A Postimplantation Lethal Mutation Induced by Transgene Insertion on Mouse Chromosome 8

We have produced three lines of transgenic mice that contain additional copies of the mouse phosphoglycerate kinase 1 (Pgk1) gene. Two of these lines, 94-A and 94-K, which are descendants of a common founder, did not produce liveborn progeny carrying two copies of these transgenes (i.e., A/A, K/K, or A/K). Genotyping of midgestation embryos showed that A/K embryos are dead by Embryonic Day 10. Comparison of the level of transgene expression in the three transgenic lines ruled out PGK1 toxicity as the cause of death of A/A, A/K, and K/K embryos. The death of A/A, K/K, and A/K transgenic mice was therefore attributed to an insertional mutation disrupting a gene or genes essential for normal embryogenesis. Analysis of the structure of the 94-A and 94-K transgenes indicated that they differ in the number of tandem repeats and in the positions of the transgene-cellular DNA junctions. To determine if the two transgenes represent a single integration followed by a rearrangement or two independent integration events, we cloned the endogenous sequences surrounding the 94-A and 94-K transgene insertion sites. Restriction analysis of the isolated genomic clones indicated that the endogenous sequences abutting the 3′ ends of the 94-A and 94-K transgenes are separated by less than 20 kb, providing strong support for the single integration model. Further analysis indicated that the 94-A transgene is associated with a deletion of at least 18 kb and is located in the vicinity of a widely transcribed endogenous gene. Chromosomal mapping of the endogenous sequences flanking the 94-A and 94-K transgene insertions using mouse-hamster somatic cell hybrids and a (C57BL/6J × SPRET/Ei)F1 × SPRET/Ei backcross panel allowed us to assign the 94-A(K) transgene insertion to the subcentral region of mouse chromosome 8.     

Enhanced susceptibility of mouse embryos heterozygous for oligosyndactyly (Os/+) to mitomycin C-induced skeletal abnormalities

The mouse mutation, oligosyndactyly (Os), results in syndactyly, muscle anomalies, and deficiency of nephrons in heterozygous animals and early embryonic lethality in homozygotes. Since the homozygous lethality results from mitotic arrest with intact spindles at the time of implantation, we have hypothesized that the heterozygous manifestations may result from impairment of cell proliferation in regions with high proliferative rates. To test this hypothesis, Os/+ and +/+ mouse embryos at 6.5 days of gestation were exposed to mitomycin C (MMC), an agent that causes a high degree of embryonic cell death which is "compensated" for by a period of rapid cell proliferation. 17.9% of MMC-treated +/+ fetuses had fused vertebrae, a significant increase over untreated fetuses, and this frequency was further increased to 33.6% in MMC-treated Os/+ fetuses. Saline treated Os/+ and +/+ fetuses showed the same low rate (0-3%) of vertebral fusion. These results indicate that Os/+ embryos have an increased sensitivity to the vertebral fusion-inducing effect of MMC at 6.5 days of gestation, a finding compatible with the hypothesis that rapid cell proliferation may be impaired in Os/+ embryos and fetuses.     

The effect of mutation dominant spotting-Yurlovo (KitW-Y) on spermatogenesis, early embryogenesis, and fertility of C57BL/6JY mice

The effect of mutation KitW-Y found in C57BL/6 mice on fertility, spermatogenesis, and early embryogenesis of mice have been studied. If heterozygotes KitW-Y/+ are crossed with wild-type mice, fertility decreases by 20%. Homozygotes Kitw-Y/KitW-Y and compounds KitW-Y/KitSsm are nonviable. The study of spermatogenesis in KitW-Y/+ mice has demonstrated a negative effect of this mutation on spermatocytes. Histological examination of the testes of mutant males has shown local empty spaces in seminal ducts. Electron microscopic examination of synaptonemal complexes have demonstrated desynapsis disturbance in some nuclei at the diplotene stage of meiotic prophase I. However, these disturbances do not cause a decrease in the number of fertilized oocytes/ova. The decrease in fertility is accounted for disturbances of early embryogenesis. In vivo and in vitro analyses of early embryogenesis have demonstrated that cleavage divisions are asynchronous in KitW-Y/+ heterozygous embryos. Some of these embryos die before implantation, and others cleave more rapidly than wildtype embryos, which give them selective advantage during the postimplantation period of embryogenesis. The pattern of KitW-Y expression during spermatogenesis and embryogenesis mimics potential human pathology, which makes these mutants an interesting and valuable object for genetics and developmental biology.     

Spindle-pole organization during early mouse development

Spindle-pole organization during early mouse development was examined using a variety of immunological reagents that recognize centrosomal components. Spindle poles of unfertilized eggs and blastocysts were found to react positively with two antisera (centrin and NRS-01), whereas poles of activated eggs and early cleavage-stage embryos were negative when treated with the same sera. In contrast, a third antiserum (5051) showed positive spindle-pole staining throughout the preimplantation stages of development. Two monoclonal antibodies (MPM-1 and MPM-2) that are known to react with mitotic phosphoproteins were also used in this study. Both antibodies stained the cytoplasm of mitotic cells with extremely high intensity. In addition, MPM-2 was found to stain spindle poles. These results suggest that organizational changes in the spindle pole are occurring during early mouse development. Embryos homozygous for a recessive lethal mutation known as oligosyndactyly (Os) were also treated with the reagents described above. This mutation results in a metaphase arrest at the blastocyst stage with intact spindles being present. Spindle poles were observed in Os homozygous mutants stained with centrin, NRS-01, and 5051. However, when Os mutants were stained with the MPM monoclonal antibodies, about half of the mitotic cells completely lacked the dramatic cytoplasmic staining. This observation is in contrast to that observed for wild-type embryos, where greater than 95% of mitotic cells showed positive cytoplasmic staining.     

Tyrosinase-related protein 2 promoter targets transgene expression to ocular and neural crest-derived tissues

In an effort to identify a promoter suitable for studying early ocular development, we generated transgenic mice carrying the lacZ reporter gene linked to the tyrosinase-related protein 2 (TRP2) promoter. TRP2-lacZ was expressed in early retinal pigment epithelium (RPE) and early neural crest cells in embryos. The promoter activity was robust and consistent in independent transgenic lines. The transgene was also expressed in the optic nerve and neural crest-derived neuronal cells in which the endogenous TRP2 gene is not expressed. This suggests that repressor elements may be missing in the promoter used in this study. To test whether this promoter can be used to study melanocyte development, we cross-mated TRP2-lacZ transgenic mice with mice heterozygous for the Patch (Ph) mutation. The pattern of beta-galactosidase activity in the embryos correlates well with the pigmentation phenotype in postnatal and adult Ph/+ mice. We also generated transgenic mice expressing fibroblast growth factor 9 (FGF9) directed by the TRP2 promoter and examined the effect on ocular development. Ectopic expression of FGF9 in the early embryonic RPE switched its differentiation pathway to a neuronal fate, resulting in formation of a duplicated neural retina in transgenic mice. These studies demonstrate that the TRP2 promoter is valuable for transgenic studies of ocular differentiation and development of neural crest cells.     

Evidence for Mitotic Recombination in W(ei)/+ Heterozygous Mice

A number of alleles at coat color loci of the house mouse give rise to areas of wild-type pigmentation on the coats of otherwise mutant animals. Such unstable alleles include both recessive and dominant mutations. Among the latter are several alleles at the W locus. In this report, phenotypic reversions of the Wei allele at the W locus were studied Mice heterozygous in repulsion for both Wei and buff (bf) [i.e. Wei+/+bf] were examined for the occurrence of phenotypic reversion events. Buff (bf) is a recessive mutation, which lies 21 cM from W on the telomeric side of chromosome 5 and is responsible for the khaki colored coat of nonagouti buff homozygotes (a/a; bf/bf). Two kinds of fully pigmented reversion spots were recovered on the coats of a/a; Wei+/+bf mice: either solid black or khaki colored. Furthermore phenotypic reversions of Wei/+ were enhanced significantly following X-irradiation of 9.25-day-old Wei/+ embryos (P less than 0.04). These observations are consistent with the suggestion of a role for mitotic recombination in the origin of these phenotypic reversions. In addition these results rise the intriguing possibility that some W mutations may enhance mitotic recombination in the house mouse.     

Clonal analysis of the tissue specificity of recessive female-sterile mutations of Drosophila melanogaster using a dominant female-sterile mutation Fs(1)K1237

Using the newly isolated, germ line-dependent dominant female-sterile mutation Fs(1)K1237, we have characterized the germ line or somatic line dependence of 25 X-linked recessive female-sterile mutations. Since Fs(1)K1237/+ females fail to lay eggs, only germ line cells which lose Fs(1)K1237 as a result of X-ray-induced mitotic recombination are capable of producing eggs. Such recombination events will render genes on the homologous chromosome homozygous. If this chromosome carries a recessive female-sterile mutation, the fertility will be restored only if the altered function is not required in the germ line. Using this test, we have classified 25 recessive female-sterile mutations: 12 affect germ line function, 12 affect somatic line function, and one gave an ambiguous result for which an explanation is proposed. For a few of the somatic line-dependent mutants, we found that some eggs derived from germ line clones showed the same phenotype as eggs laid by females homozygous for the recessive female-sterile mutation. These results are discussed in terms of a coincident production of clones in the follicle cells.     

The Lethal(1)tw-6(cs) Mutation of Drosophila Melanogaster Is a Dominant Antimorphic Allele of Nod and Is Associated with a Single Base Change in the Putative Atp-Binding Domain

The l(1)TW-6cs mutation is a cold-sensitive recessive lethal mutation in Drosophila melanogaster, that affects both meiotic and mitotic chromosome segregation. We report the isolation of three revertants of this mutation. All three revert both the meiotic and mitotic effects as well as the cold sensitivity, demonstrating that all three phenotypes are due to a single lesion. We further show that these revertants fail to complement an amorphic allele of the nod (no distributive disjunction) locus, which encodes a kinesin-like protein. These experiments demonstrate that l(1)TW-6cs is an antimorphic allele of nod, and we rename it nodDTW. Sequencing of the nod locus on a nodDTW-bearing chromosome reveals a single base change in the putative ATP-binding region of the motor domain of nod. Recessive, loss-of-function mutations at the nod locus specifically disrupt the segregation of nonexchange chromosomes in female meiosis. We demonstrate that, at 23.5 degrees, the meiotic defects in nodDTW/+ females are similar to those observed in nod/nod females; that is, the segregation of nonexchange chromosomes is abnormal. However, in nodDTW/nodDTW females, or in nodDTW/+ females at 18 degrees, we observe a more severe meiotic defect that apparently affects the segregation of both exchange and nonexchange chromosomes. In addition, nodDTW homozygotes and hemizygous males have previously been shown to exhibit mitotic defects including somatic chromosome breakage and loss. We propose that the defective protein encoded by the nodDTW allele interferes with proper chromosome movement during both meiosis and mitosis, perhaps by binding irreversibly to microtubules.     

Developmental Genetics of the 2c-D Region of the Drosophila X Chromosome

We have conducted a genetic and developmental analysis of genes within the 2C-D area of the X chromosome. Phenotypes of 33 mutations representing nine adjacent complementation groups including eight recessive lethals and one visible homeotic mutation (polyhomeotic) are described. Germline clonal analysis of the eight zygotic lethals has revealed three types of gene requirements: normal activity at two pupal lethal loci (corkscrew and C204) and one larval lethal locus (ultraspiracle) is required for normal embryogenesis; normal activity at three larval lethal loci (DF967, VE651 and Pgd) is required for normal oogenesis; and activity at only one locus (EA82), a larval lethal, appears to have no maternal requirement. Ambiguous results were obtained for the GF316 lethal complementation group. Analysis of mitotic figures of the pupal lethals indicates that C204 disrupts an essential mitotic function. This result correlates with the preblastoderm arrest observed among embryos derived from germline clones of C204. Embryos derived from germline clones of corkscrew (csw) exhibit a "twisted" phenotype. The recessive lethal ultraspiracle (usp) disrupts the organization of the posterior tip of the larval both zygotically and maternally: second instar usp/Y larvae derived from heterozygous usp/+ mothers possess an extra set of spiracles, whereas usp/Y embryos derived from females possessing a germline clone (usp/usp) exhibit a localized ventral defect in the ninth or posterior eighth abdominal segment. Analysis of the phenotypes of deficiency-hemizygous embryos indicates the presence of an embryonic zygotic lethal locus, as yet unidentified, which produces central nervous system and ventral hypoderm degeneration. Additional information on the genetic organization of loci within the adjacent 2E area are also described.(ABSTRACT TRUNCATED AT 250 WORDS)     

COP9 signalosome subunit 3 is essential for maintenance of cell proliferation in the mouse embryonic epiblast

Csn3 (Cops3) maps to the mouse chromosome 11 region syntenic to the common deletion interval for the Smith-Magenis syndrome, a contiguous gene deletion syndrome. It encodes the third subunit of an eight-subunit protein complex, the COP9 signalosome (CSN), which controls a wide variety of molecules of different functions. Mutants of this complex caused lethality at early development of both plants and Drosophila melanogaster. CSN function in vivo in mammals is unknown. We disrupted the murine Csn3 gene in three independent ways with insertional vectors, including constructing a approximately 3-Mb inversion chromosome. The heterozygous mice appeared normal, although the protein level was reduced. Csn3(-/-) embryos arrested after 5.5 days postcoitum (dpc) and resorbed by 8.5 dpc. Mutant embryos form an abnormal egg cylinder which does not gastrulate. They have reduced numbers of epiblast cells, mainly due to increased cell death. In the Csn3(-/-) mice, subunit 8 of the COP9 complex was not detected by immunohistochemical techniques, suggesting that the absence of Csn3 may disrupt the entire COP9 complex. Therefore, Csn3 is important for maintaining the integrity of the COP9 signalosome and is crucial to maintain the survival of epiblast cells and thus the development of the postimplantation embryo in mice.     

Optic, olfactory, and vestibular dysmorphogenesis in the homozygous mouse insertional mutant Tg9257

The transgene insertional mutation 9257 on mouse chromosome 18 was originally identified by the circling behavior caused by vestibular abnormalities in heterozygous mutants. To characterize the homozygous phenotype, we generated F2 offspring from the cross (C57BL/6J-tg/+ x DBA/2J). Eye defects ranging in severity from microphthalmia to anophthalmia were observed in the tg/tg offspring. Dysmorphic development of the lens was evident as early as E10.5 in homozygous transgenic mice. Apparent agenesis of the lateral semicircular canal was evident at E14.5. Anomalies of nasomaxillary structures and olfactory neuroepithelium were present in heterozygous and homozygous transgenic mice. The 9257 mutation provides a model for analysis of the morphogenesis of these three neurosensory systems and their associated bony structures.     

Rescue of the neural tube defect of loop-tail mice by a BAC clone containing the Ltap gene

The mouse mutant loop-tail (Lp) is an accepted model for the study of neural tube defects (NTDs) in humans. Whereas Lp/+ heterozygotes show a mild tail defect (looped), homozygous Lp/Lp embryos show a very severe form of NTD, with a completely open neural tube from the hindbrain region to the caudal portion of the spinal cord (craniorachischisis). We have recently identified a positional candidate for Lp on chromosome 1, designated as Ltap. Here, we have used an in vivo complementation approach in transgenic mice to attempt to correct the looped-tail phenotype with a bacterial artificial chromosome clone (BAC280A23) that harbors a full-length copy of the Ltap gene. Genotype:phenotype correlations in Lp/+ heterozygotes carrying BAC280A23 show that this clone can rescue the looped-tail phenotype in two independent founder lines (P < 0.05 and P < 0.0001). Importantly, BAC280A23 is also observed to rescue the lethal NTD of Lp/Lp homozygotes, because several viable transgenic Lp/Lp mice could be identified and appeared normal (P < 0.05). Results from these gain-of-function transgenic animals strongly suggest that the positional candidate Ltap present in this BAC is indeed the gene that is defective in loop-tail.     

Loss of BubR1 acetylation causes defects in spindle assembly checkpoint signaling and promotes tumor formation

BubR1 acetylation is essential in mitosis. Mice heterozygous for the acetylation-deficient BubR1 allele (K243R/+) spontaneously developed tumors with massive chromosome missegregations. K243R/+ mouse embryonic fibroblasts (MEFs) exhibited a weakened spindle assembly checkpoint (SAC) with shortened mitotic timing. The generation of the SAC signal was intact, as Mad2 localization to the unattached kinetochore (KT) was unaltered; however, because of the premature degradation of K243R-BubR1, the mitotic checkpoint complex disassociated prematurely in the nocodazole-treated condition, suggesting that maintenance of the SAC is compromised. BubR1 acetylation was also required to counteract excessive Aurora B activity at the KT for stable chromosome–spindle attachments. The association of acetylation-deficient BubR1 with PP2A-B56α phosphatase was reduced, and the phosphorylated Ndc80 at the KT was elevated in K243R/+ MEFs. In relation, there was a marked increase of micronuclei and p53 mutation was frequently detected in primary tumors of K243R/+ mice. Collectively, the combined effects of failure in chromosome–spindle attachment and weakened SAC cause genetic instability and cancer in K243R/+ mice.     

Abnormal bone production associated with mutant mouse genes pa and we

A syndrome including deficient linear, endochondral, and radial bone growth associated with severe cervico-thoracic lordosis, decreased intrathoracic volume, atelectasis, and early death has been noted in mice possessing the phenotypes of the recessive mutant genes pallid (pa) and wellhaarig (we) as the result of recombination of chromosome 2 between these genes. The syndrome is not seen in the parental strains, which are homozygous for the chromosomal segment containing one or the other gene (pa +/pa + or + we/+ we), nor in the intercross mice heterozygous for both genes in the trans configuration (pa+/+we). The abnormal offspring appeared randomly in the breeding colony with no F1 breeding pair producing more than one pa we mouse. These observations rule out the presence of a mutant gene, fixed or unfixed, as an explanation for this syndrome. We hypothesize that the syndrome is the result of the complementary action of the genes or the chromosomal segments containing the genes pa and we or weBkr. The posited synergism is further supported by the finding that we, which functions as a recessive gene in mice of the pa/+ genotype, appears to function as a dominant gene in mice possessing the pa/pa genotype.     

Generation of a conditionally null allele of the laminin alpha1 gene

Laminins are heterotrimeric glycoproteins of the basement membranes. Laminin 1 (alpha1, beta1, gamma1) is the major laminin expressed during early mouse embryogenesis. To gain access to the physiological function of laminin alpha1 chain, we developed a conditionally null allele of its encoding gene (Lama1) using the cre/loxP system. Floxed-allele-carrying mice (Lama1(flox/flox)) display no overt phenotype. Lama1(flox/flox) mice were crossed with transgenic deleter mice (CMV-Cre) to generate Lama1-deficient mice (Lama1(Delta/Delta)). Lama1(Delta/Delta) embryos die during the early postimplantation period after embryonic day 6.5. They lack Reichert's membrane, an extraembryonic basement membrane in which laminin alpha1 is normally highly expressed. In parallel, Lama1(Delta/Delta) embryos display 1) parietal and visceral endoderm differentiation defects with altered expression of cytokeratin 19 and GATA4, respectively, and 2) an induction of apoptosis. This new mouse model is of particular interest as it will allow time- and tissue-specific inactivation of the Lama1 gene in various organs.     

Expression of a new mutation (Axd) causing axial defects in mice correlates with maternal phenotype and age

A new autosomal mutation, Axd (axial defects), is described. Axd segregates in a simple Mendelian fashion, and it is dominant with incomplete penetrance and variable expressivity. The phenotype of Axd heterozygotes ranges from a variety of tail anomalies to visibly normal tails. Approximately 12% of neonates from curly-tail (CT) F1 (Axd/+) x F1 (Axd/+) matings exhibit open neural tube defects (NTD) in the lumbosacral region and 16% have curly tails. Mean litter sizes and resorption rates comparable to wild type indicate that homozygosity for Axd is not obligately lethal. Genetic background plays a major role in Axd expression. Strains such as BALB/cByJ allow the highest penetrance of the mutation in single dose (46%), whereas, in CF-1 mice Axd is recessive. The tail phenotype of heterozygous Axd/+ dams, in part reflective of their genetic background, correlates with the incidence of NTD in F2 offspring: CT mothers produce significantly more neonates with frank NTD than normal tail mothers. At the one embryonic period examined for this study (D13/D14 post-coitus), an 85% higher incidence of total axial defects is observed than among the F2 at birth. Unchanging litter size and the relative increase in phenotypically normal offspring by birth suggest that Axd acts by delaying posterior neural tube closure. One of the most significant findings in this study is that maternal age influences the survival of Axd embryos in utero. Axd/+ dams older than 8 months yield fewer mean implants, higher resorption rates, and fewer viable embryos with axial defects than do Axd/+ dams younger than 8 months. Axd is not allelic to nor linked to the Sp (splotch) gene which also affects neurulation.