Temperature-Sensitive Mutations in DROSOPHILA MELANOGASTER. Xvii. Heat- and Cold-Sensitive Lethals on Chromosome 3

Ethyl methanesulfonate-treated third chromosome of Drosophila melanogaster were tested for the presence of dominant and recessive temperature-sensitive lethal mutations at 17 degrees , 22 degrees and 29 degrees C. Out of 1,176 chromosomes tested, no dominant ts lethals, 21 heat-sensitive, 22 cold-sensitive and 10 heat-cold-sensitive lethals were recovered. Heat-cold sensitivity was produced by a single mutation in all cases. Sixty-two percent of the ts lethals were fertile as homozygotes in both sexes. Surprisingly, 88% of the ts lethals mapped between st and Sb, a region straddling the centromere and estimated to comprise 12.9% of the genetic length and 55% of the physical length of chromosome 3. All but one of the heat- and cold-sensitive lethals complemented with each other at their respective restrictive temperatures.     

Analysis of molting and metamorphosis in the ecdysteroid-deficient mutant L(3)3DTS of Drosophila melanogaster

The dominant temperature-sensitive mutation L(3)3^DTS (DTS-3) in Drosophila melanogaster causes lethality of heterozygotes during the third larval instar at the restrictive temperature (29°C). Temperature-shift experiments revealed two distinct temperature-sensitive periods, with lethal phases during the third larval instar (which may persist for 4 weeks) and during the late pupal stage. At 29°C mutant imaginal discs are unable to evert in situ, but did evert normally if cultured in the presence of exogenous ecdysterone or when implanted into wild-type larval hosts. The only morphologically abnormal tissue present in the lethal larvae is the ring gland, the prothoracic gland being greatly hypertrophied in third instar DTS-3 larvae. Injection of a single wild-type ring gland rescued these mutant larvae, indicating that the mutant gland is functionally, as well as morphologically, abnormal. Finally, the mutant larvae were shown to have less than 10% of the wild-type ecdysteroid levels. These results are all consistent with a proposed lesion in ecdysteroid hormone production in DTS-3 larvae. A comparison with the phenotypes of other “ecdysone-less” mutants is presented.     

Temperature-Sensitive Mutations in DROSOPHILA MELANOGASTER. IX. Dominant Cold-Sensitive Lethals on the Autosomes

Ethyl methanesulfonate-treated autosomes were screened for the presence of dominant cold-sensitive (DCS) lethal mutations in Drosophila melanogaster. None was found among 6,552 treated and 168 untreated third chromosomes. Twenty-three DCS-L chromosomes which caused death at 17 degrees C but survived at 22 degrees C and 29 degrees C were recovered from 5,046 mutagenized chromosome 2's.-The DCS-L mutations all mapped around dp and appeared to be functionally allelic. Lethality of heterozygotes for most of the DCS-L's occurred over a prolonged interval from the embryonic through the larval instars. Prolonged incubation at 17 degrees C did not demonstrate any maternal effect on zygotic survival.     

Conditionally lethal amber mutations in the leader peptidase gene of Escherichia coli.

The lep gene of Escherichia coli encodes the leader peptidase which cleaves amino-terminal leader sequences of secreted proteins. To facilitate the study of structure-function relationships of the leader peptidase, 22 amber mutations in lep were isolated by localized mutagenesis. These amber mutants grew at 32 degrees C but not at 42 degrees C in the presence of a temperature-sensitive amber suppressor. Most of them were lethal under sup0 conditions. However, one amber mutant, the lep-9 mutant, exhibited temperature-sensitive growth in the sup0 strain, indicating that the amber fragment is active at 32 degrees C but not at 42 degrees C. Protein precursors of the maltose-binding protein and OmpA accumulate strikingly in the lep-9 mutant.     

A genetic suppressor of two dominant temperature-sensitive lethal proteasome mutants of Drosophila melanogaster is itself a mutated proteasome subunit gene

Two dominant temperature-sensitive (DTS) lethal mutants of Drosophila melanogaster are Pros26(1) and Prosbeta2(1), previously known as DTS5 and DTS7. Heterozygotes for either mutant die as pupae when raised at 29 degrees , but are normally viable and fertile at 25 degrees . Previous studies have identified these as missense mutations in the genes encoding the beta6 and beta2 subunits of the 20S proteasome, respectively. In an effort to isolate additional proteasome-related mutants a screen for dominant suppressors of Pros26(1) was carried out, resulting in the identification of Pros25(SuDTS) [originally called Su(DTS)], a missense mutation in the gene encoding the 20S proteasome alpha2 subunit. Pros25(SuDTS) acts in a dominant manner to rescue both Pros26(1) and Prosbeta2(1) from their DTS lethal phenotypes. Using an in vivo protein degradation assay it was shown that this suppression occurs by counteracting the dominant-negative effect of the DTS mutant on proteasome activity. Pros25(SuDTS) is a recessive polyphasic lethal at ambient temperatures. The effects of these mutants on larval neuroblast mitosis were also examined. While Prosbeta2(1) shows a modest increase in the number of defective mitotic figures, there were no defects seen with the other two mutants, other than slightly reduced mitotic indexes.     

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.

     

Temperature-sensitive mutations in Drosophila melanogaster. XI. Male sterile mutants of the Y chromosome

Eight temperature-sensitive (ts) male sterile mutations have been induced by ethyl methanesulfonate treatment of Y chromosomes derived from a selected temperature-resistant Amherst wild-type stock of Drosophila melanogaster. Males carrying such mutated Y chromosomes (Y^ts) are sterile when raised at 29°C but fertile when reared at 22°C. Complementation tests of the mutants with Y chromosome fragments, deletions, and inter se localized all eight to the long arm of the chromosome in four different complementation groups.When Y^ts-bearing males, reared to adulthood at 22°C, were subjected to a 48-hr regimen at 29°C and mated to fresh virgin females daily, a significant reduction in fertility resulted 5 days after initiation of 29°C treatments. This period of sterility was transient (48–72-hr duration) and corresponded to a temperature-sensitive period (TSP) of spermatogenesis during the primary spermatocyte stage. A more precise definition of the TSP utilized exposure of subadult males to 29°C at selected developmental periods during which only certain germ cell stages are present. Upon eclosion adult males were subjected to a similar schedule of consecutive matings of 12-hr duration in order to detect any delay in the appearance of fertility. Different ts males could be distinguished by the resultant pattern of sterility, and the TSP of different mutations thus localized to either primary spermatocyte or immediately post-meiotic stage.Associated with Y^ts-mediated sterility, spermiogenesis is defective at restrictive temperature as evidenced by the production of nonmotile sperm and a failure to transfer such sperm to the female during copulation. In addition, electron microscopy detected a variety of ultrastructural abnormalities, including defects of axoneme formation, irregularities of Nebenkern derivative development, and failures of separation from the syncitial state or mature cyst with subsequent degeneration.     

Male-Specific Lethal Mutations of DROSOPHILA MELANOGASTER

A total of 7,416 ethyl methanesulfonate (EMS)-treated second chromosomes and 6,212 EMS-treated third chromosomes were screened for sex-specific lethals. Four new recessive male-specific lethal mutations were recovered. When in homozygous condition, each of these mutations kills males during the late larval or early pupal stages, but has no detectable effect in females. One mutant, mle^ts, is a temperature sensitive allele of maleless, mle (Fukunaga, Tanaka and Oishi 1975), while the other three mutants identify two new loci: male-specific lethal-1 (msl-1) (two alleles) at map position 2-53.3 and male-specific lethal-2 (msl-2) at 2-9.0.——The male-specific lethality associated with these mutants is not related to the sex per se of the mutant flies, since sex-transforming genes fail to interact with these mutations. Moreover, the presence or absence of a Y chromosome in males or females has no influence on the male-specific lethal action of these mutations. Finally, no single region of the X chromosome, when present as a duplication, is sufficient to rescue males from the lethal effects of msl-1 or msl-2. These results suggest that the number of complete X chromosomes determines whether a fly homozygous for a male-specific lethal mutation lives or dies.     

Mutations in Polycombeotic, a Drosophila Polycomb-Group Gene, Cause a Wide Range of Maternal and Zygotic Phenotypes

The polycomb-group genes, a set of genes characterized by mutations that cause similar phenotypes and dosage-dependent interactions, are required for the normal expression of segment-specific homeotic loci. Here we report that polycombeotic (formerly 1(3)1902), originally identified by a lethal mutation that causes a small-disc phenotype, is also a member of this group of essential genes. Adults homozygous for temperature-sensitive pco alleles that were exposed to the restrictive temperature during larval life display the second and third leg to first leg transformation characteristic of polycomb-group mutants. Adult females homozygous for temperature-sensitive alleles exposed to the restrictive temperature during oogenesis produce embryos that show anterior segments with structures normally unique to the eighth abdominal segment, another transformation characteristic of polycomb-group mutants. Mutations in the polycombeotic gene also cause defects not reported for mutations in other polycomb-group genes. Females homozygous for the most extreme temperature-sensitive allele are sterile, and larvae homozygous for null alleles have small imaginal discs and reduced frequencies of mitotic figures in the brain. Dominant mutations originally identified as enhancers or suppressors of zeste are gain-of-function alleles of polycombeotic. The type and variety of defects displayed by different mutations in this gene indicate that the product might be involved in chromosome structure and/or function.     

Genetic Analysis of Temperature-Sensitive Lethal Mutants of Salmonella Typhimurium

We have isolated 440 mutants of Salmonella typhimurium that show temperature-sensitive growth on complex medium at 44 degrees. Approximately 16% of the mutations in these strains have been mapped to 17 chromosomal locations; two of these chromosomal locations seem to include several essential genes. Genetic analysis of the mutations suggests that the collection saturates the genes readily mutable to a ts lethal phenotype in S. typhimurium. Physiological characteristics of the ts lethal mutants were tested: 6% of the mutants can grow at high temperature under anaerobic conditions, 17% can grow when the medium includes 0.5 M KCl, and 9% of the mutants die after a 2-hr incubation at the nonpermissive temperature. Most ts lethal mutations in this collection probably affect genes required for growth at all temperatures (not merely during high temperature growth) since Tn10 insertions that cause a temperature-sensitive lethal phenotype are rare.     

Localized defects of blastoderm formation in maternal effect mutants of Drosophila

In the three maternal effect lethal mutant strains of D. melanogaster described in this report, the homozygous mutant females produce defective eggs that cannot support normal embryonic development. The embryos from these eggs begin to develop for the first 2 hr after fertilization in an apparently normal way, forming a blastula containing a cluster of pole cells at the posterior end and a layer of syncytial blastoderm nuclei. During the subsequent transition from a syncytial to a cellular blastoderm, cell formation in the blastoderm is either partially or totally blocked. In mutant mat(3)1 no blastoderm cells are formed, indicating that there are separate genetic controls for pole cells and blastoderm cells. The other two mutants form an incomplete cellular blastoderm in which certain regions of the blastoderm remain noncellular. The noncellular region in mutant mat(3)3 is on the posterior-dorsal surface, covering about 30% of the total blastoderm. In mutant mat(3)6 blastoderm cells are formed only at the anterior and posterior ends, separated by a noncellular region that covers about 70% of the total blastoderm. The selective effects on blastoderm cell formation in the three mutants emphasize the importance of components present in the egg before fertilization for the transition from a syncytial to a cellular blastoderm.The genes defective in the three mutants are essential only for oogenesis and not for any other period of development, as indicated by a strict dependence of the lethal phenotypes on the maternal genotypes. Heterozygous embryos from the eggs of homozygous mutant females die, whereas homozygous mutant embryos from the eggs of heterozygous females develop into viable adults.One of the mutants, mat(3)3, has a temperature-sensitive phenotype. Homozygous mat(3)3 females maintained at a restrictive temperature of 29°C show the lethal maternal effect. However, at a permissive temperature of 20°C the females produce viable adult progeny. The temperature-sensitive period in mat(3)3 females occurs during the last 12 hr of oogenesis, consistent with the maternal effect phenotype of the mutant.     

Developmental genetics of a temperature-sensitive RNA polymerase II mutation in Drosophila melanogaster

Summary Purified RNA polymerase II (RNA nucleotidyl-transferase; EC 2.7.7.6) extracted from flies possessing lesions in the Ultrabithorax-like (Ubl) locus of Drosophila melanogaster has altered activity in vitro (Greenleaf et al. 1979, 1980; Coulter and Greenleaf 1982). This strongly suggests that the Ubl locus encodes a subunit of RNA polymerase II. Ethyl methanesulfonate was used to induce a temperature-sensitive mutation in this locus. Flies either homozygous or hemizygous for this new X–linked mutation (Ubl ^ts) display viability comparable to that of wild-type flies at 22° C but are lethal at 29° C. The temperature-sensitive period for Ubl ^ts flies is between gastrulation (6 h, 29° C) and pupation (9–10 days, 22° C). Zygotes shifted from 22° C to 29° C die at either the late embryonic or first larval instar stage while temperature shifts of second and third instar larvae result in the lethal phase occurring at the pupal stage. Most pupae shifted from 22° C to 29° C undergo metamorphosis and eclose as adults. Adults are viable if placed at 29° C; however, all females and some males become sterile if maintained at this temperature.Somatic recombination was used to induce clones homozygous for a null allele of Ubl at different stages of development. Clones of this null allele appear to be cell lethal indicating that the Ubl ⁺ gene product is required at all stages of development. The viability of Ubl ^ts pupae and adults at 29° C may result from only a partial reduction in activity caused by the mutation at this nonpermissive temperature.     

Saccharomyces cerevisiae cdc2 mutants fail to replicate approximately one-third of their nuclear genome.

Chromosomal DNA replication was examined in temperature-sensitive mutants of Saccharomyces cerevisiae defective in a gene required for the completion of S phase at the nonpermissive temperature, 37 degrees C. Based on incorporation of radioactive precursors and density transfer experiments, strains carrying three different alleles of cdc2 failed to replicate approximately one-third of their nuclear genome at 37 degrees C. Whole-cell autoradiography experiments demonstrated that 93 to 96% of the cells synthesized DNA at 37 degrees C. Therefore, all cells failed to replicate part of their genome. DNA isolated from terminally arrested cells was of normal size as measured on neutral and alkaline sucrose gradients, suggesting that partially replicated DNA molecules do not accumulate and that DNA strands are ligated properly in cdc2 mutants. In addition, electron microscopic examination of the equivalent of more than one genome's DNA from arrested cells failed to reveal any partially replicated molecules. The sequences which failed to replicate at 37 degrees C were not highly specific; eight different cloned sequences replicated to the same extent as total DNA. The 2-microns plasmid DNA and rDNA replicated significantly less well than total DNA, but approximately one-half of these sequences replicated at 37 degrees C. These observations suggest that cdc2 mutants are defective in an aspect of initiation of DNA replication common to all chromosomes such that a random fraction of the chromosomes fail to initiate replication at 37 degrees C, but that once initiated, replication proceeds normally.     

A suppressor of temperature-sensitive rna mutations that affect mRNA metabolism in Saccharomyces cerevisiae.

We have isolated a dominant suppressor of rna mutation (SRN1) that relieves the temperature-sensitive inhibition of mRNA synthesis of ribosomal protein genes in the yeast Saccharomyces cerevisiae. The suppressor was selected for its ability to alleviate simultaneously the temperature-sensitive growth phenotypes of rna2 and rna6. Several independently isolated suppressors appeared to be recessive lethal mutations. One suppressor, SRN1, was recovered as viable in haploid strains. SRN1 can suppress rna2, rna3, rna4, rna5, rna6, and rna8 singly or in pairs, although some combinations of rna mutations are less well suppressed than others. The suppressor allows strains with rna mutations to grow at 34 degrees C but is unable to suppress at 37 degrees C; however, SRN1 does not, by itself, prevent growth at 37 degrees C. In addition, SRN1 suppresses the rna1 mutation which affects general mRNA levels and also leads to the accumulation of precursor tRNA for those tRNAs that have intervening sequences. SRN1 can suppress the rna1 mutation as well as the rna1 rna2 double mutation at 34 degrees C. The suppressor does not affect the temperature-sensitive growth of two unrelated temperature-sensitive mutations, cdc4 and cdc7.     

Mutations in Genes Encoding Essential Mitotic Functions in DROSOPHILA MELANOGASTER

Temperature-sensitive mutations at 15 loci that affect the fidelity of mitotic chromosome behavior have been isolated in Drosophila melanogaster. These mitotic mutants were detected in a collection of 168 EMS-induced X-linked temperature-sensitive (ts) lethal and semilethal mutants. Our screen for mutations with mitotic effects was based upon the reasoning that under semirestrictive conditions such mutations could cause an elevated frequency of mitotic chromosome misbehavior and that such events would be detectable with somatic cell genetic techniques. Males hemizygous for each ts lethal and heterozygous for the recessive autosomal cell marker mwh were reared under semirestrictive conditions, and the wings of those individuals surviving to adulthood were examined for an increased frequency of mwh clones. Those mutations producing elevated levels of chromosome instability during growth of the wing imaginal disc were also examined for their effects on chromosome behavior in the cell lineages producing the abdominal cuticle. Fifteen mutations affect chromosome behavior in both wing and abdominal cells and thus identify loci generally required for the fidelity of mitotic chromosome transmission. Mapping and complementation tests show that these mutations represent 15 loci. One mutant is an allele of a locus (mus-101) previously identified by mutagen-sensitive mutants and a second mutant is an allele of the lethal locus zw 10.--The 15 mutants were also examined cytologically for their effects on chromosomes in larval neuroblasts. Taken together, the results of our cytological and genetical studies show that these mutants identify loci with wild-type functions necessary for either maintenance of chromosome integrity or regular disjunction of chromosomes or chromosome condensation. Thus, these mutations define a broad spectrum of genes required for the normal execution of the mitotic chromosome cycle.     

Evidence of a Dual Function in Fl(2)d, a Gene Needed for Sex-Lethal Expression in Drosophila Melanogaster

In Drosophila melanogaster, the female sexual development of the soma and the germline requires the activity of the gene Sxl. The somatic cells need the function of the gene fl(2)d to follow the female developmental pathway, due to its involvement in the female-specific splicing of Sxl RNA. Here we report the analysis of both fl(2)d1 and fl(2)d2 mutations: (1) fl(2)d1 is a temperature-sensitive mutation lethal in females and semilethal in males; (2) fl(2)d2 is lethal in both sexes; (3) the fl(2)d1/fl(2)d2 constitution is temperature-sensitive and lethal in females, while semilethal in males. The temperature-sensitive period of fl(2)d1 in females expands the whole development. SxlM1 partially suppresses the lethality of fl(2)d1 homozygous females and that of fl(2)d1/fl(2)d2 constitution, whereas it does not suppress the lethality of fl(2)d2 homozygous females. The addition of extra Sxl+ copies does not increase the suppression effect of SxlM1. The fl(2)d1 mutation in homozygosis and the fl(2)d1/fl(2)d2 constitution, but not the fl(2)d2 in homozygosis, partially suppress the lethality of SxlM1 males. This suppression is not prevented by the addition of extra Sxl+ copies. The semilethality of both fl(2)d1 and fl(2)d1/fl(2)d2 males, and the lethality of fl(2)d2 males, is independent of Sxl function. There is no female synergistic lethality between mutations at fl(2)d and neither at sc or da. However, the female synergistic lethality between mutations at Sxl and either sc or da is increased by fl(2)d mutations. We have analyzed the effect of the fl(2)d mutations on the germline development of both females and males. For that purpose, we carried out the clonal analysis of fl(2)d1 in the germline. In addition, pole cells homozygous for fl(2)d2 were transplanted into wild-type host embryos, and we checked whether the mutant pole cells were capable of forming functional gametes. The results indicated that fl(2)d mutant germ cells cannot give rise to functional oocytes, while they can form functional sperm. Moreover, SxlM1 suppresses the sterility of the fl(2)d1 homozygous females developing at the permissive temperature. Thus, with respect to the development of the germline the fl(2)d mutations mimic the behavior of loss-of-function mutations at the gene Sxl. Females double heterozygous for fl(2)d and snf1621 are fully viable and fertile. fl(2)d2 in heterozygosis partially suppresses the phenotype of female germ cells homozygous for snf1621; however, this is not the case with the fl(2)d1 mutation. The fl(2)d mutations partially suppress the phenotype of the female germ cells homozygous for ovoDIrSI.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mutant analysis of herpes simplex virus-induced cell surface antigens: resistance to complement-mediated immune cytolysis.

BHK-21 cells infected with temperature-sensitive mutants of herpes simplex virus type 1 strain KOS representing 16 complementation groups were tested for susceptibility to complement-mediated immune cytolysis at permissive (34 degrees C) and nonpermissive (39 degrees C) temperatures. Only cells infected by mutants in complementation group E were resistant to immune cytolysis in a temperature-sensitive manner compared with wild-type infections. The expression of group E mutant cell surface antigens during infections at 34 and 39 degrees C was characterized by a combination of cell surface radioiodination, specific immunoprecipitation, and gel electrophoretic analysis of immunoprecipitates. Resistance to immune lysis at 39 degrees C correlated with the absence of viral antigens exposed at the cell surface. Intrinsic radiolabeling of group E mutant infections with [14C]glucosamine revealed that normal glycoproteins were produced at 34 degrees C but none were synthesized at 39 degrees C. The effect of 2-deoxy-D-glucose on glycosylation of group E mutants at 39 degrees C suggested that the viral glycoprotein precursors were not synthesized. The complementation group E mutants failed to complement herpes simplex virus type 1 mutants isolated by other workers. These included the group B mutants of strain KOS, the temperature-sensitive group D mutants of strain 17, and the LB2 mutant of strain HFEM. These mutants should be considered members of herpes simplex virus type 1 complementation group 1.2, in keeping with the new herpes simplex virus type 1 nomenclature.     

Cytogenetic Analysis of Chromosome Region 73ad of Drosophila Melanogaster

The 73AD salivary chromosome region of Drosophila melanogaster was subjected to mutational analysis in order to (1) generate a collection of chromosome breakpoints that would allow a correlation between the genetic, cytological and molecular maps of the region and (2) define the number and gross organization of complementation groups within this interval. Eighteen complementation groups were defined and mapped to the 73A2-73B7 region, which is comprised of 17 polytene bands. These complementation groups include the previously known scarlet (st), transformer (tra) and Dominant temperature-sensitive lethal-5 (DTS-5) genes, as well as 13 new recessive lethal complementation groups and one male and female sterile locus. One of the newly identified lethal complementation groups corresponds to the molecularly identified abl locus, and another gene is defined by mutant alleles that exhibit an interaction with the abl mutants. We also recovered several mutations in the 73C1-D1.2 interval, representing two lethal complementation groups, one new visible mutant, plucked (plk), and a previously known visible, dark body (db). There is no evidence of a complex of sex determination genes in the region near tra.     

A Cold-Sensitive Zygotic Lethal Causing High Frequencies of Nondisjunction during Meiosis I in DROSOPHILA MELANOGASTER Females

The X-linked, cold-sensitive zygotic lethal, l(1)TW-6(cs), both in homozygous and heterozygous females, induces nondisjunction of all four chromosomes at Meiosis I at both 25 degrees and 17 degrees . Nondisjunction frequencies approaching 0.5 for the X and fourth chromosomes have been observed at 16 degrees -18 degrees . The disjunction of the X chromosomes in males is not affected. The mutant causes mitotic irregularities in zygotes at both 25 degrees and 17 degrees . Mortality of all zygotes produced by the crosses 6(cs)/6(cs)x6(cs)/B(s)Y and FM7/6(cs)x6(cs)/B(s)Y is respectively 86% and 67-74% at 25 degrees and 99.8-99.9% and 94% at 17 degrees . The mortality of 6(cs) hemizygotes derived from females carrying no doses of 6(cs) (C(1)DX,y f/yx6(cs)/B(s)Y) is 45-55% at 25 degrees and 98% at 17 degrees . The length of the temperature-sensitive period for 6(cs) homo- and hemizygotes is affected by the maternal dosage of 6(cs); the shortest TSP is for zero and the longest is for two maternal doses. Mortality takes place primarily during embryogenesis with some larval and little pupal mortality. Analysis of sectioned embryos indicates that the large array of different patterns of damage observed could have arisen from abnormal cleavage divisions and the incomplete population of the blastoderm with nuclei.     

Construction and Preliminary Characterization of a Library of “Lethal” Preterminal Protein Mutant Adenoviruses

Adenoviruses containing lethal in-frame insertion mutant alleles of the preterminal protein (pTP) gene were constructed with cell lines that express pTP. Thirty in-frame insertion mutant alleles, including 26 alleles previously characterized as lethal and 4 newly constructed mutant alleles, were introduced into the viral chromosome in place of the wild-type pTP gene. The viruses were tested for ability to form plaques at 37 degrees C in HeLa-pTP cells and at 32 degrees C and 39.5 degrees C in HeLa cells. Two of the newly constructed viruses exhibited temperature sensitivity for plaque formation, one virus did not form plaques in the absence of complementation, seven additional mutants exhibited a greater than 10-fold reduction in plaque formation in the absence of complementation, and another eight mutants exhibited stronger phenotypes than did previously characterized in-frame insertion mutants in the plaque assay. These mutant viruses offer promise for analysis of pTP functions.