A clonal analysis of the roles of somatic cells and germ line during oogenesis in Drosophila

In order to test whether particular female sterile mutations block functions which normally occur in somatic or germ line derivatives, clones homozygous for each mutation were X-ray induced in heterozygous females. Using the germ line-dependent egg marker, fs(1)K10, it was possible to identify the eggs derived from clones which had been induced in the germ line. Mutations were classified as germ line dependent when these eggs also showed the phenotype associated with the female sterile mutation. Two mutations which caused early abnormalities in oogenesis (fs(1)116, fs(1)1304) were shown to affect germ cells, whereas two mutations which caused egg retention (fs(1)462, fs(1)1001) were somatically dependent. A mutation altering egg dimensions without affecting egg volume (short egg) was also shown to depend on somatic cells in the ovary. With one exception (fs(1)K4), mutations which caused production of fragile, collapsed eggs (fs(1)180, fs(1)473, fs(1)384, and fs(1)1163) were somatically dependent. Patches of mutant fs(1)384 morphology were found in the chorions of the eggs not derived from germ line clones. These patches are interpreted as being caused by homozygous clones in the somatically derived follicle cell epithelium and suggest that fs(1)384 affects processes occurring in these cells during the synthesis of the egg coverings.     

Genetic localization of a follicle cell protein locus in Drosophila melanogaster

Summary Three variant forms of a novel set of follicle cell proteins (Fc) were found when screening geographic wild-type strains of Drosophila melanogaster by SDS-polyacrylamide gel electrophoresis of ³⁵S-methionine labelled ovaries. These variant forms were used to establish X chromosomal linkage and for further genetic localization by both recombinant analysis and by cytogenetical mapping. A locus involved in the synthesis of Fc proteins was localized to the 7C1-9 region, i.e. very close to the singed locus (21.0 cM). The number of Fc proteins, their variation and possible function is discussed.     

Mutant fs(1) 1163 of Drosophila melanogaster alters yolk protein secretion from the fat body

Summary The mutant fs(1) 1163 of Drosophila melanogaster, which was isolated by Gans et al. (1975) is a recessive homozygous female sterile at 18°C and a dominant female — sterile at 29°C. We reported previously that there are reduced quantities of the largest of the three yolk polypeptides in Drosophila melanogaster in the haemolymph and eggs of this mutant at 29°C (Bownes and Hames 1978 a). In this paper we show that the yolk protein defect maps within approximately 2.5 recombination units of the female sterility at 21±2.5 map units on the X-chromosome. The temperature-sensitive period of the yolk protein defect is after emergence. In vitro labelling of fs(1) 1163 ovaries and fat bodies showed that they were able to synthesise yolk polypeptide 1. Interestingly, studies on the proteins present in the various tissues indicate that the fat body tends to accumulate all three yolk polypeptides in the mutant. This phenotype is partially co-dominant in that an effect is seen in heterozygotes as well as homozygotes and is enhanced by increased temperature. This mutant could therefore have a defect (a) in the structural gene for yolk polypeptide 1, (b) in the processing and secretion enzyme systems; (c) in the fat body or all tissues leading to altered secretion properties.Mutants like fs(1) 1163 which alter specific steps in vitellogenesis should be of value for analysing the genetic and biochemical control of the synthesis, transport and sequestering of the yolk polypeptides during oogenesis.     

Construction of a novel synergistic system for production and recovery of secreted recombinant proteins by the cell surface engineering

We determined whether the cocultivation of yeast cells displaying a ZZ-domain and secreting an Fc fusion protein can be a novel tool for the recovery of secreted recombinant proteins. The ZZ-domain from Staphylococcus aureus protein A was displayed on the cell surface of Saccharomyces cerevisiae under the control of the GAL1 promoter. Strain S. cerevisiae BY4742 cells displaying the ZZ-domain on their surface were used for cocultivation with cells that produce a target protein fused to the Fc fragment as an affinity tag. The enhanced green fluorescent protein or Rhizopus oryzae lipase was genetically fused to the N and C termini of the Fc fragment of human immunoglobulin G, respectively. Through analysis by fluorescence-activated cell sorting and enzymatic assay, it was demonstrated that these fusion proteins are successfully produced in the medium and recovered by affinity binding with the cell surface displaying the ZZ-domain. These results suggest that the ZZ-domain-displaying cell and Fc fusion protein-secreting cell can be applied to use in synergistic process of production and recovery of secreted recombinant proteins.     

Yolk polypeptide secretion and vitelline membrane deposition in a female sterile Drosophila mutant

Ovarian follicle cells of wild type Drosophila melanogaster simultaneously secrete yolk polypeptides (YP1, YP2 and YP3) and vitelline membrane proteins. In order to understand the relationship between these two secretory activities, we have investigated the ultrastructure of a female sterile mutation that alters YP1 secretion and vitelline membrane deposition. Homozygous fs(1)1163 females lay eggs that collapse and contain reduced quantities of YP1. Secretory granules in follicle cells contain an electron-translucent component that is assembled into the developing vitelline membrane in both mutant and wild-type ovaries, and an electron-dense component that disperses after secretion in wild-type ovaries. Mutant ovaries differ from wild-type by (1) having larger secretory granules (2) forming clumps of the dense secretory component within the developing vitelline membrane (3) accumulating more tubules in the cortical ooplasm of vitellogenic oocytes, and (4) possessing altered yolk spheres. Mutant ovaries implanted into wild-type hosts showed no improvement in the secretory granules and slight improvement in the vitelline membrane clumps but amelioration of the oocyte phenotypes. Since genetic evidence suggests that the fs(1)1163 mutation resides in or near the Yp1 gene and biochemical data show that the mutation alters YP1 structure, we conclude that the ultrastructural phenotypes are due to a structurally abnormal YP1 in the mutant. The alteration in vitelline membrane structure caused by the dense clumps could account for collapsed eggs and, hence, the female sterility of the mutant.     

The recovery, penetrance, and pleiotropy of X-linked, cold sensitive mutants in Drosophila

Summary The viability at 16°, 22°, and 30°C, loci, visible phenotypes if any, possible effective lethal phase, and female fertility of seven X-linked, recessive cold sensitive mutations are reported. Five of the seven are female sterile at the restrictive temperature of 16°C; two of these five are also female sterile at the permissive temperature of 25°C. For two of the five mutations which are female sterile, escapers at the restrictive temperature exhibit visible phenotypes characteristic of mutants which affect protein synthesis. The possibility that some of the mutants affect ribosomes is considered. One of the mutants, l(1)TW-6 ^cs , is probably a cold sensitive meiotic mutant as well as a cold sensitive zygotic lethal. One of the mutants is a non-conditional visible allele of lozenge.Supported by NSF Grants GB 7707 and GB 20910.     

Ty1 Gag Enhances the Stability and Nuclear Export of Ty1 mRNA

Retrotransposon and retroviral RNA delivery to particle assembly sites is essential for their replication. mRNA and Gag from the Ty1 retrotransposon colocalize in cytoplasmic foci, which are required for transposition and may be the sites for virus‐like particle (VLP) assembly. To determine which Ty1 components are required to form mRNA/Gag foci, localization studies were performed in a Ty1‐less strain expressing galactose‐inducible Ty1 plasmids (pGTy1) containing mutations in GAG or POL. Ty1 mRNA/Gag foci remained unaltered in mutants defective in Ty1 protease (PR) or deleted for POL. However, Ty1 mRNA containing a frameshift mutation (Ty1fs) that prevents the synthesis of all proteins accumulated in the nucleus. Ty1fs RNA showed a decrease in stability that was mediated by the cytoplasmic exosome, nonsense‐mediated decay (NMD) and the processing body. Localization of Ty1fs RNA remained unchanged in an nmd2Δ mutant. When Gag and Ty1fs mRNA were expressed independently, Gag provided in trans increased Ty1fs RNA level and restored localization of Ty1fs RNA in cytoplasmic foci. Endogenously expressed Gag also localized to the nuclear periphery independent of RNA export. These results suggest that Gag is required for Ty1 mRNA stability, efficient nuclear export and localization into cytoplasmic foci.     

Cytogenetical analysis of the 2B3-4-2B11 region of the X chromosome of Drosophila melanogaster

Summary Of 13 ecs mutations, which affect female fertility, as revealed by complementation analysis, 7 are chromosome rearrangements involving the br complementation group. The other six show no cytologically detectable rearrangements and behave as completely or partially noncomplementing ecs alleles. All viable combinations of these 13 mutations were characterized by partial or complete female sterility. Viable heterozygotes carrying any of these mutations and the rearrangements Df(1)sta, T(1,3)sta, Df(1)St490, previously localized distal to the ecs locus, were also sterile. Using deletions and an electrophoretic mobility variant from the Staket strain, a minor chorion gene S70 has been mapped. It had been thought this gene was located in the 2B3-5 region, and corresponded to the ecs locus. However, in the present study, this gene was shown to map in the region removed by Df(1)sta (1E1-2-2B3-4) but outside that removed by Df(1)At127 (1E1-2-2A1-2), i.e. within the 2A1-2-2B3-4 region which is distal to the ecs locus. Rearrangements and point mutations at the ecs locus that result in female sterility had no effect on synthesis of the chorion protein s70. It may therefore be suggested that the chorion protein gene is not functionally associated with the ecs locus and that sterility is caused not by disruptions of the chorion protein gene but by lesions in the ecs gene itself. Thus, an ecs product, which controlls cell sensitivity to ecdysterone is also necessary for female fertility. Data on the locations of lesions affecting female fertility indicate that at least two elements at the ecs locus are essential for this function: a cis-acting distal zone with no effect on viability and a sequence within the essential part of the ecs locus. A defect in either of these zones or their separation by chromosomal rearrangement leads to female sterility.     

Isolation of germ line-dependent female-sterile mutation that affects yolk specific sequestration and chorion formation in Drosophila

Two loci on the X chromosome have been implicated in choriogenesis by in situ hybridization of poly A-containing RNA from choriogenic eggchambers to Drosophila polytene chromosomes (A. C. Spradling and A. P. Mahowald (1979): 7E and 12E. At least two genes coding for major eggshell proteins map to region 7E (A. C. Spradling, M. E. Digan, A. P. Mahowald, M. Scott, and E. A. Craig (1980). In an effort to elucidate the functional role of the 12E gene product, 3600 EMS-treated X chromosomes were screened for recessive female-sterile mutations that mapped within the region 11F10-12F1. Four independent female-sterile mutations were recovered, three of which fell into one complementation group (fs29, fs117, and fs445). Mapping by analysis of recombinant progeny as well as of trans heterozygotes utilizing other deficiency chromosomes showed that the three noncomplementing mutations all mapped to region 12E1-12F1. Studies comparing chorion morphology and protein synthesis indicate localized perturbations in the extracellular assembly of eggshell components in mutant eggchambers. The germ line dependence of the mutations was established using germ line mosaics constructed by pole cell transplantation. Analysis of eggchamber protein accumulation patterns showed reduced amounts of yolk polypeptides (YPs) in the mutants. The elevated concentrations of YPs found in mutant hemolymph coupled with the normal YP biosynthetic patterns and active uptake of trypan blue by mutant oocytes suggest that 12E sequences play a role in yolk-specific sequestration.     

A synthetic combination of mutations, including fs(1)pyr? Su(b) , r? Su(b) and b , causes female sterility and reduces embryonic viability in Drosophila melanogaster

A Drosophila melanogaster mutant, fs(1)pyr ^Su(b) , carrying a mutation that maps to the tip of the X chromosome, has been isolated. The mutation, when present alone, does not confer a detectable phenotype. However, this mutation causes female sterility and reduces embryonic viability when combined with mutations which deregulate the pyrimidine and β-alanine pools. Embryos that are homozygous for the mutations fs(1)pyr ^Su(b) , r ^Su(b) [previously designated as Su(b)] and b, and originate from a female parent homozygous for the three mutations show severely reduced viability. Newly laid eggs begin development normally, but the majority of the embryos die just before the eggs are due to hatch. Received: 15 May 1998 / Accepted: 18 January 1999     

Analysis of the Drosophila female sterile mutation fs(1) 1304 by pole cell transplantation experiments

The Drosophila melanogaster mutant fs(1)1304 is an ovary autonomous female sterile mutant that causes abnormal morphology of the egg. Vitellogenesis proceeds at an abnormally slow rate in homozygous females. We have used pole cell transplantation to construct germ line mosaics in order to determine whether the 1304 defect depends upon the genotype of the germ line cells (oocyte or nurse cells) or the somatic line (follicle cells). We have found that the germ line is the primary target tissue where the mutant gene is expressed.     

Molecular analysis and rescue of a vitelline membrane mutant in Drosophila

The eggshell in Drosophila is produced by ovarian follicle cells during the later stages of oogenesis. Eggshell formation involves the ordered synthesis and assembly of several protein components. Genes encoding the most abundant eggshell proteins have been identified by molecular cloning studies. Morphological examination of eggs produced by females carrying female sterile mutations on the X and third chromosomes have revealed additional loci involved in chorion formation. In this study we screened a collection of female sterile mutants carrying EMS-induced mutations on the second chromosome for eggshell mutants. A class of six mutants with potential vitelline membrane defects was identified on the basis of the response of mutant eggs to hypochlorite solutions. Biochemical analysis showed that one mutant, fs(2)QJ42, failed to produce a major vitelline membrane protein, sV23. The mutation was mapped cytogenetically to 26A, a region previously implicated in vitelline membrane formation by molecular cloning studies. Northern blot analysis using a cloned copy of the sV23 gene as probe showed a 10- to 15-fold reduction of sV23 RNA levels in the mutant. sV23 synthesis and fertility were restored when a normal copy of the sV23 gene was introduced into the mutant via germ line transformation. Transposons carrying the sV23 gene with as little as 147 bp of 5' flanking DNA were capable of restoring fertility and sV23 protein to wild type levels.     

Genetic analysis of chorion formation in Drosophila melanogaster: I. The effects of one somatic-specific and seven germ-line-specific mutations

Eight X-linked recessive female sterile mutations, derived from a hybrid dysgenic screen of Drosophila melanogaster and representing eight distinct loci, have been characterized by genetic and ultrastructural analysis. Four have abnormal respiratory appendages, three have essentially normal appendages but show moderate defects in the endochorion, and one mutant, fs(1)ne1a, exhibits major defects in both the endochorion and the respiratory appendages. Germ line clones of all eight mutants were generated using the dominant female sterile technique. Seven of the eight mutations are germ line specific, indicating that, although the eggshell is produced by the follicular cells, germ line functions play a significant role in its elaboration. The mutant that shows major defects, fs(1)ne1a, is somatic line specific, and exerts its effect in the ovary.     

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The immunoglobulin G (IgG) molecule has a long circulating serum half-life (~3 weeks) through pH- dependent FcRn binding-mediated recycling. To hijack the intracellular trafficking and recycling mechanism of IgG as a way to extend serum persistence of non-antibody therapeutic proteins, we have evolved the ectodomain of a low-affinity human FcγRIIa for enhanced binding to the lower hinge and upper CH2 region of IgG, which is very far from the FcRn binding site (CH2–CH3 interface). High-throughput library screening enabled isolation of an FcγRIIa variant (2A45.1) with 32-fold increased binding affinity to human IgG1 Fc (equilibrium dissociation constant: 9.04 × 10⁻⁷ M for wild type FcγRIIa and 2.82 × 10⁻⁸ M for 2A45.1) and significantly improved affinity to mouse serum IgG compared to wild type human FcγRIIa. The in vivo pharmacokinetic profile of PD-L1 fused with engineered FcγRIIa (PD-L1–2A45.1) was compared with that of PD-L1 fused with wild type FcγRIIa (PD-L1–wild type FcγRIIa) and human PD-L1 in mice. PD-L1–2A45.1 showed 11.7- and 9.7-fold prolonged circulating half-life (t_1/2) compared to PD-L1 when administered intravenously and intraperitoneally, respectively. In addition, the AUC_inf of PD-L1–2A45.1 was two-fold higher compared to that of PD-L1–wild type FcγRIIa. These results demonstrate that engineered FcγRIIa fusion offers a novel and successful strategy for prolonging serum half-life of therapeutic proteins.     

The frequency and spectrum of mutations and the <Emphasis Type="Italic">IVS8-T</Emphasis> polymorphism of the <Emphasis Type="Italic">CFTR</Emphasis> gene in Russian infertile men

The frequency and spectrum of mutations and the IVS8-T polymorphism of the CFTR gene have been studied in a cohort of 963 in Russian infertile men. Mutations have been found in 48 out of 1926 analyzed chromosomes (2.5%) in the heterozygous state (n = 46) and in the compound heterozygote L138ins/N1303K (n = 1). A CFTR gene mutation was combined with the 5T allele (mutCFTR/5T) in 11 patients. The following mutations have been found: F508del (n = 18), CFTRdele2,3(21kb) (n = 9), W1282X (n = 7), 2143delT (n = 4), 3849 +10kbC>T (n = 2), L138ins (n = 2), 1677delTA (n = 1), 2184insA (n = 1), 3821delT (n = 1), G542X (n = 1), N1303K (n = 1), and R334W (n = 1). The F508del mutation is the most frequent; it has been detected in 37.5% of the affected chromosomes. The total proportion of four mutations (F508del, CFTRdele2,3(21kb), W1282X, and 2143delT) is about 79% of all mutations found. The 5T allele has been found in 10.9% infertile men and 4.8% of control men. Significant differences in the frequency of the IVS8-5T variant of the CFTR gene have been found between these groups (p = 0.005), as well as between infertile patients without mutations and control men (p = 0.019). In total, the mutations and /or 5T allele have been found in 14.6% of the patients examined. These data indicate increased frequencies of the mutations of the CFTR gene and its allele variant IVS8-5T in Russian infertile men.     

Genetic characterization and floral development of female sterile and stubby head, two aposporous mutants of pearl millet

 Apomixis has never been reported in natural populations of pearl millet [Pennisetum glaucum (L.) R.Br.], although many wild relatives of pearl millet are obligate or facultative aposporous apomicts. Four-nucleate aposporous embryo sacs are formed from somatic cells of the nucellus that do not undergo meiosis. Two mutants of pearl millet, female sterile (fs) and stubby head, have two developmental characteristics in common: a significant reduction in head length compared with the wild-type and the formation of aposporous embryo sacs. Reproductive development in fs and stubby head mutants was examined in depth because of the potential for illuminating basic cellular or developmental factors that may function to alter embryo sac development. Genetic analysis of stubby head showed that this phenotype is conferred by genes at two loci linked in coupling within 29 cM. Crosses between fs and stubby head mutants showed that, despite the similarities in phenotypes, the mutations are at different loci. The mutants differ from wild-type in their inflorescence structure from the time of initiation of spikelet primordia through terminal differentiation of the ovule. Both mutations could be categorized as meristic, since a change in inflorescence branch or organ number was common and gynoecium development varied. We speculate that heterochronic development of the floral meristem and organ initiation/specification programs may be the underlying mechanism for phenotypic changes in these mutants throughout the floral phase. Received: 25 October 1996 / Accepted: 13 March 1997     

Nonvitellogenic female sterile mutants and the regulation of vitellogenesis in Drosophila melanogaster.

The genetic and endocrine regulation of vitellogenesis was investigated by studying 18 female sterile mutations that disrupt the development of normal vitellogenic follicles. Applications of exogenous juvenile hormone analog and reciprocal ovarian transplants between flies of different genotypes were employed to accomplish our first two objectives: to find (1) whether the mutation blocked development of the ovary directly, and (2) whether the mutation altered the hormonal milieu. In 15 of the mutants the developmental defect was localized to the ovary, but in the other 3 the ovary was competent to respond to a permissive environment. The internal milieu of these three mutants (ap⁴, fs(3)A1, fs(2)A18) was unable to provoke normal development in wild-type ovaries, suggesting that these mutations cause endocrine defects. Our third objective was to find whether an endocrine organ was itself defective in any of these mutants. The corpus allatum from two of the mutants was unable to provoke vitellogenesis in isolated wild-type abdomens, but corpora allata from wild-type females or from other mutants were able to promote maturation of ovarian follicles in isolated abdomens. Our fourth objective was to find whether any of the mutants were able to produce yolk proteins. Immunoelectrophoresis of fly hemolymph demonstrated that in all mutants tested vitellogenins were found in the blood. These experiments permit four main conclusions. First, they identify the first Drosophila mutants in which an endocrine gland is shown to be intrinsically defective during adulthood. Second, they show that the production of morphologically normal late previtellogenic follicles is not required for the induction of vitellogenin synthesis and secretion. Third, they show that juvenile hormone can cause ovarian follicles to sequester yolk in mutant flies. And finally, they show that mutants with defective corpora allata still synthesize and secrete vitellogenin. Taken together, these conclusions suggest that in Drosophila melanogaster the uptake of vitellogenin into follicles depends upon the availability of juvenile hormone, but that the synthesis and secretion of vitellogenin are independent of both normal ovaries and totally normal corpora allata.     

Effect of otu mutations on male fertility and spermatogenesis in Drosophila melanogaster

The 17-ethyl-methyl-sulphonate (EMS) induced female sterile alleles of the ovarian tumour (otu) locus show a wide spectrum of phenotypes and affect various processes of Drosophila oogenesis. These phenotypes have been previously studied in detail, but the exact molecular function of the otu locus in the different processes of oogenesis is only poorly known. To date, no effect of otu mutations have been reported in the males. However, separate species of otu mRNAs are expressed in the testes and the thorax of the adult male, but their role is not known. In this study we analysed the effects of EMS-induced otu mutations on male fertility. We observed that the proportion of totally sterile males is significantly higher in most of the tested otu strains as compared to the wild type. There was a strong correlation between male sterility and severity of impairment in the female phenotype. Spermatogenesis of these semi-sterile strains was analysed by phase contrast microscopy, Hoechst 33258 and Feulgen stain, and by in situ hybridisation with testis-specific probes. No changes which could account for the induction of sterility were recorded and normal amounts of motile sperm were observed in all strains. Sterility turned out to be a consequence of a failure in mating behaviour. The wild type females refused to react to the courtship attempts of the mutant males. We propose two alternative explanations for this. Either the otu locus may play some important role in male somatic tissue, or some germ line function is necessary for correct mating behaviour.