Reduced epithelial surface activity is related to a higher incidence of facial clefting in A/WySn mice

The epithelial surfaces of the facial primordia were evaluated by scanning electron microscopy (SEM) during primary palatogenesis in two genetically related mouse strains, the A/J and the A/WySn strains. These two strains were selected because the reported frequency of spontaneous cleft lip with or without cleft palate [CL(P)] in the A/J strain approximates 0%, whereas the spontaneous frequency of CL(P) in the A/WySn strain is 20-30%. The embryos were examined prior to (two to six tail somites), during (seven to ten tail somites), and after (ten to 14 tail somites) primary palate fusion. During fusion, epithelial surface activity (characterized as cellular debris, dissociated cells, cellular projections, and epithelial bridging) was more pronounced in A/J embryos. A/WySn embryos with spontaneous cleft lip exhibited a marked deficiency in epithelial activity when compared to their normal littermates. No discernible differences were detected in the facial morphology, with the exception of the distal end of the medial nasal prominence, which appeared longer in the A/J strain. This study suggests that the degree of epithelial surface activity at the putative site of fusion and the relative length of the medial nasal prominence may account for the observed differences in facial clefting of the two strains. Face shape, related to prominence divergence, was similar in the two strains and could not explain the higher incidence of clefting observed in the A/WySn strain.     

Diazepam-induced cleft palate in the mouse and lack of correlation with the H-2 locus

Cleft palate frequencies were studied in AJ and SW mice following either 1- or 2-day dosing schedules with the anxiolytic drug diazepam (DAZ). In all cases, mice were food and water deprived for 24 and 48 hours in the 1- and 2-day dosing schedules, respectively. High cleft palate frequencies in control mice of both strains resulting from 48-hour food and water deprivation (on days 13.5 and 14.5 of gestation) were reduced in mice deprived for 24 hours, indicating a stress related effect. Two-day dosing with DAZ (400 mg/kg) produced a net increase in cleft palate frequency in SW (33%) and AJ (18%) mice. Mice treated only on day 13.5 had reduced control and DAZ cleft palate frequencies, neither of which were significant. Clefting was significant but reduced following 1-day dosing on day 13/20 of gestation (13 days 20 hours) in SW mice (18%), whereas no clefting was seen in the AJ strain. This strain difference was shown not to be related to differences in developmental timing. Production of cleft palate seen in AJ mice after 2 days of dosing may be indicative of an interaction of DAZ with the stresses resulting from food and water deprivation. Genes of the major histocompatibility locus, H-2, have been shown to regulate cleft palate formation following glucocorticoid and phenytoin administration to mice. Despite pharmacological similarities between DAZ and phenytoin, comparison of cleft palate frequencies following administration of DAZ to various strains of mice of different H-2 haplotypes indicated that genes associated with the H-2 locus do not regulate DAZ-induced cleft palate in these strains.     

Cleft palate: more genetic lessons from mice

Cleft palate occurred in high frequency (14%) in the F2 generation of the cross between two stocks of mice, LGG and SELH, neither of which produces more than 2% cleft palate. The cleft palate trait results from a new combination of alleles that is not present in either parental stock. The lack of cleft palate in the F2 generation after outcrosses of both parental stocks to other strains shows that this new combination of alleles has specific contributions from both parental strains, and also that there must be at least two loci involved. A deficiency of Mod-1 homozygotes in the SELH/LGG F2 adults suggests that one of the loci involved may be linked to Mod-1 and that the number of loci involved is few. Significantly more F2 males (19%) than females (9%) were affected with cleft palate. The data can be explained by a two-locus epistatic model with a dominant mutation (P) at one locus that causes cleft palate when not suppressed by or compensated for by a dominant allele (S) at a second locus. The parental stocks would be PPSS and ppss. In the F2 generation, the new combinations PPss and Ppss would express cleft palate, a total expected of 19%. Similar new combinations of alleles at two loci may explain some instances of high occurrence of cleft palate or other developmental threshold traits in previously unaffected human families.     

Accelerated Wound Closure In Vitro by Fibroblasts from a Subgroup of Cleft Lip/Palate Patients: Role of Transforming Growth Factor-α

In a fraction of patients surgically treated for cleft lip/palate, excessive scarring disturbs maxillary growth and dento-alveolar development. Since certain genes are involved in craniofacial morphogenesis as well as tissue repair, a primary defect causing cleft lip/palate could lead to altered wound healing. We performed in vitro wound healing assays with primary lip fibroblasts from 16 cleft lip/palate patients. Nine foreskin fibroblast strains were included for comparison. Cells were grown to confluency and scratch wounds were applied; wound closure was monitored morphometrically over time. Wound closure rate showed highly significant differences between fibroblast strains. Statistically, fibroblast strains from the 25 individuals could be divided into three migratory groups, namely “fast”, “intermediate”, and “slow”. Most cleft lip/palate fibroblasts were distributed between the “fast” (5 strains) and the “intermediate” group (10 strains). These phenotypes were stable over different cell passages from the same individual. Expression of genes involved in cleft lip/palate and wound repair was determined by quantitative PCR. Transforming growth factor-α mRNA was significantly up-regulated in the “fast” group. 5 ng/ml transforming growth factor-α added to the culture medium increased the wound closure rate of cleft lip/palate strains from the “intermediate” migratory group to the level of the “fast”, but had no effect on the latter group. Conversely, antibody to transforming growth factor-α or a specific inhibitor of its receptor most effectively reduced the wound closure rate of “fast” cleft lip/palate strains. Thus, fibroblasts from a distinct subgroup of cleft lip/palate patients exhibit an increased migration rate into wounds in vitro, which is linked to higher transforming growth factor-α expression and attenuated by interfering with its signaling.     

A novel spontaneous mutation of BCAR3 results in extrusion cataracts in CF#1 mouse strain

A substrain of mice originating from the CF#1 strain (an outbred colony) reared at Osaka Prefecture University (CF#1/lr mice) develops cataracts beginning at 4 weeks of age. Affected mice were fully viable and fertile and developed cataracts by 14 weeks of age. Histologically, CF#1/lr mice showed vacuolation of the lens cortex, swollen lens fibers, lens rupture and nuclear extrusion. To elucidate the mode of inheritance, we analyzed heterozygous mutant hybrids generated from CF#1/lr mice and wild-type BALB/c mice. None of the heterozygous mutants were affected, and the ratio of affected to unaffected mice was 1:3 among the offspring of the heterozygous mutants. For the initial genome-wide screening and further mapping, we used affected progeny of CF#1/lr × (CF#1/lr × BALB/c) mice. We concluded that the cataracts in CF#1/lr mice are inherited through an autosomal recessive mutation and that the mutant gene is located on mouse chromosome 3 between D3Mit79 and D3Mit216. In this region, we identified 8 genes associated with ocular disease. All 8 genes were sequenced and a novel point mutation (1 bp insertion of cytosine) in exon 7 of the Bcar3 gene was identified. This mutation produced a premature stop codon and a truncated protein. In conclusion, we have identified the first spontaneous mutation in the Bcar3 gene associated with lens extrusion cataracts. This novel cataract model may provide further knowledge of the molecular biology of cataractogenesis and the function of the BCAR3 protein.     

Genetics of Cortisone-Induced Cleft Palate in the Mouse—embryonic and Maternal Effects

Differences between mouse strains in frequency of embryonic, cortisone-induced cleft palate were examined. Probit analysis demonstrated a family of linear and parallel dose-response curves for different inbred and hybrid embryos. Since the differences between genotypes were not in the slopes of the response curves but rather in their location, it is proposed that the median effective dose (ED₅₀) of cortisone required to induce cleft palate (or the tolerance) provides a more appropriate definition of the response trait and its difference than a frequency statement. The tolerance of C57BL/6J is dominant to that of A/J. A maternal effect of A/J relative to C57BL/6J dams caused a two-fold reduction in the embryonic tolerance of cortisone. Cortisone-induced cleft palate and mortality were separate response traits.—In these and previous studies on cortisone- and other glucocorticoid-induced cleft palate in the mouse, the nature of the cleft-palate-response curve appeared to be the same for all glucocorticoids, and within-strain differences in tolerance could be used as measures of potency or bioassays for a particular effect of the glucocorticoids.     

Phenytoin teratogenicity in the primary and secondary mouse embryonic palate is influenced by the H-2 histocompatibility locus

Inbred and congenic strains of mice have been studied for susceptibility to phenytoin-induced cleft lip with or without cleft palate (CLP) and isolated cleft palate (CP). The role of genes linked to the H-2 complex on chromosome 17 has been confirmed. Congenic strains with the A background have identical levels of spontaneous CLP, whereas those strains having the A background with the H-2a haplotype have significantly higher rates of induced CLP than their congenic partners with the H-2b or H-2s haplotype. No such significant difference in the degree of CLP produced by phenytoin is demonstrable in strains with the B background. Rates of isolated CP produced by phenytoin are significantly higher in strains with H-2a than in their congenic partner strains with either H-2b or H-2s, whether the background is A or B.     

Cytokeratin, vimentin and E-cadherin immunodetection in the embryonic palate in two strains of mice with different susceptibility to glucocorticoid-induced clefting

An immunohistochemical study analyzing the pattern of distribution of some intermediate filament proteins, keratin and vimentin and, one adhesion molecule, cadherin in different stages of developing secondary palate in two strains of mice with different H-2 backgrounds was undertaken to investigate differences between a strain that is susceptible to glucocorticoid-induced cleft palate (A/Sn) and one that is resistant to glucocorticoid-induced cleft palate (C57/BL). The heads of embryos were processed by standard immunohistochemistry with antipancytokeratin (KAE1), antikeratins 18 (K18) and 19 (K19), antivimentin, and anti E-cadherin antibodies. Immunostaining with KAE1 antibody showed differences between the strains. The reaction was stronger in the medial edge epithelia of palatal processes in the A/Sn strain at all stages of palatogenesis. The C57/BL strain showed a weak immunostain to KAE1. Antivimentin antibody stained the mesenchymal cells of palatal processes and K18 and K19 showed no reaction in either strain of mice. Anti E-cadherin antibody was detected in the medial palatal epithelium of both strains of mice and in all stages of palate development. No differences were observed in E-cadherin and vimentin immunostain in palatal epithelium between the strains. The different expression of some cytokeratins in the embryonic palatal epithelium suggests that these intermediate filament proteins may be involved in different susceptibility to glucocorticoid-induced cleft palate in the mouse. The decreased immunoreaction of cytokeratins observed in the resistant strain would facilitate the disappearance of this molecule during the transformation from an epithelial to a mesenchymal phenotype that takes place during the development of the palate. These results may be related to the loss of cytokeratin expression observed during epithelial-mesenchymal transformation in the embryonic palate.     

Cleft palate fistulas: a multivariate statistical analysis of prevalence, etiology, and surgical management

A retrospective, multivariate statistical analysis of 129 consecutive nonsyndromic patients undergoing cleft palate repair was performed to document the incidence of postoperative fistulas, to determine their cause, and to review methods of surgical management. Nasal-alveolar fistulas and/or anterior palatal fistulas that were intentionally not repaired were excluded from study. Cleft palate fistulas (CPFs) occurred in 30 of 129 patients (23 percent), although nearly a half were 1 to 2 mm in size. Extent of clefting, as estimated by the Veau classification, was significantly more severe in those patients who developed cleft palate fistula. Type of palate closure also influenced the frequency of cleft palate fistula. Forty-three percent of patients undergoing Wardill-type closures developed cleft palate fistula versus 10, 22, and 0 percent for Furlow, von Langenbeck, and Dorrance style closures, respectively. The fistula rate was similar in patients with (30 percent) and without (25 percent) intravelar veloplasty. Age at palate closure did not significantly affect the rate of fistulization; however, the surgeon performing the initial closure did not have an effect. Thirty-seven percent of patients developed recurrent cleft palate fistulas following initial fistula repair. Recurrence of cleft palate fistulas was not influenced by severity of cleft or type of original palate repair. Following end-stage management, a second cleft palate fistula recurrence occurred in 25 percent of patients. Continued open discussion of results of cleft palate repair is recommended.     

Test of the isoallele hypothesis at the mouse first arch (far) locus

We tested the hypothesis that differences in wild-type (+) alleles (isoalleles) at the first arch (far) locus between mouse strains ICR/Bc and BALB/cGaBc are responsible for the partially dominant expression of far in the ICR/Bc genetic background, in contrast to its recessive expression in the BALB/cGaBc background. A similar hypothesis concerning isoalleles has been suggested to explain differences in heterozygote expression in some human genetic diseases but appears not to have been tested directly in mammals. First arch is lethal when homozygous. The dominant effects in ICR/Bc mice include defects in mystacial vibrissa pattern formation and cleft palate. To test the isoallele hypothesis, we made the four appropriate genetic crosses between +/far and +/+ mice between strains. The F1 progeny were scored on day 16 of gestation for defective mystacial vibrissa pattern formation and cleft palate. From all four crosses, approximately 30% of F1 fetuses (i.e., 60% of +/far fetuses) had disrupted mystacial vibrissa patterns, and only one fetus had cleft palate. The fact that all crosses produced approximately equal rates of defective progeny disproves the isoallele hypothesis for far. Therefore, differences between strains in alleles at other loci (modifier loci) must cause the differences in heterozygote (+/far) expression. This genetic design can be used for other mutations with strain differences in heterozygote expression to test the importance of isoalleles in mammals.     

Genetics of susceptibility to 6-aminonicotinamide-induced cleft palate in the mouse: studies in congenic and recombinant inbred strains

In a search for genetic differences in susceptibility to cleft palate, congenic and recombinant inbred strains of mice were treated with 6-aminonicotinamide or control injections. Of six loci tested, only the chromosome segment marked by N-acetyl transferase was found to affect susceptibility to 6-aminonicotinamide-induced cleft palate. This chromosome segment is known to affect glucocorticoid-induced cleft palate and phenytoin-induced cleft lip with or without cleft palate in these strains of mice.     

6-Aminonicotinamide-induced cleft palate in the mouse: the nature of the difference between the A/J and C57Bl/6J strains in frequency of response and its genetic basis.

Cleft palate induction by 6-aminonicotinamide (6-AN) was examined in the A/J and C57BL/6J strains of mice to determine the nature of the strain difference in frequency of cleft-palate response. Probit analysis of the cleft-palate response to dose of different genotypes revealed a family of linear and parallel dose-response curves. The genotypes differ only in dosage tolerance (log ED50) to 6-AN that is required for the cleft-palate response. No evidence for a maternal cytoplasmic effect on 6-AN-induced cleft palate was found under the conditions of the present study. When the difference is dosage tolerance to 6-AN between A/J and C57BL/6J was examined with a single dose and measured by differences in frequency of induced cleft palate on a probit scale, there was some departure from genetic additivity. There was an indication off dominance deviation of the F1 embryos in the direction of C57BL/6J.A3-locus, epistatic model is proposed to account for the difference in embryonic tolerance ot 6-AN-induced cleft palate. There was a suggestion of association with the brown (b) locus.     

Confirmation of the role of N-acetyltransferase 2 in teratogen-induced cleft palate using transgenics and knockouts

Previous work on Dilantin- and hydrocortisone-induced cleft palate and cleft lip with or without cleft palate using congenics for the N-acetyltransferase loci (Nat1 and Nat2 are closely linked) and recombinant inbred lines implicated the Nat1,2 region in susceptibility to teratogen-induced orofacial clefting. Since Nat1 does not differ between the two strains, Nat2 appeared to be responsible. We have now tested this conclusion using transgenics and knockouts. Transgenics for human NAT1 (equivalent to mouse Nat2) and knockouts for Nat2 were tested for susceptibility to Dilantin, hydrocortisone, and 6-aminonicotinamide-induced orofacial clefting. We found that Nat2 greatly influences teratogen-induced orofacial clefting on the A/J background but not on the C57BL/6J background. The magnitude and direction of the effects depended on which teratogen was used. The Nat2 knockout did not make C57BL/6J susceptible or A/J (already with very low activity) more susceptible but significantly decreased sporadic clefting in the A/J strain. We conclude that only the A/J strain, with several loci affecting orofacial clefting, is influenced by Nat2.     

Genetic Differences among the a/J x C57bl/6j Recombinant Inbred Mouse Lines and Their Degree of Association with Glucocorticoid-Induced Cleft Palate

Hydrocortisone sodium phosphate was injected intramuscularly into A/J, C57BL/6J and recombinant inbred lines from these two parental lines to study the genetics of steroid-induced cleft palate in a situation of identical maternal and fetal genotypes. The strains were typed for H-2 (the major histocompatibility locus), beta-glucuronidase and beta 2-microglobulin, which served as markers on chromosomes 17, 5 and 2, respectively. Hepatic glucocorticoid binding capacity had been previously measured in Hepes buffer and Hepes buffer plus dithiothreitol (DTT). The level of glucocorticoid binding in Hepes buffer and in Hepes plus DTT, as well as their ratio, was compared to the incidence of steroid-induced cleft palate in the recombinant inbred lines. A correlation was found between the response of glucocorticoid binding to DTT (expressed as a ratio of binding in the presence of DTT to binding without DTT) and hydrocortisone-induced cleft palate. When analyzing the effect of the three chromosomal markers on hydrocortisone-induced cleft palate, the b alleles of beta 2-microglobulin and of beta-glucuronidase were associated with a higher incidence. Genetic analyses of the differences between these two inbred strains of mice in the incidence of steroid-induced cleft palate show it not to be monogenic.     

Dose-response relations of palatal slit, cleft palate, and fetal mortality in mice treated with a glucocorticoid

C57BL/6 (C57BL) and SWV mice were treated subcutaneously with triamcinolone acetonide in a single dose of 1.0-7.0 mg/kg on day 12 of pregnancy, and the palate of their fetuses was examined at term. In C57BL mice palatal slit occurred spontaneously and its frequency increased with increasing doses of triamcinolone. However, this defect was not seen in SWV fetuses, even when dams were treated with the doses that induced cleft palate. The frequency of cleft palate increased in both C57BL and SWV as the dose of triamcinolone increased. Fetal mortality increased in SWV, but not in C57BL, with increasing doses of triamcinolone. Dose-response relations were analyzed by the log-probit transformation method. In C57BL mice, the slope of the dose-response curve of palatal slit was significantly different from that of cleft palate. In contrast, the dose-response curves of cleft palate were similar in both C57BL and SWV; the median effective dose was significantly greater in C57BL than in SWV. The mechanism of induced palatal slit appears to be different from that of induced cleft palate; the mechanism of cleft palate induction may be the same in both C57BL and SWV. The slope of the dose-response curve of fetal mortality in SWV mice was different from that of cleft palate; the mechanisms underlying the resorption and cleft palate responses must be different.     

Chondrodystrophic mice with coincidental agnathia: evidence for the tongue obstruction hypothesis in cleft palate

Mice homozygous for either of two mutations, chondrodysplasia (cho) or cartilage matrix deficiency (cmd), have short-limbed chondrodystrophy. This phenotype includes retrognathia, relative macroglossia, and cleft palate. It has been postulated that the cleft palate in these mice is the result of tongue obstruction during palatogenesis. Agnathia associated with microglossia is an independent spontaneously occurring defect in the strains bearing these mutations. The coincidental occurrence of agnathia-microglossia with chondrodystrophy lends itself to the study of the mechanism of cleft palate formation. We examined approximate midsagittal histological sections of normal and chondrodystrophic newborn mice, both with and without agnathia. Mandibular measurements and examinations of palate closure and tongue structure were made from photographic prints. Typical chondrodystrophic mutants with cleft palates had a mean mandibular length that was 66% of normal and a tongue that appeared large relative to the shortened mandible. Chondrodystrophic mutants with agnathia and microglossia had a mean mandibular length that was further reduced to 30% of normal, yet had a closed palate. We also observed two nonagnathic chondrodystrophic mutants that had slightly decreased mandibular lengths, microglossia, and closed palates. These observations suggest that tongue obstruction during palatogenesis is the pathogenetic mechanism of cleft palate in chondrodystrophic mice. A similar tongue obstruction hypothesis has been proposed as the mechanism of cleft palate formation in the human Pierre Robin sequence, which consists of retrognathia, glossoptosis, and cleft palate. This mechanistic hypothesis has been challenged, but our findings support the tongue obstruction hypothesis in the Robin cleft.     

The relation between maternal restraint and food deprivation, plasma corticosterone, and induction of cleft palate in the offspring of mice.

The blood level of corticosterone was measured in mice following the injection on day 14 of pregnancy of a dose of corticosterone sufficient to cause a low frequency of cleft palate in the fetuses. This was compared with the blood levels present during maternal restraint and food deprivation that produced a similar frequency of cleft palate. The mean blood level over the 24 h following injection of corticosterone was 660 mug/100 ml, and during a similar period of restraint was 485 mug/100 ml. Other mice were subjected either to restraint or food deprivation for 24 h beginning day 14 of pregnancy, the plasma corticosterone levels measured during that time, and the frequency of cleft palate in late fetuses compared with the individual plasma corticosterone levels during treatment. There was a significant (P less than 0.025) correlation between high maternal corticosteroid levels and the frequency of cleft palate in the offspring of the restrained mice but not in the food-deprived animals. It is suggested that in some stressed mice endogenous plasma corticosterone can reach levels sufficient to account for the development of cleft palate.     

Periconceptional multivitamin intake during early pregnancy, genetic variation of acetyl-N-transferase 1 (NAT1), and risk for orofacial clefts

BACKGROUND: Periconceptional supplementation of multivitamins that include folic acid have been shown to prevent several birth defects, including neural tube defects and orofacial clefts. We investigated whether polymorphic variants of fetal acetyl-N-transferase 1 (NAT1), an enzyme involved in the catabolism of folates, differentially interacted with maternal multivitamin use during early pregnancy to alter the risk of delivering an infant with an orofacial cleft malformation. METHODS: Using a large population-based case-control study, we genotyped 421 California infants born with an isolated cleft and 299 controls for two NAT1 polymorphisms. RESULTS: Compared to the homozygous wild-type genotypes, odds ratios for isolated cleft lip with/without cleft palate were slightly increased among infants who were homozygous for the variant alleles of NAT1 1088 and 1095. For isolated cleft palate, no similar associations with these two NAT1 variants were observed. For NAT1 1088 genotypes, we did not observe any differential risks for clefts related to maternal multivitamin intake. For NAT1 1095 genotypes, however, we found a two-fold higher risk for isolated cleft lip with/without cleft palate among infants who were homozygous for the variant allele and whose mothers did not take multivitamins during early pregnancy. CONCLUSIONS: We found evidence suggestive of an interaction between the NAT1 1095 polymorphism and lack of maternal multivitamin use that increased risks of isolated cleft lip with/without cleft palate.     

Restriction fragment length polymorphisms, glucocorticoid receptors, and phenytoin-induced cleft palate in congenic strains of mice with steroid susceptibility differences.

A gene that affects susceptibility to cortisone-induced cleft palate maps between H-2S and H-2D on mouse chromosome 17. Congenic mouse strains that differ at this locus, designated Cps-1 (cleft palate susceptibility-1), have been tested for the presence of several closely linked markers. All data obtained so far are consistent with a gene order of H-2S-Cps-1-BAT-5-BAT-2-TNF-H-2D. The Cps-1 gene does not appear to affect the level of glucocorticoid receptors or the susceptibility of mice to phenytoin-induced cleft palate.     

Alteration of medial-edge epithelium cell adhesion in two Tgf-beta3 null mouse strains

Abstract Although palatal shelf adhesion is a crucial event during palate development, little work has been carried out to determine which molecules are responsible for this process. Furthermore, whether altered palatal shelf adhesion causes the cleft palate presented by Tgf -β₃ null mutant mice has not yet been clarified. Here, we study the presence/distribution of some extracellular matrix and cell adhesion molecules at the time of the contact of palatal shelves in both wild-type and Tgf -β₃ null mutant palates of two strains of mice (C57/BL/6J (C57), and MF1) that develop cleft palates of different severity. We have performed immunohistochemistry with antibodies against collagens IV and IX, laminin, fibronectin, the α₅- and β₁-integrins, and ICAM-1; in situ hybridization with a Nectin-1 riboprobe; and palatal shelf cultures treated or untreated with TGF-β₃ or neutralizing antibodies against fibronectin or the α₅-integrin. Our results show the location of these molecules in the wild-type mouse medial edge epithelium (MEE) of both strains at the time of the contact of palatal shelves; the heavier (C57) and milder (MF1) alteration of their presence in the Tgf -β₃ null mutants; the importance of TGF-β₃ to restore their normal pattern of expression; and the crucial role of fibronectin and the α₅-integrin in palatal shelf adhesion. We thus provide insight into the molecular bases of this important process and the cleft palate presented by Tgf -β₃ null mutant mice.