Krüppel, a gene whose activity is required early in the zygotic genome for normal embryonic segmentation

Embryos homozygous for Krüppel die as late embryos with an altered segmentation pattern. In strong alleles the normal thoracic and anterior abdominal segments are replaced by a partial mirror image duplication of the posterior abdomen. Weak alleles cause smaller pattern deletions in the thorax and abdomen and are not associated with mirror image duplications. The altered segmentation pattern can be traced back to 12 min after the onset of gastrulation, when the shorter germ bands in homozygous Kr embryos provide a first indication of abnormal patterning. The mutant was mapped to position 107.6 at the tip of the right arm of the second chromosome, cytologically to bands 60F2-5. Analysis of homozygous deficiency embryos indicate that the phenotype produced by strong point mutations probably represents the amorphic condition. The requirement for Kr+ gene activity is strictly zygotic. Maternal dosage of Kr+ has no effect on the embryonic phenotype, nor does homozygosity for Kr prevent germ cells from making normal eggs capable of normal embryonic development when fertilized by wild-type sperm. The requirement for Kr+ seems restricted to embryogenesis. Homozygous clones induced in imaginal discs during larval development survive and develop normally and in vivo cultures established from homozygous embryos proliferate normally and metamorphose into adult structures of normal morphology.     

Mutations in a newly identified Drosophila melanogaster gene, mago nashi, disrupt germ cell formation and result in the formation of mirror-image symmetrical double abdomen embryos.

The mago nashi (mago) locus is a newly identified strict maternal effect, grandchildless-like, gene in Drosophila melanogaster. In homozygous mutant mago females reared at 17 degrees C, mago+ function is reduced, the inviable embryos lack abdominal segments and 84-98% of the embryos die. In contrast, at 25 degrees C, some mago alleles produce a novel gene product capable of inducing the formation of symmetrical double abdomen embryos. Reciprocal temperature-shift experiments indicate that the temperature-sensitive period is during oogenetic stages 7-14. Furthermore, embryos collected from mago1 homozygous females contain no apparent functional posterior determinants in the posterior pole. In viable F1 progeny from mago mutant females, regardless of genotype and temperature, polar granules are reduced or absent and germ cells fail to form (the grandchildless-like phenotype). Thus, we propose that the mago+ product is a component of the posterior determinative system, required during oogenesis, both for germ cell determination and delineation of the longitudinal axis of the embryo.     

The segment polarity gene costal-2 in Drosophila. I. The organization of both primary and secondary embryonic fields may be affected

A series of loss of function alleles at the costal-2 locus is described. Embryos mutant for lethal alleles that are derived from a mutant female germ line display polarity defects on the larval segments. A posterior part of the segmental denticle belt is missing and in its place is a mirror-image duplication of the anterior part including the segment boundary. Maternally rescued embryos are lethal but have normal morphology. Hypomorphic alleles escape to adults that display pattern duplications on the wings and halteres. Dominant gain of function alleles at the Costal-1 locus are also described and data are presented that argue that these are neomorphic and act in trans to impair functioning of costal-2. Some wild-type isoalleles of costal-2 are particularly sensitive to interference from Costal-1 mutations and different combinations of these alleles with Costal-1 can lead to embryos in which the primary embryonic field is disrupted (bicaudal phenotype) and adults with pattern duplications on the anterior compartment of most body segments.     

Viability of Female Germ-Line Cells Homozygous for Zygotic Lethals in DROSOPHILA MELANOGASTER

We have analyzed the viability of different types of X chromosomes in homozygous clones of female germ cells. The chromosomes carried viable mutations, single-cistron zygotic-lethal and semi-lethal mutations, or small (about six chromosome band) deletions. Homozygous germ-line clones were produced by recombination in females heterozygous for an X-linked, dominant, agametic female sterile.

All the zygotic-viable mutants are also viable in germ cells. Of 16 deletions tested (uncovering a total of 93 bands) only 2 (of 4 and 5 bands) are germ-cell viable. Mutations in 15 lethal complementation groups in the zeste-white region were tested. When known, the most extreme alleles at each locus were tested. Only in five loci (33%) were the mutants viable in the germ line. Similar studies of the same deletions and point-mutant lethals in epidermal cells show that 42% of the bands and 77% of the lethal alleles are viable. Thus, germ-line cells have more stringent cell-autonomous genetic requirements than do epidermal cells.

The eggs recovered from clones of three of the germ-cell viable zw mutations gave embryos arrested early in embryogenesis, although genotypically identical embryos derived from heterozygous oogonia die as larvae or even hatch as adult escapers. For two genes, homozygosis of the mutations tested also caused embryonic arrest of heterozygous female embryos, and in one case, the eggs did not develop at all. Germ-line clones of one quite leaky mutation gave eggs that were indistinguishable from normal. The abundance of genes whose products are required for oogenesis, whose products are required in the oocyte, and whose activity is required during zygotic development is discussed.

     

Two Drosophila learning mutants, dunce and rutabaga, provide evidence of a maternal role for cAMP on embryogenesis

The dunce gene of Drosophila melanogaster encodes a cAMP-specific phosphodiesterase (form II). Mutant dunce flies have elevated levels of cAMP and exhibit a number of defects including learning deficiencies and female sterility. Two partial suppressors of the female sterility phenotype have been selected in an X chromosome containing a dunce null mutation. Both suppressors are associated with reduced AC2 activity. Complementation analyses suggest that both are alleles of the learning mutant rutabaga. Females homozygous for dunce null mutations that abolish PDE activity do not deposit eggs. The suppressors exhibit differential effects on egg deposition and production of progeny; double-mutant females deposit many eggs that fail to hatch, but some develop to adults. These adult progeny exhibit morphological defects that are confined mostly to the second and third thoracic segments or to the first five abdominal segments. These observations demonstrate that the dunce gene is required in adult females for egg laying and that the dunce gene provides an essential maternal function required for normal development of the zygote. Clonal analysis, employing the dominant female-sterile mutation ovoD1, demonstrates that the former requirement for PDE activity resides in somatic cells and that the latter requirement resides in germ line cells. Female germ line cells homozygous for a dunce null mutation produce oocytes that fail to develop. Thus, homozygous dunce null-mutant zygotes develop to adults solely because of the enzyme or mRNA present in the oocytes of heterozygous mothers. Mutant alleles of rutabaga act in the germ line cells to partially suppress the developmental defects caused by dunce mutations. Thus the rutabaga gene, as well as the dunce gene, functions in both somatic and germ line cells.     

Deletion and Interallelic Complementation Analysis of Steel Mutant Mice

Mutations at the Steel (St) locus produce pleiotropic effects on viability as well as hematopoiesis, pigmentation and fertility. Several homozygous viable Sl alleles have previously been shown to contain either structural alterations in mast cell growth factor (Mgf) or regulatory mutations that affect expression of the Mgf gene. More severe Sl alleles cause lethality to homozygous embryos and all lethal Sl alleles examined to data contain deletions that remove the entire Mgf coding region. As the timing of the lethality varies from early to late in gestation, it is possible that some deletions may affect other closely linked genes in addition to Mgf. We have analyzed the extent of deleted sequences in seven homozygous lethal Sl alleles. The results of this analysis suggest that late gestation lethality represents the Sl null phenotype and that peri-implantation lethality results from the deletion of at least one essential gene that maps proximal to Sl. We have also examined gene dosage effects of Sl by comparing the phenotypes of mice homozygous and hemizygous for each of four viable Sl alleles. Lastly, we show that certain combinations of the viable Sl alleles exhibit interallelic complementation. Possible mechanisms by which such complementation could occur are discussed.     

Different requirements for l(1) giant in two embryonic domains of Drosophila melanogaster

l(1) giant is a zygotic lethal mutation which affects the embryonic development of both the labial/thoracic segments and a subset of posterior abdominal segments. Using antibodies specific for proteins encoded by several Drosophila genes to identify the compartmental origin of the defects, we show that the requirement of giant activity is different in these two embryonic domains. Anteriorly, the posterior compartment of the labial segment is missing at the blastoderm stage. Posteriorly, cells are specifically deleted by cell death within the anterior compartments of abdominal segments 5-7 during germ band elongation. In mature embryos, posterior compartment structures of the peripheral nervous system of A5-7 are fused. In addition to a different pattern of defect in the two parts of the embryo, the kind of action appears different. Anteriorly, giant resembles a gap mutation in that a particular region is missing from the blastoderm fate map, whereas in the abdominal domain, giant affects the development of anterior compartment-specific structures.     

Lethal bithorax complex mutations of Drosophila melanogaster show no germ line maternal effects

Three Ultrabithorax (Ubx) alleles and three different deficiencies of the bithorax complex (BX-C) of Drosophila melanogaster have been tested for maternal effects in the germ line. The dominant female sterile technique was used. The Ubx alleles and a deletion of the abdominal region of the BX-C are homozygous viable in germ line clones and show no maternal effects. Two deletions which lack the proximal portion of the BX-C are lethal in the female germ line indicating either that these deficiencies lack genes apart from the BX-C that are necessary for fertility or that there are BX-C genes that are essential for normal maternal germ line function. The significance of the bias in the isolation of only zygotic mutations at the BX-C are discussed with respect to these results.     

Different requirements for l(1)giant in two embryonic domains of Drosophila melanogaster

L(1)giant is a zygotic lethal mutation which affects the embryonic development of both the labial/thoracic segments and a subset of posterior abdominal segments. Using antibodies specific for proteins encoded by several Drosophila genes to identify the compartmental origin of the defects, we show that the requirement of giant activity is different in these two embryonic domains. Anteriorly, the posterior compartment of the labial segment is missing at the blastoderm stage. Posteriorly, cells are specifically deleted by cell death within the anterior compartments of abdominal segments 5–7 during germ band elongation. In mature embryos, posterior compartment structures of the peripheral nervous system of A5–7 are fused. In addition to a different pattern of defect in the two parts of the embryo, the kind of action appears different. Anteriorly, giant resembles a gap mutation in that a particular region is missing from the blastoderm fate map, whereas in the abdominal domain, giant affects the development of anterior compartment-specific structures.     

Localization of vasa, a component of Drosophila polar granules, in maternal-effect mutants that alter embryonic anteroposterior polarity

Cytoplasm at the posterior pole of the early Drosophila embryo, known as polar plasm, serves as a source of information necessary for germ cell determination and for specification of the abdominal region. Likely candidates for cytoplasmic elements important in one or both of these processes are polar granules, organelles concentrated in the cortical cytoplasm of the posterior pole. Females homozygous for any one of the maternal-effect mutations, tudor, oskar, staufen, vasa, or valois give rise to embryos that lack localized polar granules, fail to form the germ cell lineage and have abdominal segment deletions. Using antibodies against a polar granule component, the vasa protein, we find that vasa synthesis or localization is affected by these mutations. In vasa mutants, synthesis of vasa protein is absent or severely restricted. In oskar and staufen mutant females, vasa synthesis appears normal, but the vasa protein is not localized. In tudor and valois mutant females, vasa is localized to the posterior pole of oocytes, but this localization is lost following egg activation. In addition to the posterior localized vasa, there is a low level of vasa distributed throughout the embryo. A function for this distributed vasa is postulated based on the observation that embryos from Bicaudal-D mothers, in which abdominal determinants are incorrectly localized to the anterior pole, do not show any ectopic vasa localization, though abdomen development at the anterior end depends on the amount of vasa protein in the embryo.     

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.     

Role of hunchback in segment patterning of Locusta migratoria manilensis revealed by parental RNAi

In long germ embryos, all body segments are specified simultaneously during the blastoderm stage. In contrast, in short germ embryos, only the anterior segments are specified during the blastoderm stage, leaving the rest of the body plan to be specified later. The striking embryological differences between short and long germ segmentation imply fundamental differences in patterning at the molecular level. To gain insights into the segmentation mechanisms of short germ insects, we have investigated the role of the homologue of the Drosophila gap gene hunchback (hb) in a short germ insect Locusta migratoria manilensi by paternal RNA interference (RNAi). Phenotypes resulting from hb knockdown were categorized into three classes based on severity. In the most extreme case, embryos developed the most anterior structures only, including the labrum, antennae and eyes. The following conclusions were drawn: (i) L. migratoria manilensis hb (Lmm'hb) controls germ band morphogenesis and segmentation in the anterior region; (ii) Lmm'hb may function as a gap gene in a wide domain including the entire gnathum and thorax; and (iii) Lmm'hb is required for proper growth of the posterior germ band. These findings suggest a more extensive role for L. migratoria manilensis hunchback in anterior patterning than those described in Drosophila.     

Analysis of fast neutron-generated mutants at the Arabidopsis thaliana HY4 locus

Ionizing radiation is expected to produce mutants with deletions or other chromosomal rearrangements. These mutants are useful for a variety of purposes, such as creating null alleles and cloning genes whose existence is known only from their mutant phenotype; however, only a few mutations generated by ionizing radiation have been characterized at the molecular level in Arabidopsis thaliana . Twenty fast neutron-generated alleles of the Arabidopsis HY4 locus, which encodes a blue light receptor, CRY1, were isolated and characterized. Nine of the mutant alleles displayed normal genetic behavior. The other 11 mutant alleles were poorly transmitted through the male gametophyte and were lethal in homozygous plants. Southern blot analysis demonstrated that alleles of the first group generally contain small or moderate-sized deletions at HY4 , while alleles of the second group contain large deletions at this locus. These results demonstrate that fast neutrons can produce a range of deletions at a single locus in Arabidopsis . Many of these deletions would be suitable for cloning by genomic subtraction or representational difference analysis. The results also suggest the presence of an essential locus adjacent to HY4 .     

Genomic analysis of gamma-ray-induced germ-cell mutations at the b locus recovered from the medaka specific-locus test.

To study how gamma-ray-induced germ-cell mutations are fixed at the early embryonic stage of the next generation, genomic alterations in the b locus mutants (colorless melanophores) detected during development in the medaka specific-locus test (SLT) were analyzed. First, nine anonymous DNA markers linked to the b locus were cloned and mapped into the region extending about 47cM surrounding the b locus. Next, losses of paternal alleles of these DNA markers were examined in each of the 51 gamma-ray-induced b locus mutants obtained after irradiation of sperm or spermatids. In these mutants, 47 were dominant lethals, three were semi-viable and one was viable. All the mutants examined had large deletions surrounding the b locus. One viable mutant had an interstitial deletion, while all the semi-viable and dominant lethal ones appeared to have terminal deletions. Deletions extending about 20-35cM were the most frequently observed in 18 of the 51 mutants examined. The largest one extended more than 40cM. These results suggest that most of the gamma-ray induced germ cell mutations recovered as total specific-locus mutants were accompanied by large genomic deletions, which eventually led the mutant embryos to dominant lethality.     

Non-canonical functions of hunchback in segment patterning of the intermediate germ cricket Gryllus bimaculatus

In short and intermediate germ insects, only the anterior segments are specified during the blastoderm stage, leaving the posterior segments to be specified later, during embryogenesis, which differs from the segmentation process in Drosophila, a long germ insect. To elucidate the segmentation mechanisms of short and intermediate germ insects, we have investigated the orthologs of the Drosophila segmentation genes in a phylogenetically basal, intermediate germ insect, Gryllus bimaculatus (Gb). Here, we have focused on its hunchback ortholog (Gb'hb), because Drosophila hb functions as a gap gene during anterior segmentation, referred as a canonical function. Gb'hb is expressed in a gap pattern during the early stages of embryogenesis, and later in the posterior growth zone. By means of embryonic and parental RNA interference for Gb'hb, we found the following: (1) Gb'hb regulates Hox gene expression to specify regional identity in the anterior region, as observed in Drosophila and Oncopeltus; (2) Gb'hb controls germband morphogenesis and segmentation of the anterior region, probably through the pair-rule gene, even-skipped at least; (3) Gb'hb may act as a gap gene in a limited region between the posterior of the prothoracic segment and the anterior of the mesothoracic segment; and (4) Gb'hb is involved in the formation of at least seven abdominal segments, probably through its expression in the posterior growth zone, which is not conserved in Drosophila. These findings suggest that Gb'hb functions in a non-canonical manner in segment patterning. A comparison of our results with the results for other derived species revealed that the canonical hb function may have evolved from the non-canonical hb functions during evolution.     

A genetic and developmental analysis of mutations in the Deformed locus in Drosophila melanogaster

Individuals expressing recessive mutations in the Deformed (Dfd) locus of Drosophila melanogaster were examined for embryonic and adult defects. Mutant embryos were examined in both scanning electron microscope and light microscope preparations. The adult Dfd recessive mutant phenotype was assessed in somatic clones and in survivors homozygous for hypomorphic alleles of the gene. The time of Dfd+ action was determined by studying a temperature conditional allele. Dfd+ is required in three embryonic cephalic segments to form a normal head. Mutant embryos of Dfd display defects in derivatives of the maxillary segment, of the mandibular segment, and of some more anterior segments. In the adult fly, defects are seen in the posterior aspect of the head when the gene is mutant. A transformation from head to thoracic-like tissue is seen dorsally and a deletion of structures is seen ventrally. Shift studies utilizing a temperature conditional allele have shown that the gene product is necessary during at least two periods of development, during embryonic segmentation and head involution and during the late larval and pupal stages. From these studies we conclude that Dfd is a homeotic gene necessary for proper specification of both the embryonic and the adult head.     

Partial rescue of dorsal, a maternal effect mutation affecting the dorso-ventral pattern of the Drosophila embryo, by the injection of wild-type cytoplasm

Mutant alleles at the maternal effect locus dorsal cause a dorsalization of the Drosophila embryo. In extreme mutants, the embryos develop exclusively structures which derive from the dorsal-most region in normal eggs, in less strong phenotypes in addition to dorsal structures, structures normally derived from a dorso-lateral to lateral egg region are formed. Injection of cytoplasm from wild-type embryos into mutant embryos partially restores the dorso-ventral pattern in that injected embryos develop additional structures never formed in uninjected control embryos or embryos injected with mutant cytoplasm. The phenotype of injected embryos resembles that of weaker alleles at the dorsal locus indicating that the wild-type cytoplasm partially rescues the mutant phenotype. The response of the mutant embryos is restricted to the site of injection and occurs only when cytoplasm is injected into the ventral and not into the dorsal side of mutant embryos. The rescuing activity appears to be equally distributed in cleavage stage wild-type embryos, whereas, in syncytial blastoderm embryos, cytoplasm from the ventral side is about twice as effective as that taken from the dorsal side.     

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.