations.     

Characterization and strain distribution of four alleles at the hemoglobin α-chain structural locus in the mouse

In a survey of mice from 40 inbred strains, largely previously untested, four alleles were distinguished at the Hba locus, determining structure of adult mouse hemoglobin chain. This finding supports and extends previous sequence studies by others. Methods are given by which each phenotype was characterized by its solubility profile at varying pH and by its chromatography pattern. Concordance was complete between histidine-positive T-4 (defining Hba ^c) and high-intermediate solubility profile. In three inbred strains, a distinct new low-solubility profile, not associated with his-positive T-4, was recognized, and mice with this phenotype were classified as Hba ^d. Implications of observed widely distributed four-allele polymorphism of mouse hemoglobin -chain structure are discussed.This investigation was supported in part by NIH research grant CA-01074 from the National Cancer Institute and in part by the Virginia and D. K. Ludwig Foundation. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

Mapping of the interleukin 5 receptor gene to human Chromosome 3 p25–p26 and to mouse Chromosome 6 close to the Raf-1 locus with polymorphic tandem repeat sequences

Simple-sequence tandem repeat sequences in the 3 UTR of interleukin 5 (IL5)-receptor gene of human and mouse are polymorphic in their length among humans and different strains of mice. In 20 different human Epstein-Barr virus (EBV)-transformed cell lines, six alleles of IL5R could be distinguished. In the mouse, three different alleles are found. With the human-specific IL5R tandem repeat marker in human-rodent somatic cell hybrids, the IL5R gene was mapped to human Chromosome (Chr) 3 p25–p26. With the mouse-specific IL5R tandem repeat sequence in recombinant inbred strains of mice, the Il5r gene was mapped to the distal part of mouse Chr 6 close to the Raf-1 locus.     

Structural and evolutionary comparisons of four alleles of the mouse immunoglobulin kappa chain gene,Igk-VSer

The mouseIgK-VSer gene encodes an immunoglobulin light chain variable region which gives rise to two phenotypic polymorphisms of mouse chains. The nucleotide sequences of coding and flanking regions of theIgk-VSer ^c andIgk-VSer ^d alleles found in recently inbred strains of wild mice are compared with those of theIgk-VSer ^a andIgk-VSer ^b alleles described previously. Results suggest that the gene is evolving randomly and that framework 2 and complentarity determining region 2 are preserved, presumably for overall light chain structure. Results indicate that all four allels have an octamer motif upstream of the gene which should be functional and allow prediction of whether or not the product of the germ line gene will be detectable as either the I_B-peptide or Ef1^a phenotypic polymorphism. Southern hybridization of genomic DNA using as probe a 1-kbXba I-Xba I fragment located approximately 4 kb upstream of the BALB/cIgk-VSer ^b coding region demonstrated the presence of homologous DNA in mice bearing theIgk-VSer ^a allele and absence from mice bearing theIgk-VSer ^c andIgk-VSer ^d alleles. Nucleotide sequence comparison of BALB/c and SK/CamRk (Igk-VSer ^d ) DNA in this region demonstrated that BALB/c contained an insertion 2.4 kb in length which was absent from SK/CamRk. Both strains contain DNA homologous to the reverse complement of the mouse Bam5 repetitive element at the point of the insertion, with BALB/c containing approximately 70 nucleotides more of the element than SK/CamRk. Surprisingly, the strains containing DNA related to theXba I-Xba I probe are not those determined to be the most similar by nucleotide sequence comparisons and by the Phylogenetic Analysis Using Parsimony program. The evolutionary relationship of the alleles and a possible basis for the inconsistency presented by theXba I-Xba I fragment-related DNA are discussed.     

Gene responsible for dificient activity of the β subunit of C8, the eighth component of complement,is located on mouse chromosome 4

Sera from 73 strains of mice were tested for hemolytic activity through the classical and the alternative pathways (CP and AP) in a single radical hemolysis assay. Sera from 16 out of 45 laboratory inbred strains had n o lytic activity, and Ouchternoly analysis with anti-C5 serum showed them to be C5-deficient. Sera from 2 out of 28 strains derived from wild mice also had no lytic activity, but the C5 molecule was detectable in both. The hemolytic activity of sera from these strains can be restored serum deficient in C8-, leading us to conclude that strains M.MOL-MSM (MSM) and Mae are deficient in the subunit of C8. Typing of (DBA/2J ×MSM)F₁ hybrids and of progeny of a backcross to MSM showed that this C8 deficiency is controlled by a singles recessive gene, designated C8b; the allele with hemolytic activity is C8b ¹; and the allele with no activity C8b ⁰. Because of synteny homologies in mouse and human , we looked for and found close linkage between C8b and Pgm-2. Typing of recombinant mice for Mup-1 mapped the C8b locus 2.3 centimorgans (cM) telomeric to Pgm-2 on mouse chromosome 4.     

Structural and evolutionary comparisons of four alleles of the mouse Igk-J locus which encodes immunoglobulin kappa light chain joining (J K ) segments

The Igk-J locus of the mouse encodes the immunoglobulin light chain joining (J) segments. Four Igk-J alleles have been described on the basis of restriction enzyme length polymorphisms. The nucleotide sequences of the Igk-J ^a allele (type strain, C.C58), Igk-J ^c allele (type strain, SJL/J), and Igk-J ^d allele (type strain, SK/CamRk) have been determined and are compared with the previously reported Igk-J ^b allele sequence (type strain, BALB/c). The mouse sequences are also compared with published sequences for rat and human J _k sequences. Far more differences were found between the Igk-J ^a allele and the other mouse alleles than between any two of the latter. These result in two amino acid substitutions which distinguish the J2 and J3 ¹ segments of the Igk-J ^a allele from the other three alleles. Use of the Phylogenetic Analysis Using Parsimony program to generate a phylogenetic tree strongly indicates that after divergence from the rat ancestor, there appears to have been an early split between the Igk-J ^a allele and the evolutionary precursor of the other mouse alleles. There also appears to have been far less divergence from the ancestral condition in the Igk-J ^a allele than in the other alleles. Also, the presence of only one convergent mutation among the four mouse alleles provides strong evidence against any crossing over within the Igk-J locus during the history of these alleles. Finally, the differences in rates of evolution of the Igk-J alleles are in marked contrast to the relatively uniform rates of divergence of four alleles of a mouse V _k gene, Igk-VSer.     

The genetics of some polymorphic Esterases in Drosophila simulans

Analysis of strains of Drosophila simulans derived from a natural population in Turkey has shown that three alleles at the Esterase-6 locus are present in some strains. These alleles produce allozymes with mobilities equivalent to other esterases coded for by three other loci, one of which () is tightly linked to Esterase-6. Active alleles at all these loci are present at low frequencies. The presence of the active allele at the locus in laboratory strains in absolutely correlated with the presence of the Esterase 6 ^-3 allele and strong linkage disequilibrium between these two loci exists.It appears possible that the origin of one or more of these hitherto unremarked loci, whose active alleles are expressed only in females, lies in gene duplication, coupled with the action of selection in an environment thought to be heavily     

Determination of Malathion and Diazinon Resistance by Sequencing the MdαE7 Gene from Guatemala,Colombia, Manhattan,and Thailand Housefly (Musca domestica L.) Strains

Organophosphate (OP) insecticides (parathion/diazinon) resistance in housefly (Musca domestica L.) is associated with the change in carboxylesterase activity. The product of E7 gene, which is a member of -esterase gene cluster, is probably playing a role in detoxyfication of the xenobiotic esters. In parathion/diazinon resistant M. domestica species Gly¹³⁷ to Asp substitution was found in the active center of the product of E7 gene. In malathion (an OP) resistant M. domestica strains Trp²⁵¹ to Ser substitution was identified in the active center of the MdE7. In our research, to understand the allelic diversity of the MdE7, the gene was partially sequenced from four different housefly strains from different localities (Guatemala, Manhattan (USA), Colombia (USA), and Thailand). It was found out that; in Thailand strain one allele has Cys residue at the position of 251, the other allele contains a Trp for the same site. In Colombia strain, one allele has Asp¹³⁷, the other allele contains a Gly residue at this point. The Manhattan and Guatemala strains have Asp¹³⁷ and Trp²⁵¹ residues on their both alleles at these two different positions.     

Association of Xmv-10 and the non-agouti (a) mutation explained by close linkage instead of causality

In a previous survey of endogenous proviruses among inbred mouse strains, the Xmv-10 provirus was found only in strains that carried the non-agouti (a) mutation (Frankel et al. J. Virol. 63: 1763–1774, 1989). To determine whether insertion of Xmv-10 caused the a mutation, we cloned a portion of Xmv-10 and its insertion site. Using a fragment of flanking cellular DNA as a Southern hybridization probe, we found that the Xmv-10 provirus was still present in revertant alleles of a to a ^tor A W.A restriction fragment length variant (RFLV) in cellular DNA at the Xmv-10 insertion site was found to be correlated with the presence or absence of the provirus among inbred strains of laboratory mice regardless of their agouti allele. This correlation did not extend to wild mice, however, in which none of the samples contained Xmv-10, yet one, Mus domesticus poschiavinus, contained the insertion site RFLV correlated with Xmv-10 in laboratory mice. Analysis of an intersubspecific backcross with RFLVs at the insertion sites of Xmv-10 and Emv-15 (an endogenous provirus associated with A ^y)revealed the following genetic map information: cen-A-0.31±0.31 cM-Emv-15-0.62±0.27 cM-Xmv-10-tel. Haplotype analysis of inbred strains in which a was not associated with Xmv-10 and in which A ^ywas not associated with Emv-15 demonstrated that these exceptions were explained most simply by a single recombination that disturbed the linkage relationships evident in most inbred strains. These results demonstrate that Xmv-10 did not cause the a mutation, suggest that insertion of Xmv-10 occurred recently in the evolution of laboratory mice, and show that the associations between agouti alleles and endogenous proviruses are due to linkage disequilibrium.     

Deletion mapping of the mouse ornithine decarboxylase-related locus Odc-rs8 within Igh-V

The Odc-rs8 locus belongs to a family of mouse DNA sequences related to the gene encoding ornithine decarboxylase (ODC). Odc-rs8 was mapped by recombinant inbred (RI) strain analysis to the region of Chromosome (Chr) 12 occupied by the variable region genes of the immunoglobulin heavy chain (Igh) complex. In the present study, alleles at Odc-rs8 were shown to cosegregate with those for Igh variable region (Igh-V or V _H) genes among 37 inbred mouse strains that had been characterized previously for their haplotypes at Igh. For a more precise definition of the location of Odc-rs8 relative to Igh-V, DNAs from 17 Abelson murine leukemia virus (A-MuLV)-transformed pre-B cell lines cultured from mice heterozygous at Igh and Odc-rs8 were analyzed for the presence of DNA restriction fragments (RFs) derived from each parental Odc-rs8 allele. These cell lines, each of which has rearranged one or both Igh genes, previously were employed in mapping members of nine V _H gene families by deletion analysis (Brodeur et al. 1988). Comparing the deletion profiles of the cell lines for Odc-rs8 with those for the V _H gene families has located Odc-rs8 ^b within the V_HJ558/V_H3609 gene cluster and Odc-rs8 ^c either within or upstream of the 5-most 9% of V_HJ558, identifying Odc-rs8 as a potentially useful marker for the 5 end of the Igh complex.     

Definition of microsatellite size variants forTnfa andHsp70 in autoimmune and nonautoimmune mouse strains

We have cloned and sequenced the upstream regulatory region of tumor necrosis factor (Tnfa) gene in 12 different mouse strains and identified an allelic polymorphism in the upstream regulatory region of the mouseTnfa gene. TheTNF allele found in the NZW strain is distinct from those of all otherH-2 haplotypes, supporting our previous suggestion that this allele may be associated with a regulatory or structural defect. In addition, simple tandem repeat sequences (microsatellites) within the promoter region of theTnfa gene and the 3 untranslated region of one of the members of the HSP70 family (Hsp68c clone) were utilized as genetic markers. Ten TNF size variants and twelve HSP70 variants were identified in over forty mouse strains. Using these markers in a set of congenic mice, we mapped this member of the HSP70 family to the central portion of theH-2 complex, centromeric to theTnfa gene. The NOD and NZW strains carry uniqueHSP70 alleles based on the variability in the length of this marker. These findings raise the possibility that this protein may play a role in the association of the major histocompatibility complex with these autoimmune diseases.     

A null mutation at the mouse Phosphoglucomutase-1 locus and a new locus,Pgm-3

A null mutation at the phosphoglucomutase locus (Pgm-1) was discovered by electrophoretic analysis of the inbred mouse strain C57 BL/6J. The null allele (Pgm-1 ⁿ) was shown to segregate as a Mendelian unit alternative to the Pgm-1 ^a and Pgm-1 ^b alleles. Mice expressing the Pgm-1 ⁿ allele, either in the heterozygous or homozygous state, are viable, healthy, and fertile. The occurrence of the Pgm-1 ⁿ mutant revealed a previously unreported genetic locus (Pgm-3) that controls the expression of a third phosphoglucomutase. Two electrophoretically expressed alleles of Pgm-3 (inherited without dominance) are found in the inbred mouse strains C57 BL/6J and DBA/2J. Linkage observed between the Pgm-3 locus, the dilute locus (d) and the cytoplasmic malic enzyme locus (Mod-1) has allowed assignment of the Pgm-3 locus to chromosome 9. A striking tissue specific expression of Pgm-1 and Pgm-3 was observed. Products of the Pgm-3 locus were detected in kidney, testes, brain, and heart. In contrast, Pgm-1 controlled isozymes were present in kidney, spleen, ovaries, and erythrocytes.Financial support for this work was provided in part by Contract #263-78-C-0393 from the National Institute of Environmental Health Sciences to the Research Triangle Institute.     

Immunoglobulin constant kappa gene alleles in twelve strains of mice

Genomic DNA for the immunoglobulin (Ig) constant kappa Igk-C gene region was amplified by the polymerase chain reaction (PCR) method and sequenced from twelve commonly used inbred mouse strains. PCR products were used directly as templates in dideoxy-DNA-sequencing, a method which avoids the sequencing errors caused by Taq polymerase, since no cloning step is required. In restriction fragment length polymorphism (RFLP) studies the SJL mouse strain has been shown to belong to a Igk-C allogroup different from other common inbred mouse strains. The BALB/c Igk-C region was sequenced earlier, but our Igk-C sequences clarify the situation and confirm the existence of three Igk-C alleles in inbred mice (Mus musculus domesticus). Mice belonging to the kappa (Igk) haplotype e (SJL) have allele c of the Igk-C gene. The strains belonging to the kappa haplotype [a albino strain, K subline (AKR), PL and d (C58)] have allele a, and all other eight strains belonging to three different Igk haplotypes (b, c, and f) use allele b of the gene. Allele b has at least one (possibly two) nucleotide differences from allele a in the Igk-C region, but five compared to allele c. The allelic sequences also predict two allotypic kappa polypeptide chains among twelve inbred strains. Alleles a and b encode identical polypetides, but allele c (SJL) has a conserved lysine to arginine substitution in residue 142.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession numbers X67002-X67012.     

Involvement of cyclic AMP and its receptor protein in the sensitivity of Escherichia coli K 12 toward serine: excretion of 2-ketobutyrate, a precursor of isoleucine.

Summary A relationship between serine-induced growth sensitivity and the cAMP-CAP complex is established. Mutants of Escherichia coli K 12 deficient either in the cya or crp gene function exhibit a resistant phenotype on serine media although they harbor a relA allele normally leading to sensitivity toward serine. The presence of a crp ^* allele in a cya rela background restores the sensitivity phenotype, while the analysis of serine resistant mutants selected from a crp ^* cya relA strains shows that the mutation leading to resistance is located at, or very near, the crp gene, giving a more or less Crp^- phenotype. In addition crp ^* cya relA strains excrete large quantities of 2-ketobutyrate when grown on glucose M63 medium. This excretion is unambiguously linked to the presence of the crp ^* allele and is correlated with an enhanced threonine deaminase activity. Besides, the complex regulation exerted on the acetolactate synthase activities is discussed.     

Genetic Regulation of Plasma Corticosterone Concentration and its Response to Castration and Allogeneic Tumour Growth in the Mouse

EXCESS fat deposition after castration is thought to be a response to hyperinsulinism induced by an increased level of adrenal glucocorticoids¹. Two mutant alleles, lethal yellow (A^y) and viable yellow (A^vy), at the agouti locus in the mouse induce excess fat deposition; the A^y allele has also been found to induce insulin resistance². Katsh³ concluded that in adrenalectomized KL strain mice a considerable portion of the high insulin tolerance depended on normal adrenal function. In the inbred YS/Wf and VY/Wf strains, both yellow pheno-types modulate serum insulin concentration⁴. Castration of inbred YS strain males causes a large decrease in serum insulin⁴, suggesting a possible relationship¹ to the concentration of adrenal glucocorticoids. Growth of allogeneic tumour cells has different effects on the serum insulin concentrations of YS and VY strain mice⁴.     

Genetics and ontogeny of alcohol dehydrogenase isozymes in the mouse: Evidence for a cis-acting regulator gene (Adt-1) controlling C2 isozyme expression in reproductive tissues and close linkage of Adh-3 and Adt-1 on chromsome 3

An electrophoretic variant previously reported for the stomach isozyme of alcohol dehydrogenase (ADH-C2) in inbred strains of Mus musculus (Holmes, 1977) has been used to localize the gene encoding this enzyme (Adh-3) on chromosome 3 near Va (varitint) (9.6 ± 3.6% recombinants). Genetic variation of ADH-C2 activity in male and female reproductive tissues among inbred strains and Harwell linkage testing stocks was also observed. Reproductive tissue ADH-C2 phenotypes were inherited in a normal Mendelian fashion among F₂ progeny of an F₁ (LII × C57BL/Go) × C57BL/Go backcross as though controlled by a single cis-acting regulator locus (designated Adt-1) with two alleles: Adt-1 ^a (presence of ADH-C2) and Adt-1 ^b (absence or low activity of ADH-C2). No recombinants were observed among 73 progeny or among 13 inbred strains and six Harwell linkage testing stocks of mice, indicating that Adh-3 and Adt-1 are closely linked or identical genes. A single recombinant phenotype was observed in Peru-Coppock mice, suggesting that they are separate genes. Ontogenetic analyses demonstrated that ADH-B₂ is present throughout development from late fetal stages in stomach, liver, and kidney; similar results were found for ADH-C2 in developing kidney and stomach extracts, whereas ADH-A2 exhibited high activity in liver extracts after 3 weeks of age in both sexes and in male kidney extracts after 6 weeks.     

The sucrase-isomaltase structural gene (Si-s) and a regulatory gene (Si-r) are closely linked to esterase-26 (Es-26) on mouse Chromosome 3

A cDNA clone of the rat sucrase-isomaltase (SI) structural gene detected two distinct patterns of DNA fragments on Southern blots of mouse DNA. Screening of 18 AKXL and 25 AKXD recombinant inbred (RI) strains revealed that all bands in each pattern co-segregated and there were no (0/43) recombinants with Es-26 on mouse Chromosome (Chr) 3. Since CBA/CaJ mice have approximately threefold less sucrase activity than other strains, we intercrossed them with SJL/J mice to map the previously identified SI regulatory gene, Si-r. Fifty-six mice from the F₂ generation were assayed for sucrase activity, and the genotype of the murine SI structural gene locus, Si-s, was determined by Southern blot analysis. Nine animals (16%) were homozygous for the CBA/CaJ allele (C) and had an average sucrase activity (jejunum + ileum) of 1.51 moles/h/mg protein (SE=0.067), 19 (34%) were homozygous for the SJL/J allele (S) and had an average sucrase activity of 5.95 moles/h/mg protein (SE=0.267), and 28 (50%) were heterozygous (C/S) for Si-s with an average sucrase activity of 3.70 moles/h/mg protein (SE=0.127). We conclude that Si-s and Si-r are closely linked on Chr. 3.