The maternal and zygotic control of development by cinnamon, a new mutant in Drosophila melanogaster

A genetic analysis of the X-linked mutant cinnamon (cin) in Drosophila melanogaster demonstrates that this locus controls a process that is essential for zygote survival. Survival of a zygote is shown to be ensured by either the maternal expression of the cin⁺ allele or by the presence of a cin⁺ allele in the zygotic genome. The cin locus is also shown to affect pteridine pigment metabolism. The presence of a cin⁺ allele in either the mother or zygote is requisite for normal zygotic eye pigmentation. It is shown that cin flies lack xanthine dehydrogenase, an enzyme involved in pteridine metabolism, and accumulate the enzyme's pteridine and purine substrates. The relationship between the effects of cin on viability and xanthine dehydrogenase activity is discussed.     

The maternal and zygotic roles of the gene Polycomb in embryonic determination in Drosophila melanogaster

The mutation Polycomb (Pc) is known to cause a variety of intersegmental transformations in homozygous and heterozygous individuals of Drosophila melanogaster; Pc⁺ is thought to act as a negative regulator of genes of the bithorax complex. The function of this gene in the maternal germ line has been assessed by examining the variation in expression of these homoeotic phenotypes in individuals derived from a maternal germ line with a single or no dose of the Pc⁺ allele. Mosaic individuals with a homozygous or heterozygous Pc germ line were produced by transplantation of pole cells, the embryonic precursors of the germ line. By employing an X-linked dominant female-sterile mutation, the identification of mosaic females and the study of progeny derived from the exogenous germ line were greatly simplified; the advantages of this system for the transplantation of pole cells for such analyses are described. In general, all thoracic and abdominal segments of homozygous Pc embryos differentiate characteristics of the eighth, most posterior, abdominal segment. The extent and uniformity of this transformation as well as other manifestations of the homozygous Pc genotype are described and shown to be correlated with the maternal germ line genotype; homozygous Pc embryos derived from a homozygous Pc maternal germ line show greater expression of these phenotypes than do genetically identical embryos derived from a heterozygous Pc maternal germ line. The expression of some homoeotic phenotypes typical of heterozygous Pc adults shows only a slight correlation with the maternal genotype, while no homoeotic transformations are clearly evident in heterozygous larvae of either origin. Thus, the maternal effect of Pc is rescuable. The results suggest that the Pc⁺ gene is active in the maternal germ line but that the absence of the maternally derived Pc⁺ product can be largely compensated by the introduction of a wild-type allele upon fertilization; this rescue indicates that the maternal activity of Pc⁺ plays no major role in the normal process of embryonic segmental determination. The normal fertility of males and females with a homozygous Pc germ line and of their progeny suggests that Pc⁺ plays no role in the determination or development of the germ line in either the maternal or zygotic genome.     

Autonomy for a specific gene product in oocytes: Experimental evidence in the polychaetous annelid,Platynereis dumerilii

Oocytes of Platynereis dumerilii in early vitellogenesis were injected into female worms with oocytes of similar diameter. The donor oocytes were labeled by the or gene controlling eye pigmentation and, after some weeks of growth, were spawned together with the host oocytes. In most cases, a few donor progeny could be found among the offspring produced by the hosts. Donor progeny were examined with respect to an or gene-dependent maternal effect which normally causes wild-type eye color in homozygous ($\text{or}\text{or}$) larvae originating from the crossings of heterozygous ($\text{or}{}^{\mathrm{+}}\text{or}$) females and homozygous ($\text{or}\text{or}$) males. This maternal effect was absent from homozygous ($\text{or}\text{or}$) larvae derived from homozygous ($\text{or}\text{or}$) donor oocytes which had developed in heterozygous females. Conversely, this maternal effect was observed in homozygous ($\text{or}\text{or}$) larvae derived from heterozygous ($\text{or}{}^{\mathrm{+}}\text{or}$) donor oocytes which had developed in homozygous ($\text{or}\text{or}$) host females. It is concluded that the oocyte genome is active at the or⁺ locus during oogenesis and that the oocyte is autonomous with respect to the product of synthesis of the or⁺ locus. In the present case, the “maternal effect” is therefore caused by synthetic activity in the growing oocyte. The results are discussed with respect to current information on gene products from animal genomes.     

Injection of wild-type cytoplasm and poly(A)+ RNA provokes phenotype rescue in spätzle mutant Drosophila embryos

Summary spätzle (spz), a maternal effect gene of Drosophila, is involved in the establishment of the dorso-ventral axis during embryogenesis. Eggs from females lacking the spz gene product develop into completely dorsalized embryos, i.e. the ventral and lateral pattern elements fail to develop. Upon injection of either cytoplasm or poly(A)⁺ RNA from early wild-type embryos, spz embryos develop lateral pattern elements represented by Filzkörper and in the case of injected cytoplasm additional ventral pattern elements represented by ventral setae. Wild-type cytoplasm retains the rescuing activity longer than the poly(A)⁺ RNA fraction does, and cytoplasm is always more effective in provoking the rescue than poly(A)⁺ RNA. Mosaic females containing spz germ cells surrounded by spz ⁺ tissues were generated by pole cell transplantations; a mutant genotype in the germ cells is sufficient to produce all aspects of the spz mutant phenotype, suggesting that the maternal source of spz gene product is the germ line.     

The role of melanocyte-stimulating hormone (MSH) receptor in bovine coat color determination

The melanocyte-stimulating hormone (MSH) receptor has a major function in the regulation of black (eumelanin) versus red (phaeomelanin) pigment synthesis within melanocytes. We report three alleles of the MSH-receptor gene found in cattle. A point mutation in the dominant allele E ^D gives black coat color, whereas a frameshift mutation, producing a prematurely terminated receptor, in homozygous e/e animals, produces red coat color. The wild-type allele E ⁺ produces a variety of colors, reflecting the possibilities for regulating the normal receptor. Microsatellite analysis, RFLP studies, and coat color information were used to localize the MSH-receptor to bovine Chromosome (Chr) 18.     

Epigenetic regulation of oogenesis and germ stem cell maintenance by the Drosophila histone methyltransferase Eggless/dSetDB1

The Drosophila melanogaster histone lysine methyltransferase (HKMT) Eggless (Egg/dSETDB1) catalyzes methylation of Histone H3 lysine 9 (H3K9), a signature of repressive heterochromatin. Our previous studies showed that H3K9 methylation by Egg is required for oogenesis. Here we analyze a set of EMS-induced mutations in the egg gene, identify the molecular lesions of these mutations, and compare the effects on oogenesis of both strong loss-of-function and weak hypomorphic alleles. These studies show that H3K9 methylation by Egg is required for multiple stages of oogenesis. Mosaic expression experiments show that the egg gene is not required intrinsically in the germ cells for their early differentiation, but is required in the germ cells for their survival past stage 5 of oogenesis. egg is also required in germ stem cells for their maintenance, since egg⁻ germ stem cells initially survive but are not maintained as females age. Mosaic analysis also reveals that the early egg chamber budding defects in egg⁻ ovaries are due to an intrinsic requirement for egg in follicle stem cells and their descendents, and that egg plays a non-autonomous role in somatic cells in the germarium to influence the differentiation of early germ cells.     

Genetic Analysis of Three Dominant Female-Sterile Mutations Located on the X Chromosome of DROSOPHILA MELANOGASTER

Three dominant female-sterile mutations were isolated following ethyl methanesulfonate (EMS) mutagenesis. Females heterozygous for two of these mutations show atrophy of the ovaries and produce no eggs (ovo ^D1) or few eggs (ovo^D2); females heterozygous for the third mutation, ovo^D3, lay flaccid eggs. All three mutations are germ line-dependent and map to the cytological region 4D-E on the X chromosome; they represent a single allelic series. Two doses of the wild-type allele restore fertility to females carrying ovo^D3 and ovo^D2, but females carrying ovo^D1 and three doses of the wild-type allele remain sterile. The three mutations are stable in males but are capable of reversion in females; reversion of the dominant mutations is accompanied by the appearance, in the same region, of a recessive mutation causing female sterility. We discuss the utility of these mutations as markers of clones induced in the female germ line by mitotic recombination as well as the nature of the mutations.     

Germ line dependence of the deep orange maternal effect in Drosophila

Pole cell transplantations were used to determine the tissue specificity of maternal effects in Drosophila. The deep orange maternal effect is shown to be germ line autonomous. A cytoplasmic injection assay was used to determine when the dor⁺ substance could be detected in the developing oocyte. The dor⁺ substance is present during the early stages of vitellogenesis but could not be detected in the yolk of the embryo after blastoderm cellularization.     

The effect of embryo and maternal genotypes on prolificacy, intrauterine growth retardation and postnatal development of Nos3-knockout mice

Mice deficient for endothelial nitric oxide synthase (NOS3(-/-)) may represent a good model for studying embryo loss and intrauterine growth retardation caused by vascular deficiencies. We determined the effects of embryo genotype (homozygous vs. heterozygous descendants with paternal or maternal source of the non-functional NOS3 allele) and maternal environment (NOS3(-/-) vs. wild-type NOS3(+/+) females) on the appearance of estrus, fertility and prolificacy rates and live weight in the first week of life as well as phenotypic characteristics of offspring during the postnatal period. The results indicated that pregnancy outcomes and postnatal development of NOS3(-/-) mice seem to be related to deficiencies in fetal programming mainly determined by maternal genotype.     

Germ-line dependence of the maroon-like maternal effect in Drosophila

We have used pole cell transplantations to construct germ-line mosaics for maroon-like (mal), a maternal effect mutation in Drosophila. Such mosaics allow one to determine the cell type in which a gene is active. We find that the maroon-like maternal effect is (1) autonomous to the germ line and (2) dose sensitive in germ-line mosaics. Aldehyde oxidase activity is used as a histological probe to investigate the tissue and temporal distribution of mal⁺ activity in the developing ovary. The adult ovary shows mal⁺ activity in the germ line at all discernible stages of oogenesis but no activity is observed in the mesodermally derived follicle cells. Differential mal⁺ activity is observed even in the ovary of the third-instar larvae.     

Sex and the Single Cell. I. on the Action of Major Loci Affecting Sex Determination in DROSOPHILA MELANOGASTER

Sex determination in Drosophila melanogaster is under the control of the X chromosome:autosome ratio and at least four major regulatory genes: transformer (tra), transformer-2 (tra-2), doublesex (dsx) and intersex (ix). Attention is focused here on the roles of these four loci in sex determination. By examining the sexual phenotype of clones of homozygous mutant cells produced by mitotic recombination in flies heterozygous for a given recessive sex-determination mutant, we have shown that the tra, tra-2 and dsx loci determine sex in a cell-autonomous manner. The effect of removing the wild-type allele of each locus (by mitotic recombination) at a number of times during development has been used to determine when the wild-type alleles of the tra, tra-2 and dsx loci have been transcribed sufficiently to support normal sexual development. The wild-type alleles of all three loci are needed into the early pupal period for normal sex determination in the cells that produce the sexually dimorphic (in pigmentation) cuticle of the fifth and sixth dorsal abdominal segments. tra⁺ and tra-2⁺ cease being needed shortly before the termination of cell division in the abdomen, whereas dsx⁺ is required at least until the end of division. By contrast, in the foreleg, the wild-type alleles of tra⁺ and tra-2⁺ have functioned sufficiently for normal sexual differentiation to occur by about 24 to 48 hours before pupariation, but dsx⁺ is required in the foreleg at least until pupariation.——A comparison of the phenotypes produced in mutant/deficiency and homozygous mutant-bearing flies shows that dsx, tra-2 and tra mutants result in a loss of wild-type function and probably represent null alleles at these genes.—All possible homozygous doublemutant combinations of ix, tra-2 and dsx have been constructed and reveal a clear pattern of epistasis: dsx > tra, tra-2 > ix. We conclude that these genes function in a single pathway that determines sex. The data suggest that these mutants are major regulatory loci that control the batteries of genes necessary for the development of many, and perhaps all, secondary sexual characteristics.—The striking similarities between the properties of these loci and those of the homeotic loci that determine segmental and subsegmental specialization during development suggest that the basic mechanisms of regulation are the same in the two situations. The phenotypes and interactions of these sex-determination mutants provide the basis for the model of how the wild-type alleles of these loci act together to effect normal sex determination. Implications of these observations for the function of other homeotic loci are discussed.     

Maternal effects of zygotic mutants affecting early neurogenesis inDrosophila

Summary The size of the neurogenic region ofDrosophila melanogaster is under the control of several genes of zygotic expression. Lack of function from any of those genes produces an increase of the size of the neurogenic region at the expense of the epidermal anlage. However, differences exist in the extent of neuralisation achieved by each of the genetic loci upon mutation. The present results show that in the case ofN andmam phenotype differences are due to different contributions of maternal gene expression. This could be shown by studying the phenotype which appeared in mutant embryos when the oocytes developed from homozygous mutant precursor cells. Clones of mutant cells were induced in the germ line of females heterozygous for the neurogenic mutationin trans over germ line dependent, dominant female sterile mutations. After removing maternal information the phenotype ofN andmam mutants became identical in both cases. Furthermore maternal information fromN ⁺ was found to be necessary for viability of the wildtype.     

Isolation of a new paramutagenic allele of thesulfurea locus in the tomato cultivar Moneymaker following in vitro culture

A new allele, SC148, of thesulfurea locus inLycopersicon esculentum was detected in a line derived after repeated selfing of plants that had been regenerated from tissue culture. Like the originalsulf mutant, SC148 displayed two mutant phenotypes: green-yellow speckled plants in which thesulf ^vag allele is present and pure yellow plants homozygous for thesulf ^tpura allele. Although the mutant alleles are recessive to wild-type, an unpredictable number of variegated and pura plants appeared in F₁ progenies that had been derived from crosses between SC148 and wild-type tomato plants. The presence of the wild-typesulf ⁺ allele in these variegated heterozygotes was demonstrated using a cytological marker that is linked tosulf. It is concluded that the mutantsulf allele of SC148, imposes its variegated expression state on the wild-typesulf ⁺ allele present insulf ⁺/sulf^vag heterozygotes. This behaviour, known as paramutation, has also been described for the originalsulf allele. The SC148 allele, however, seems to induce changes at an earlier stage in development. The analogy of this paramutagenic system to dominant position effect variegation inDrosophila is discussed.     

Specificity of embryonic lethal mutations in Drosophila analyzed in germ line clones

Summary Only a small fraction of the known mutations causing death to homozygous Drosophila produce gross morphological defects during embryogenesis. We have examined fourteen such loci on the X-chromosome to determine: 1) whether the requirement for their respective activities is restricted to embryogenesis; and 2) whether the embryonic phenotype in mutant embryos is affected by the dosage of wild-type alleles in the mother. For two alleles per locus germ line clones were produced during larval development by irradiating females heterozygous for the lethal mutation and a dominant female sterile (ovo^D). Only one of the 14 loci (armadillo) is required during development of the germ cell to make morphologically normal eggs. Mutations at two other loci, (bazooka and Notch), allow normal oogenesis but cause major reductions in the viability of genetically normal (i.e., heterozygous) progeny. The majority of the loci (11/14) are not required in the germ line for either oogenesis or embryogenesis. However, in three cases (extradenticle, faintoid and lethal myospheroid), germ line homozygosity results in a readily detectible enhancement of embryonic phenotype over that observed in embryos derived from heterozygous mothers still possessing one wild type allele. The same six loci which show the most substantial effects on germ line homozygosity (arm, baz, N, exd, ftd and mys) also show an amelioration of the mutant phenotypes when maternal dosage is increased to wild type levels by using attached-X females. Four of these same loci (arm, baz, N and exd were cell lethal in imaginal discs.     

Isolation and Characterization of Sex-Linked Female-Sterile Mutants in DROSOPHILA MELANOGASTER

The purpose of the experiments described was to identify X chromosome genes functioning mainly or exclusively during oogenesis. Two mutagenesis experiments were carried out with ethyl methane sulfonate. Following treatment inducing 60% lethals, 9% of the treated X chromosomes carried a female sterility mutation which did not otherwise seriously affect viability. Among —95 isolated mutants, 19 were heat-sensitive and 5 cold-sensitive. The mutants have been classified as follows: I (16 mutants; 12 complementation groups): the females laid few or no eggs; the defect concerned either ovulation or oogenesis. II (37 mutants; 18 complementation groups): the female laid morphologically abnormal eggs, often with increased membrane permeability. III A (13 mutants; at least 8 complementation groups): the homozygous females were sterile if mated to mutant males; their progeny (homo- and hemizygous) died at a late embryonic stage (11 mutants), at the larval stage (1 mutant) or at the pupal stage (1 mutant). However fertility was partly restored by breeding to wild-type males as shown by survival of some heterozygous descendants. III B (29 mutants; 22 complementation groups): the fertility of the females was not restored by breeding to a wild-type male. Most of the eggs of 13 of the mutants died at a late stage of embryogenesis. The eggs of the others ceased development earlier or, perhaps, remained unfertilized. The distribution of the number of mutants per complementation group led to an estimation of a total of about 150 X-linked genes involved in female fertility. The females of three mutants, heat-sensitive and totally sterile at 29°, produced at a lower temperature descendants morphologically abnormal or deprived of germ cells. Three other mutants not described in detail showed a reduction in female fertility with many descendants lacking germ cells. A desirable mutant which was not recovered was one with normal fertile females producing descendants which, regardless of their genotype, bore specific morphological abnormalities. The value of the mutants isolated for analysis of the complex processes leading to egg formation and initiation of development is discussed.     

Analysis of compound heterozygotes reveals that the mouse floxed <Emphasis Type="Italic">Pax6</Emphasis><Superscript><Emphasis Type="Italic">tm1Ued</Emphasis></Superscript> allele produces abnormal eye phenotypes

Analysis of abnormal phenotypes produced by different types of mutations has been crucial for our understanding of gene function. Some floxed alleles that retain a neomycin-resistance selection cassette (neo cassette) are not equivalent to wild-type alleles and provide useful experimental resources. Pax6 is an important developmental gene and the aim of this study was to determine whether the floxed Pax6 ^tm1Ued (Pax6 ^fl ) allele, which has a retained neo cassette, produced any abnormal eye phenotypes that would imply that it differs from the wild-type allele. Homozygous Pax6 ^fl/fl and heterozygous Pax6 ^fl/+ mice had no overt qualitative eye abnormalities but morphometric analysis showed that Pax6 ^fl/fl corneas tended be thicker and smaller in diameter. To aid identification of weak effects, we produced compound heterozygotes with the Pax6 ^Sey-Neu (Pax6 ^?) null allele. Pax6 ^fl/? compound heterozygotes had more severe eye abnormalities than Pax6 ^+/? heterozygotes, implying that Pax6 ^fl differs from the wild-type Pax6 ⁺ allele. Immunohistochemistry showed that the Pax6 ^fl/? corneal epithelium was positive for keratin 19 and negative for keratin 12, indicating that it was abnormally differentiated. This Pax6 ^fl allele provides a useful addition to the existing Pax6 allelic series and this study demonstrates the utility of using compound heterozygotes with null alleles to unmask cryptic effects of floxed alleles.     

Epigenetic effect of the rad201(G1) mutation in a system with mobilization of nonautonomous P elements in Drosophila

The effect on P-element activity in somatic cells was studied for a repair mutation localized in the Drosophila genome in the region of the rad201 and Rad51C overlapping genes. When one of the parents carried nonautonomous P elements and the rad201 mutation and the other carried a P-transposase source, a high dominant pupal lethality was observed in the progeny heterozygous for the mutant allele and their sibs homozygous for the rad201 ⁺ wild-type allele. The sib response was due to the epigenetic effect of the rad201 mutation and was maintained through at least two generations. The specifics of the epigenetic effect are discussed in terms of its possible association with P transpositions and mitotic crossing over events determined by P transposase. Based on the results of genetic and genomic DNA analyses of the rad201 mutant, it was assumed that the phenomenon in question was determined by several genetic factors.     

Effects of high K+ concentrations on the growth and development of ciliary ganglion neurons in cell culture

Extracts prepared from embryonic eye tissue permit all of the neurons present in embryonic ciliary ganglia to survive and develop in cell culture. High K⁺ concentrations stimulate growth of the neurons in culture above the maximal levels obtained with eye extract alone. Growth in 25 mM K⁺ produced parallel increases in the levels of choline acetyltransferase activity, lactate dehydrogenase activity (a common cytoplasmic enzyme), and total protein synthesis per neuron. The K⁺ effect appears to be mediated by membrane depolarization. Intracellular recording confirmed that the neurons were chronically depolarized in 25 mM K⁺. Veratridine produced the same stimulation of growth, while tetrodotoxin blocked the veratridine effect without preventing the K⁺ effect. Ca²⁺ may also play a role in the K⁺ effect. Two drugs thought to block Ca²⁺ channels (Mg²⁺ and D600) each blocked or reduced in the increase in growth caused by 25 mM K⁺. The drugs did not interfere with neuronal growth in control cultures, indicating that eye extract and membrane depolarization influence neuronal growth by different mechanisms.     

Ovary-autonomous maternal inheritance at a developmental locus in Drosophila

The sex-linked temperature-sensitive mutation shibire^ts of Drosophila melanogaster shows a maternal effect causing embryonic lethality at 29°C. The maternal influence is due to gene action autonomous to the ovary. Embryos carrying the paternally derived wild-type gene can survive at 29°C but only if heat pulses are begun at least 9 hr after oviposition. The paternal rescue is presumably due to zygotic gene action at this locus beginning part way through embryogenesis. A maternal wild-type genome, however, can produce shi embryos that have sufficient shi⁺ product to support embryogenesis up to the hatching stage even at 29°C.     

A first genotyping assay of French cattle breeds based on a new allele of the extension gene encoding the melanocortin-1 receptor (Mc1r)

The seven transmembrane domain melanocortin-1 receptor (Mc1r) encoded by the coat color extension gene (E) plays a key role in the signaling pathway of melanin synthesis. Upon the binding of agonist (melanocortin hormone, α-MSH) or antagonist (Agouti protein) ligands, the melanosomal synthesis of eumelanin and/or phaeomelanin pigments is stimulated or inhibited, respectively. Different alleles of the extension gene were cloned from unrelated animals belonging to French cattle breeds and sequenced. The wild type E allele was mainly present in Normande cattle, the dominant E^D allele in animals with black color (i.e. Holstein), whereas the recessive e allele was identified in homozygous animals exhibiting a more or less strong red coat color (Blonde d''Aquitaine, Charolaise, Limousine and Salers). A new allele, named E¹, was found in either homozygous (E¹/E¹) or heterozygous (E¹/E) individuals in Aubrac and Gasconne breeds. This allele displayed a 4 amino acid duplication (12 nucleotides) located within the third cytoplasmic loop of the receptor, a region known to interact with G proteins. A first genotyping assay of the main French cattle breeds is described based on these four extension alleles.