Congenital malformations in rats with the semilethal mutation fused pulmonary lobes

It has been demonstrated that an autosomal recessive gene, fused pulmonary lobes (fpl), causes fusion of the right pulmonary lobes with several associated malformations and a high incidence of death in homozygous newborns (Aoyama et al. Teratology 1988; 37:159-166). The aim of the present study was to investigate whether the deaths of fpl/fpl newborns were caused by functional abnormalities of the malformed lung or other associated malformations. Day-20 fpl/fpl and fpl/+ fetuses were weighed and examined for gross abnormalities. The lungs of selected fetuses were further examined for histological abnormalities. A wide variety of associated external, visceral, and skeletal anomalies as well as relatively lower body weights than those of phenotypically normal fpl/+ littermates were observed in the fpl/fpl fetuses. The associated anomalies consisted of hematomas and/or subcutaneous hemorrhages in the head, truncus and limbs, eyelid anomalies, CNS defects, lobation anomalies of the liver, hypoplasia of the spleen, partial absence of the skull bones, and dorsi- or ventriflexion of the phalanges of the limbs. Among them, CNS defects and partial absence of the skull bones were considered to be possible causes of newborn deaths. However, the incidence of these malformations was approximately 10% and was lower than the neonatal mortality, which had been estimated to be approximately 50% in the previous study (Aoyama et al. Teratology 1988; 37:159-166). The lungs of fpl/fpl fetuses consistently had hypoplasia of the intermediate lobe and fusion of the right pulmonary lobes. No histological changes suggesting postnatal respiratory insufficiency were found in the lungs of day-20 fpl/fpl fetuses, and the cause of newborn death remains unclear.     

Polydactyly lethal: a new mutant spontaneously occurring in the FPL strain of rats

A new mutant gene that causes preaxial polydactyly in the hindlimbs was found in the strain of rats with fused pulmonary lobes (fpl). Genetic analysis has revealed that the new mutation is inherited as an autosomal recessive trait and is not closely linked with the fpl gene. Since homozygous mutants die within the first 2 days after birth, the mutant gene was named polydactyly lethal, gene symbol pl. A test for allelism between the pl gene and another gene, pd, which also causes preaxial duplication anomalies, showed no allelism between these two genes. Skeletal examination revealed that all pl/pl newborns had thickening and/or bifurcation of tarsal I and metatarsal I, as well as duplication of the proximal and distal phalanges of digit I in the hindlimbs. In some cases, phalangeal duplication or bifurcation in digit I with thickening of metacarpal I was also found in the forelimbs, although extra forelimb digits were not detected externally. The pl/pl newborns showed hunchback-like abnormal posture externally and had several associated vertebral abnormalities in varying degrees, i.e., kyphosis, scoliosis, splitting of the thoracic vertebral bodies, and fusion of the lumbar vertebral bodies. No major malformations were seen in the visceral organs. The cause of neonatal deaths has not yet been determined.     

Interaction of mutant genes Fgf5(go-Y), we, and wal changes the duration of hair growth cycles in mice

Mutant gene wallhaarig (wa) was acting as a modifier of the mutant gene waved alopecia (wal), substantially increasing hair loss rate in mice, as was previously shown in our laboratory. The current paper is devoted to a study of mutant gene angora- Y(Fgf5(go-Y)), which had extended anagen stage of the first and second generations hair growth cycles in triple heterozygotes (Fgf5(go-Y)/Fgf5(go-Y) we/we wal/wal). First generation guard hair in triple homozygotes had their anagen stage 4 days longer than the same stage in double homozygotes (+/+ we/we wal/wal). Hair loss started at a catagen stage in double homozygotes, while it started in triple homozygotes at the end of the same stage or even in a telogen. Such mutant gene interaction in hair follicle morphogenesis led to a partial recovery of a body hair coat in triple homozygotes.     

Viable mutant homozygotes at Adh1 locus in sugar beet and their combination ablility

Selection for an increased frequency of mutant semilethal allele Adh1-S of the gene for alcohol dehydrogenase (ADH) was conducted in inbred families of sugar beet. Starting from the fourth generation, viable plants of mutant Adh1-SS homozygotes appeared. In the sixth generation of selection, the combinative ability of mutant homozygotes SS, normal homozygotes FF, and heterozygotes FS was estimated. The hybrids of mutant homozygotes outperformed the hybrids of normal homozygotes in all parameters examined (germinating capacity of seeds, length and weight of 1-week shoots, chlorophyll content in leaves, and root weight). The hybrids of heterozygotes had intermediate values of the parameters. The results obtained are discussed with regard to the mechanisms underlying the recovery of viability of mutant homozygotes and the formation of a compensating gene complex (CGC).     

Interaction of mutant genes Fgf5go-Y, we, and wal changes the duration of hair growth cycles in mice

Mutant gene wallhaarig (wa) was acting as a modifier of the mutant gene waved alopecia (wal), substantially increasing hair loss rate in mice, as was previously shown in our laboratory. The current paper is devoted to a study of mutant gene angora-Y (Fgf5 ^go-Y ), which had extended anagen stage of the first and second generations hair growth cycles in triple heterozygotes (Fgf5 ^go-Y /Fgf5 ^go-Y we/we wal/wal). First generation guard hair in triple homozygotes had their anagen stage 4 days longer than the same stage in double homozygotes (+/+ we/we wal/wal). Hair loss started at a catagen stage in double homozygotes, while it started in triple homozygotes at the end of the same stage or even in a telogen. Such mutant gene interaction in hair follicle morphogenesis led to a partial recovery of a body hair coat in triple homozygotes.     

Cardiac and CNS defects in a mouse with targeted disruption of suppressor of fused

The hedgehog (Hh) pathway is conserved from Drosophila to humans and plays a key role in embryonic development. In addition, activation of the pathway in somatic cells contributes to cancer development in several tissues. Suppressor of fused is a negative regulator of Hh signaling. Targeted disruption of the murine suppressor of fused gene (Sufu) led to a phenotype that included neural tube defects and lethality at mid-gestation (9.0-10.5 dpc). This phenotype resembled that caused by loss of patched (Ptch1), another negative regulator of the Hh pathway. Consistent with this finding, Ptch1 and Sufu mutants displayed excess Hh signaling and resultant altered dorsoventral patterning of the neural tube. Sufu mutants also had abnormal cardiac looping, indicating a defect in the determination of left-right asymmetry. Marked expansion of nodal expression in 7.5 dpc embryos and variable degrees of node dysmorphology in 7.75 dpc embryos suggested that the pathogenesis of the cardiac developmental abnormalities was related to node development. Other mutants of the Hh pathway, such as Shh, Smo and Shh/Ihh compound mutants, also have laterality defects. In contrast to Ptch1 heterozygous mice, Sufu heterozygotes had no developmental defects and no apparent tumor predisposition. The resemblance of Sufu homozygotes to Ptch1 homozygotes is consistent with mouse Sufu being a conserved negative modulator of Hh signaling.     

Intracellular mechanisms of gonadotropin-stimulated gene expression in granulosa cells.

Previous studies have shown that the gonadotropins follicle-stimulating hormone and luteinizing hormone stimulate proopiomelanocortin (POMC) promoter activity and mRNA levels in ovarian granulosa cells. The objective of these studies was to determine the role of cAMP-dependent protein kinases (pKA) in gonadotropin-stimulated gene expression. Primary cultures of rat granulosa cells were transfected with a gene construct consisting of the POMC promoter (-150 to +63; designated pOMC-CAT) fused to the chloramphenicol acetyltransferase (CAT) reporter gene either alone or cotransfected with an expression plasmid (designated mutant RI), which overexpresses a mutant form of the murine RI subunit incapable of binding cAMP and serving as an irreversible inhibitor of the catalytic subunit of pKA. Follicle-stimulating hormone or isoproterenol caused a significant stimulation of pOMC-CAT activity in transfected cells. Cotransfection of pOMC-CAT with mutant RI caused a significant inhibition of basal pOMC-CAT activity and abolished the gonadotropin stimulation. As a control, transfection of the SV-40 viral enhancer-promoter fused to CAT (pSV2-CAT) was unresponsive to follicle-stimulating hormone stimulation and cotransfection with mutant RI had no significant effect on pSV2-CAT activity. These studies suggest that gonadotropin regulation of the POMC promoter is mediated by pKA and that promoter activity is stringently controlled by pKA.     

Animal Model Studies of Allelism: Characterization of Arylsulfatase B Mutations in Homoallelic and Heteroallelic (Genetic Compound) Homozygotes with Feline Mucopolysaccharidosis VI

The identification of a second structural gene mutation at the feline arylsulfatase B locus (MPS VIb) provided the opportunity to investigate the expression of allelism by characterization of the residual enzymatic activity in feline mucopolysaccharidosis VI, an animal analogue of human Maroteaux-Lamy syndrome. Matings were designed to produce affected homozygotes who were homoallelic for the MPS VIa and MPS VIb mutations or heteroallelic genetic compounds (MPS VIa/VIb). The physicokinetic and immunological properties of the partially purified residual hepatic arylsulfatase B isozymes from the affected homoallelic and heteroallelic cats were compared to those of the normal feline enzyme. The residual hepatic arylsulfatase B activities from the inbred MPS VIa and MPS VIb homozygotes were distinguished by differences in physicokinetic and immunological properties. The newly identified mutant isozyme b had abnormal kinetic properties toward artificial and natural substrates, normal cryo- and thermostabilities, a normal molecular weight and an altered electrophoretic mobility. Polyacrylamide gel electrophoresis demonstrated that the mutant b subunits formed dimers with normal subunits in obligate heterozygotes (MPS VI+/b). In contrast, mutant isozyme a subunits from obligate MPS VIa/+ heterozygotes did not dimerize with the normal subunit, and the mutant and normal isozymes could be separated by anion exchange chromatography and polyacrylamide gel electrophoresis. Characterization of the partially purified residual hepatic arylsulfatase B activity from the heteroallelic homozygotes revealed the presence of both mutant isozymes a and b. The demonstration of two allelic mutations in the feline arylsulfatase B gene documented the occurrence of genetic heterogeneity in feline mucopolysaccharidosis VI and permitted characterization of the enzymatic defect in homoallelic and heteroallelic (genetic compound) homozygotes, providing a model for the study of allelism in human genetic disorders.     

Tail anomaly lethal Tal: a new mutant gene in the rat.

A new hereditary tail anomaly (gene symbol Tal) in rats was found in the course of teratological studies with trypan blue. The characteristic feature of the tail anomaly was a short and kinked tail. The genetic analysis indicated that the tail anomaly was caused by an autosomal dominant gene and the homozygotes were lethal in the prenatal stage. The first sign of degeneration in the homozygous embryo appeared in the late egg cylinder stage. The phenotype of this mutant is similar to that of T-locus mutants in mice.     

Percutaneous in vivo gene transfer to the peripheral lungs using plasmid-liposome complexes

The purpose of this study was to investigate a new method of in vivo gene transfer to the lung parenchyma by the percutaneous approach. The plasmid that contains the gene for firefly luciferase driven by a cytomegalovirus (CMV) promoter (pCMVL) in combination with cationic lipids was percutaneously injected into the lung parenchyma. Luciferase activities were localized to the lobes of the lung where the plasmids with cationic lipids were injected. Percutaneous injection of the plasmid containing the human endothelin-1 (hET-1) gene driven by a CMV promoter (pRc/CMVhET-1) in combination with cationic lipids into the lungs caused pulmonary fibrosis localized to the injection site in the peripheral lungs. We concluded that percutaneous in vivo gene transfer to the lungs is a unique and important approach to introduce exogenous gene expression in the limited area of the lung parenchyma. This method of gene transfer will be applicable for human gene therapy for targeted areas of peripheral lung and will also be useful to assess the function of the proteins expressed by a gene in the local area of the lungs.     

Dependence of the combining ability of mutant sugar beet plants on their phenotype

Repetitive gametic selection for a higher frequency of the Adh1-S semilethal mutant allele of the alcohol dehydrogenase (ADH) gene yielded viable homozygotes Adh1-SS. The plants varied in phenotype from weak mutant to nearly normal (restored). Phenotypically different plants were individually tested for combining ability. This parameter was high in plants with the mutant phenotype and tended to decrease, rather than further increase, in plants with a restored normal phenotype. The results are discussed in terms of viability restoration mechanisms in homozygotes for semilethal mutant alleles.     

The we gene is a modifier of the wal gene in mice

Interaction of gene wellhaarig (we) with genes waved alopecia (wal) and hairless (hr) was studied in mice. The mutant gene we is responsible for the development of a specific waved coat in homozygotes. Homozygous mice carrying mutant gene wal also have a wavy coat, though a partial alopecia develops with time in these animals. In homozygotes for the hr gene, hair loss is observed beginning from the age of ten days. A series of crosses we/we and wal/wal yielded animals with we/+wal/wal and we/we wal/wal genotypes. In mice we/+wal/wal carrying gene we at a single dose, alopecia is accelerated significantly as compared to the single-dose homozygotes +/+wal/wal. In we/we wal/wal mice, alopecia starts earlier than in we/+wal/wal mice; by the age of one month, the double homozygotes are almost hairless except for small body areas covered with a sparse coat. In addition, curliness of the first-generation hair in mice we/we wal/wal is much more expressed than in +/+wal/wal and we/we+/+ mice. The obtained evidence suggests that the we gene is a modifier of the wal gene because the former enhances the effects of the wal gene, which is confirmed by the earlier onset of alopecia and progression of the latter in mice having the we/+wal/wal genotype and especially in we/we wal/wal animals. The we/we hr/+ mice do not differ in coat from we/we+/+ mice; in both cases, the coat is wavy. The coat of double homozygotes we/we hr/hr, is similar to that of we/we+/+ mice until ten days of age, when the signs of alopecia appear. By the age of 21 days, mice we/we hr/hr have lost their coat completely like mice +/+ hr/hr. Hence, the we gene is a modifier of the wal gene though it does not interact with hr gene during the coat formation.     

Phenotypes Recognizable in the Progeny of Axolotl Parents Both Heterozygous for the Same Two Mutant Genes

SYNOPSIS. A survey has been made of the types of progeny infourteen groups of axolotl spawnings from parents both heterozygousfor the same two mutant genes. For none of the parental typesdid the progeny homozygous for both mutant genes constitutea distinct phenotype as did the rrlxx larvae recently describedby Humphrey and Chung (1977) from matings of parents both heterozygousfor genes r and x. In four of the fourteen types of matingssome few double homozygotes were recognizable by the fact thatthe gene pair dominating the development of their morphologicaltype had failed to prevent theappearance of one particular featureresulting from the action of the second gene pair. In spawningsfrom parents with the other ten gene combinations no doublehomozygotes were recognized. In many of these, the excess numberof mutants of one of the two expected types indicated that thedouble homozygotes had been identified as being of that type. It is concluded that in the majority of matings in which doublehomozygotes are expected, the mutant gene whose influence ondevelopment begins earliest determines the visible pattern ofmorphology and also the approximate life span of the doublehomozygote. The latter sometimes dies before the stage at whichfeatures determined by its second gene pair are due to appear.Only when the two pairs of mutant genes act more or less simultaneouslyand in a cumulative fashion is the double homozygote likelyto appear as a phenotype distinctly different from the two usualmutant types included among its siblings.     

Phenotype Dependence of the Combining Ability in Mutant Sugar Beet

Repetitive gametic selection for a higher frequency of the Adh1-Ssemilethal mutant allele of the alcohol dehydrogenase (ADH) gene yielded viable homozygotes Adh1-SS. The plants varied in phenotype from weak mutant to nearly normal (restored). Phenotypically different plants were individually tested for combining ability. This parameter was high in plants with the mutant phenotype and tended to decrease, rather than further increase, in plants with a restored normal phenotype. The results are discussed in terms of viability restoration mechanisms in homozygotes for semilethal mutant alleles.     

Gene angora enhances the effects of gene waved alopecia in mice

Interaction between the mutant gene angora-Y (Fgf5(go-Y)) and the mutant gene waved alopecia (wal) in mice has been studied. Gene Fgf5(go-Y) in a homozygous state increases the length of hair of all types, whereas the homozygotes at wal gene display a waved hair with subsequent development of partial alopecia. Crosses between Fgf5(go-Y)/Fgf5(go-Y) and wal/wal mice gave the animals displaying the genotypes +/Fgf5(go-Y) wal/wal and Fgf5(go-Y)/Fgf5(go-Y) wal/walas well as F2 +/+ wal/wal mice. The first signs of alopecia in F2 +/+ wal/wal appear at the same time as in the mutant wal/wal BALB/c mice. This demonstrates that the genetic background has no effect on the expression of mutant gene wal. A single dose of gene Fgf5(go-Y) in +/Fgf5(go-Y) wal/wal mice causes a considerably earlier appearance of the first signs of alopecia compared with the +/+ wal/wal single homozygotes. The signs of alopecia in double homozygotes Fgf5(go-Y)/Fgf5(go-Y) wal/wal appear even earlier than in the mice +/Fgf5(go-Y) wal/wal. By the end of the first month after birth, the majority of double homozygotes have a virtually bold back with preserved scarce long hairs, guard hairs. Alopecia covers also the sides and belly. However, the head retains its hair and the regions of thinned long hairs remain on the limbs and near the tail base. The data obtained demonstrate that gene Fgf5(go-Y) is a modifier of gene wal, as it enhances considerably the effect of gene wal. This appears in an earlier development of alopecia and its more pronounced progress in the mice with genotypes +/Fgf5(go-Y) wal/wal and, particularly, Fgf5(go-Y)/Fgf5(go-Y) wal/wal.     

Blood pressure cosegregates with a microsatellite of angiotensin I converting enzyme (ACE) in F2 generation from a cross between original normotensive Wistar-Kyoto rat (WKY) and stroke-prone spontaneously hypertensive rat (SHRSP).

We investigated the linkage between high blood pressure and the ACE gene in the F2 generation between SHRSP/Izm and WKY/Izm. The male F2 rats were categorized into 3 genotypes according to a microsatellite polymorphism in the ACE gene. Significantly high blood pressure was observed in the SHRSP homozygotes when it was compared to the blood pressure of the heterozygotes. Further, after 2 or 3 months salt-loading, the blood pressure was significantly higher in the SHRSP homozygotes than in the heterozygotes and the WKY homozygotes. The heterozygotes had a blood pressure similar to that in the WKY homozygotes, indicating that the effect of the ACE gene genotype was recessive. Salt appetite was neither correlated with the salt-sensitivity nor cosegregated with the ACE genotype. The results indicate that the locus of ACE gene associates with the development of hypertension, especially salt-sensitive hypertension.     

Clinical characteristics and plasma lipids in subjects with familial combined hypolipidemia: a pooled analysis

Angiopoietin-like 3 (ANGPTL3) regulates lipoprotein metabolism by modulating extracellular lipases. Loss-of function mutations in ANGPTL3 gene cause familial combined hypolipidemia (FHBL2). The mode of inheritance and hepatic and vascular consequences of FHBL2 have not been fully elucidated. To get further insights on these aspects, we reevaluated the clinical and the biochemical characteristics of all reported cases of FHBL2. One hundred fifteen FHBL2 individuals carrying 13 different mutations in the ANGPTL3 gene (14 homozygotes, 8 compound heterozygotes, and 93 heterozygotes) and 402 controls were considered. Carriers of two mutant alleles had undetectable plasma levels of ANGPTL3 protein, whereas heterozygotes showed a reduction ranging from 34% to 88%, according to genotype. Compared with controls, homozygotes as well as heterozygotes showed a significant reduction of all plasma lipoproteins, while no difference in lipoprotein(a) [Lp(a)] levels was detected between groups. The prevalence of fatty liver was not different in FHBL2 subjects compared with controls. Notably, diabetes mellitus and cardiovascular disease were absent among homozygotes. FHBL2 trait is inherited in a codominant manner, and the lipid-lowering effect of two ANGPTL3 mutant alleles was more than four times larger than that of one mutant allele. No changes in Lp(a) were detected in FHBL2. Furthermore, our analysis confirmed that FHBL2 is not associated with adverse clinical sequelae. The possibility that FHBL2 confers lower risk of diabetes and cardiovascular disease warrants more detailed investigation.     

The site of the action of the angora-Y gene and its interaction with the fuzzy-Y gene in the mouse

The site of action of the goY mutant gene was determined in the aggregation chimaeras C57BL-goY/goY----DBA (+/+). Chimerism was detected by mosaicism of coat pigmentation and electrophoretic pattern of glucose phosphate isomerase. In 28-day-old chimaeras the regions of light-brown coat alternated black coat, stripes of short hairs alternated those of long hairs. These stripes of different length and width extended from spine in lateral-ventral direction. The hairs plucked from long hairs stripes had a similar length that those of goY/goY mice of same age, but the hairs plucked from short hair stripes corresponded to the hair length of +/+ mice. These data show that the goY gene acts in epidermal cells of hair follicles and its expression is autonomous. It has been established that in double homozygotes goY/goYfzY/fzY both mutant genes are expressed: the considerable increase of hair length as compared to norm--the effect of the goY gene and curly coat--the effect of the fzY gene. In goY/goYfzY/fzY mice during the formation of G1 guard hairs the incomplete expression of the goY gene is observed that is due to the suppression of hair growth by the fzY mutant gene. The fzY gene does not suppress the growth of G2 hairs and therefore the full expression of the goY gene occurs in goY/goYfzY/fzY adult mice.     

Biosynthesis of truncated N-linked oligosaccharides results from non-orthologous hexosaminidase-mediated mechanisms in nematodes, plants, and insects

In many invertebrates and plants, the N-glycosylation profile is dominated by truncated paucimannosidic N-glycans, i.e. glycans consisting of a simple trimannosylchitobiosyl core often modified by core fucose residues. Even though they lack antennal N-acetylglucosamine residues, the biosynthesis of these glycans requires the sequential action of GlcNAc transferase I, Golgi mannosidase II, and, finally, beta-N-acetylglucosaminidases. In Drosophila, the recently characterized enzyme encoded by the fused lobes (fdl) gene specifically removes the non-reducing N-acetylglucosamine residue from the alpha1,3-antenna of N-glycans. In the present study, we examined the products of five beta-N-acetylhexosaminidase genes from Caenorhabditis elegans (hex-1 to hex-5, corresponding to reading frames T14F9.3, C14C11.3, Y39A1C.4, Y51F10.5, and Y70D2A.2) in addition to three from Arabidopsis thaliana (AtHEX1, AtHEX2, and AtHEX3, corresponding to reading frames At1g65590, At3g55260, and At1g05590). Based on homology, the Caenorhabditis HEX-1 and all three Arabidopsis enzymes are members of the same sub-family as the aforementioned Drosophila fused lobes enzyme but either act as chitotriosidases or non-specifically remove N-acetylglucosamine from both N-glycan antennae. The other four Caenorhabditis enzymes are members of a distinct sub-family; nevertheless, two of these enzymes displayed the same alpha1,3-antennal specificity as the fused lobes enzyme. Furthermore, a deletion of part of the Caenorhabditis hex-2 gene drastically reduces the native N-glycan-specific hexosaminidase activity in mutant worm extracts and results in a shift in the N-glycan profile, which is a demonstration of its in vivo enzymatic relevance. Based on these data, it is hypothesized that the genetic origin of paucimannosidic glycans in nematodes, plants, and insects involves highly divergent members of the same hexosaminidase gene family.