Growth, metastasis, and invasiveness of Drosophila tumors caused by mutations in specific tumor suppressor genes

 More than 50 genes have been identified in Drosophila by loss-of-function mutations that lead to overgrowth of specific tissues. Loss-of-function mutations in the lethal giant larvae, discs large, or brain tumor genes cause neoplastic overgrowth of larval brains and imaginal discs. In the present study, the growth and metastatic potential of tumors resulting from mutations in these genes were quantified. Overgrown brains and imaginal discs were transplanted into adults and β-galactosidase accumulation was used as a marker to identify donor cells. Mutations in these three genes generated tumors with similar metastatic patterns. For brain tumors, the metastatic index (a measure we defined as the fraction of hosts that acquired secondary tumors normalized for the amount of primary tumor growth) of each of the three mutants was similar. Analysis of cell proliferation in mutant brains suggests that the tumors arise from a population of several hundred cells which represent only 1–2% of the cells in third instar larval brains. For imaginal disc tumors from lethal giant larvae and brain tumor mutants, it is shown for the first time that they can be metastatic and invasive. Primary imaginal disc tumors from lethal giant larvae and brain tumor mutants formed secondary tumors in 43 and 53% of the hosts, respectively, although the secondary tumors were, in general, smaller than the secondary tumors derived from primary brain tumors. Received: 18 August 1997 / Accepted: 16 October 1997     

When the control is lacking—the role of tumour suppressor genes in cancer development

The potential to genetically dissect tumorigenesis provides the major reason to study this process in the fruit flyDrosophila. Over the last 30 years genetic analysis has identified some 55 genes in which recessive mutations cause the appearance of specific tumours during development in tissues such as the imaginal discs, the brain hemispheres, the hematopoietic organs or the gonads, Since the normal allele acts dominantly over the mutated allele, these genes are designated as tumour suppressor genes. The estimate of the number of genes that can be mutated to tumour formation may be, however, much higher ranging between I00 to 200. The challenge before this field is how best to identify these genes and elucidate their function. Current molecular procedures, such as mutagenesis mediated by P-element transposon, provide new ways for tagging any gene of interest inDrosophila and thus for cloning it rapidly. Function of the gene product can be inferred by comparing its amino acid sequence with sequences of proteins with known function or can be determined by histochemical and biochemical investigations. Progress in the understanding of tumour suppression inDrosophila is most advanced in the case of genes regulating cell growth in imaginal discs. The imaginal discs are small groups of cells displaying a strong apical-basal polarity and form folded sacs of epithelia which grow throughout the larval life and give rise to the adult tegument during metamorphosis. Tumour suppressor genes regulating cell growth of imaginal discs, such as thelethal(2)giant larvae (l(2)g1),lethal(1)discs large-1 andexpanded genes, were found to encode proteins localized in domains of cell to cell contact on the plasma membrane and were thus thought to maintain cell adhesion. However, recent studies of l(2)gl have revealed that the l(2)gl protein is a component of the normal cytoskeleton which can participates to the cytoskeletal matrix underlaying the plasma membrane. These findings indicate that the changes in cell shape and the loss of apical-basal polarity in imaginal disc cells result primarily from alterations in the cytoskeleton structure. Furthermore the neoplastic growth of the mutated cells may be caused by the disorganization of an intracellular communication system that ultimately controls cell proliferation and/or cell differentiation.     

The mechanism of telomere protection: a comparison between Drosophila and humans

Drosophila telomeres are maintained by transposition of specialized retrotransposons rather than by telomerase activity, and their stability is independent of the sequence of DNA termini. Recent studies have identified several proteins that protect Drosophila telomeres from fusion events. These proteins include the telomere capping factors HP1/ORC-associated protein (HOAP) and heterochromatin protein 1 (HP1), the Rad50 and Mre11 DNA repair proteins that are required for HOAP and HP1 localization at telomeres, and the ATM kinase. Another telomere-protecting factor identified in Drosophila is UbcD1, a polypeptide highly homologous to class I ubiquitin-conjugating E2 enzymes. In addition, it has been shown that HP1 and both components of the Drosophila Ku70/80 heterodimer act as negative regulators of telomere length. Except for HOAP, all these proteins are conserved in humans and are associated with human telomeres. Collectively, these results indicate that Drosophila is an excellent model system for the analysis of the mechanisms of telomere maintenance. In past and current studies, 15 Drosophila genes have been identified that prevent telomeric fusion, and it has been estimated that the Drosophila genome contains at least 40 genes required for telomere protection. We believe that the molecular characterization of these genes will lead to identification of many novel human genes with roles in telomere maintenance.     

<Emphasis Type="Italic">Drosophila</Emphasis> retinophilin contains MORN repeats and is conserved in humans

The function of conserved novel human genes can be efficiently addressed in genetic model organisms. From a collection of genes expressed in the Drosophila visual system, cDNAs expressed in vertebrates were identified and one similar to a novel human gene was chosen for further investigation. The results reported here characterize the Drosophila retinophilin gene and demonstrate that a similar gene is expressed in the human retina. The Drosophila and human retinophilin sequences are 50% identical, and they share an additional 16% conserved substitutions. Examination of the cDNA and genomic sequence indicates that it corresponds to the gene CG10233 of the annotated genome and predicts a 22.7 kDa protein. Polyclonal antibodies generated to a predicted retinophilin peptide recognize an antigen in Drosophila photoreceptor cells. The retinophilins encode 4 copies of a repeat associated with a Membrane Occupation and Recognition Nexus (MORN) function first discovered in junctophilins, which may interact with the plasma membrane. These results therefore show that Drosophila retinophilin is expressed in fly photoreceptor cells, demonstrate that a conserved human gene is expressed in human retina, and suggest that a mutational analysis of the Drosophila gene would be valuable.     

Serum,insulin and phorbol esters stimulate rRNA and tRNA gene expression in both dividing and nondividing Drosophila cells

The expression of genes that code for the large ribosomal RNAs (rRNAs) and tRNAs can be regulated by calcium, serum, insulin and a tumor-promoting phorbol ester, TPA. These effectors can rapidly alter rRNA and tRNA synthesis in dividing and nondividing Drosophila cells. In an in vitro assay system of the nondividing cells of the male accessory glands, calcium, insulin and TPA were shown to increase both rRNA and tRNA synthesis. Exposure of actively dividing Drosophila culture cells to differing serum concentrations or TPA also altered rRNA and tRNA synthesis. Nuclear run-on assays demonstrate that the exposure of these cells to increased serum concentrations coordinately alters RNA polymerase I loading on both 18S and 28S rDNA. These data indicate that calcium, growth factors and a tumor-promoter each can signal changes in ribosomal and tRNA gene expression.     

Expression patterns of twist and snail in Tribolium (Coleoptera) suggest a homologous formation of mesoderm in long and short germ band insects

The mesodermal region in Drosophila is determined by a maternally derived morphogenetic gradient system which specifies the different cell fates along the dorsoventral axis, including the prospective mesodermal cells at the ventral side of the embryo. There are at least two zygotic target genes, twist and snail, which are required for mesoderm formation in Drosophila. To analyze whether a similar mode of mesoderm specification might also apply to short germ band insect embryos, we have cloned twist and snail- related gene fragments from the flour beetle Tri-bolium and have analyzed their expression pattern. Both genes are expressed in a ventral stripe at early blastoderm stage, which is restricted to the region of the developing germ rudiment. The cells expressing the two genes are those that invaginate during gastrulation, indicating that the early stages of mesoderm specification are indeed very similar between the two species. Interestingly, both genes are also expressed during germband extension in a subregion of the growth zone of the embryo which forms the mesodermal cells. This suggests that the expression of the two genes is required for mesoderm formation both at early blastoderm stage and during germband elongation until the end of the segmental growth process. © 1994 Wiley-Liss, Inc.     

Characterization of Maltase Clusters in the Genus <Emphasis Type="Italic">Drosophila</Emphasis>

To reveal evolutionary history of maltase gene family in the genus Drosophila, we undertook a bioinformatics study of maltase genes from available genomes of 12 Drosophila species. Molecular evolution of a closely related glycoside hydrolase, the α-amylase, in Drosophila has been extensively studied for a long time. The α-amylases were even used as a model of evolution of multigene families. On the other hand, maltase, i.e., the α-glucosidase, got only scarce attention. In this study, we, therefore, investigated spatial organization of the maltase genes in Drosophila genomes, compared the amino acid sequences of the encoded enzymes and analyzed the intron/exon composition of orthologous genes. We found that the Drosophila maltases are more numerous than previously thought (ten instead of three genes) and are localized in two clusters on two chromosomes (2L and 2R). To elucidate the approximate time line of evolution of the clusters, we estimated the order and dated duplication of all the 10 genes. Both clusters are the result of ancient series of subsequent duplication events, which took place from 352 to 61 million years ago, i.e., well before speciation to extant Drosophila species. Also observed was a remarkable intron/exon composition diversity of particular maltase genes of these clusters, probably a result of independent intron loss after duplication of intron-rich gene ancestor, which emerged well before speciation in a common ancestor of all extant Drosophila species.     

Out of the testis,into the ovary: biased outcomes of gene duplication and deletion in Drosophila

Gene turnover is a key source of adaptive variation. Yet most evolutionary studies have focused on gene duplication, dismissing gene deletion as a mechanism that simply eradicates redundancy. Here, I use genome‐scale sequence and multi‐tissue expression data from Drosophila melanogaster and Drosophila pseudoobscura to simultaneously assess the evolutionary outcomes of gene duplication and deletion in Drosophila. I find that gene duplication is more frequent than gene deletion in both species, indicating that it may play a more important role in Drosophila evolution. However, examination of several genic properties reveals that genes likely possess distinct functions after duplication that diverge further before deletion, suggesting that loss of redundancy cannot explain a majority of gene deletion events in Drosophila. Moreover, in addition to providing support for the well‐known “out of the testis” origin of young duplicate genes, analyses of gene expression profiles uncover a preferential bias against deletion of old ovary‐expressed genes. Therefore, I propose a novel “into the ovary” hypothesis for gene deletion in Drosophila, in which gene deletion may promote adaptation by salvaging genes that contribute to the evolution of female reproductive phenotypes. Under this combined “out of the testis, into the ovary” evolutionary model, gene duplication and deletion work in concert to generate and maintain a balanced repertoire of genes that promote sex‐specific adaptation in Drosophila.     

Sites of Fgf signalling and perception during embryogenesis of the beetle Tribolium castaneum

The development of multicellular embryos depends on coordinated cell-to-cell signalling events. Among the numerous cell-signalling pathways, fibroblast growth factors (FGFs) are involved in important processes during embryogenesis, such as mesoderm formation during gastrulation and growth. In vertebrates, the Fgf superfamily consists of 22 family members, whereas only few FGFs are contained in the less complex genomes of insects and worms. In the recently sequenced genome of the beetle Tribolium, we identified four Fgf family members representing three subfamilies. Tribolium has Fgf1 genes that are absent in Drosophila but known from vertebrates. By phylogenetic analysis and microsynteny to Drosophila, we further classify Tc-fgf 8 as an ancestor of pyramus and thisbe, the fly Fgf8 genes. Tc-fgf8 expression in the growth zone suggests an involvement in mesoderm formation. In the embryonic head, expression of Tc-fgf8 subdivides the brain into a larger anterior and a smaller posterior region. The Fgf Tc-branchless is expressed in the embryonic tracheal placodes and in various gland-like structures. The expression patterns of the only Tribolium Fgf receptor and the adaptor molecule Downstream-of-Fgfr are largely congruent with Tc-Fgf8 and Tc-bnl. Thus, in contrast to Drosophila, only one Fgf receptor canalises Fgf signalling in different tissues in Tribolium. Our findings significantly advance our understanding of the evolution of Fgf signalling in insects.     

The embryonic expression pattern of labial, posterior homeotic complex genes and the teashirt homologue in an apterygote insect

 During embryogenesis of the fruit fly, Drosophila melanogaster, the homeotic genes are required to specify proper cell fates along the anterior-posterior axis of the embryo. We cloned partial cDNAs of homologues of the Drosophila homeotic gene teashirt and five of the homeotic-complex (HOM-C) genes from the thysanuran insect, Thermobia domestica, and assayed their embryonic expression patterns. The HOM-C genes we examined were labial, Antennapedia, Ultrabithorax, abdominal-A and Abdominal-B. As the expression pattern of these HOM-C genes is largely conserved among insects and as Thermobia is a member of a phylogenetically basal order of insects, we were able to infer their ancestral expression patterns in insects. We compare the expression patterns of the Thermobia HOM-C genes with their expression in Drosophila and other insects and discuss the potential roles these genes may have played in insect evolution. Interestingly, the teashirt homologue shows greater variability between Thermobia and Drosophila than any of the HOM-C genes. In particular, teashirt is not expressed strongly in the Thermobia abdomen, unlike Drosophila teashirt. We propose that teashirt expression has expanded posteriorly in Drosophila and contributed to a homogenization of the Drosophila larval thorax and abdomen. Received: 23 July 1998 / Accepted: 1 November 1998     

Excessive Dpp signaling induces cardial apoptosis through dTAK1 and dJNK during late embryogenesis of <Emphasis Type="Italic">Drosophila</Emphasis>

Background  

To identify genes involved in the heart development of Drosophila, we found that embryos lacking raw function exhibited cardial phenotypes. raw was initially identified as a dorsal open group gene. The dorsal open phenotype was demonstrated to be resulted from the aberrant expression of decapentaplegic (dpp), a member of the tumor growth factor beta (TGF-β), signaling pathway. Despite the role of dpp in pattering cardioblasts during early embryogenesis of Drosophila have been demonstrated, how mutation in raw and/or excessive dpp signaling involves in the differentiating heart of Drosophila has not been fully elaborated at late stages.     

Modeling tumor invasion and metastasis in Drosophila

Conservation of major signaling pathways between humans and flies has made Drosophila a useful model organism for cancer research. Our understanding of the mechanisms regulating cell growth, differentiation and development has been considerably advanced by studies in Drosophila. Several recent high profile studies have examined the processes constraining the metastatic growth of tumor cells in fruit fly models. Cell invasion can be studied in the context of an in vivo setting in flies, enabling the genetic requirements of the microenvironment of tumor cells undergoing metastasis to be analyzed. This Perspective discusses the strengths and limitations of Drosophila models of cancer invasion and the unique tools that have enabled these studies. It also highlights several recent reports that together make a strong case for Drosophila as a system with the potential for both testing novel concepts in tumor progression and cell invasion, and for uncovering players in metastasis.     

The Drosophila homolog of human AF10/AF17 leukemia fusion genes (Dalf) encodes a zinc finger/leucine zipper nuclear protein required in the nervous system for maintaining EVE expression and normal growth

Sibling neurons in the embryonic central nervous system (CNS) of Drosophila can adopt distinct states as judged by gene expression and axon projection. In the NB4-2 lineage, two even-skipped (eve)-expressing sibling neuronal cells, RP2 and RP2sib, are formed in each hemineuromere. Throughout embryogenesis, only RP2, but not RP2sib, maintains eve expression. In this report, we describe a P-element induced mutation that alters the expression pattern of EVE in RP2 motoneurons in the Drosophila embryonic CNS. The mutation was mapped to a Drosophila homolog of human AF10/AF17 leukemia fusion genes (alf), and therefore named Dalf. Like its human counterparts, Dalf encodes a zinc finger/leucine zipper nuclear protein that is widely expressed in embryonic and larval tissues including neurons and glia. In Dalf mutant embryos, the RP2 motoneuron no longer maintains EVE expression. The effect of the Dalf mutation on EVE expression is RP2-specific and does not affect other characteristics of the RP2 motoneuron. In addition to the embryonic phenotype, Dalf mutant larvae are retarded in their growth and this defect can be rescued by the ectopic expression of a Dalf transgene under the control of a neuronal GAL4 driver. This indicates a requirement for Dalf function in the nervous system for maintaining gene expression and the facilitation of normal growth.     

Parental Imprinting in Drosophila

Genetic imprinting is a form of epigenetic silencing. But with a twist. The twist is that while imprinting results in the silencing of genes, chromosome regions or entire chromosome sets, this silencing occurs only after transmission of the imprinted region by one sex of parent. Thus genetic imprinting reflects intertwined levels of epigenetic and developmental modulation of gene expression. Imprinting has been well documented and studied in Drosophila, however, these studies have remained largely unknown due to nothing more significant than differences in terminology. Imprinting in Drosophilais invariably associated with heterochromatin or regions with unusual chromatin structure. The imprint appears to spread from imprinted centers that reside within heterochromatin and these are, seemingly, the only regions that are normally imprinted in Drosophila. This is significant as it implies that while imprinting occurs in Drosophila, it is generally without phenotypic consequence. Hence the evolution of imprinting, at least in Drosophila, is unlikely to be driven by the function of specific imprinted genes. Thus, the study of imprinting in Drosophilahas the potential to illuminate the mechanism and biological function of imprinting, and challenge models based solely on imprinting of mammalian genes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Pro-apoptotic cell death genes, <Emphasis Type="Italic">hid</Emphasis> and <Emphasis Type="Italic">reaper</Emphasis>, from the tephritid pest species, <Emphasis Type="Italic">Anastrepha suspensa</Emphasis>

Pro-apoptotic proteins from the reaper, hid, grim (RHG) family are primary regulators of programmed cell death in Drosophila due to their antagonistic effect on inhibitor of apoptosis (IAP) proteins, thereby releasing IAP-inhibition of caspases that effect apoptosis. Using a degenerate PCR approach to conserved domains from the 12 Drosophila species, we have identified the first reaper and hid orthologs from a tephritid, the Caribfly Anastrepha suspensa. As-hid is the first identified non-drosophilid homolog of hid, and As-rpr is the second non-drosophilid rpr homolog. Both genes share more than 50% amino acid sequence identity with their Drosophila homologs, suggesting that insect pro-apoptotic peptides may be more conserved than previously anticipated. Importantly, both genes encode the conserved IBM and GH3 motifs that are key for IAP-inhibition and mitochondrial localization. Functional verification of both genes as cell death effectors was demonstrated by cell death assays in A. suspensa embryonic cell culture, as well as in heterologous Drosophila melanogaster S2 cells. Notably, heterologous cell death activity was found to be higher for Anastrepha genes than their Drosophila counterparts. In common with the Drosophila cognates, As-hid and As-rpr negatively regulated the Drosophila inhibitor of apoptosis (DIAP1) gene to promote apoptosis, and both genes when used together effected increased cell death activity, indicating a co-operative function for As-hid and As-rpr. We show that these tephritid cell death genes are functional and potent as cell death effectors, and could be used to design improved transgenic lethality systems for insect population control.     

EST! EST!! EST!!!

A recently published study⁽¹⁾ has identified a set of candidate genes for human diseases based on findings from Drosophila. Each human expressed sequence tag (EST) in a large database was compared with all known Drosophila genes. After eliminating matches between genes of already known function, the remaining sequences were mapped in the human genome. In each region, the phenotypes of all known human diseases were compared with the phenotypes of known Drosophila mutations in order to identify candidate genes for the human diseases. Are the correspondences real or coincidental?     

Pair-rule and gap gene mutants in the flour beetle Tribolium castaneum

 Early pattern formation in the Drosophila embryo occurs in a syncytial blastoderm where communication between nuclei is unimpeded by cell walls. During the development of other insects, similar gene expression patterns are generated in a cellular environment. In Tribolium, for instance, pair-rule stripes are transiently expressed near the posterior end of the growing germ band. To elucidate how pattern formation in such a situation deviates from that of Drosophila, functional data about the genes involved are essential. In a genetic screen for Tribolium mutants affecting the larval cuticle pattern, we isolated 4 mutants (from a total of 30) which disrupt segmentation in the thorax and abdomen. Two of these mutants display clear pair-rule phenotypes. This demonstrates that not only the expression, but also the function of pair-rule genes in this short-germ insect is in principle similar to Drosophila. The other two mutants appear to identify gap genes. They provide the first evidence for the involvement of gap genes in abdominal segmentation of short-germ embryos. However, significant differences between the phenotypes of these mutants and those of known Drosophila gap mutants exist which indicates that evolutionary changes occurred in either the regulation or action of these genes. Received: 8 May 1998 / Accepted: 17 June 1998     

Two Frequenins in <Emphasis Type="Italic">Drosophila</Emphasis>: unveiling the evolutionary history of an unusual Neuronal Calcium Sensor (NCS) duplication

Background  

Drosophila Frequenin (Frq), the homolog of the mammalian Neuronal Calcium Sensor-1 (NCS-1), is a high affinity calcium-binding protein with ubiquitous expression in the nervous system. This protein has an important role in the regulation of neurotransmitter release per synapse, axonal growth and bouton formation. In D. melanogaster, Frequenin is encoded by two genes (frq1 and frq2), a very unexpected feature in the Frq/NCS-1 subfamily. These genes are located in tandem in the same genomic region, and their products are 95% identical in their amino acid sequence, clearly indicating their recent origin by gene duplication. Here, we have investigated the factors involved in this unusual feature by examining the molecular evolution of the two frq genes in Drosophila and the evolutionary dynamics of NCS family in a large set of bilaterian species.     

Molecular Aspects of Intron Evolution in Dynein Encoding Mega-Genes on The Heterochromatic Y Chromosome of Drosophila sp.

Fertility genes on the heterochromatic Y chromosome of various Drosophilaspecies are unique for several reasons. Most of them are megabase-sized. Their expression is restricted to premeiotic spermatocytes and often associated with unfolding of huge species-specific lampbrush loops. Molecular analysis of the orthologous dynein genes Dhc-Yh3, DhDhc7(Y)and DeDhc7(Y)on the Y chromosome of the three species D. melanogaster, D. hydeiand D. eohydei, respectively, revealed that the megabase gene size as well as the species-specific morphology of the corresponding lampbrush loops kl-5, Threadsand diffuse loopsresult from huge introns and their specific sequence composition, whereas the majority of all 20 introns in each of the three genes is in a size of 45–72 bp. The loop-specifying introns are extreme exceptions due to extended assemblies of degenerated transposable elements and/or large clusters of satellite DNAs. Here we use sequence information from the complete intron sets of three orthologous Y chromosomal dynein genes to deduce a scenario for an evolutionary pathway leading to the megabase-sized genes on the heterochromatic Y chromosome of Drosophila. The obvious bias between very small and species-specific mega introns is explained as the result of an autocatalytic mode of intron growth. An initial coincidental hit by a single transposable element extends the size of a 50 bp intron for about two orders of magnitude and determines it for preferential extension by similar insertion events. This phase of continuous moderate growth is followed by rapid size enlargements by repeating amplifications generating extended clusters of satellite DNA. Size control by recombination, on the other hand, is suppressed in Drosophilamales by achiasmatic meiosis. This revised version was published online in July 2006 with corrections to the Cover Date.