Gene expression profiling identifies retinoids as potent inducers of macrophage lipid efflux

Vitamin A and its naturally occurring derivatives 9-cis retinoic acid (9-cis RA) and all-trans retinoic acid (ATRA) exert a variety of biological effects including immunomodulation, growth, differentiation, and apoptosis of normal and neoblastic cells. In order to directly study the effects of these retinoids on macrophage gene expression and lipid metabolism, primary human monocytes and in vitro differentiated macrophages were stimulated with beta-carotene, 9-cis RA, and ATRA and global gene expression profiles were analyzed by Affymetrix DNA-microarrays and differentially regulated genes were verified by quantitative TaqMan RT-PCR. Among others, we have identified a strong up-regulation of a cluster of genes involved in cholesterol metabolism including apolipoproteins (apoC-I, apoC-II, apoC-IV, apoE), the scavenger receptor CD36, steroid-27-hydroxylase (CYP27A1), liver X receptor alpha (LXRalpha), and ATP-binding cassette transporters A1 (ABCA1) and G1 (ABCG1). Since the CYP27A1 gene displayed the strongest up-regulation on the mRNA level, we cloned various deletion constructs of the promoter region and analyzed the response to retinoids in macrophages. Thereby, a novel retinoic acid-responsive element could be located within 191 bp of the proximal CYP27A1 promoter. To further assess the functional consequences of retinoid receptor action, we carried out phospholipid and cholesterol efflux assays. We observed a strong induction of apoA-I-dependent lipid efflux in stimulated macrophages, implicating an important role for retinoids in cellular functions of macrophages.     

Role and regulation of starvation-induced autophagy in the Drosophila fat body

In response to starvation, eukaryotic cells recover nutrients through autophagy, a lysosomal-mediated process of cytoplasmic degradation. Autophagy is known to be inhibited by TOR signaling, but the mechanisms of autophagy regulation and its role in TOR-mediated cell growth are unclear. Here, we show that signaling through TOR and its upstream regulators PI3K and Rheb is necessary and sufficient to suppress starvation-induced autophagy in the Drosophila fat body. In contrast, TOR's downstream effector S6K promotes rather than suppresses autophagy, suggesting S6K downregulation may limit autophagy during extended starvation. Despite the catabolic potential of autophagy, disruption of conserved components of the autophagic machinery, including ATG1 and ATG5, does not restore growth to TOR mutant cells. Instead, inhibition of autophagy enhances TOR mutant phenotypes, including reduced cell size, growth rate, and survival. Thus, in cells lacking TOR, autophagy plays a protective role that is dominant over its potential role as a growth suppressor.     

Redundant cis-acting elements control expression of the Drosophila affinidisjuncta Adh gene in the larval fat body.

The alcohol dehydrogenase (Adh) gene in the Hawaiian species of fruit fly, Drosophila affinidisjuncta, like the Adh genes from all Drosophila species analyzed, is expressed at high levels in the larval fat body via a larval-specific promoter. To identify the cis-acting elements involved in this highly conserved aspect of Adh gene expression, deleted D. affinidisjuncta genes were introduced into D. melanogaster by somatic transformation. Unlike previously described methods, this transformation system allows analysis of Adh gene expression specifically in the larval fat body. The arrangement of sequences influencing expression of the proximal promoter of this gene in the larval fat body differs markedly from that described for the Adh gene from the distant relative, D. melanogaster. Multiple redundant elements dispersed 5' and 3' to the gene, only some of which map to regions carrying evolutionarily conserved sequences, affect expression in the fat body. D. affinidisjuncta employs a novel mode of Adh gene regulation in which the proximal promoter is influenced by sequences having roles in expression of the distal promoter. This gene is also unique in that far upstream sequences can compensate for loss of sequences within 200 bp of the proximal RNA start site. Furthermore, expression is influenced in an unusual, context-dependent manner by a naturally-occurring 3' duplication of the proximal promoter--a feature found only in Hawaiian species.     

Regulation of synthesis of larval serum proteins after transplantation of larval fat body into adult Drosophila melanogaster

The larval serum proteins, LSP1 and LSP2, of Drosophila melanogaster are synthesized by the fat body during the third instar. We examined the potential for LSP synthesis by fat body implants in adult flies. Fat body from third instar donors will continue to synthesize LSPs in both males and females. Implants from late second instar larvae will start synthesizing LSP1 and LSP2 in females but only LSP1 in males, suggesting that regulation of these proteins is not the same and that the physiological milieu in the two sexes differs. The newly synthesized LSPs are secreted into the hemolymph for approximately 48 hr when secretion stops but synthesis continues. This sequence follows the pattern for LSP secretion in situ. Fat body from mid second instar larvae is variable in its ability to synthesize LSPs. LSPs are not detected in implants from first instar larvae despite there being a high level of protein synthesis in the implant and considerable growth of the fat body cells. We conclude that there is a critical stage of differentiation during the latter half of the second instar when the fat body becomes independent of the larval milieu and can synthesize LSPs in the adult.     

Circadian rhythmicity of tyrosine aminotransferase activity in larval and prepupal fat body of Drosophila melanogaster

Abstract

Drosophila melanogaster was reared under LD 12:12. Fat body was isolated in form of cells and cell groups from dissected larvae or prepupae by treatment with collagenase and hyaluronidase and subsequent centrifugation. Tyrosine aminotransferase of the fat body showed an extremely sharp pH dependence, with two narrow, well separable maxima at pH 5.6 and 6.0, possibly caused by different isoenzymes. Enzyme activity at pH 5.6 exhibited biphasic circadian rhythms in both wild‐type 3rd instar larvae and early prepupae. At pH 6.0, the rhythmicity was much weaker, perhaps even absent. In larvae from an ebony strain, at either pH the basal tyrosine aminotransferase activity was enhanced, and the rhythmicity was altered.     

A dual function for Deep orange in programmed autophagy in the Drosophila melanogaster fat body

Lysosomal degradation of cytoplasm by way of autophagy is essential for cellular amino acid homeostasis and for tissue remodeling. In insects such as Drosophila, autophagy is developmentally upregulated in the larval fat body prior to metamorphosis. Here, autophagy is induced by the hormone ecdysone through down-regulation of the autophagy-suppressive phosphoinositide 3-kinase (PI3K) signaling pathway. In yeast, Vps18 and other members of the HOPS complex have been found essential for autophagic degradation. In Drosophila, the Vps18 homologue Deep orange (Dor) has previously been shown to mediate fusion of multivesicular endosomes with lysosomes. A requirement of Dor for ecdysone-mediated chromosome puffing has also been reported. In the present report, we have tested the hypothesis that Dor may control programmed autophagy at the level of ecdysone signaling as well as by mediating autophagosome-to-lysosome fusion. We show that dor mutants are defective in programmed autophagy and provide evidence that autophagy is blocked at two levels. First, PI3K activity was not down-regulated correctly in dor larvae, which correlated with a decrease in ecdysone reporter activity. The down-regulation of PI3K activity was restored by feeding ecdysone to the mutant larvae. Second, neither exogenous ecdysone nor overexpression of PTEN, a silencer of PI3K signaling, restored fusion of autophagosomes with lysosomes in the fat body of dor mutants. These results indicate that Dor controls autophagy indirectly, via ecdysone signaling, as well as directly, via autolysosomal fusion.     

Chewing the fat; regulating autophagy in Drosophila

Autophagy is the major cellular process responsible for bulk cytoplasmic degradation. Two reports in this issue of Developmental Cell describe how both PI3 kinase and TOR signaling in Drosophila are critical for controlling autophagy in response to developmental and environmental cues.     

Ultrastructure of the preparative phase of cell death in the larval fat body of Drosophila melanogaster

Progressive changes in the ultrastructure of the larval fat body of Drosophila melanogaster were studied during the third instar. In addition to electron microscopy, light microscopy and morphometric stereology were employed to evaluate the tissue at five 12-hr intervals: 48, 60, 72, 84, and 96 hr after hatching from the egg. Lipid and glycogen were found stored throughout the instar, whereas protein is stored in the form of cytoplasmic granules mainly during the final 24 hr. The cells increased in cross-sectional area, and there was a concomitant increase in the relative amounts of these substances. Based on morphological characteristics there were three types of protein granules which we called dense granules (D), heterogeneous granules (H), and autophagic vacuoles. The morphology, size range, time of appearance, and changes in frequency of these granules suggested that the H type arose from D granules, and that the autophagic vacuoles were derived from D and H types. Morphological evidence indicated D granules have the unusual characteristic of forming in the intercellular space before entering the cytoplasm.     

Gene expression profiling between embryonic and larval stages of the silkworm, Bombyx mori

To elucidate the molecular mechanisms associated with metamorphic phenomenon relating to Bombyx mori, an important organism in the sericulture industry, we identified genes that are expressed in the different developmental stages, specifically the embryonic (ES) and larval (LS) stages of B. mori. Of 8230 high-quality ESTs from two full-length enriched cDNA libraries, 3442 of the ES ESTs were coalesced into 1325 clusters, while 4788 were coalesced into 927 clusters. The functional classification of these ESTs based on Gene Ontology showed that the types of genes that are associated with oxidoreductase activity, enzyme inhibition, and larval development were highly observed in LS, whereas the types of genes that are involved in nucleotide binding, enzyme activity, and protein transport activity were highly observed in ES. In addition, when the gene expression profile between ES and LS was examined by counting the EST frequencies in each library, 69 genes were identified as being either up- or down-regulated in the larval stage compared to the embryonic stage (P>0.99) and this was confirmed by semi-quantitative RT-PCR. The results show that genes involved in proteolysis and peptidolysis, and lipid and carbohydrate metabolism were dramatically up-regulated in LS, while those related to protein metabolism, DNA/RNA, and coenzymes were highly down-expressed. In particular, a GO analysis of these genes revealed that genes that are involved in hydrolase activity were observed to be highly expressed in amount as well as diversity in LS, while those involved in nucleic acid binding were highly expressed in ES. These data may contribute to elucidating genetic events that distinguish the developmental stage and to our understanding of the metamorphosis of B. mori.