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This chapter reviews the book Private Giving, Public Good: The Impact of Philanthropy at the University of Edinburgh (2014), by Jean Grier and Mary Bownes. The book offers an account of ‘private giving’, focusing primarily on recent gifts and drawing on the case of the University of Edinburgh. It shows that Scottish universities lacked the inherited wealth of Oxford and Cambridge. In the nineteenth century they received significant support from the state, but from the 1860s also made serious efforts to appeal to private donors and build up endowments. There is a chapter devoted to ‘research and scholarship’, which illustrates some of the problems of relying on private philanthropy. Another chapter deals with ‘bursaries, scholarships, and prizes’—once a favourite field for individual legacies and donations, and for the Carnegie Trust.

Myosin VI is a motor protein which is necessary for the morphogenesis of epithelial tissues during Drosophila development. The spatial and temporal expression of Myosin VI was examined by expressing a GFP (Green Fluorescent Protein) tagged Myosin VI molecule (PGM), under the control of a Myosin VI-Gal4 line. PGM was present in tissues that were shown previously to express Myosin VI, such as the ovarian follicle epithelium, and the individualization complex; and in other tissues, including the trachea, the midgut, the salivary glands and the imaginal discs. The GFP-tagged Myosin V1 rescued the male sterile phenotype of Jaguar showing it is functional in vivo. Within individual cells, the role of the head and neck domain and the tail domain in targeting of the Myosin V1 molecule was examined by investigating the localisation of the separate domains tagged to GFP. In salivary glands and follicle cells the head and neck domains were concentrated in the cell nucleus, where the minus end of each actin filament is located. We found that the tail domain anchors the whole molecule outside of the nucleus. Similarly, in the individualization complex in the testes, the tail anchors the whole molecule to the base of the complex while the separated head with neck domain becomes scattered along the entire actin molecule suggesting the cellular location may be determined by cargo proteins that bind to the tail domain rather than by the movement of Myosin VI along the actin filaments.

The effect of an experimentally increased octopamine content (feeding flies with OA) on the levels of juvenile hormone (JH) degradation, dopamine (DA), and 20-hydroxyecdysone (20E) contents, oogenesis, and fecundity of wild type Drosophila flies has been studied. OA feeding of the flies was found to (1) cause a considerable decrease in JH degradation in females, but not males, of D. melanogaster and D. virilis; (2) have no effect on DA content in D. melanogaster and D. virilis; (3) increase 20E contents in D. virilis females; (4) decrease to a large extent the number of vitellogenic (stages 8-10) and mature (stage 14) oocytes in D. virilis; and (5) decrease the fecundity of D. melanogaster and D. virilis. A possible mechanism of action of OA as a neurohormone on the reproductive function of Drosophila is discussed.

There are 16 classes of unconventional myosins. Class V myosins have been shown to be involved in transporting cargo to and from the cell periphery. Class VI myosins have also been shown to transport cargo from the cell periphery, although it seems that these proteins have many roles which include the mediation of cell migration and stereocillia stabilisation. With the requirement of myosin VI for Drosophila oogenesis, the localised expression of Myosin V in the developing egg chamber and recent mounting evidence which links myosin VI to the migration of human ovarian cancer cell lines, we wanted to investigate the expression pattern of these two myosin classes in the normal mouse ovary. Here we show that these myosins are expressed, localised and regulated within the oocyte and granulosa cells of the developing mouse follicle.

We describe a polymerase chain reaction (PCR) protocol suitable for use in secondary schools and colleges. This PCR protocol can be used to investigate genetic variation between plants. The protocol makes use of primers which are complementary to sequences of nucleotides that are highly conserved across different plant genera. The regions of chloroplast DNA amplified lie between these conserved sequences and are non-coding. These non-coding regions display a high frequency of mutations and show relatively high rates of evolutionary change. Thus it is possible to use the protocol to explore evolutionary relationships between plants. Results from Brassica oleracea can be used to highlight genetic similarity and differences within and across genera. The protocol is robust and is suitable for use either with a thermocycler or a series of water-baths, thus making it accessible for use in most schools and colleges.

extramacrochaetae (emc) functions during many developmental processes in Drosophila, such as sensory organ formation, sex determination, wing vein differentiation, regulation of eye photoreceptor differentiation, cell proliferation and development of the Malpighian tubules, trachea and muscles in the embryo. It encodes a Helix-Loop-Helix transcription factor that negatively regulates bHLH proteins. We show here that emc mRNA and protein are present throughout oogenesis in a dynamic expression pattern and that emc is involved in the regulation of chorionic appendage formation during late oogenesis. Expression of sense and antisense emc constructs as well as emc follicle cell clones leads to eggs with shorter, thicker dorsal appendages that are closer together at base than in the wild type. We demonstrate that emc lies downstream of fs(1)K10, gurken and EGFR in the Grk/EGFR signalling pathway and that it participates in controlling Broad-Complex expression at late stages of oogenesis.

The effects of dopamine (DA) on juvenile hormone (JH) metabolism and fitness (estimated as fecundity and viability levels under heat stress (38 degrees C)) in Drosophila virilis have been studied. An increase of DA level obtained by feeding with DA reduced fitness of wild-type (wt) flies under stress, and decreased JH degradation in young wt females while increasing it in sexually mature wt females. A decrease in DA levels resulted from 3-iodo-tyrosine treatment and caused a decrease in JH degradation in sexually mature wt and heat sensitive (hs) mutant females (DA level in hs females is twice as high in wt females). A dramatic decrease in viability under stress and fecundity under normal conditions in wt, but not hs, females was observed. 3-iodo-tyrosine treatment also reduced the number of oocytes at stages 8-14, delayed oocyte transition to stage 10 and resulted in the accumulation of mature eggs in wt females. It delayed maturation of wt, but not hs, males as well, but did not affect their fertility. This advances our understanding of the regulation of JH metabolism by DA in Drosophila and suggests a crucial role for the basal DA level in fitness.

Heterotrimeric G proteins mediate asymmetric division of Drosophila neuroblasts. Free Gβγ appears to be crucial for the generation of an asymmetric mitotic spindle and consequently daughter cells of distinct size. However, how Gβγ is released from the inactive heterotrimer remains unclear. Here we show that Locomotion defects (Loco) interacts and colocalizes with Gαi and, through its GoLoco motif, acts as a guanine nucleotide dissociation inhibitor (GDI) for Gαi. Simultaneous removal of the two GoLoco motif proteins, Loco and Pins, results in defects that are essentially indistinguishable from those observed in Gβ13F or Gγ1 mutants, suggesting that Loco and Pins act synergistically to release free Gβγ in neuroblasts. Furthermore, the RGS domain of Loco can also accelerate the GTPase activity of Gαi to regulate the equilibrium between the GDP- and the GTP-bound forms of Gαi. Thus, Loco can potentially regulate heterotrimeric G-protein signaling via two distinct modes of action during Drosophila neuroblast asymmetric divisions.

The link between reproduction and environmental signals is poorly understood at the physiological, genetic and molecular levels. We describe a mutant strain of Drosophila virilis that has altered responses to heat stress. Heat stress in wild-type females results in oocyte maturation delays, degradation of early vitellogenic egg chambers, inhibition of yolk protein gene expression in follicle cells and accumulation of mature oocytes. The mutant females have increased levels of ecdysteroids and decreased juvenile hormone degradation, and show all of the heat-stress-induced reproductive effects observed in wild-type flies, without exposure to heat stress. During oogenesis in mutant females following heat stress there is an increase in early vitellogenic oocyte degradation and some degradation of late egg chambers. 20-Hydroxyecdysone levels, but not juvenile hormone degradation, change following heat stress in mutant females.

The apterous56f (ap56f) mutation leads to increases in juvenile hormone (JH) degradation levels and JH-esterase makes a greater contribution to the increase than JH-epoxide hydrolase. Dopamine levels in ap56f females, but not males, are higher than in wild-type. JH treatment of ap56f and wild-type females decreases their dopamine levels. ap56f females, but not males, produce less progeny. Survival under heat stress is dramatically decreased in ap56f females, but not males. ap56f flies show a stress reaction, as judged by changes in tyrosine decarboxylase and JH-hydrolysing activities, dopamine levels and fertility, but its intensity in the mutant females, but not males, differs significantly from wild-type. Thus, the ap56f mutation causes dramatic changes in female, but not male, metabolism and fitness.

The regulation of the Drosophila melanogaster yolk protein genes 1 and 2 have been well characterised. Cis-acting DNA elements and trans-acting factors regulating ovarian fat body and sex-specific expression have been identified. In this paper we have analysed the regulation of yolk protein 3, which is separated from the other two genes on the X-chromosome. We have separated sex-specific control from fat body control in some constructs in transgenic flies. We propose that the organisation of the regulatory elements in yp3 differs from yp1 and yp2 for control of fat body expression and that it closely resembles the regulation of a reporter gene using Musca and Calliphora yp promoter enhancer sequences in transgenic Drosophila.

Despite similar functions, the yolk proteins of the higher dipteran flies and the vitellogenins found in other insects are unrelated at the sequence level and have evolved from different genes. Both are selectively endocytosed into the ovary via receptors belonging to the LDLR receptor subfamily. We cloned the Drosophila yp1 gene into an E. coli expression vector and showed that the yolk protein produced by E. coli is taken up into ovaries of both Drosophila melanogaster and the malaria mosquito Anopheles gambiae, which normally uses vitellogenin.

Myosins constitute a superfamily of motor proteins that convert energy from ATP hydrolysis into mechanical movement along the actin filaments. Phylogenetic analysis currently places myosins into 17 classes based on class-specific features of their conserved motor domain. Traditionally, the myosins have been divided into two classes depending on whether they form monomers or dimers. The conventional myosin of muscle and nonmuscle cells forms class II myosins. They are complex molecules of four light chains bound to two heavy chains that form bipolar filaments via interactions between their coiled-coil tails (type II). Class I myosins are smaller monomeric myosins referred to as unconventional myosins. Now, at least 15 other classes of unconventional myosins are known. How many myosins are needed to ensure the proper development and function of eukaryotic organisms? Thus far, three types of myosins were found in budding yeast, six in the nematode Caenorhabditis elegans, and at least 12 in human. Here, we report on the identification and classification of Drosophila melanogaster myosins. Analysis of the Drosophila genome sequence identified 13 myosin genes. Phylogenetic analysis based on the sequence comparison of the myosin motor domains, as well as the presence of the class-specific domains, suggests that Drosophila myosins can be divided into nine major classes. Myosins belonging to previously described classes I, II, III, V, VI, and VII are present. Molecular and phylogenetic analysis indicates that the fruitfly genome contains at least five new myosins. Three of them fall into previously described myosin classes I, VII, and XV. Another myosin is a homolog of the mouse and human PDZ-containing myosins, forming the recently defined class XVIII myosins. PDZ domains are named after the postsynaptic density, disc-large, ZO-1 proteins in which they were first described. The fifth myosin shows a unique domain composition and a low homology to any of the existing classes. We propose that this is classified when similar myosins are identified in other species.

The loco gene encodes members of a family of RGS proteins responsible for the negative regulation of G-protein signalling. At least two transcripts of loco are expressed in oogenesis, loco-c2 is observed in the anterior-dorsal follicle cells and is downstream of the epidermal growth factor receptor signalling pathway, initiated in the oocyte. loco-c3 is a new transcript of loco, which is expressed in the nurse cells from stage 6 onwards. Analysis of newly generated mutants and antisense technology enabled us to establish that disrupting loco in follicle cells results in ventralized eggs, while disrupting loco in nurse cells results in short eggs, due to defective dumping of the nurse cell cytoplasm into the oocyte.

The Drosophila gene Dstpk61 encodes a serine threonine protein kinase homologous to human phosphoinositide-dependent protein kinase (PDK1), and also has homologues in S. cerevisiae, S. pombe, C. elegans, A. thaliana, mouse, and sheep. Where its function has been investigated, this kinase is thought to be involved in regulating cell growth and survival in response to extracellular signals such as insulin and growth factors. In Drosophila it produces multiple transcripts, some of which appear to be sex-specific. In addition to the five Dstpk61 cDNAs we have described previously we report the existence of a further 18 expressed sequence tag (EST) cDNAs, three of which we have fully sequenced. We conclude that Dstpk61 is a complex locus that utilises a combination of alternative promoters, alternative splice sites and alternative polyadenylation sites to produce a vast array of different transcripts. These cDNAs encode at least four different DSTPK61 protein isoforms with variant N-termini. In this paper, we discuss the possible functions of the distinct Dstpk61 transcripts and how they might be differentially regulated. We also discuss the roles that DSTPK61 protein isoforms might play in relation to the protein domains they contain and their potential targets in the cell. Finally, we report the putative structure of the human PDK1 gene based on computer comparisons of available mRNA and genomic sequences. The value of using sequence data from other species for experimental design in mammalian systems is discussed.

The Drosophila melanogaster staufen gene encodes an RNA binding protein (Dm Stau) required for the localization and translational repression of mRNAs within the Drosophila oocyte. In mammals translational repression is important for normal spermatogenesis in males and storage of mRNAs in the oocytes of females. In the present study we identified two mouse cDNA expressed sequence tags (ESTs), encoding proteins with significant homology to Dm Stau and used these firstly to screen a mouse kidney cDNA library and secondly to determine whether staufen mRNAs are expressed in the ovaries and testes of mice and rats. Sequence analysis of the cDNAs revealed that they originated from two different genes. Using Northern blots of RNAs from kidneys, ovaries and testes, both cDNAs hybridized to mRNA species of approximately 3 kb in all three tissues. On sections of mouse ovaries, staufen mRNA was localized specifically to oocytes. On sections of mouse testes, staufen mRNA was expressed in spermatocytes found in seminiferous tubules at stages VI-XII of the spermatogenic cycle. In conclusion, we have shown that the mammalian homologues of Dm stau are expressed in germ cells in both male and female mice, consistent with a role for these RNA binding proteins in mammalian gametogenesis.

Many genetic cascades are conserved in evolution, yet they trigger different responses and hence determine different cell fates at specific times and positions in development. At stage 10 of oogenesis, mirror is expressed in anterior-dorsal follicle cells, and we show that this is dependent upon the Gurken signal from the oocyte. The fringe gene is expressed in a complementary pattern in posterior-ventral follicle cells at the same stage. Ectopic expression of mirror represses fringe expression, thus linking the epidermal growth factor receptor (EGFR) signalling pathway to the Fringe signalling pathway via Mirror. The EGFR pathway also triggers the cascade that leads to dorsal-ventral axis determination in the embryo. We used twist as an embryonic marker for ventral cells. Ectopic expression of mirror in the follicle cells during oogenesis ultimately represses twist expression in the embryo, and leads to similar phenotypes to the ectopic expression of the activated form of EGFR. Thus, mirror also controls the Toll signalling pathway, leading to Dorsal nuclear transport. In summary, we show that the Mirror homeodomain protein provides a link that coordinates the Gurken/EGFR signalling pathway (initiated in the oocyte) with the Fringe/Notch/Delta pathway (in follicle cells). This coordination is required for epithelial morphogenesis, and for producing the signal in ventral follicle cells that determines the dorsal/ventral axis of the embryo.

We have isolated and sequenced a cDNA encoding a predicted 524 amino acid protein from a Drosophila melanogaster ovarian library. Sequence comparisons suggest that this protein encodes a sodium-dependent inorganic phosphate co-transporter similar to a sequence isolated from a rat brain library. In situ hybridisation to messenger RNA in ovaries shows strong expression in germarium at stage 2 of oogenesis. Expression is then weak in follicle cells until stage 10, when high transcript levels are seen in the nurse cells and transferred to the oocyte. This presumably reflects functions in oogenesis and the production of stored mRNAs for use in embryogenesis.

The Broad-Complex (BR-C) is an early ecdysone response gene that functions during metamorphosis and encodes a family of zinc-finger transcription factors. It is expressed in a dynamic pattern during oogenesis. Its late expression in the lateral-dorsal-anterior follicle cells is related to the morphogenesis of the chorionic appendages. All four zinc-finger isoforms are expressed in oogenesis, which is consistent with the abnormal appendage phenotypes resulting from their ectopic expression. We investigated the mechanism by which the BR-C affects chorion deposition by using BrdU to follow the effects of BR-C misexpression on DNA replication and in situ hybridization to ovarian mRNA to evaluate chorion gene expression. Ectopic BR-C expression leads to prolonged endoreplication and to additional amplification of genes, besides the chorion genes, at other sites in the genome. The pattern of chorion gene expression is not affected along the anterior-posterior axis, but the follicle cells at the anterior of the oocyte fail to migrate correctly in an anterior direction when BR-C is misexpressed. We conclude that the target genes of the BR-C in oogenesis include a protein essential for endoreplication and chorion gene amplification. This may provide a link between steroid hormones and the control of DNA replication during oogenesis.

We report that Drosophila unconventional myosin VI, encoded by Myosin heavy chain at 95F (Mhc95F), is required for both imaginal disc and egg chamber morphogenesis. During oogenesis, Mhc95F is expressed in migrating follicle cells, including the border cells, which migrate between the nurse cells to lie at the anterior of the oocyte; the columnar cells that migrate over the oocyte; the centripetal cells that migrate between the oocyte and nurse cells; and the dorsal-anterior follicle cells, which migrate to secrete the chorionic appendages. Its function during development has been studied using a targeted gene silencing technique, combining the Gal4-UAS targeted expression system and the antisense RNA technique. Antibody staining shows that the expression of myosin 95F is greatly decreased in follicle cells when antisense Mhc95F RNA is expressed. Interfering with expression of Drosophila myosin VI at various developmental stages frequently results in lethality. During metamorphosis it results in adult flies with malformed legs and wings, indicating that myosin VI is essential for imaginal disc morphogenesis. During oogenesis, abnormal follicle cell shapes and aberrant follicle cell migrations are observed when antisense Mhc95F is expressed in follicle cells during stages 9 to 10, suggesting that the Drosophila myosin VI is required for follicle cell epithelial morphogenesis.

We describe the characterization of several transcripts of the Drosophila serine/threonine protein kinase 61 (Dstpk61) gene. Dstpk61 produces at least four transcripts, including a 3.0-kb testis-specific transcript, a 4.5-kb female-specific carcass transcript, a 3.5-kb ovary-specific transcript, and a 4.7-kb non-sex-specific transcript. Two cDNAs, a 4.5-kb cDNA (cDNAB) and a 3.0-kb cDNA (cDNAA), likely to correspond to either the non-specific or the female-specific carcass and the testis-specific transcript, respectively, were fully sequenced and found to encode a novel OPA-repeat-containing serine/threonine-specific protein kinase. cDNAA and cDNAB both contain the entire ORF that encodes this predicted protein, but differ in the untranslated regions. The cDNAs contain translational control elements which are found in transcripts under male germline-specific translational control, and doublesex-like 13-nucleotide repeat elements, which are required for transformer/transformer-2-mediated splicing of the female doublesex transcript. The complex tissue and sex-specific transcripts, differing in the untranslated regions which are likely to be crucial in translational control, suggest that this kinase may have both general and sex-specific functions. The protein is homologous to human 3-phosphoinositide dependent protein kinase, which is involved in transduction of insulin signalling.

In many sexually mature insects egg production and oviposition are tightly coupled to copulation. Sex-Peptide is a 36-amino-acid peptide synthesized in the accessory glands ofDrosophila melanogastermales and transferred to the female during copulation. Sex-Peptide stimulates vitellogenic oocyte progression through a putative control point at about stage 9 of oogenesis. Here we show that application of the juvenile hormone analogue methoprene mimics the Sex-Peptide-mediated stimulation of vitellogenic oocyte progression in sexually mature virgin females. Apoptosis is induced by 20-hydroxyecdysone in nurse cells of stage 9 egg chambers at physiological concentrations (10−7M). 20-Hydroxyecdysone thus acts as an antagonist of early vitellogenic oocyte development. Simultaneous application of juvenile hormone analogue, however, protects early vitellogenic oocytes from 20-hydroxyecdysone-induced resorption. These results suggest that the balance of these hormones in the hemolymph regulates whether oocytes will progress through the control point at stage 9 or undergo apoptosis. These data are further supported by a molecular analysis of the regulation of yolk protein synthesis and uptake into the ovary by the two hormones. We conclude that juvenile hormone is a downstream component in the Sex-Peptide response cascade and acts by stimulating vitellogenic oocyte progression and inhibiting apoptosis. Since juvenile hormone analogue does not elicit increased oviposition and reduced receptivity, Sex-Peptide must have an additional, separate effect on these two postmating responses.

Epidermal growth factor receptor (EGFR) signaling pathways are frequently involved in generating cell fate diversity in a number of organisms. During anterior–posterior and dorso–ventral polarity in the Drosophila egg chamber and eggshell, EGFR signaling leads to a number of determinative events in the follicle cell layer. A high level of Gurken signal leads to the expression of argos in dorsal midline cells. Lateral follicle cells, receiving a lower level of Gurken signal, can continue to express the Broad-Complex (BR-C) and differentiate into cells which produce chorionic appendages. Misexpression of argos in mid-oogenesis causes the midline cells to retain expression of BR-C, resulting in a single fused large appendage. Evidence that argos can directly repress Gurken-induced EGFR signaling is seen when premature expression of argos is induced earlier in oogenesis. It represses the Gurken signal at stage 5–6 of oogenesis which determines posterior follicle cells and occasionally leads to eggs with anteriors at both ends. We propose that the Gurken signal at stage 9 of oogenesis induces follicle cells to take on two fates, dorsal midline and lateral, each producing different parts of the eggshell and that argos is one of the key downstream genes required to select between these two fates. Dev. Genet. 25:375–386, 1999. © 1999 Wiley-Liss, Inc.

Class-V myosins are a unique type of myosin motor with roles in intracellular transport. The mouse dilute gene was the first member of this class to be cloned, with mutations resulting in lightening of the coat colour or neurogenic defects leading to early death. Further examples of class-V myosins have been described in yeast, chicken and rat. Here, we report the cloning of the first class-V myosin from Drosophila. We show that expression of this myosin is predominantly in the adult germ line and early embryo and that the transcript is localised in the oocyte during oogenesis. Genetic and in situ hybridisation experiments have determined that this gene is located in the 43C region. We have evidence that it maps to a mutation in this region with an embryonic lethal phenotype.

The yolk protein (yp) genes encode the major nutritional polypeptides deposited in developing oocytes for subsequent utilization during embryogenesis, and represent a highly conserved family of genes in higher Diptera. Originally isolated from Drosophila melanogaster, they are expressed in a temporal-, tissue- and sex-specific manner in all species in which they have been identified. We report here the isolation of cDNAs encoding three independent yolk proteins from the common housefly, Musca domestica. Expression of the three M. domestica yp genes is analysed both by Northern and in-situ hybridization. We discuss in an evolutionary context both the significance of the expression patterns, and regions of apparent polypeptide sequence divergence.

Background: The activation of protein kinase B (PKB, also known as c-Akt) is stimulated by insulin or growth factors and results from its phosphorylation at Thr308 and Ser473. We recently identified a protein kinase, termed PDK1, that phosphorylates PKB at Thr308 only in the presence of lipid vesicles containing phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P 3 ) or phosphatidylinositol 3,4-bisphosphate (PtdIns(3,4)P 2 ). Results: We have cloned and sequenced human PDK1. The 556-residue monomeric enzyme comprises a catalytic domain that is most similar to the PKA, PKB and PKC subfamily of protein kinases and a carboxy-terminal pleckstrin homology (PH) domain. The PDK1 gene is located on human chromosome 16p 13.3 and is expressed ubiquitously in human tissues. Human PDK1 is homologous to the Drosophila protein kinase DSTPK61, which has been implicated in the regulation of sex differentiation, oogenesis and spermatogenesis. Expressed PDK1 and DSTPK61 phosphorylated Thr308 of PKB α only in the presence of PtdIns(3,4,5)P 3 or PtdIns(3,4)P 2 . Overexpression of PDK1 in 293 cells activated PKB α and potentiated the IGF1-induced phosphorylation of PKB α at Thr308. Experiments in which the PH domains of either PDK1 or PKB α were deleted indicated that the binding of PtdIns(3,4,5)P 3 or PtdIns(3,4)P 2 to PKB α is required for phosphorylation and activation by PDK1. IGF1 stimulation of 293 cells did not affect the activity or phosphorylation of PDK1. Conclusions: PDK1 is likely to mediate the activation of PKB by insulin or growth factors. DSTPK61 is a Drosophila homologue of PDK1. The effect of PtdIns(3,4,5)P 3 /PtdIns(3,4)P 2 in the activation of PKB α is at least partly substrate directed.

We have investigated the conservation of regulatory elements for sex- and tissue-specific gene expression in three dipteran species, Drosophila melanogaster, Musca domestica and Calliphora erythrocephala, using the yolk protein (yp) genes. Yolk proteins of the fruitfly, medfly, housefly and blowfly are very well conserved both in their sequence and their expression in ovarian follicle cells and in fat bodies of adult females. Furthermore, yp regulation by both hormonal and nutritional factors shows similar features in all four species. To study conservation of yp regulation in dipteran insects, we tested 5' flanking regions from one Musca yp gene and one Calliphora yp gene for enhancer functions in D. melanogaster. Two fragments of 823 and 1046 bp isolated from Musca and Calliphora yp genes, respectively, are able to direct correct expression of a reporter gene in the ovarian follicle cells of transformed Drosophila at specific stages during oogenesis. Surprisingly, these enhancers do not confer sex-specific reporter gene expression in the fat body, as expression was found in both sexes of the transformed flies. None-the-less by in vitro DNA/protein interaction assays, a 284-bp DNA region from the Musca yp enhancer was able to bind the Drosophila DOUBLESEX (DSX) protein, which in D.melanogaster confers sex-specific expression of yp. We speculate that the sex-determining pathway is not directly involved in yp regulation in Musca or Calliphora adult females, but depends instead on hormonal controls to achieve sex-specific expression of yp genes in the adult.

genes which are expressed in the adult female fat body are Many eukaryotic genes generate alternately spliced trantargets of the DSX protein (Burtis et al., 1991) and their yolk scripts which can produce different proteins or which have protein products are essential for oocyte development. altered translational controls. One of the most direct demHowever, the use of alternate splicing in sexual developonstrations that alternately spliced forms of transcripts lead ment in Drosophila is not limited to dsx. Alternate splicing to different developmental consequences lies within the sex of dsx transcripts is controlled by the products of the transdetermination pathway of Drosophila. The doublesex (dsx) former (tra) and transformer-2 (tra-2) genes (Nagoshi et al., gene at the end of this pathway in somatic cells encodes 1988). tra RNA is also alternately spliced, in this case with two differently spliced transcripts, one specific for males the dramatic consequence that in males no functional proand one specific for females (Burtis and Baker, 1989). These tein product is made (Butler et al., 1986; McKeown et al., encode proteins with a common DNA binding region and 1987), whereas in females an RNA binding protein is proa sexually unique carboxy terminus; DSX and DSX act as duced which interacts with the tra-2-encoded RNA binding transcription factors and have opposing activities. The main protein (Belote and Baker, 1982), directing the female-spedevelopmental consequences are the repression of a set of cific splicing of dsx. It seems likely that tra and tra-2 have downstream female-specific differentiation genes by DSX other targets in addition to dsx that are important for sexual in males and the repression of certain male characteristics development, since several aspects of sexual dimorphism by DSX in females (for reviews see Slee and Bownes, 1990; depend upon the tra/tra-2 genes but are independent of dsx Steinmann-Zwicky et al., 1990; Ryner and Swain, 1995). (Taylor et al., 1994). This includes courtship behaviour; the Many of the sexual differences between male and female development of abdominal cells, which produce a female Drosophila are controlled by the two alternate products of pheromone; and the correct innervation of nerves needed the dsx gene (Burtis and Baker, 1989). They direct both the for the development of a male-specific muscle (Lawrence determination of sex-specific characteristics in the imaginal and Johnston, 1986; Taylor, 1992). cells and the maintenance of determination throughout The female-specific splicing of tra RNA is itself directed subsequent cell divisions. This regulation leads to the final by an alternately spliced gene product. This is encoded by differentiation of male or female genitalia, the differences the Sex-lethal (Sxl) gene that is at the head of the sex-deterin pigmentation patterns in the abdomen of each sex and mination hierarchy (Cline, 1984, 1993). Sxl produces many in other sex-specific bristle patterns, such as the sex comb transcripts, including several specific to female somatic on the first leg of the male. Differences between the sexes cells, that generate a functional RNA binding protein. The in the pattern of nerve cell divisions are also directed by male mRNA from Sxl does not encode a functional protein the two related DSX proteins (Taylor and Truman, 1992), (Bell et al., 1988). The SXL protein is known to direct the as is the selection between the male or female development female-specific splicing of its own RNAs as well as that of

Investigation of an enhancer-trap line exhibiting testis-specific beta-galactosidase expression led to the isolation of the Drosophila gene encoding inosine monophosphate dehydrogenase (IMPD), the rate-limiting enzyme in guanine nucleotide synthesis, which has been implicated in cell cycle control and malignant transformation. Northern and in situ hybridization analysis demonstrated that the gene has a complex expression pattern involving several independently regulated transcripts. Two ubiquitous, but highly ovary enriched, transcripts of 2.5 and 1.9 kb are expressed in the nurse cells and delivered to the oocyte, whilst a 0.9 kb transcript is found exclusively in the testis. The 2.5 kb transcript encodes a 58 kDa protein, which is highly similar in length and sequence to mouse and human IMPDs and is presumably required for GTP synthesis during early embryogenesis. Over-expression of this cDNA in Escherichia coli yielded a product of the predicted size, which was demonstrated to possess IMPD activity in a spectrophotometric assay. The coding capacity of the other transcripts is currently uncertain. We present evidence that IMPD is the product of the raspberry (ras) locus at 9E and the functions of the gene are discussed in relation to the phenotypes of ras mutants.

SummaryInDrosophila, the threeyolk protein(yp) genes are transcribed in a sex-, tissue- and developmentally specific manner, providing an ideal system in which to investigate the factors involved in their regulation. The yolk proteins are synthesized in the fat body of adult females, and in the ovarian follicle cells surrounding the developing oocyte during stages 8–10 of oogenesis. We report here an analysis of theyolk protein 3(yp3) gene and its flanking sequences by means of P-element mediated germ-line transformation and demonstrate that a 747 bp promoter region is sufficient to direct sex-specific expression in the female fat body and both the temporal- and cell-type-specificity of expression during oogenesis. Two elements that independently governyp3transcription in these tissues have been separated and no other sequences in the upstream, downstream or coding regions have been identified that are autonomously involved inyp3expression.

Interactions between germ cells and somatic cells are important at several stages of Drosophila development. The types of interactions that will be discussed include: (1) molecules physically transferred from one cell to another; (2) long range interactions by hormones; and (3) local interactions between germ cells and somatic cells when they are in close proximity. These interactions have been mostly characterized during oogenesis.

During vitellogenesis the 3 major yolk proteins of Drosophila are synthesized and transported from the tissues which produce them to the oocyte. Here they are endocytosed by the oocyte and stored in yolk granules for utilization during embryogenesis. In this paper the regulation of vitellogenesis is discussed, including the tissue-specific and hormonal regulation of the yolk protein genes; transport of yolk proteins to the oocyte; storage of the proteins; and their possible functions during embryogenesis.

The three yolk protein genes (yp) of Drosophila melanogaster are transcribed in a sex- and tissue-limited fashion. We have searched for cis-regulatory sequences in regions flanking yp1 and yp2 to identify the elements that confer female-specific expression in the fat body. One such 127 bp element has previously been identified in this region. We show here the existence of two additional regions which confer female fat body-specific expression on an Adh reporter gene and on the native yp2 gene, respectively. This suggests some redundancy in the regulation of expression of the yp genes. Computer searches for putative binding sites for the DSX protein, which regulates sex-specific expression of the yp genes, revealed several such sites in our constructs. However, the significance of these is unclear since many such sites also occur in genes which one would not expect to be regulated in a sex-specific manner (e.g. Adh, Actin 5C). We suggest that DSX acts in concert with other proteins to mediate sex- and tissue-specific expression of the yp genes.

An abundant ovarian cDNA from Drosophila melanogaster has been cloned and sequenced. The predicted protein sequence is similar to that of the ribosomal protein 1024 of Dictyostelium discoideum, the 40S ribosomal protein ys11 of Saccharomyces cerevisiae and a 22 kd protein from Trypanosoma brucei. It seems, therefore, that the Drosophila cDNA also encodes a ribosomal protein. Transcripts are found at all stages of the life cycle but are especially abundant in the ovary, suggesting that this mRNA is maternally stored for utilization in embryogenesis to enable the rapid production of ribosomal proteins and assembly of ribosomes.

The three yolk proteins (YP1, YP2 and YP3) of Drosophila melanogaster are synthesized in two tissues of the adult female, the fat body and ovarian follicle cells. The YPs are selectively accumulated in the oocyte to provide nutrients for embryogenesis. We describe a female-sterile mutant, fs(1) A1526, which lacks YP3 in the haemolymph. The female sterility mutation mapped some distance away from the yp3 gene on the X chromosome and we were able to separate the YP3 defect from the female sterility by recombination, thus producing a fertile line of flies having no YP3 in the eggs. This shows that YP3 is not essential for embryogenesis. The mutant line is to be known as YP3s1. Investigation of yp3 transcription in the mutant females revealed that the gene is transcribed but yp3s1 mRNA levels are reduced relative to wild type. Transcription of the mutant yp3 gene can be induced in males by ecdysone. Investigation of the yolk proteins in YP3s1 females suggested that the YP3s1 polypeptide is synthesized in the fat body but not secreted. The mutant YP3 protein shows an increase in apparent molecular weight of approximately 1 kDa. The mutant yp3 gene was cloned and the DNA sequence determined. The sequence differences between the mutant and wild-type genes include an amino acid substitution in the leader sequence. We suggest that this may be responsible for the failure of YP3 secretion in the mutant YP3s1, and speculate on the cause of the reduction seen in the steady-state level of yp3 mRNA.

Background The loco gene encodes several different isoforms of a regulator of G-protein signalling. These different isoforms of LOCO are part of a pathway enabling cells to respond to external signals. LOCO is known to be required at various developmental stages including neuroblast division, glial cell formation and oogenesis. Less is known about LOCO and its involvement in male development therefore to gain further insight into the role of LOCO in development we carried out a genetic screen and analysed males with reduced fertility. Results We identified a number of lethal loco mutants and four semi-lethal lines, which generate males with reduced fertility. We have identified a fifth loco transcript and show that it is differentially expressed in developing pupae. We have characterised the expression pattern of all loco transcripts during pupal development in the adult testes, both in wild type and loco mutant strains. In addition we also show that there are various G-protein α subunits expressed in the testis all of which may be potential binding partners of LOCO. Conclusion We propose that the male sterility in the new loco mutants result from a failure of accurate morphogenesis of the adult reproductive system during metamorphosis, we propose that this is due to a loss of expression of loco c3. Thus, we conclude that specific isoforms of loco are required for the differentiation of the male gonad and genital disc.

The three genes, located in the X chromosome, which code for the three yolk polypeptides (YPs) of Drosophila melanogaster are expressed in the fat bodies and ovarian follicle cells of adult females. Both juvenile hormone and ecdysone are involved in regulating their expression. The yolk protein genes (YP genes), normally not transcribed in males, become expressed when males are injected with or fed 20-hydroxyecdysone. Superimposed on this hormonal regime is a sex determination mechanism which ensures that normally YP gene expression is female-specific. There are a series of autosomal genes in D. melanogaster which ensure that individual cells follow a male or female developmental pathway. When they are mutant, flies with two X chromosomes, which would normally be female, can become intersexual in phenotype or transformed into sterile males and flies with one X and one Y chromosome can become intersexual. It has been found that the YPs are part of the set of female characteristics controlled by these sex genes. The YP genes are expressed in female and intersexual flies, regardless of the X chromosome constitution, but not in males or pseudomales. Transcript levels of yolk proteins have been measured in female and intersexual flies by hybridization to cloned YP DNA sequences. It is suggested that transcription of the YP genes is under the cell-autonomous control of the sex genes and that the sex genes do not exert their effect by modulating the levels of steroid hormones in adults.