A two-locus model for experience-conditioned direction of paw usage in the mouse is suggested by dominant and recessive constitutive paw usage behaviours.

Left-right direction of paw usage in the mouse depends on the genotype and the directional nature of the test. There are two phenotypic classes; in some strains, direction of paw usage is learned or conditioned by the direction of the initial test chamber and the experience of reaching and, in other strains, paw usage is a constitutive behaviour not affected by previous experience. We report the evidence for locus heterogeneity in the cause of constitutive versus experience-conditioned paw usage from a phenotypic analysis of F1 hybrid generations from the experience-conditioned C57BL/6J, C3H/HeHa, and SWV strains and the constitutive CDS/Lay and DBA/2J strains. The F1 hybrids between strains of different phenotypic classes provide evidence of locus heterogeneity. Constitutive paw usage in CDS/Lay is phenotypically dominant to experience-conditioned behaviour in both C57BL/6J and SWV. However, constitutive paw usage in DBA/2J is phenotypically recessive to experience-conditioned behaviour in C57BL/6J and dominant to experience-conditioned behaviour in SWV. Among the experience-conditioned strains, C57BL/6J is highly lateralized but SWV is only weakly lateralized. Our data suggest a model in which C57BL/6J may have a "strong" allele that identifies a functional difference between the constitutive paw usage of CDS/Lay and DBA/2J. DBA/2J may have a loss-of-function mutation at the same locus that is recessive to the strong C57BL/6J allele. SWV may have a "weak" allele and the (SWV x D2)F1 compound heterozygote may be below a threshold for detectability of experience-conditioned behaviour, making the constitutive behaviour of DBA/2J appear to be dominant to the experience-conditioned behaviour of SWV. CDS/Lay may have a dominant allele at a second locus that suppresses experience-conditioned behaviour in all F1 hybrids.

Lateral asymmetry of paw usage: phenotypic survey of constitutive and experience-conditioned paw-usage behaviours among common strains of the mouse.

Left-right direction of paw usage in the mouse is defined by the right-paw entry (RPE) score, which is the number of reaches with the right paw to retrieve food from a small food tube in a total of 50 right- and left-paw reaches. Two qualitatively different paw-usage behaviours can be identified by the difference in the RPE scores from naive mice in left- or right-biased test chambers and their retest, 1 week later, in the opposite-biased test chamber. In mice with constitutive paw usage, the RPE score may respond to the direction of a biased test chamber, but it returns to the value that is expected for naive mice in the opposite-biased test chamber. In mice with experience-conditioned paw usage, the RPE score responds to the direction of a biased test chamber and does not return to its expected value in the opposite-biased test chamber. In this report, we document the alternate paw usage behaviours in an extended phenotypic survey of different strains that will be useful for its genetic analysis. We also validate an alternate biometrical method to identify constitutive and experience-conditioned paw usage that is based on the mean average RPE score from the biased test and opposite-biased retest of individual mice. This alternate biometrical method demonstrated that, in some strains with experience-conditioned paw usage, there may be asymmetry or an interaction between genotype and the direction of the test sequence. In addition, the strain survey demonstrated that the qualitative difference between constitutive and experience-conditioned paw usage is independent of the well-known quantitative difference in the degree of lateralization of preferred-paw usage.

Mouse genetic model for left-right hand usage: context, direction, norms of reaction, and memory.

Asymmetry of paw usage in the laboratory mouse is an experimental model for left-right asymmetry of hand usage. Given a set number of reaches into a centrally placed food tube (an unbiased or U-world test), individual mice exhibit a number of left and right paw reaches that is reliably expressed on retesting. Whereas different inbred strains appear to have equal numbers of individual mice with a left- or a right-preferred paw after a U-world test, there are significant differences among strains in the degree or strength of lateralization of the preferred paw. We report here a systematic series of tests of paw usage with naive mice and retests of the individuals in test chambers with the food tube biased to the left or to the right, contrasting the highly lateralized C57BL/6J and the very weakly lateralized (or ambilateral) CDS/Lay inbred strains and their (B6 x CDS) F1 generation. The results caused a shift in the paradigm of paw usage. There is an unexpected qualitative difference in paw usage between C57BL/6J and CDS/Lay. C57BL/6J is random in its left-right paw usage, but it is conditioned by the left or right direction of the initial biased-world test and by usage. CDS/Lay is constitutively equal-pawed, responds very little to direction of the test chamber, and is not conditioned by it. The probability of left-paw versus right-paw usage depends on both the genotype and the context of the test. The (B6 x CDS) F1 generation suggests that constitutive equal-paw usage of CDS/Lay is dominant to experience-conditioned paw usage of C57BL/6J. There is also an apparent quantitative difference between the very weakly lateralized (ambilateral) preferred paw usage in CDS/Lay and the highly lateralized preferred paw usage in C57BL/6J. The difference in degree of lateralization of preferred paw usage between the constitutively equal-pawed CDS/Lay strain and (B6 x CDS) F1 generation must originate from allelic differences at other gene loci between the CDS/Lay and C57BL/6J parental strains. The SWV and NOD/Lt strains were also assessed in asymmetrical tests because they were known to be weakly lateralized and similar to each other in a U-world test and to be significantly different from both C57BL/6J and CDS/Lay. SWV is experience-conditioned and weakly lateralized; NOD/Lt is constitutively equal-pawed and weakly lateralized. Further analysis will determine the genetic cause of the qualitative difference between constitutive equal-paw and experience-conditioned paw usage and the genetic cause of the quantitative differences in degree of lateralization of the preferred paw within each type of paw usage.

Sex and death in the mouse: genetically delayed reproduction and senescence.

A mammalian model of genetically postponed aging would be an important tool to test not only different mechanisms of aging but also the predictive value of various biomarkers of the aging process. Under conventional conditions, the historical strains of the laboratory mouse produce their first litter between 9 and 13 weeks of age and have a median time of death in their 2nd year. Our POSCH-2 strain, which was derived from wild-caught Mus musculus domesticus, produces its first litter in the current breeding generations at approximately 47 weeks of age and continues to breed throughout its 2nd and into its 3rd year of life. The aging curve of POSCH-2 has not yet been determined for economic reasons. Late onset of breeding is a characteristic of both females and males, but sexual maturity is more reliably assessed in females. The later breeding phenotype of POSCH-2 is genetically recessive to early breeding of the C57BL/6J historical laboratory strain and, since POSCH-2 females can be induced to ovulate at 8 weeks of age (but pregnancy does not result), the signal rather than the ovarian receptor to ovulate may be delayed. The genetically delayed reproduction and potentially longer life of the POSCH-2 strain appears to be a new trait in the mouse. The strain may be a useful mammalian model for aging studies and for the evaluation of antagonistic pleiotropy as a genetic model for the evolution of aging.

The degree of lateralization of paw usage (handedness) in the mouse is defined by three major phenotypes.

Lateralization of paw usage in the laboratory mouse may be a useful model system in which to assess the genetic and developmental cause of asymmetry of hand usage. With a set number of paw reaches from a centrally placed food tube, individual mice from an inbred strain will exhibit a reliable number of left and right paw reaches. For a single inbred strain, there are approximately equal numbers of left-pawed and right-pawed mice, but strain differences have been reported in the degree of lateralization of paw preference. We reported a preliminary strain survey in which the strains appeared to fall into two groups of highly lateralized and weakly lateralized paw preference (Biddle et al., 1993). We review here our expanded survey of genetically different strains and stocks of the laboratory mouse, including different species and subspecies. The major genetic trait is the degree of lateralization of paw preference and the strain differences appear to fall into three major classes of highly lateralized, weakly lateralized, and ambilateral preference. The trait exhibits both additivity and dominance in preliminary reciprocal crosses, depending on which strain pairs are used. The wide difference between strains that have highly lateralized and ambilateral paw preference suggests specific genetic tools that could be used to begin a genetic dissection of the causes of this trait. Preliminary assessment of the size of the corpus callosum in three strains with significantly different degrees of lateralization suggests that genetically determined deficiencies and absence of this structure are not the direct cause of the strain differences in the trait of degree of lateralization. In the expanded survey, some strains appear to exhibit a directional deviation from equal numbers of mice with left and right paw usage. Therefore, direction of paw usage may not be a genetically neutral trait, but replicate assessments and genetic tests are needed to confirm this.

Directional dominance and a developmental model for the expression of the Tda testis-determining autosomal trait of the mouse.

The POSCH-2 Y chromosome from the poschiavinus variety of Mus musculus domesticus causes incomplete testis development in the recessive autosomal background of the C57BL/6J laboratory mouse strain. Testis development is normal with the POSCH-2 Y in its native strain background as well as in some strains of the laboratory mouse such as DBA/2J. The phenotype or expression of XY gonadal hermaphroditism in a C57BL/6J strain, which was constructed to be consomic for the POSCH-2 Y, is a threshold trait in which liability is normally distributed and thresholds in the development of the testis define the probability of observing XY embryos with different combinations of ovaries, ovotestes, and testes. The difference in this testis-determining autosomal or Tda trait between the C57BL/6J and DBA/2J strain pair has been demonstrated to be multigenic. We conducted a survey among different strains of the laboratory mouse by test mating females with C57BL/6J.Y-POS males that are consomic for the POSCH-2 Y. We identified five groups of strains with significantly different response of XY gonadal hermaphroditism in their XY-POS F1 test embryos. In test embryos, four groups of strains produced gonadal hermaphroditism with different distributions of the types of gonad that appear to have the same variance or shape of a normally distributed liability, but the means of the distributions are at different locations on a scale of gonadal development. The fifth group of strains produced only tests in the test embryos. Several additional matings produced results suggesting that a model of dominance, in the direction of more complete testis development, could interpret the strain differences. The differences in response to the POSCH-2 Y chromosome among the five groups of strains may represent the phenotypes of the genetic recombinants in the Tda trait that were suggested previously by a segregation analysis between C57BL/6J and DBA/2J. The strains may also provide the tools to further dissect the allelic differences and locus determinants of the Tda trait.

Segregation analysis of the testis-determining autosomal trait, Tda, that differs between the C57Bl/6J and DBA/2J mouse strains suggests a multigenic threshold model.

The testis-determining autosomal trait (Tda) of the mouse was uncovered when the Y chromosome of the poschiavinus variety of Mus musculus domesticus was introduced into the C57BL/6J laboratory strain background. Testis development is normal in the F1 generation but, in the backcross and subsequent crosses to C57BL/6J females, XY individuals with the poschiavinus Y chromosome expressed bilateral ovaries or various combinations of an ovotestis with a contralateral ovary or testis or bilateral ovotestes and few had testes bilaterally. In other strain backgrounds, such as DBA/2J, XY individuals with the poschiavinus Y chromosome always expressed normal testes bilaterally. The first breeding analysis of this difference in the interaction of strain background with the poschiavinus Y chromosome suggested that the Tda trait was due to a single gene, but attempts to map it failed. We constructed two strains of C57BL/6J and DBA/2J that are consomic for the poschiavinus Y chromosome in order to conduct a segregation analysis of the Tda trait. In the C57BL/6J.Y-POS consomic strain, liability to express incomplete testis development is normally distributed and thresholds in development specify the probability of different classes of ovary, ovotestis, and testis combinations. Testis development is complete in the DBA/2J.Y-POS consomic strain. We demonstrated previously that the Tda trait of C57BL/6J is recessive to that of DBA/2J and the segregating first backcross generation of embryos rejected the single-gene model. We have extended our analysis to a F2 generation of embryos that also rejects a single-gene model. We also report a test mating analysis of the first backcross generation. It was initiated to provide an independent assessment of the single-gene model, but the analysis of the distribution of test mating results suggests that the difference in the Tda trait between C57BL/6J and DBA/2J may be due to a small number of loci, possibly four or five, and that the phenotypic effect between loci may be additive.

Haldane's rule and heterogametic female and male sterility in the mouse.

Failed genetic experiments or experiments designed for other purposes sometimes reveal novel genetic information. The interspecific cross between laboratory strain mice of the Mus musculus musculus/domesticus complex and the separate species M. spretus is known to produce fertile F1 females and sterile F1 males. Infertility of the interspecific F1 XY male is said to be an example of what has become known as Haldane's rule: "When in the F1 offspring of two different animal races one sex is absent, rare, or sterile, that sex is the heterozygous [heterogametic] sex." We attempted to use fertile single-X (or XO) female laboratory mice of the M. m. musculus/domesticus complex mated to M. spretus males to construct females with specific X chromosomes to study segregation distortion of X chromosome marker genes that we reported previously in crosses with the two species. We assumed that the interspecific F1 XO female would be fertile like the interspecific F1 XX female but, instead, we found that it is infertile. Haldane's rule is not specific to sex, but demonstration of this has required study of separate species pairs with heterogametic males or with heterogametic females. The fertile XO laboratory mouse is female, but it is also heterogametic, producing both X and nullo-X eggs. Infertility of both the interspecific and heterogametic F1 XO female and F1 XY male in the same cross between laboratory mice and M. spretus suggests that heterogamety is at the cause of the infertility.(ABSTRACT TRUNCATED AT 250 WORDS)

The testis-determining autosomal trait, Tda-1, of C57BL/6J is determined by more than a single autosomal gene when compared with DBA/2J mice.

The putative Tda-1 or testis-determining autosomal trait of the C57BL/6J mouse strain came to attention when the Y chromosome from the poschiavinus variety of Mus musculus domesticus was introduced into C57BL/6J by backcross matings. The F1 generation expressed normal testis development in XY individuals with the poschiavinus Y chromosome. In the backcross and subsequent crosses to C57BL/6J females, XY individuals expressed ovaries bilaterally or various combinations of an ovotestis with a contralateral ovary or testis or bilateral ovotestes and a few had testes bilaterally. Some of the previous breeding data appeared to support the hypothesis that C57BL/6J had an autosomal recessive factor that differed from the poschiavinus strain and, in the homozygous state, caused incomplete testis development with the poschiavinus Y chromosome. Subsequent attempts to map the Tda-1 factor, using a recombinant inbred strain approach, failed to localize Tda-1 and this suggests it might map to different chromosomes depending on which strain pairs are used. We constructed two strains of C57BL/6J and DBA/2J that are congenic for the poschiavinus Y chromsome. In the C57BL/6J. Y-POS congenic strain, liability to express incomplete testis development is normally distributed and thresholds in development specify the probability (or areas under the normal distribution) of different classes of ovary, ovotestis, and testis combinations. Testis development is normal in the DBA/2J. Y-POS congenic strain. With the two congenic strains and their normal parental strains we were able to conduct standard crosses to examine the reciprocal F1 and four types of backcross generations to the C57BL/6J strain in which all XY individuals have the poschiavinus Y chromosome.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic variation in paw preference (handedness) in the mouse.

Lateralization of paw preference in laboratory mice in a single-paw reaching task has been used as a model system for left- and right-hand usage. Given a set number of paw reaches for food from a centrally placed food tube, an individual mouse will exhibit a reliable number of left and right paw reaches. Within any single inbred strain, there are approximately equal numbers of left-pawed and right-pawed mice. Nevertheless, significant strain differences have been reported for the degree of lateralization of paw preference. We report here a systematic survey of paw preference in 12 inbred strains of the mouse in which the degree of lateralization falls into two groups of weakly lateralized and highly lateralized paw preference. The genetic inference is that a single major gene may control some function, and alternate alleles at this locus are expressed as weakly and highly lateralized paw preference. Reciprocal crosses indicate the trait is additive with no maternal or X-linked effects. The direction of paw preference has previously appeared to be genetically neutral, but in some strains there is evidence of significant deviation of the numbers of mice to the left and right of equal paw usage, independent of degree of lateralization, and this suggests that direction of left-right paw usage may be a separate genetic trait in the mouse model.

Penetrance and expressivity of acetazolamide-ectrodactyly provide a method to define a right-left teratogenic gradient that differs between the C57BL/6J and WB/ReJ mouse strains.

Penetrance or the frequency of embryos with any degree of forelimb ectrodactyly is the usual method to describe the forelimb ectrodactyly response of mouse embryos to acetazolamide. A digit score for number of small or absent digits for the separate right and left forelimb response to acetazolamide provides a measure of expressivity or the severity of response. We examine the relationship between expressivity and penetrance using right and left forelimb data from a previously reported dose-response analysis of the C57BL/6J and WB/ReJ strains to acetazolamide. The data show that expressivity and penetrance are highly correlated for the separate right and left forelimbs for both strains. In C57BL/6J, the dose-response analyses of both expressivity and penetrance of the separate right and left forelimbs demonstrate a teratogenic gradient, decreasing from right to left, that depends on the symmetrical ectrodactyly response of the right and left forelimbs. In WB/ReJ, the right forelimb is also more sensitive than the left, but the dose-response analyses of both penetrance and expressivity show the two forelimbs are asymmetrical in their ectrodactyly response and that there is not a simple teratogenic gradient in this strain. In WB/ReJ, the left forelimb is resistant at even the highest non-lethal doses. The high correlation between expressivity and penetrance for the separate forelimbs of both C57BL/6J and WB/ReJ suggests that this right-left difference between the two strains may not be a property of the limbs themselves but may be an intrinsic genetic difference between the two types of embryos perhaps in the amount of teratogen to which the embryos are exposed.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetically determined variation in the azygos vein in the mouse.

The normal mouse is expected to have a single and left-sided azygos vein that develops from the paired embryonic cardinal venous system and drains most of the right and left thoracic walls into the left anterior vena cava. During routine autopsies of adult mice, most individuals of the C57BL/6J strain were found to have this pattern but a distribution of different azygos venous patterns was found in the WB/ReJ strain. In WB/ReJ the patterns varied from a single unpaired vein on the right side that connected to the right anterior vena cava through bilaterally symmetrical and paired veins to the expected unpaired vein on the left side. A classification scheme for the observed patterns of azygos veins was developed and the frequency distributions of C57BL/6J and WB/ReJ mice in these classes were compared. The strain difference in the azygos venous system between C57BL/6J and WB/ReJ can be interpreted as a genetically determined threshold trait of development. Beginning with a paired and symmetrical cardinal venous system, the C57BL/6J genotype shifts to a left-sided azygos pattern but the WB/ReJ genotype remains with a more bilateral azygos pattern. Genetic study of this azygos trait will be useful for the study of lateral asymmetries in mammalian development and for the interpretation of venous heterotaxies (anomalous placement of veins) in the mouse that are found in association with mutations such as situs inversus viscerum (iv) and dominant hemimelia (Dh).

Time-response and dose-response to acetazolamide in the WB/ReJ and C57BL/6J mouse strains: genetic interaction in the ectrodactyly response.

The WB/ReJ and C57BL/6J strains were compared in their time and dose responses to acetazolamide administered in a single subcutaneous injection regime. WB/ReJ has a genetically determined, high-frequency, transient fetal edema that has maximum expression on day 14 and is resolved by day 18. Acetazolamide, at 1,000 mg/kg, appears to induce edema in WB/ReJ with a time of response on days 9 and 10, and the induced edema follows the same time course of appearance and disappearance as the spontaneous trait. The dose-response analysis is not interpretable in the WB/ReJ and C57BL/6J strains and their reciprocal F1 fetuses because there was significant response only at the highest dose (2,000 mg/kg) used in this study. The time of ectrodactyly response is maximal on day 9 in both WB/ReJ and C57BL/6J strains. The dose-response analysis demonstrates that, for the usual measure of total fetuses with ectrodactyly (or penetrance), the Wb/ReJ and C57BL/6J strains and the WB/ReJ x C57BL/6J F1 (WB.B6F1) have the same slope of the dose-response curve and the strain difference in response can be interpreted as a difference in dosage tolerance. The tolerance of WB/ReJ is twofold greater than that of C57BL/6J. This overdominance of relative resistance to acetazolamide ectrodactyly supports the general finding of directional dominance of relative resistance among genetically different strain pairs. The median effective dose for penetrance of the ectrodactyly response of the reciprocal B6.WBF1 embryo is similar to the WB.B6F1, but the slope of the dose-response curve is significantly different, and a different teratogenic mechanism of response may be involved. Ectrodactyly was predominantly right sided in all genotypes, and, in bilaterally affected fetuses, the right forelimb was more severely affected. An unexpected difference between WB/ReJ and C57BL/6J was found when the laterality of ectrodactyly was analyzed further. There is a significant increase with dosage in bilaterally affected fetuses (a measure of expressivity) in C57BL/6J but not in WB/ReJ, even though the dose-response of total affected fetuses (penetrance) is similar in both strains. In C57BL/6J, the left and right forelimbs are correlated in their responses with the left, requiring approximately a threefold greater dose. The left and right forelimbs are symmetrical in response, and the difference can be interpreted in terms of a developmental (or teratogenic) gradient. In WB/ReJ, the right forelimb has the same dose response as C57BL/6J and requires a twofold greater dose than the right forelimb of C57BL/6J, but the left forelimb has a very flat slope and is not correlated with the response of the right.(ABSTRACT TRUNCATED AT 400 WORDS)

A DNA polymorphism from five inbred strains of the mouse identifies a functional class of domesticus-type Y chromosome that produces the same phenotypic distribution of gonadal hermaphrodites.

The wild-derived CLA inbred strain of the house mouse contains a domesticus-type Y chromosome that lacks a 2.3-kb TaqI band with fragment 1 of the AC11 probe. The CLA Y chromosome also causes a low frequency of XY gonadal hermaphrodites when backcrossed to the C57BL/6J strain (F. G. Biddle and Y. Nishioka, 1988. Genome, 30:870-878). A similar domesticus-type Y chromosome, lacking the 2.3-kb TaqI band has now been found in the four historical inbred strains AKR/J, MA/MyJ, PL/J, and RF/J. When backcrossed to C57BL/6J, these four Y chromosomes cause low frequencies of gonadal hermaphrodites similar to the CLA Y and phenotypic distribution of types of gonad are indistinguishable from that with the CLA Y. The absence of the 2.3-kb TaqI band appears to be a polymorphism among domesticus-type Y chromosomes that identifies one of the three functional classes that, so far, can be distinguished only by their effects on testis differentiation in backcross test fetuses with the C57BL/6J strain. Three other historical inbred strains, BUB/BnJ, ST/bJ, and SWR/J, with a domesticus-type Y chromosome but containing the 2.3-kb TaqI band, were also assayed. They permit normal testis development in backcross test fetuses with C57BL/6J.

Familial X-linked ichthyosis, steroid sulfatase deficiency, mental retardation, and nullisomy for Xp223-pter.

Steroid sulfatase (STS)-deficient X-linked ichthyosis was diagnosed in a man with short stature and mental retardation. His generation includes five similarly affected male members. A translocation chromosome is segregating in this Newfoundland kindred. The proband's mother and grandmother have normal skin and are of normal intelligence. From his carrier mother, the proband inherited an X short arm (Xp) to Y long arm (Yq) translocation chromosome, with the entire Y short arm and the X short arm terminal segment deleted (Xp223-pter). His cells are completely deficient in STS activity, confirming assignment of the STS locus to Xp223-pter. Effective management of his ichthyosis included treatment with 6% salicylic acid gel under plastic occlusion and removal of the scales by scrubbing.

Genetic control of sex-chromosomal univalency in the spermatocytes of C57BL/6J and DBA/2J mice.

The genetic control of sex-chromosomal univalency was examined in the primary spermatocytes of the mouse. The C57BL/6J strain expresses 3% X-Y univalency and DBA/2J expresses 37% univalency. The reciprocal F1 and the eight types of reciprocal backcross males were examined. In the C57BL/6J--DBA/2J strain pair, X--Y univalency is controlled by three genetic systems. Autosomal factors of unknown number that are dominant in DBA/2J increase the probability of univalency from 3% in C57BL/6J to 12%. The DBA/2J-Y chromosome, in place of the C57BL/6J-Y chromosome, has an additive effect to increase the probability of univalency from 12 to 37% in the DBA/2J strain. Two X-chromosome factors that differ between C57BL/6J and DBA/2J regulate the probability of univalency. The X-chromosome factors appear to be separated by sufficient distance so that, with the DBA/2J-Y chromosome and dominant DBA/2J autosomal factors, there are two recombinant classes of X--Y univalency at 20 and 60%. The genetic factors in the univalency trait may be involved in the regulation or structure of the terminal attachment sites between the X and Y chromosomes.