The modifier subunit of Drosophila glutamate-cysteine ligase regulates catalytic activity by covalent and noncovalent interactions and influences glutathione homeostasis in vivo

Glutamate-cysteine ligase (GCL) has a key influence on glutathione homeostasis. It has been proposed that mammalian GCL is regulated by the redox environment, and we show here that cysteine residues in the Drosophila melanogaster GCL modifier subunit (DmGCLM) can form covalent interactions with the catalytic subunit (DmGCLC) and modify its activity. Candidate components of intersubunit disulfides (Cys213, Cys214, and Cys267) were identified using matrix-assisted laser desorption ionization time-of-flight spectroscopy of iodoacetamide-modified DmGCLM as well as examination of the evolutionary conservation of cysteines. Mutation of the 3 cysteine residues allowed DmGCLM to associate with DmGCLC, but inhibited the formation of intersubunit disulfides. This caused a 2-fold reduction in the catalytic efficiency of Drosophila GCL, although activity remained significantly higher than the catalytic subunit alone. The cysteine mutant was also more sensitive to inhibition by glutathione than the unmodified holoenzyme. Notably, human GCLM could substitute for DmGCLM in modification of DmGCLC activity. The role of DmGCLM in vivo was examined by analysis of a Drosophila mutant (l(3)L0580) containing a P-element insertion in Gclm. We found that the P-element is not responsible for the lethal phenotype and separated the recessive lethal mutation from the P-element by recombination. This yielded two fully viable and fertile recombinants bearing the P-element insertion, which Western and Northern blotting indicated is a severely hypomorphic allele of Gclm. Glutathione levels were approximately 2-fold lower in the GclmL0580 mutants than in control strains, demonstrating the importance of DmGCLM in the regulation of glutathione homeostasis in vivo.     

DNA ligase from Drosophila melanogaster embryos. Substrate specificity and mechanism of action

DNA ligase has been purified to homogeneity from 6-12 h Drosophila melanogaster embryos (Rabin, B. A., Hawley, R. S., and Chase, J. W. (1986) J. Biol. Chem. 261, 10637-10645). This enzyme had an apparent Km for ATP of 1.6 microM. Of a variety of nucleotides tested, only adenosine 5'-O-(3-thio)triphosphate could substitute for ATP in the joining reaction. The enzyme was competitively inhibited by dATP, with an apparent Ki of 2.3 microM. The apparent Km for DNA using p(dT)20 annealed with poly(dA) as substrate was 1.0 microM. Studies utilizing synthetic homopolymers showed that in addition to joining DNA to DNA, this enzyme could join the 5'-phosphoryl termini of RNA to the 3'-hydroxyl termini of DNA or RNA, when they were annealed with DNA. In addition, p(dT)7U could be joined when annealed with poly(dA). No joining was detected when RNA served as the template. Drosophila DNA ligase also catalyzed the joining of oligonucleotides containing a single mismatched nucleotide at their 3'-hydroxyl termini, as well as DNA containing short, complementary 5'-protruding ends, and in the presence of polyethylene glycol 6000, blunt-ended duplex DNA. The overall reaction mechanism was shown to be identical to that of the homologous prokaryotic DNA ligases. The joining reactions catalyzed by the Drosophila and T4 DNA ligases were shown to be reversible. Incubation of superhelical closed circular DNA molecules with the purified enzymes and AMP resulted in the production of a population of DNA molecules which had lost most, if not all, of their superhelical density.     

Identification of a variant antioxidant response element in the promoter of the human glutamate-cysteine ligase modifier subunit gene. Revision of the ARE consensus sequence

Constitutive and inducible expression of the gene encoding the modulator subunit of human glutamate-cysteine ligase (GCLM) is regulated by either of two regions of the promoter; an antioxidant response element (ARE) at -302:-291 and a 44-bp fragment (-346:-303) upstream of the ARE. This second region includes a consensus AP-1 site previously considered responsible for the enhancer activity of the upstream fragment. Deletion of a 165-bp fragment (-348:-183) including the ARE and upstream 44-bp fragment totally ablated t-butyl hydroquinone (tBHQ) inducibility of a GCLM promoter/luciferase transgene. Mutation analyses confirmed that both the ARE and the -346:-303 fragment could support induction following tBHQ exposure but demonstrated that induction in the latter case did not involve the AP-1 site at -341:-335. A region sharing significant homology with the consensus ARE sequence except for a single nucleotide mismatch at -330 (5'-TTACnnnGCA-3' versus 5'-TGACnnnGCA-3') was identified at the 5'-end of the 44-bp fragment immediately adjacent to the AP-1 site. A G in this position has been considered an invariant requirement of functional ARE sequences. Mutation of T(-330) to A (a substitution known to ablate ARE function) or C eliminated basal and inducible expression. Substitution of a G at -330 enhanced basal expression relative to the wild-type sequence, but induction following tBHQ exposure was comparable, indicating that either sequence (5'-TTACnnnGCA-3' versus 5'-TGACnnnGCA-3') may function as an ARE, although the former sequence is less effective at directing basal expression. This possibility was confirmed by similar mutational analyses of the core sequence of hNQO1, a prototypic ARE. Electrophoretic mobility shift competition assays revealed that the 5'-TTACnnnGCA-3' sequence could compete with the hNQO1 ARE for protein binding but was less effective than a similar probe containing the 5'-TGACnnnGCA-3' motif. Probes including the T(-330)A or T(-330)C mutations were ineffective. These results reveal that the GCLM promoter includes two functional AREs, one having a variant sequence. The results indicate that the consensus ARE sequence should be revised to 5'-RTKAYnnnGCR-3'.     

Drosophila fibronectin: a protein that shares properties similar to those of its mammalian homologue.

This is the first report on the existence in Drosophila of a protein with properties similar to those of vertebrate fibronectin that we shall refer to as Drosophila fibronectin. Rabbit antibodies against human plasma fibronectin have allowed the detection of this molecule in Drosophila haemolymph; common epitopes are shared by the two proteins. Drosophila fibronectin with a subunit mol. wt of approximately 230 kd is a glycoprotein which binds to denatured mammalian collagen. It is present throughout development and is as abundant in embryos as in larvae and adult flies. Drosophila fibronectin is differentially expressed during embryogenesis, a small amount being present before the blastoderm stage. Its concentration increases at gastrulation and reaches a steady-state value at the end of organogenesis. Drosophila fibronectin is predominantly detected by immunofluorescence on frozen sections of 16 h embryos in the extracellular spaces lying between the different tissues and organs. In mature third instar larvae, most of the staining is concentrated in fat body and imaginal discs, and the pattern strongly supports an extracellular localization of the protein. In addition, it is shown that Drosophila embryonic cells can functionally utilize vertebrate fibronectin for their spreading and differentiation. Finally, injection of antihuman plasma fibronectin antibodies in early embryos leads to the same phenotype as injection of Arg-Gly-Asp-containing peptides. This result suggests that one of the Arg-Gly-Asp-bearing protein(s) involved in gastrulation might be fibronectin.     

A cAMP-binding phosphoprotein in Drosophila heads is similar to the regulatory subunit of the mammalian type II cAMP-dependent protein kinase

Cyclic AMP (cAMP)-dependent regulation of in vitro phosphorylation of several proteins including a cAMP-binding protein was studied with crude membrane and cytosol fractions from Drosophila heads. Phosphorylation of at least seven distinct proteins was enhanced in the presence of cAMP. Interestingly, however, the phosphorylation of a 56 kDa protein was apparently reduced by cAMP in the membrane but not in the cytosol fraction. The following data strongly indicate that the 56 kDa phosphoprotein in both membrane and cytosol fractions is a cAMP-binding protein, very similar to the regulatory subunit (RII) of a mammalian cAMP-dependent protein kinase, and that its binding to cAMP makes this protein very susceptible to the action of phosphatases: (i) cAMP highly stimulated the dephosphorylation of the 56 kDa phosphoprotein by the endogenous phosphatase in the membrane fraction. (ii) The dephosphorylation of a similar 56 kDa phosphoprotein in the cytosol fraction by an exogenous, cAMP-independent, alkaline phosphatase was also highly stimulated by cAMP. (iii) The 56 kDa phosphoprotein was covalently bound to cAMP by u.v. irradiation. (iv) The alkaline-phosphatase treatment reversibly converted this phosphoprotein to a 53 kDa non-phosphorylated protein. (v) The 53 kDa protein was selectively bound to cAMP-agarose and subsequently eluted by cAMP and high salt. (vi) This protein served as a substrate for the catalytic subunit of a mammalian cAMP-dependent protein kinase.     

Initial characterization of the glutamate-cysteine ligase modifier subunit Gclm(-/-) knockout mouse. Novel model system for a severely compromised oxidative stress response

Glutamate-cysteine ligase (GCL) is the rate-limiting enzyme in the GSH biosynthesis pathway. In higher eukaryotes, this enzyme is a heterodimer comprising a catalytic subunit (GCLC) and a modifier subunit (GCLM), which change the catalytic characteristics of the holoenzyme. To define the cellular function of GCLM, we disrupted the mouse Gclm gene to create a null allele. Gclm(-/-) mice are viable and fertile and have no overt phenotype. In liver, lung, pancreas, erythrocytes, and plasma, however, GSH levels in Gclm(-/-) mice were 9-16% of that in Gclm(+/+) littermates. Cysteine levels in Gclm(-/-) mice were 9, 35, and 40% of that in Gclm(+/+) mice in kidney, pancreas, and plasma, respectively, but remained unchanged in the liver and erythrocytes. Comparing the hepatic GCL holoenzyme with GCLC in the genetic absence of GCLM, we found the latter had an approximately 2-fold increase in K(m) for glutamate and a dramatically enhanced sensitivity to GSH inhibition. The major decrease in GSH, combined with diminished GCL activity, rendered Gclm(-/-) fetal fibroblasts strikingly more sensitive to chemical oxidants such as H(2)O(2). We conclude that the Gclm(-/-) mouse represents a model of chronic GSH depletion that will be very useful in evaluating the role of the GCLM subunit and GSH in numerous pathophysiological conditions as well as in environmental toxicity associated with oxidant insult.     

Drosophila neuralized is a ubiquitin ligase that promotes the internalization and degradation of delta.

The Drosophila gene neuralized (neur) has long been recognized to be essential for the proper execution of a wide variety of processes mediated by the Notch (N) pathway, but its role in the pathway has been elusive. In this report, we present genetic and biochemical evidence that Neur is a RING-type, E3 ubiquitin ligase. Next, we show that neur is required for proper internalization of Dl in the developing eye. Finally, we demonstrate that ectopic Neur targets Dl for internalization and degradation in a RING finger-dependent manner, and that the two exist in a physical complex. Collectively, our data indicate that Neur is a ubiquitin ligase that positively regulates the N pathway by promoting the endocytosis and degradation of Dl.     

The acute phase protein haptoglobin is a mammalian extracellular chaperone with an action similar to clusterin

Haptoglobin (Hp) is an acidic glycoprotein present in most body fluids of humans and other mammals. Although the functions of Hp are not yet fully understood, the available evidence indicates that it is likely to play an important role in suppressing inflammatory responses. Some earlier work suggested that Hp might be a newly identified member of a small group of extracellular chaperones found at significant levels in human body fluids. Previously, the only well-characterized member of this group was clusterin, which shares functional similarities with the small heat-shock proteins. We report here that Hp specifically inhibited the precipitation of a variety of proteins induced by either heat or oxidation, including proteins in unfractionated human serum. We also show that, like clusterin, Hp (i) inhibits the precipitation of stressed proteins by forming solubilized high molecular weight complexes with them, (ii) cannot protect enzymes from heat-induced loss of function, and (iii) lacks ATPase activity and the ability to independently refold proteins following stresses. Furthermore, we show that Hp has maximum chaperone activity at mildly alkaline pH and, unlike clusterin, does not undergo significant changes in oligomerization state coincident with pH-induced changes in chaperone activity. Our results raise the possibility that Hp may exert an anti-inflammatory action in vivo by inhibiting the inappropriate self-association of "damaged" (misfolded) extracellular proteins.     

Overexpression of Methoprene-tolerant, a Drosophila melanogaster gene that is critical for juvenile hormone action and insecticide resistance

The Methoprene-tolerant (Met) gene of Drosophila melanogaster is involved in both juvenile hormone (JH) action and resistance to JH insecticides, such as methoprene. Although the consequences of Met mutations on development and methoprene resistance are known, no studies have examined Met+ overexpression. Met+ was overexpressed in transgenic lines with various promoters that drive overexpression to different levels. Flies expressing either genomic or cDNA Met+ transgenes showed higher susceptibility to both the morphogenetic and toxic effects of methoprene, consistent with the hormone-binding property of MET. Both the sensitive period and lethal period were the same as seen for non-overexpressing Met+ flies. However, continual exposure of high-overexpressing Met+ larvae to borderline-toxic or higher methoprene doses advanced the sensitive period from prepupae to first instar and the lethal period from pharate adults to larvae and early pupae. When expression of transgenic UAS-Met+ was driven to high levels by either an actin-GAL4 or tubulin-GAL4 promoter, larvae showed high mortality in the absence of methoprene, indicating that high MET titer is lethal, perhaps resulting from expression in an inappropriate tissue. Adults overexpressing Met+ did not show enhanced oogenesis, ruling out MET as a limiting factor for this hormone-driven physiology.     

Heterochromatin of the Drosophila melanogaster Y chromosome as modifier of position effect variegation: the time of its action.

Summary Addition of heterochromatin suppresses while subtraction enhances position effect variegation. The heterochromatin-sensitive period has been determined in white/white-apricot variegated eyes of Y ^S w ^a /w ^a ; Dp (1;3) w ^265-58 flies. When such larvae, carrying a Y-short (Y ^S ) arm at the distal end of one X chromosome, are X-rayed, mitotic recombination leads to one daughter cell with two Y ^S arms and an adjacent daughter cell with no Y ^S arm. When induced after clonal initiation, the frequency of dark clones developing from daughter cells with two Y ^S arms is significantly higher than the frequency of dark clones in the rest of the eye; and this frequency is. even higher when induced before clonal initiation. The modifying action of the Y-heterochromatin is exerted, therefore, during and after clonal initiation. Surprisingly, the frequency of dark clones developing from cells with no Y ^S arm is not lower than the frequency of dark clones in the rest of the eye.     

Regulation of Commissureless by the ubiquitin ligase DNedd4 is required for neuromuscular synaptogenesis in Drosophila melanogaster

Muscle synaptogenesis in Drosophila melanogaster requires endocytosis of Commissureless (Comm), a binding partner for the ubiquitin ligase dNedd4. We investigated whether dNedd4 and ubiquitination mediate this process. Here we show that Comm is expressed in intracellular vesicles in the muscle, whereas Comm bearing mutations in the two PY motifs (L/PPXY) responsible for dNedd4 binding [Comm(2PY-->AY)], or bearing Lys-->Arg mutations in all Lys residues that serve as ubiquitin acceptor sites [Comm(10K-->R)], localize to the muscle surface, suggesting they cannot endocytose. Accordingly, aberrant muscle innervation is observed in the Comm(2PY-->AY) and Comm(10K-->R) mutants expressed early in muscle development. Similar muscle surface accumulation of Comm and innervation defects are observed when dNedd4 is knocked down by double-stranded RNA interference in the muscle, in dNedd4 heterozygote larvae, or in muscles overexpressing catalytically inactive dNedd4. Expression of the Comm mutants fused to a single ubiquitin that cannot be polyubiquitinated and mimics monoubiquitination [Comm(2PY-->AY)-monoUb or Comm(10K-->R)-monoUb] prevents the defects in both Comm endocytosis and synaptogenesis, suggesting that monoubiquitination is sufficient for Comm endocytosis in muscles. Expression of the Comm mutants later in muscle development, after synaptic innervation, has no effect. These results demonstrate that dNedd4 and ubiquitination are required for Commissureless endocytosis and proper neuromuscular synaptogenesis.