TOR coordinates bulk and targeted endocytosis in the Drosophila melanogaster fat body to regulate cell growth

Target of rapamycin (TOR) is a central regulator of cellular and organismal growth in response to nutrient conditions. In a genetic screen for novel TOR interactors in Drosophila melanogaster, we have identified the clathrin-uncoating ATPase Hsc70-4, which is a key regulator of endocytosis. We present genetic evidence that TOR signaling stimulates bulk endocytic uptake and inhibits the targeted endocytic degradation of the amino acid importer Slimfast. Thus, TOR simultaneously down-regulates aspects of endocytosis that inhibit growth and up-regulates potential growth-promoting functions of endocytosis. In addition, we find that disruption of endocytosis leads to changes in TOR and phosphatidylinositol-3 kinase activity, affecting cell growth, autophagy, and rapamycin sensitivity. Our data indicate that endocytosis acts both as an effector function downstream of TOR and as a physiologically relevant regulator of TOR signaling.     

DRONC coordinates cell death and compensatory proliferation

Accidental cell death often leads to compensatory proliferation. In Drosophila imaginal discs, for example, gamma-irradiation induces extensive cell death, which is rapidly compensated by elevated proliferation. Excessive compensatory proliferation can be artificially induced by "undead cells" that are kept alive by inhibition of effector caspases in the presence of apoptotic stimuli. This suggests that compensatory proliferation is induced by dying cells as part of the apoptosis program. Here, we provide genetic evidence that the Drosophila initiator caspase DRONC governs both apoptosis execution and subsequent compensatory proliferation. We examined mutants of five Drosophila caspases and identified the initiator caspase DRONC and the effector caspase DRICE as crucial executioners of apoptosis. Artificial compensatory proliferation induced by coexpression of Reaper and p35 was completely suppressed in dronc mutants. Moreover, compensatory proliferation after gamma-irradiation was enhanced in drice mutants, in which DRONC is activated but the cells remain alive. These results show that the apoptotic pathway bifurcates at DRONC and that DRONC coordinates the execution of cell death and compensatory proliferation.     

Vesicular stomatitis virus growth in Drosophila melanogaster cells: G protein deficiency.

In cultured Drosophila melanogaster cells, vesicular stomatitis virus (VSV) established a persistent, noncytopathic infection. No inhibition of host protein synthesis occurred even though all cells were initially infected. No defective interfering particles were detected, which would explain the establishment of the carrier state. In studies of the time course of viral protein synthesis in Drosophila cells, N, NS, and M viral polypeptides were readily detected within 1 h of infection. The yield of G protein and one of its precursors; G1, was very low at any time of the virus cycle; the released viruses always contained four to five times less G than those produced by chicken embryo cells, whatever the VSV strain or serotype used for infection and whatever the Drosophila cell line used as host. Actinomycin D added to the cells before infection enhanced VSV growth up to eight times. G and G1 synthesis increased much more than that of the other viral proteins when the cells were pretreated with the drug; nevertheless, the released viruses exhibited the same deficiency in G protein as the VSV released from untreated cells. Host cell control on both G-protein maturation process and synthesis at traduction level is discussed in relation to G biological properties.     

Daughterless coordinates somatic cell proliferation,differentiation and germline cyst survival during follicle formation in Drosophila

During Drosophila oogenesis two distinct stem cell populations produce either germline cysts or the somatic cells that surround each cyst and separate each formed follicle. From analyzing daughterless (da) loss-of-function, overexpression and genetic interaction phenotypes, we have identified several specific requirements for da(+) in somatic cells during follicle formation. First, da is a critical regulator of somatic cell proliferation. Also, da is required for the complete differentiation of polar and stalk cells, and elevated da levels can even drive the convergence and extension that is characteristic of interfollicular stalks. Finally, da is a genetic regulator of an early checkpoint for germline cyst progression: Loss of da function inhibits normally occurring apoptosis of germline cysts at the region 2a/2b boundary of the germarium, while da overexpression leads to postmitotic cyst degradation. Collectively, these da functions govern the abundance and diversity of somatic cells as they coordinate with germline cysts to form functional follicles.     

The Drosophila tuberous sclerosis complex gene homologs restrict cell growth and cell proliferation

The inherited human disease tuberous sclerosis, characterized by hamartomatous tumors, results from mutations in either TSC1 or TSC2. We have characterized mutations in the Drosophila Tsc1 and Tsc2/gigas genes. Inactivating mutations in either gene cause an identical phenotype characterized by enhanced growth and increased cell size with no change in ploidy. Overall, mutant cells spend less time in G1. Coexpression of both Tsc1 and Tsc2 restricts tissue growth and reduces cell size and cell proliferation. This phenotype is modulated by manipulations in cyclin levels. In postmitotic mutant cells, levels of Cyclin E and Cyclin A are elevated. This correlates with a tendency for these cells to reenter the cell cycle inappropriately as is observed in the human lesions.     

Biological stoichiometry of growth in Drosophila melanogaster

We examined the relationship between growth rate, C:N:P stoichiometry, and nucleic acid content in Drosophila melanogaster. The "Growth Rate Hypothesis" predicts that N and P contents per unit body mass will be high during ontogenetic stages characterized by rapid growth, reflecting the large requirement for P-rich ribosomal RNA during these periods. The ratio of RNA:DNA also is predicted to change with changes in growth rate. Growth is rapid in early D. melanogaster larvae, slowing considerably just prior to pupation. As predicted, a positive relationship was found between growth rate and N and P content, but not C. Thus, body C:P and N:P ratios declined with increasing growth rate. The relationship between RNA content and growth rate also was positive. Additionally, the fraction of total body P contributed by ribosomal RNA increased with increasing growth rate.     

Genomic and structural organization of Drosophila melanogaster G elements.

The properties and the genomic organization of G elements, a moderately repeated DNA family of D. melanogaster, are reported. G elements lack terminal repeats, generate target site duplications at the point of insertion and exhibit at one end a stretch of A residues of variable length. In a large number of recombinant clones analyzed G elements occur in tandem arrays, interspersed with specific ribosomal DNA (rDNA) segments. This arrangement results from the insertion of members of the G family within the nontranscribed spacer (NTS) of rDNA units. Similarity of the site of integration of G elements to that of ribosomal DNA insertions suggests that distinct DNA sequences might have been inserted into rDNA through a partly common pathway.     

Shar-pei mediates cell proliferation arrest during imaginal disc growth in Drosophila

During animal development, organ size is determined primarily by the amount of cell proliferation, which must be tightly regulated to ensure the generation of properly proportioned organs. However, little is known about the molecular pathways that direct cells to stop proliferating when an organ has attained its proper size. We have identified mutations in a novel gene, shar-pei, that is required for proper termination of cell proliferation during Drosophila imaginal disc development. Clones of shar-pei mutant cells in imaginal discs produce enlarged tissues containing more cells of normal size. We show that this phenotype is the result of both increased cell proliferation and reduced apoptosis. Hence, shar-pei restricts cell proliferation and promotes apoptosis. By contrast, shar-pei is not required for cell differentiation and pattern formation of adult tissue. Shar-pei is also not required for cell cycle exit during terminal differentiation, indicating that the mechanisms directing cell proliferation arrest during organ growth are distinct from those directing cell cycle exit during terminal differentiation. shar-pei encodes a WW-domain-containing protein that has homologs in worms, mice and humans, suggesting that mechanisms of organ growth control are evolutionarily conserved.     

Tribbles, a cell-cycle brake that coordinates proliferation and morphogenesis during Drosophila gastrulation

BACKGROUND: The final shape and size of an organism is determined by both morphogenetic processes and cell proliferation and it is essential that these processes be properly coordinated. In particular, cell division is incompatible with certain types of morphogenetic cell behaviour, such as migration, adhesion and changes in cell shape. Mechanisms must therefore exist to ensure that one does not interfere with the other. RESULTS: We address here the coordination of proliferation and morphogenesis during the development of the mesoderm in Drosophila. We show that it is essential that mitosis be blocked in the mesoderm during early gastrulation, and identify the putative serine/threonine kinase Tribbles as controlling this block. In its absence, the mitotic block is lifted, resulting in severe defects during early gastrulation. Tribbles, a homologue of a group of vertebrate proteins of unknown function, acts in concert with another, as yet unidentified, factor to counteract the activity of the protein phosphatase Cdc25/String. CONCLUSIONS: In a finely tuned balance with Cdc25/String, Tribbles controls the timing of mitosis in the prospective mesoderm, allowing cell-shape changes to be completed. This mechanism for coordinating cell division and cell-shape changes may have helped Drosophila to evolve its mode of rapid early development.     

The Drosophila melanogaster gene brain tumor negatively regulates cell growth and ribosomal RNA synthesis.

The regulation of ribosome synthesis is likely to play an important role in the regulation of cell growth. Previously, we have shown that the ncl-1 gene in Caenorhabditis elegans functions as an inhibitor of cell growth and ribosome synthesis. We now indicate that the Drosophila melanogaster tumor suppressor brain tumor (brat) is an inhibitor of cell growth and is a functional homolog of the C. elegans gene ncl-1. The brat gene is able to rescue the large nucleolus phenotype of ncl-1 mutants. We also show that brat mutant cells are larger, have larger nucleoli, and have more ribosomal RNA than wild-type cells. Furthermore, brat overexpressing cells contain less ribosomal RNA than control cells. These results suggest that the tumorous phenotype of brat mutants may be due to excess cell growth and ribosome synthesis.     

Notch signalling coordinates tissue growth and wing fate specification in Drosophila

During the development of a given organ, tissue growth and fate specification are simultaneously controlled by the activity of a discrete number of signalling molecules. Here, we report that these two processes are extraordinarily coordinated in the Drosophila wing primordium, which extensively proliferates during larval development to give rise to the dorsal thoracic body wall and the adult wing. The developmental decision between wing and body wall is defined by the opposing activities of two secreted signalling molecules, Wingless and the EGF receptor ligand Vein. Notch signalling is involved in the determination of a variety of cell fates, including growth and cell survival. We present evidence that growth of the wing primordium mediated by the activity of Notch is required for wing fate specification. Our data indicate that tissue size modulates the activity range of the signalling molecules Wingless and Vein. These results highlight a crucial role of Notch in linking proliferation and fate specification in the developing wing primordium.     

产气荚膜梭菌促进黑腹果蝇的生长和发育

【目的】黑腹果蝇Drosophila melanogaster肠道中栖生着众多微生物,通过分离和研究其内共生菌,以研究肠道菌群的多态性和作用。【方法】利用Hungate滚管技术从黑腹果蝇成虫肠道分离厌氧细菌;通过记录果蝇的发育历期和生长速率,检测该细菌对果蝇发育和生长的影响。【结果】首次从黑腹果蝇肠道内分离到一株产气荚膜梭菌Clostridium perfringens。该菌能够有效地定植到果蝇肠道内,是果蝇肠道共生菌。产气荚膜梭菌显著地缩短无菌果蝇的发育历期,将无菌果蝇成蛹天数由20 d缩短到8.1 d,羽化天数由30 d缩短到12.7 d。该菌还可以提高果蝇生长速率。【结论】本研究揭示了产气荚膜梭菌是果蝇的内共生菌,可以通过提高生长速率而有效地促进果蝇的生长和发育。     

黑腹果蝇细胞谱系分析方法进展

对动物体内单个细胞的谱系进行分析有助于追踪其在发育过程中的作用,但是体内各种组织都是由很多形态、结构、功能各不相同的细胞构成的复杂系统,这种复杂性严重阻碍了对单个细胞的研究。嵌合克隆技术(Mosaic technique)和标记技术(Labeling technique)的出现为这一研究提供了强有力的手段。文章介绍了近几年来黑腹果蝇(Drosophila melanogaster)研究中常用的7种嵌合克隆标记方法,包括FRT介导的有丝分裂重组(FRT-mediated mitotic recombination)、MARCM(Mosaic analysis with a repressible cell marker)、TSG(Twin spotgenerator)、Twin-spot MARCM、Q-MARCM(Q system-based MARCM)、Coupled MARCM和G-TRACE(Gal4technique for real-time and clonal expression)技术,详述了这些技术的原理及应用,并对不同技术进行了对比。运用这些技术研究者可以从单细胞水平进行遗传学标记和操作,特别是在神经系统等复杂系统中追踪单个细胞的发育过程。果蝇中的这些技术也将为其他模式生物追踪细胞谱系提供参考。     

敲低piwi基因对黑腹果蝇血细胞增殖及分化的影响

[目的]探究敲低piwi基因对黑腹果蝇Drosophila melanogaster血细胞增殖及分化的影响.[方法]利用黑腹果蝇e33C-Gal4和Hml-Gal4-UAS-2×EGFP品系分别与野生型W1118和UAS-piwi RNAi品系杂交,实现在黑腹果蝇游离血细胞或淋巴腺中降低piwi基因的表达;采用免疫荧光...