Drosophila Immunity: Analysis of Larval Hemocytes by P-Element-Mediated Enhancer Trap

Our aim was to identify new genes involved in the cellular aspects of defense mechanisms of Drosophila, as well as in melanotic tumor formation processes that are linked to blood cell disregulation. We have screened 1341 enhancer detector fly lines for expression of the lacZ reporter gene in larval hemocytes at the end of the third instar. We have selected 21 lines in which we observed a reproducible lacZ expression in blood cells. These lines were classified according to the subsets of hemocytes in which lacZ was expressed, and we identified five lines that can be used as lamellocyte markers. Three lines were selected for further analysis. The first exhibited strong lacZ expression in all lamellocytes. The second expressed lacZ in plasmatocytes and lamellocytes, and exhibited a melanotic tumor phenotype in larvae homozygous for the insertion. A third line showed a striking insertion-linked phenotype of melanized lymph glands (the hematopoietic organ), which resulted in the total absence of circulating hemocytes in the mutant larvae. We anticipate that this mutation, which we named domino, will prove a useful tool in the analysis of the role of hemocytes during the various aspects of immune response and melanotic tumor formation.     

Regulator gene of phenyl oxidase activity in Drosophila melanogaster

A recessive lethal mutation l(2)hemo causing the occurrence of melanotic tumors in homozygous Drosophila larvae was found. The study of phenoloxidase (PO) activity revealed that the number of hemocytes with PO activity in homozygous larvae was significantly reduced (0.4 +/- 0.24%), compared to wild-type larvae (6.3 +/- 0.5%). On injury followed by injection with bacterial cells, the formation of melanotic thrombus did not occurred and hemocytes with PO activity were not recorded in homozygotes of line P103. Suppression of the activity of PO isozymes A1 and A3 was detected by means of electrophoretic analysis of homozygotes. According to gene mapping data, the localization of this mutation did not match any structural gene for known PO forms and is therefore related to a regulatory gene controlling the activity of the immune system of Drosophila.     

Activation of a Drosophila Janus kinase (JAK) causes hematopoietic neoplasia and developmental defects.

In mammals, many cytokines and growth factors stimulate members of the Janus kinase (JAK) family to transduce signals for the proliferation and differentiation of various cell types, particularly in hematopoietic lineages. Mutations in the Drosophila hopscotch (hop) gene, which encodes a JAK, also cause proliferative defects. Loss-of-function alleles result in lethality and underproliferation of diploid tissues of the larva. A dominant gain-of-function allele, Tumorous-lethal (hopTum-l), leads to formation of melanotic tumors and hypertrophy of the larval lymph glands, the hematopoietic organs. We show that a single amino acid change in Hop is associated with the hopTum-l mutation. Overexpression of either wild-type hop or hopTum-l in the larval lymph glands causes melanotic tumors and lymph gland hypertrophy indistinguishable from the original hopTum-l mutation. In addition, overexpression of Hop in other tissues of the larva leads to pattern defects in the adult or to lethality. Finally, overexpression of either hop or hopTum-l in Drosophila cell culture results in tyrosine phosphorylation of Hop protein. However, overexpression of hopTum-l results in greater phosphorylation than overexpression of the wild-type. We conclude that hopTum-l encodes a hyperactive Hop kinase and that overactivity of Hop in lymph glands causes malignant neoplasia of Drosophila blood cells.     

SNF4Agamma, the Drosophila AMPK gamma subunit is required for regulation of developmental and stress-induced autophagy

In holometabolous insects including Drosophila melanogaster a wave of autophagy triggered by 20-hydroxyecdysone is observed in the larval tissues during the third larval stage of metamorphosis. We used this model system to study the genetic regulation of autophagy. We performed a genetic screen to select P-element insertions that affect autophagy in the larval fat body. Light and electron microscopy of one of the isolated mutants (l(3)S005042) revealed the absence of autophagic vesicles in their fat body cells during the third larval stage. We show that formation of autophagic vesicles cannot be induced by 20-hydroxyecdysone in the tissues of mutant flies and represent evidence demonstrating that the failure to form autophagic vesicles is due to the insertion of a P-element into the gene coding SNF4Agamma, the Drosophila homologue of the AMPK (AMP-activated protein kinase) gamma subunit. The ability to form autophagic vesicles (wild-type phenotype) can be restored by remobilization of the P-element in the mutant. Silencing of SNF4Agamma by RNAi suppresses autophagic vesicle formation in wild-type flies. We raised an antibody against SNF4Agamma and showed that this gene product is constitutively present in the wild-type larval tissues during postembryonal development. SNF4Agamma is nearly absent from the cells of homozygous mutants. SNF4Agamma translocates into the nuclei of fat body cells at the onset of the wandering stage concurrently with the beginning of the autophagic process. Our results demonstrate that SNF4Agamma has an essential role in the regulation of autophagy in Drosophila larval fat body cells.     

A mosaic analysis in Drosophila fat body cells of the control of antimicrobial peptide genes by the Rel proteins Dorsal and DIF.

Expression of the gene encoding the antifungal peptide Drosomycin in Drosophila adults is controlled by the Toll signaling pathway. The Rel proteins Dorsal and DIF (Dorsal-related immunity factor) are possible candidates for the transactivating protein in the Toll pathway that directly regulates the drosomycin gene. We have examined the requirement of Dorsal and DIF for drosomycin expression in larval fat body cells, the predominant immune-responsive tissue, using the yeast site-specific flp/FRT recombination system to generate cell clones homozygous for a deficiency uncovering both the dorsal and the dif genes. Here we show that in the absence of both genes, the immune-inducibility of drosomycin is lost but can be rescued by overexpression of either dorsal or dif under the control of a heat-shock promoter. This result suggests a functional redundancy between both Rel proteins in the control of drosomycin gene expression in the larvae of Drosophila. Interestingly, the gene encoding the antibacterial peptide Diptericin remains fully inducible in the absence of the dorsal and dif genes. Finally, we have used fat body cell clones homozygous for various mutations to show that a linear activation cascade Spaetzle--> Toll-->Cactus-->Dorsal/DIF leads to the induction of the drosomycin gene in larval fat body cells.     

Dark is a Drosophila homologue of Apaf-1/CED-4 and functions in an evolutionarily conserved death pathway

Here we identify a new gene, dark, which encodes a Drosophila homologue of mammalian Apaf-1 and Caenorhabditis elegans CED-4, cell-death proteins. Like Apaf-1, but in contrast to CED-4, Dark contains a carboxy-terminal WD-repeat domain necessary for interactions with the mitochondrial protein cytochrome c. Dark selectively associates with another protein involved in apoptosis, the fly apical caspase, Dredd. Dark-induced cell killing is suppressed by caspase-inhibitory peptides and by a dominant-negative mutant Dredd protein, and enhanced by removal of the WD domain. Loss-of-function mutations in dark attenuate programmed cell deaths during development, causing hyperplasia of the central nervous system, and other abnormalities including ectopic melanotic tumours and defective wings. Moreover, ectopic cell killing by the Drosophila cell-death activators, Reaper, Grim and Hid, is substantially suppressed in dark mutants. These findings establish dark as an important apoptosis effector in Drosophila and raise profound evolutionary considerations concerning the relationship between mitochondrial components and the apoptosis-promoting machinery.     

The PIKE Homolog Centaurin gamma Regulates Developmental Timing in Drosophila

Phosphoinositide-3-kinase enhancer (PIKE) proteins encoded by the PIKE/CENTG1 gene are members of the gamma subgroup of the Centaurin superfamily of small GTPases. They are characterized by their chimeric protein domain architecture consisting of a pleckstrin homology (PH) domain, a GTPase-activating (GAP) domain, Ankyrin repeats as well as an intrinsic GTPase domain. In mammals, three PIKE isoforms with variations in protein structure and subcellular localization are encoded by the PIKE locus. PIKE inactivation in mice results in a broad range of defects, including neuronal cell death during brain development and misregulation of mammary gland development. PIKE -/- mutant mice are smaller, contain less white adipose tissue, and show insulin resistance due to misregulation of AMP-activated protein kinase (AMPK) and insulin receptor/Akt signaling. here, we have studied the role of PIKE proteins in metabolic regulation in the fly. We show that the Drosophila PIKE homolog, ceng1A, encodes functional GTPases whose internal GAP domains catalyze their GTPase activity. To elucidate the biological function of ceng1A in flies, we introduced a deletion in the ceng1A gene by homologous recombination that removes all predicted functional PIKE domains. We found that homozygous ceng1A mutant animals survive to adulthood. In contrast to PIKE -/- mouse mutants, genetic ablation of Drosophila ceng1A does not result in growth defects or weight reduction. Although metabolic pathways such as insulin signaling, sensitivity towards starvation and mobilization of lipids under high fed conditions are not perturbed in ceng1A mutants, homozygous ceng1A mutants show a prolonged development in second instar larval stage, leading to a late onset of pupariation. In line with these results we found that expression of ecdysone inducible genes is reduced in ceng1A mutants. Together, we propose a novel role for Drosophila Ceng1A in regulating ecdysone signaling-dependent second to third instar larval transition.     

A Regulatory Gene for Phenoloxidase Activity in Drosophila melanogaster

A recessive lethal mutationl(2)hemocausing the occurrence of melanotic tumors in homozygous Drosophilalarvae was found. The study of phenoloxidase (PO) activity revealed that the number of hemocytes with PO activity in homozygous larvae was significantly reduced (0.4 ± 0.24%), compared to wild-type larvae (6.3 ± 0.5%). On injury followed by injection with bacterial cells, the formation of melanotic thrombus did not occurred and hemocytes with PO activity were not recorded in homozygotes of line P103. Suppression of the activity of PO isozymes A₁and A₃was detected by means of electrophoretic analysis of homozygotes. According to gene mapping data, the localization of this mutation did not match any structural gene for known PO forms and is therefore related to a regulatory gene controlling the activity of the immune system ofDrosophila.     

Mutations in the Drosophila mitochondrial tRNA amidotransferase, bene/gatA, cause growth defects in mitotic and endoreplicating tissues

Rapid larval growth is essential in the development of most metazoans. In this article, we show that bene, a gene previously identified on the basis of its oogenesis defects, is also required for larval growth and viability. We show that all bene alleles disrupt gatA, which encodes the Drosophila homolog of glutamyl-tRNA(Gln) amidotransferase subunit A (GatA). bene alleles are now referred to as gatA. GatA proteins are highly conserved throughout eukaryotes and many prokaryotes. These enzymes are required for proper translation of the proteins encoded by the mitochondrial genome and by many eubacterial genomes. Mitotic and endoreplicating tissues in Drosophila gatA loss-of-function mutants grow slowly and never achieve wild-type size, and gatA larvae die before pupariation. gatA mutant eye clones exhibit growth and differentiation defects, indicating that gatA expression is required cell autonomously for normal growth. The gatA gene is widely expressed in mitotic and endoreplicating tissues.     

The Chloroplast Function Database: a large‐scale collection of Arabidopsis Ds/Spm‐ or T‐DNA‐tagged homozygous lines for nuclear‐encoded chloroplast proteins,and their systematic phenotype analysis

A majority of the proteins of the chloroplast are encoded by the nuclear genome, and are post‐translationally targeted to the chloroplast. From databases of tagged insertion lines at international seed stock centers and our own stock, we selected 3246 Ds/Spm (dissociator/suppressor–mutator) transposon‐ or T‐DNA‐tagged Arabidopsis lines for genes encoding 1369 chloroplast proteins (about 66% of the 2090 predicted chloroplast proteins) in which insertions disrupt the protein‐coding regions. We systematically observed 3‐week‐old seedlings grown on agar plates, identified mutants with abnormal phenotypes and collected homozygous lines with wild‐type phenotypes. We also identified insertion lines for which no homozygous plants were obtained. To date, we have identified 111 lines with reproducible seedling phenotypes, 122 lines for which we could not obtain homozygotes and 1290 homozygous lines without a visible phenotype. The Chloroplast Function Database presents the molecular and phenotypic information obtained from this resource. The database provides tools for searching for mutant lines using Arabidopsis Genome Initiative (AGI) locus numbers, tagged line numbers and phenotypes, and provides rapid access to detailed information on the tagged line resources. Moreover, our collection of insertion homozygotes provides a powerful tool to accelerate the functional analysis of nuclear‐encoded chloroplast proteins in Arabidopsis. The Chloroplast Function Database is freely available at http://rarge.psc.riken.jp/chloroplast/ . The homozygous lines generated in this project are also available from the various Arabidopsis stock centers. We have donated the insertion homozygotes to their originating seed stock centers.     

Characterization of the molecular basis of the Drosophila mutations in carboxypeptidase D. Effect on enzyme activity and expression

Carboxypeptidase D (CPD) functions in the processing of proteins and peptides in the secretory pathway. Drosophila CPD is encoded by the silver gene (svr), which is differentially spliced to produce long transmembrane protein forms with three metallocarboxypeptidase (CP)-like domains and short soluble forms with a single CP domain. Many svr mutants have been reported, but the precise molecular defects have not been previously determined. In the present study, three mutant lines were characterized. svr (PG33) mutants do not survive past the early larval stage. These mutants have a P-element insertion within exon 1B upstream of the initiation ATG, which greatly reduces mRNA levels of all forms of CPD. Both svr (1) and svr (poi) mutants are viable, with a silvery body color and pointed wings. The wing shape is generally similar between these two mutants, although svr (poi) mutants have smaller wings. The svr (1) gene has a three-nucleotide deletion in exon 6, removing a leucine in a region of the protein predicted to function as a folding domain for the second CP-like domain. svr (poi) has a 1072-bp duplication of the gene that introduces a stop codon into the open reading frame, causing the truncation of the protein in the middle of the second CP-like domain. Both deletions eliminate enzyme activity of the second CP-like domain and appear to cause the misfolding of the protein. This greatly reduces the levels of the long forms of CPD protein but do not affect the levels of the short forms. Taken together, these findings suggest that lethal and viable svr alleles differ in which protein forms are affected. Flies that retain the short form are viable, whereas flies that are missing all forms of CPD do not survive past the early larval stages.     

COP9 signalosome subunits 4 and 5 regulate multiple pleiotropic pathways in Drosophila melanogaster

The COP9 signalosome (CSN) is an essential eight-subunit repressor of light-regulated development in ARABIDOPSIS: This complex has also been identified in animals, though its developmental role remains obscure. CSN subunits have been implicated in various cellular processes, suggesting a possible role for the CSN as an integrator of multiple signaling pathways. In order to elucidate the function of the CSN in animals, a Drosophila model system has previously been established. Gel-filtration analysis with antibodies against CSN subunits 4, 5 and 7 revealed that these proteins act as a complex in Drosophila that is similar in size to the plant and mammalian complexes. Null mutations in either one of two subunits, CSN4 or CSN5, are larval lethal. Successful embryogenesis appears to be a consequence of maternal contribution of the complex. Biochemical analysis indicates that the different subunits are found in both CSN-dependent and CSN-independent forms, and that these forms are differentially affected by the mutations. Phenotypic characterization of these two mutants indicates that they show both shared and unique phenotypes, which suggest specific roles for each subunit. Both mutants have defective oocyte and embryo patterning, and defects in response to DNA damage, while csn5 mutants develop melanotic tumors and csn4 mutants have phenotypes reminiscent of defects in ecdysone signaling.     

Damaged DNA binding protein 1 in Drosophila defense reactions

We have focused attention on functions of Drosophila damaged DNA binding protein 1 (D-DDB1) in Drosophila hematopoiesis and previously reported that its whole body dsRNA over-expression using a GAL4-UAS targeted expression system results in melanotic tumors and complete lethality. Since the lesions appear to arise as a normal and heritable response to abnormal development, forming groups of cells that are recognized by the immune system and encapsulated in melanized cuticle, D-DDB1 appears to be an essential development-associated factor in Drosophila. To probe the possibility that it contributes to hemocyte development, we used a collagen promoter-GAL4 strain to over-express dsRNA of D-DDB1 in Drosophila hemocytes. The D-DDB1 gene silencing caused melanotic tumors and mortality at the end of larval development. Similarly, it interfered with melanization and synthesis of antimicrobial peptides. Transgenic flies with D-DDB1 gene silencing were found to accumulate abnormal large blood cells, reminiscent of human leukemia, suggesting that D-DDB1 has functions in hemocyte development.     

The lethal prune/Killer-of-prune interaction of Drosophila causes a syndrome resembling human neurofibromatosis (NF1).

The eye color mutant prune (pn) of Drosophila melanogaster shows a lethal interaction with the Killer-of-prune (K-pn) allele of the abnormal wing disc (awd) locus. The awd gene is the Drosophila homologue of the mammalian tumor metastasis gene nm23, and it has been postulated that pn encodes a protein with similarity to a GAP, a GTPase-activating protein. Such GAPs potentially control Ras-like proteins, which are important molecular switches. However, there is only a low sequence homology with the genes for human GAP and neurofibromatosis (NF1), and with yeast IRA1 and IRA2, and there is no evidence for the functional significance of this homologization. I now show that pn mutations lower the concentrations of larval pteridines, and that this phenomenon is enhanced by two orders of magnitude by the lethal interaction between pn and awdK-pn. These gradual effects on the pteridin concentrations indicate a corresponding drop of the pools of free GTP, and favor the involvement of GTP-binding proteins. In addition, cytology reveals a considerable hypertrophy of the neuroglia and the perineurium of the larval brain. Furthermore, the lymph glands of the larvae are highly abnormal and form melanotic (pseudo)tumors upon ageing of the larvae. These pseudotumors consist predominantly of lamellocytes which are part of the cellular defence system of Drosophila. These observations most likely indicate hyperactivity of a Ras-like protein which becomes manifest in cell types equivalent to the cell types affected by human neurofibromatosis (NF1). Thus, it is very suggestive to regard the synthetic lethal system prune/Killer-of-prune as the Drosophila model for human neurofibromatosis.     

amontillado,the Drosophila homolog of the prohormone processing protease PC2, is required during embryogenesis and early larval development

Biosynthesis of most peptide hormones and neuropeptides requires proteolytic excision of the active peptide from inactive proprotein precursors, an activity carried out by subtilisin-like proprotein convertases (SPCs) in constitutive or regulated secretory pathways. The Drosophila amontillado (amon) gene encodes a homolog of the mammalian PC2 protein, an SPC that functions in the regulated secretory pathway in neuroendocrine tissues. We have identified amon mutants by isolating ethylmethanesulfonate (EMS)-induced lethal and visible mutations that define two complementation groups in the amon interval at 97D1 of the third chromosome. DNA sequencing identified the amon complementation group and the DNA sequence change for each of the nine amon alleles isolated. amon mutants display partial embryonic lethality, are defective in larval growth, and arrest during the first to second instar larval molt. Mutant larvae can be rescued by heat-shock-induced expression of the amon protein. Rescued larvae arrest at the subsequent larval molt, suggesting that amon is also required for the second to third instar larval molt. Our data indicate that the amon proprotein convertase is required during embryogenesis and larval development in Drosophila and support the hypothesis that AMON acts to proteolytically process peptide hormones that regulate hatching, larval growth, and larval ecdysis.     

Mesorhizobium loti increases root-specific expression of a calcium-binding protein homologue identified by promoter tagging in Lotus japonicus

A promoter tagging program in the legume Lotus japonicus was initiated to identify plant genes involved in the nitrogen-fixing symbiosis between legumes and rhizobia. Seven transformed plant lines expressing the promoterless reporter gene uidA (beta-glucuronidase; GUS) specifically in roots and/or nodules were identified. Four of these expressed GUS in the roots only after inoculation with nodule-forming Mesorhizobium loti. In one line (T90), GUS activity was found in the root epidermis, including root hairs. During seedling growth, GUS expression gradually became focused in developing nodules and disappeared from root tissue. No GUS activity was detected when a non-nodulating mutant of M. loti was used to inoculate the plants. The T-DNA insertion in this plant line was located 1.3 kb upstream of a putative coding sequence with strong homology to calcium-binding proteins. Four motifs were identified, which were very similar to the "EF hands" in calmodulin-related proteins, each binding one Ca2+. We have named the gene LjCbp1 (calcium-binding protein). Northern (RNA) analyses showed that this gene is expressed specifically in roots of L. japonicus. Expression was reduced in roots inoculated with non-nodulating M. loti mutants and in progeny homozygous for the T-DNA insertion, suggesting a link between the T-DNA insertion and this gene.