Efficient transformation of the yellow fever mosquito Aedes aegypti using the piggyBac transposable element vector pBac[3xP3-EGFP afm]

We report efficient germ-line transformation in the yellow fever mosquito Aedes aegypti accomplished using the piggyBac transposable element vector pBac[3xP3-EGFP afm]. Two transgenic lines were established and characterized; each contained the Vg-Defensin A transgene with strong eye-specific expression of the enhanced green fluorescent protein (EGFP) marker gene regulated by the artificial 3xP3 promoter. Southern blot hybridization and inverse PCR analyses of genomic DNA demonstrated a precise piggyBac-mediated, single copy insertion of the pBac[3xP3-EGFP afm,Vg-DefA] transposon in each transgenic line. For each line, genetic analysis confirmed stability and integrity of the entire transposon construct in the mosquito genome through the G2-G6 generations. Successful establishment of homozygous transgenic lines indicated that in both cases a non-lethal integration of the transposon into the mosquito genome had occurred. The 3xP3-EGFP marker was tested in mosquitoes with different genetic backgrounds. In white-eyed transgenic mosquitoes, the strong eye-specific expression of GFP was observed throughout all stages of development, starting from newly hatched first instar larvae to adults. A similar level and pattern of fluorescence was observed in red-eyed mosquitoes that were generated by crossing the 3xP3-EGFP transformants with the kh(w) white-eye mosquitoes transformed with the Drosophila cinnabar gene. Importantly, the utility of the 3xP3-EGFP, as marker gene for transformation of wild type mosquitoes, was demonstrated by strong eye-specific GFP expression in larval and pupal stages of black-eyed hybrids of the 3xP3-EGFP white-eye transformants and the wild type Rockefeller/UGAL strain. Finally, analysis of the Vg-DefA transgene expression in transformants from two established lines demonstrated strong blood-meal activation and fat-body-specific expression regulated by the Vg 1.8-kb 5' upstream region.

Organization and developmental expression of the mosquito vitellogenin receptor gene

Vitellogenin is a precursor of the major yolk protein, vitellin. It is internalized by developing oocytes via receptor-mediated endocytosis. Previously, we characterized the vitellogenin receptor (VgR) from oocytes of the mosquito Aedes aegypti [Sappington, T.W., Kokoza,V.A., Cho,W.L. and Raikhel,A.S. (1996) Molecular characterization of the mosquito vitellogenin receptor reveals unexpected high homology to the Drosophila yolk protein receptor. Proc Natl Acad Sci USA 93: 8934-8939]. The VgR receptor has a unique structure with two putative ligand-binding domains. In order to understand the regulation of this important molecule, we characterized the VgR gene structure and its expression during vitellogenesis in the mosquito A. aegypti. We report here that the VgR gene was separated by five introns that have an average length of 60 bp, except for the second intron which was more than 20 kb long. Most introns were located within the coding regions of the first protein domain. We isolated two allelic variations of the VgR gene, VgR1 and VgR2, the nucleotide sequences of which differing only in their 5'-flanking regions. Considering their frequency in the mosquito genome, VgR2 appeared to be a major allele. The expression of VgR mRNA was studied by the Northern blot analysis and in situ hybridization. The level of the VgR transcript started to rise in the ovary one day post-eclosion. It continued its dramatic rise during the vitellogenic period, reaching its peak at 24 h PBM. The VgR transcript was present exclusively in ovaries where it was seen in oocytes and nurse cells of primary follicles and germ-line cells of the germarium.

Requirement of co-factors for the ligand-mediated activity of the insect ecdysteroid receptor in yeast

In insects, a steroid hormone 20-hydroxyecdysone has an important role in regulating critical events such as development and reproduction. The action of 20-hydroxyecdysone is mediated by its binding to the ecdysteroid receptor (EcR), which requires a heterodimeric partner, ultraspiracle protein (USP), a homologue of the retinoid X receptor (RXR). The EcR-USP heterodimer represents a functional receptor complex capable of initiating transcription of early genes. Our goal was to establish a ligand-dependent transactivation system in yeast utilizing an insect EcR-USP heterodimer. This has been achieved using mosquito Aedes aegypti AaEcR-USP. Expression of AaEcR alone, but not USP, resulted in constitutive transcription of the ecdysone reporter gene coupled with the Drosophila heat shock protein-27 ecdysone response elements. Removal of the N-terminal A/B domain of AaEcR abolished its constitutive transcription. Constitutive transcription was also eliminated in the presence of its heterodimeric partner, AaUSPa, AaUSPb or mammalian RXR. This suggests that the A/B domain is essential for the EcR ligand-independent transactivation and its interaction with the yeast transcription complex. A ligand-mediated transactivation of Aa(Delta A/B)EcR-USP or Aa(Delta A/B)EcR-RXR heterodimers in response to an ecdysteroid agonist RH-5992 was observed only in the presence of GRIP1, a mouse co-activator. In the presence of a co-repressor, SMRT, Aa(Delta A/B)EcR-USP heterodimer exhibited a ligand-dependent repression activity. In addition, ligand-dependent transactivation systems for spruce budworm and fruit fly ecdysone receptors were also reported. This is the first report establishing the requirements of co-factors for a highly efficient ligand-dependent function of the insect EcR-USP in yeast. These findings open a way to study insect EcR-USP structure and function and to identify ligands that are specific for a certain group of insects, such as mosquitoes.

Transcriptional regulation of the mosquito vitellogenin gene via a blood meal-triggered cascade

In anautogenous mosquitoes, a blood meal is required for activation of genes encoding yolk protein precursors (YPP). Vitellogenin (Vg), the major YPP gene, is transcribed at a very high level following blood meal activation. It is expressed exclusively in the female fat body, the tissue producing most of mosquito hemolymph and immune proteins. In this paper, we analyzed the upstream region of the Aedes aegypti Vg gene in order to identify regulatory elements responsible for its unique expression pattern. To achieve this goal, we analyzed the gene using transgenic Drosophila and Aedes as well as DNA-binding assays. These analyses revealed three regulatory regions in the 2.1 kb upstream portion of the Vg gene. The proximal region containing binding sites to EcR/USP, GATA, C/EBP and HNF3/fkh is required for the correct tissue- and stage-specific expression at a low level. The median region carrying sites for early ecdysone response factors E74 and E75 is responsible for hormonal enhancement of Vg expression. Finally, the distal GATA-rich region is necessary for extremely high expression levels characteristic of the Vg gene. The present work elucidates the molecular basis of blood meal-dependent expression of this mosquito gene, laying the foundation for mosquito-specific expression cassettes with predictable stage and tissue specificity.

Molecular characterization of the VLDL receptor homolog mediating binding of lipophorin in oocyte of the mosquito Aedes aegypti

Lipophorin (Lp) functions as a yolk protein precursor in the mosquito Aedes aegypti and it is internalized via receptor-mediated endocytosis (Insect Biochem. Mol. Biol., 30 (2000) 1161). We cloned and molecularly characterized a putative mosquito ovarian lipophorin receptor (AaLpRov) cDNA. The cDNA has a length of 3468 bp coding for a 1156-residue protein with a predicted molecular mass of 128.9 kDa. The deduced amino acid sequence of the cDNA revealed that it encodes a protein homolog of the LDL receptor superfamily, and that it harbors eight cysteine-rich ligand binding repeats at the N-terminus like vertebrate VLDL receptors. The deduced amino acid sequence of this mosquito ovarian receptor is most similar to that of the locust lipophorin receptor (LmLpR) (64.3%), and is only distantly related to the mosquito vitellogenin receptor (VgR) (18.3%), another ovarian LDLR homolog with a different ligand. The AaLpRov cDNA was expressed in a TnT Coupled Reticulocyte Lysate system, and co-immunoprecipitation experiments confirmed that the receptor protein specifically binds Lp. Developmental expression profiles clearly showed that AaLpRov transcripts are present in the vitellogenic ovary, with peak expression at 24-36 h post blood meal. In situ hybridization indicated that AaLpRov transcripts are present only in female germ line cells. Distance-based phylogenetic analyses suggest that the insect LpR and vertebrate LDL/VLDL receptor lineages separated after divergence from the insect VgR lineage.

A novel function of 20-hydroxyecdysone: translational repression of the lysosomal protease mRNA in the mosquito fat body

In the female fat body of the mosquito Aedes aegypti, lysosomes play important roles during the cessation of vitellogenesis by degrading the biosynthetic machinery and aiding the remodeling of the fat body cells. A detailed study of a mosquito lysosomal aspartic protease (AaLAP) has shown a unique expression pattern in the vitellogenic fat body: the level of AaLAP mRNA dramatically rises and peaks at 24 h post blood meal (PBM) correlating with the high titer of ecdysteroids; however, there is a 12 h lag before peak levels of AaLAP protein and its enzymatic activity has been observed. These observations suggest that the high titer of 20-hydroxyecdysone (20E) may hinder translation of the AaLAP mRNA. Here, we used an in vitro organ culture to study the effect of 20E on the protein synthesis of AaLAP in the fat body. The increase in the AaLAP protein level in the fat body, dissected at 24 h PBM and incubated for 6 or 12 h, was inhibited by the presence of 10(-5) M 20E in the medium. Incubation in the hormone-free medium did not effect accumulation of the AaLAP protein which proceeded at the levels comparable to the intact insect. Furthermore, the effect of 10(-5) M 20E on the AaLAP accumulation was reversible. These experiments support the hypothesis of the 20E-mediated repression of lysosomal protease mRNAs at the translational level in the regulation of vitellogenic and postvitellogenic events in the mosquito fat body. Analysis of the 5' and 3' -end untranslated regions (UTR) of AaLAP mRNA form secondary structures suggest that they may also contribute to mRNA stability and 20E-mediated translational inhibition.

The vitellogenin gene of the mosquito Aedes aegypti is a direct target of ecdysteroid receptor

In the female mosquito Aedes aegypti, vitellogenin (Vg), the major YPP, is activated by 20-hydroxyecdysone (20E) at the transcriptional level. We used cell transfection assays in the Drosophila S2 cells to investigate whether 20E acts directly on the Vg gene via its functional receptor, the heterodimer composed of the ecdysteroid receptor (EcR) and the ultraspiracle (USP) proteins. We demonstrated that the Vg 5'-regulatory region contains a functional ecdysteroid-responsive element (VgEcRE1) that is necessary to confer responsiveness to 20E. VgEcRE binds directly to EcR-USP produced in vitro and extracted from the vitellogenic fat body nuclei. The binding intensity of the EcR-USP-EcRE1 complex from nuclear extracts corresponds to the levels of ecdysteroids and of the Vg transcript during the vitellogenic cycle. Given the modest level of 20E-dependent activation, it is likely that the EcR-USP receptor acts synergistically with other transcription factors to bring about the high level of Vg gene expression.

A novel GATA factor transcriptionally represses yolk protein precursor genes in the mosquito Aedes aegypti via interaction with the CtBP corepressor

In anautogenous mosquitoes, vitellogenesis, the key event in egg maturation, requires a blood meal. Consequently, mosquitoes are vectors of many devastating human diseases. An important adaptation for anautogenicity is the previtellogenic arrest (the state of arrest) preventing the activation of the yolk protein precursor (YPP) genes Vg and VCP prior to blood feeding. A novel GATA factor (AaGATAr) that recognizes GATA binding motifs (WGATAR) in the upstream region of the YPP genes serves as a transcriptional repressor at the state of arrest. Importantly, AaGATAr can override the 20-hydroxyecdysone transactivation of YPP genes, and its transcriptional repression involves the recruitment of CtBP, one of the universal corepressors. AaGATAr transcript is present only in the adult female fat body. Furthermore, in nuclear extracts of previtellogenic fat bodies with transcriptionally repressed YPP genes, there is a GATA binding protein forming a band with mobility similar to that of AaGATAr. The specific repression of YPP genes by AaGATAr in the fat body of the female mosquito during the state of arrest represents an important molecular adaptation for anautogenicity.

Lipophorin as a yolk protein precursor in the mosquito, Aedes aegypti

We examined expression of the lipophorin (Lp) gene, lipophorin (Lp) synthesis and secretion in the mosquito fat body, as well as dynamic changes in levels of this lipoprotein in the hemolymph and ovaries, during the first vitellogenic cycle of females of the yellow fever mosquito, Aedes aegypti. Lipophorin was purified by potassium bromide (KBr) density gradient ultracentrifugation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Polyclonal antibodies were produced against individual Lp apoproteins, apolipoprotein-I (apoLp-I) and apolipoprotein-II (apoLp-II), with molecular weights of 240 and 75 kDa, respectively. We report here that in the mosquito A. aegypti, Lp was synthesized by the fat body, with a low level of the Lp gene expression and protein synthesis being maintained in pre- and postvitellogenic females. Following a blood meal, the Lp gene expression and protein synthesis were significantly upregulated. Our findings showed that the fat body levels of Lp mRNA and the rate of Lp secretion by this tissue reached their maximum at 18 h post-blood meal (PMB). 20-Hydroxyecdysone was responsible for an increase in the Lp gene expression and Lp protein synthesis in the mosquito fat body. Finally, the immunocytochemical localization of Lp showed that in vitellogenic female mosquitoes, this protein was accumulated by developing oocytes where it was deposited in yolk granules.

Conserved molecular mechanism for the stage specificity of the mosquito vitellogenic response to ecdysone

In the mosquito Aedes aegypti, the adult female becomes competent for a vitellogenic response to ecdysone after previtellogenic development. Here, we show that betaFTZ-F1, the nuclear receptor implicated as a competence factor for stage-specific responses to ecdysone during Drosophila metamorphosis, serves a similar function during mosquito vitellogenesis. AaFTZ-F1 is expressed highly in the mosquito fat body during pre- and postvitellogenic periods when ecdysteroid titers are low. The mosquito AaFTZ-F1 transcript nearly disappears in mid-vitellogenesis when ecdysteroid titers are high. An expression peak of HR3, a nuclear receptor implicated in the activation of betaFTZ-F1 in Drosophila, precedes each rise in mosquito FTZ-F1 expression. In in vitro fat body culture, AaFTZ-F1 expression is inhibited by 20-hydroxyecdysone (20E) and superactivated by its withdrawal. Following in vitro AaFTZ-F1 superactivation, a secondary 20E challenge results in superinduction of the early AaE75 gene and the late target VCP gene. Electrophoretic mobility-shift assays show that the onset of ecdysone-response competence in the mosquito fat body is correlated with the appearance of the functional AaFTZ-F1 protein at the end of the previtellogenic development. These findings suggest that a conserved molecular mechanism for controlling stage specificity is reiteratively used during metamorphic and reproductive responses to ecdysone.

Molecular determinants of differential ligand sensitivities of insect ecdysteroid receptors

The functional receptor for insect ecdysteroid hormones is a heterodimer consisting of two nuclear hormone receptors, ecdysteroid receptor (EcR) and the retinoid X receptor homologue Ultraspiracle (USP). Although ecdysone is commonly thought to be a hormone precursor and 20-hydroxyecdysone (20E), the physiologically active steroid, little is known about the relative activity of ecdysteroids in various arthropods. As a step toward characterization of potential differential ligand recognition, we have analyzed the activities of various ecdysteroids using gel mobility shift assays and transfection assays in Schneider-2 (S2) cells. Ecdysone showed little activation of the Drosophila melanogaster receptor complex (DmEcR-USP). In contrast, this steroid functioned as a potent ligand for the mosquito Aedes aegypti receptor complex (AaEcR-USP), significantly enhancing DNA binding and transactivating a reporter gene in S2 cells. The mosquito receptor also displayed higher hormone-independent DNA binding activity than the Drosophila receptor. Subunit-swapping experiments indicated that the EcR protein, not the USP protein, was responsible for ligand specificity. Using domain-swapping techniques, we made a series of Aedes and Drosophila EcR chimeric constructs. Differential ligand responsiveness was mapped near the C terminus of the ligand binding domain, within the identity box previously implicated in the dimerization specificity of nuclear receptors. This region includes helices 9 and 10, as determined by comparison with available crystal structures obtained from other nuclear receptors. Site-directed mutagenesis revealed that Phe529 in Aedes EcR, corresponding to Tyr611 in Drosophila EcR, was most critical for ligand specificity and hormone-independent DNA binding activity. These results demonstrated that ecdysone could function as a bona fide ligand in a species-specific manner.

Expression of the early-late gene encoding the nuclear receptor HR3 suggests its involvement in regulating the vitellogenic response to ecdysone in the adult mosquito

The insect steroid hormone, 20-hydroxyecdysone (20E), is a key factor controlling critical developmental events of embryogenesis, larval molting, metamorphosis, and, in some insects, reproduction. We are interested in understanding the molecular basis of the steroid hormone ecdysone action in insect egg development. The yellow fever mosquito, Aedes aegypti, in addition to being an important vector of human diseases, represents an outstanding model for studying molecular mechanisms underlying egg maturation due to stringently controlled, blood meal-activated reproductive events in this insect. To elucidate the genetic regulatory hierarchy controlling the reproductive ecdysone response, we have investigated ecdysone-regulated gene expression in vitellogenic mosquito ovaries and fat bodies. We have previously demonstrated the conservation of a primary ecdysone-triggered regulatory hierarchy, implicated in development of immature stages of Drosophila, represented by the ecdysone receptor/Ultraspiracle complex and an early gene E75 during the reproductive ecdysone response (Wang, S.-F., Miura, K., Miksicek, R.J., Segraves, W.A., Raikhel, A.S., 1998. DNA binding and transactivation characteristics of the mosquito ecdysone receptor - Ultraspiracle complex. J. Biol. Chem. 273, 27531-27540; Pierceall, W. E., Li, C., Biran, A., Miura, K., Raikhel, A.S., Segraves, W.A., 1999. E75 expression in mosquito ovary and fat body suggests reiterative use of ecdysone-regulated hierarchies in development and reproduction. Mol. Cell. Endocrinol. 150, 73-89). The present paper demonstrates that conservation of the factors involved in the ecdysone-responsive genetic hierarchy regulating female reproduction extends beyond the early genes. Here, we identify AHR3, a highly conserved homologue of the Drosophila HR3 early-late ecdysone-inducible gene in the mosquito. We show that AHR3 is expressed in both vitellogenic tissues of the female mosquito, the fat body and the ovary. The expression of AHR3 correlates with the ecdysteroid titer, reaching a peak at 24 h after a blood meal. Moreover, in vitro fat body culture experiments demonstrate that the kinetics and dose response of AHR3 to 20-hydroxyecdysone (20E), an active ecdysteroid in the mosquito, is similar to those of the late vitellogenic genes rather than the early E75 gene. However, as shown for other early and early-late genes, the 20E activation of AHR3 is not inhibited by the presence of cycloheximide, a protein synthesis inhibitor. Taken together, these findings strongly suggest AHR3 involvement in regulating the vitellogenic response to ecdysone in the adult mosquito.

Differential expression and regulation by 20-hydroxyecdysone of mosquito ultraspiracle isoforms

Ultraspiracle (USP), the insect homologue of the vertebrate retinoid X receptor, is an obligatory dimerization partner for the ecdysteroid receptor (EcR). Two USP isoforms, USP-A and USP-B, with distinct N-termini, occur in the mosquito Aedes aegypti. In the fat body and ovary, USP-A mRNA is highly expressed during the pre- and late vitellogenic stages, corresponding to a period of low ecdysteroid titer, while USP-B mRNA exhibits its highest levels during the vitellogenic period, correlating with a high ecdysteroid titer. Remarkably, 20-hydroxyecdysone (20E) has opposite effects on USP isoform transcripts in in vitro fat body culture. This steroid hormone upregulates USP-B transcription and its presence is required to sustain a high level of USP-B expression. In contrast, 20E inhibits activation of USP-A transcription. Although EcR.USP-A recognizes the same ecdysteroid-responsive elements, EcR.USP-B binds them with an affinity twofold higher than that of EcR.USP-A. Likewise, EcR.USP-B transactivates a reporter gene in CV-1 cells twofold more strongly than EcR.USP-A. These results suggest that USP-B functions as a major heterodimerization partner for EcR during the vitellogenic response to 20E in the mosquito.

AHR38, a homolog of NGFI-B, inhibits formation of the functional ecdysteroid receptor in the mosquito Aedes aegypti

In anautogenous mosquitoes, vitellogenesis, the key event in egg maturation, requires a blood meal. Consequently, mosquitoes are vectors of numerous devastating human diseases. After ingestion of blood, 20-hydroxyecdysone activates yolk protein precursor (YPP) genes in the metabolic tissue, the fat body. An important adaptation for anautogenicity is the previtellogenic developmental arrest (the state-of-arrest) preventing the activation of YPP genes in previtellogenic females prior to blood feeding. Here, we show that a retinoid X receptor homolog, Ultraspiracle (AaUSP), which is an obligatory partner in the functional ecdysteroid receptor, exists at the state-of-arrest as a heterodimer with the orphan nuclear receptor AHR38, a homolog of Drosophila DHR38 and nerve growth factor-induced protein B. Yeast two-hybrid and glutathione S-transferase pull-down assays demonstrate that AHR38 can interact strongly with AaUSP. AHR38 also disrupts binding of ecdysteroid receptor to ecdysone response elements. Cell co-transfection of AHR38 with AaEcR and AaUSP inhibits ecdysone-dependent activation of a reporter gene by the ecdysteroid receptor. Co-immunoprecipitation experiments indicate that AaUSP protein associates with AHR38 instead of AaEcR in fat body nuclei at the state-of-arrest.

Two distinct subpopulations of ecdysone receptor complex in the female mosquito during vitellogenesis

The native functional ecdysone receptor complex, a heterodimer of the ecdysone receptor (EcR) and ultraspiracle (USP) proteins, was identified in the fat body of adult female mosquitoes, Aedes aegypti, through electrophoretic mobility shift assays (EMSA) using previously characterized Drosophila ecdysone response elements (EcREs). The use of different salt concentrations during preparation of nuclear extracts enabled us to characterize two distinct subpopulations of the receptor complex, one of which was high salt-sensitive and responsive to exogenous 20-hydroxyecdysone (20E), and the other of which was high salt-resistant and refractory to exogenous 20E. Salt-sensitivity correlated with ligand responsiveness. Developmental EMSA analyses demonstrated that previtellogenic fat body nuclei and nuclei from the termination phase of vitellogenesis with low 20E titer contained solely high-salt-sensitive, ligand responsive complexes, which could be recovered in nuclear extracts (NEs) only by low salt tissue homogenization, suggesting these complexes were unliganded. In contrast, the fat body nuclei from stages of active vitellogenesis with high 20E titer contained almost exclusively high salt-resistant, ligand refractory complexes, implying these complexes were liganded; the nuclei from the intermediate stages, early and late phases of vitellogenesis, contained a mixture of the two subpopulations. The developmental profile of fully activated, ligand refractory receptor complexes closely correlated with that of yolk protein expression, suggesting an intimate involvement of the ecdysone receptor complex in both the induction and maintenance of high level expression of yolk protein genes.

Mosquito cathepsin B-like protease involved in embryonic degradation of vitellin is produced as a latent extraovarian precursor

Here we report identification of a novel member of the thiol protease superfamily in the yellow fever mosquito, Aedes aegypti. It is synthesized and secreted as a latent proenzyme in a sex-, stage-, and tissue-specific manner by the fat body, an insect metabolic tissue, of female mosquitoes during vitellogenesis in response to blood feeding. The secreted, hemolymph form of the enzyme is a large molecule, likely a hexamer, consisting of 44-kDa subunits. The deduced amino acid sequence of this 44-kDa precursor shares high similarity with cathepsin B but not with other mammalian cathepsins. We have named this mosquito enzyme vitellogenic cathepsin B (VCB). VCB decreases to 42 kDa after internalization by oocytes. In mature yolk bodies, VCB is located in the matrix surrounding the crystalline yolk protein, vitellin. At the onset of embryogenesis, VCB is further processed to 33 kDa. The embryo extract containing the 33-kDa VCB is active toward benzoyloxycarbonyl-Arg-Arg-para-nitroanilide, a cathepsin B-specific substrate, and degrades vitellogenin, the vitellin precursor. Both of these enzymatic activities are prevented by trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane (E-64), a thiol protease inhibitor. Furthermore, addition of the anti-VCB antibody to the embryonic extract prevented cleavage of vitellogenin, strongly indicating that the activated VCB is involved in embryonic degradation of vitellin.

E75 expression in mosquito ovary and fat body suggests reiterative use of ecdysone-regulated hierarchies in development and reproduction

The steroid hormone ecdysone controls genetic regulatory hierarchies underlying insect molting, metamorphosis and, in some insects, reproduction. Cytogenetic and molecular analysis of ecdysone response in Drosophila larval salivary glands has revealed regulatory hierarchies including early genes which encode transcription factors controlling late ecdysone response. In order to determine whether similar hierarchies control reproductive ecdysone response, we have investigated ecdysone-regulated gene expression in vitellogenic mosquito ovaries and fat bodies. Here, we identify the homologue of the Drosophila E75 early ecdysone inducible gene in the yellow fever mosquito Aedes aegypti, and show that, as in Drosophila, the mosquito homologue, AaE75, consists of three overlapping transcription units with three mRNA isoforms, AaE75A, AaE75B, and AaE75C, originating as a result of alternative splicing. All three AaE75 isoforms are induced at the onset of vitellogenesis by a blood meal-activated hormonal cascade, and highly expressed in the mosquito ovary and fat body, suggesting their involvement in the regulation of oogenesis and vitellogenesis, respectively. Furthermore, in vitro fat body culture experiments demonstrate that AaE75 isoforms are induced by 20-hydroxyecdysone, an active ecdysteroid in the mosquito. These findings suggest that related ecdysone-triggered regulatory hierarchies may be used reiteratively during developmental and reproductive ecdysone responses.

Three isoforms of a hepatocyte nuclear factor-4 transcription factor with tissue- and stage-specific expression in the adult mosquito

We cloned three isoforms of hepatocyte nuclear factor-4 (HNF-4) from the mosquito Aedes aegypti, designated AaHNF-4a, AaHNF-4b, and AaHNF-4c. AaHNF-4a and AaHNF-4b are typical members of the HNF-4 subfamily of nuclear receptors with high amino acid conservation. They differ in N-terminal regions and exhibit distinct developmental profiles in the female mosquito fat body, a metabolic tissue functionally analogous to the vertebrate liver. The AaHNF-4b mRNA is predominant during the previtellogenic and vitellogenic phases, while the AaHNF-4a mRNA is predominant during the termination phase of vitellogenesis, coinciding with the onset of lipogenesis. The third isoform, AaHNF-4c, lacks part of the A/B and the entire C (DNA-binding) domains. The AaHNF-4c transcript found in the fat body during the termination of vitellogenesis may serve as a transcriptional inhibitor. Both AaHNF-4a and AaHNF-4b bind to the cognate DNA recognition site in electrophoretic mobility shift assay. Dimerization of AaHNF-4c with other mosquito HNF-4 isoforms or with mammalian HNF-4 prevents binding to the HNF-4 response element. In transfected human 293T cells, AaHNF-4c significantly reduced the transactivating effect of the human HNF-4alpha1 on the apolipoprotein CIII promoter. Electrophoretic mobility shift assay confirmed the presence of HNF-4 binding sites upstream of A. aegypti vg and vcp, two yolk protein genes expressed in the female mosquito fat body during vitellogenesis. Therefore, HNF-4, an important regulator of liver-specific genes, plays a critical role in the insect fat body.

DNA binding and transactivation characteristics of the mosquito ecdysone receptor-Ultraspiracle complex

The steroid hormone 20-hydroxyecdysone is a key regulatory factor, controlling blood-meal triggered egg maturation in mosquitoes. To elucidate the ecdysone hierarchy governing this event, we cloned and characterized the ecdysone receptor (AaEcR) and the nuclear receptor Ultraspiracle (AaUSP), a retinoid X receptor homologue, from the mosquito, Aedes aegypti, which form a functional complex capable of ligand and DNA binding. Here we analyzed the DNA-binding properties of the AaEcR.AaUSP heterodimer with respect to the effects of nucleotide sequence, orientation, and spacing between half-sites in natural Drosophila and synthetic ecdysone response element (EcREs). By using an electrophoretic gel mobility shift assay, we showed that AaEcR.AaUSP exhibits a broad binding specificity, forming complexes with inverted (IR) and direct (DR) repeats of the nuclear receptor response element half-site consensus sequence AGGTCA separated by spacers of variable length. A single nucleotide spacer was optimal for both imperfect (IRhsp-1) and perfect (IRper-1) inverted repeats; adding or removing 1 base pair in an IRhsp-1 spacer practically abolished binding. However, changing the half-site to the consensus sequence AGGTCA (IRper-1) increased binding of AaEcR.AaUSP 10-fold over IRhsp-1 and, at the same time, reduced the stringency of the spacer length requirement, with IRper-0 to IRper-5 showing detectable binding. Spacer length was less important in DRs of AGGTCA (DR-0 to DR-5); although 4 bp was optimal, DR-3 and DR-5 bound AaEcR.AaUSP almost as efficiently as DR-4. Furthermore, AaEcR. AaUSP also bound DRs separated by 11-13 nucleotide spacers. Competition experiments and direct estimation of binding affinity (Kd) indicated that, given identical consensus half-sites and an optimal spacer, the AaEcR.AaUSP heterodimer bound an IR with higher affinity than a DR. Co-transfection assays utilizing CV-1 cells demonstrated that the mosquito EcR.USP heterodimer is capable of transactivating reporter constructs containing either IR-1 or DR-4. The levels of transactivation are correlated with the respective binding affinities of the response elements (IRper-1 > DR-4 > IRhsp-1). Taken together, these analyses predict broad variability in the EcREs of mosquito ecdysone-responsive genes.

Molecular characteristics of insect vitellogenins and vitellogenin receptors

The recent cloning and sequencing of several insect vitellogenins (Vg), the major yolk protein precursor of most oviparous animals, and the mosquito Vg receptor (VgR) has brought the study of insect vitellogenesis to a new plane. Insect Vgs are homologous to nematode and vertebrate Vgs. All but one of the insect Vgs for which we know the primary structure are cleaved into two subunits at a site [(R/K)X(R/K)R or RXXR with an adjacent beta-turn] recognized by subtilisin-like proprotein convertases. In four of the Vgs, the cleavage site is near the N-terminus, but in one insect species, it is near the C-terminus of the Vg precursor. Multiple alignments of these Vg sequences indicate that the variation in cleavage location has not arisen through exon shuffling, but through local modifications of the amino acid sequences. A wasp Vg precursor is not cleaved, apparently because the sequence at the presumed ancestral cleavage site has been mutated from RXRR to LYRR and is no longer recognized by convertases. Some insect Vgs contain polyserine domains which are reminiscent of, but not homologous to, the phosvitin domain in vertebrate Vgs. The sequence of the mosquito VgR revealed that it is a member of the low-density lipoprotein receptor (LDLR) family. Though resembling chicken and frog VgRs, which are also members of the LDLR family, it is twice as big, carrying two clusters of cysteine-rich complement-type (Class A) repeats (implicated in ligand-binding) instead of one like vertebrate VgRs and LDLRs. It is very similar in sequence and domain arrangement to the Drosophila yolk protein receptor (YPR), despite a non-vitellogenin ligand for the latter. Though vertebrate VgRs, insect VgR/YPRs, and LDLR-related proteins/megalins all accommodate one cluster of eight Class A repeats, fingerprint analysis of the repeats in these clusters indicate they are not directly homologous with one another, but have undergone differing histories of duplications, deletions, and exon shuffling so that their apparent similarity is superficial. The so-called epidermal growth factor precursor region contains two types of motifs (cysteine-rich Class B repeats and YWXD repeats) which occur independently of one another in diverse proteins, and are often involved in protein-protein interactions, suggesting that they potentially are involved in dimerization of VgRs and other LDLR-family proteins. Like the LDLR, but unlike vertebrate VgRs and the Drosophila YPR, the mosquito VgR contains a putative O-linked sugar region on the extra-cellular side of the transmembrane domain. Its function is unclear, but may protect the receptor from membrane-bound proteases. The cytoplasmic tail of insect VgR/YPRs contains a di-leucine (or leucine-isoleucine) internalization signal, unlike the tight-turn tyrosine motif of other LDLR-family proteins. The importance of understanding the details of yolk protein uptake by oocytes lies in its potential for exploitation in novel insect control strategies, and the molecular characterization of the proteins involved has made the development of such strategies a realistic possibility.

Ligand-binding domains in vitellogenin receptors and other LDL-receptor family members share a common ancestral ordering of cysteine-rich repeats

Insect vitellogenin and yolk protein receptors (VgR/YPR) are newly discovered members of the low-density lipoprotein receptor (LDLR) family, which is characterized by a highly conserved arrangement of repetitive modular elements homologous to functionally unrelated proteins. The insect VgR/YPRs are unique in having two clusters of complement-type cysteine-rich (class A) repeats or modules, with five modules in the first cluster and seven in the second cluster, unlike classical LDLRs which have a single seven-module cluster, vertebrate VgRs and very low density lipoprotein receptors (VLDLR) which have a single eight-module cluster, and LDLR-related proteins (LRPs) and megalins which have four clusters of 2-7, 8, 10, and 11 modules. Alignment of clusters across subfamilies by conventional alignment programs is problematic because of the repetitive nature of the component modules which may have undergone rearrangements, duplications, and deletions during evolution. To circumvent this problem, we "fingerprinted" each class A module in the different clusters by identifying those amino acids that are both relatively conserved and relatively unique within the cluster. Intercluster reciprocal comparisons of fingerprints and aligned sequences allowed us to distinguish four cohorts of modules reflecting shared recent ancestry. All but two of the 57 modules examined could be assigned to one of these four cohorts designated A, B, C, and D. Alignment of clusters based on modular cohorts revealed that all clusters are derived from a single primordial cluster of at least seven modules with a consensus arrangement of CDCADBC. All extant clusters examined are consistent with this consensus, though none matches it perfectly. This analysis also revealed that the eight-module clusters in vertebrate VgRs, insect VgR/YPRs, and LRP/megalins are not directly homologous with one another. Assignment of modules to cohorts permitted us to properly align 32 class A clusters from all four LDLR subfamilies for phylogenetic analysis. The results revealed that smaller one-cluster and two-cluster members of the family did not originate from the breakup of a large two-cluster or four-cluster receptor. Similarly, the LRP/megalins did not arise from the duplication of a two-cluster insect VgR/YPR-like progenitor. Rather, it appears that the multicluster receptors were independently constructed from the same single-cluster ancestor.

Mosquito clathrin heavy chain: analysis of protein structure and developmental expression in the ovary during vitellogenesis

We have deduced the amino acid sequences of clathrin heavy chain (CHC) polypeptides based on cDNA and genomic clones from the mosquito, Aedes aegypti. Two isoforms which differ in the very beginning of the N-terminal domain, ovary-specific AaCHCa and somatic-specific AaCHCb, were identified, characterized and compared to one another as well as to CHC polypeptides from different species. The 1682 amino acid sequence of the AaCHCa isoform predicts a molecular mass (M[r]) of 191,743 daltons and an isoelectric point of 5.80, whereas the 1674 amino acid sequence of the AaCHCb isoform predicts a M(r) of 191,033 daltons and an isoelectric point of 5.71. Both mosquito AaCHC isoforms are highly conserved, with full-sequence identities of 88% to Drosophila melanogaster, 81% to mammal (rat, cow and human), 71% to C. elegans, 58% to Dictyostelium discoideum, and 49% to yeast CHC polypeptides. The highest degree of conservation is in the middle portion of the mosquito CHC molecule which includes the linker region and extended triskelion arm, with decreasing conservation through the N-terminal domain, trimerization domain, and the relatively diverged C-terminal region. The protein domains do not directly correspond to specific exons of the mosquito AaCHC gene, with the exception of exon 6 which encodes the C-terminal domain of the CHC polypeptide. Polyclonal antibodies raised against a bacteria-expressed AaCHC fusion protein recognized one major band of about 180 kDa in vitellogenic ovary whole-lysate. Immunogold labelling of the AaCHC polypeptide localized it to the coat of coated pits and coated vesicles in oocytes from vitellogenic follicles. Northern blot and in situ hybridization analyses suggest that regulation of AaCHC gene expression in the ovary is complex, and it likely involves both developmental and hormonal signals.

Secretory and internalization pathways of mosquito yolk protein precursors

The vitellogenic female fat body of the mosquito Aedes aegypti produces three yolk protein precursors that are deposited in the yolk bodies of developing oocytes: vitellogenin, vitellogenic carboxypeptidase (VCP), and 44-kDa protein (44KP). We have used gold immunocytochemistry to investigate the pathways of their secretion in fat body trophocytes and their internalization by oocytes. In fat body trophocytes, all three yolk protein precursors are co-localized in the Golgi complex and secretory granules, indicating that they proceed simultaneously through the secretory pathway. The lysosomal system plays an important role in the termination of vitellogenesis in mosquito trophocytes, by degrading biosynthetic organelles and secretory granules. At this time, VCP and 44KP are found together with vitellogenin in trophocyte autophagolysosomes, suggesting that all three yolk protein precusors are redirected from the secretory to the lysosomal degradative pathway. Localization of VCP and 44KP in developing mosquito oocytes clearly shows that the internalization of these yolk protein precursors by oocytes occurs via the same endocytotic route as vitellogenin: all three yolk protein precursors are found on the oocyte microvillus membrane, in coated vesicles, and early endosomes. They are observed intermixed with one another in the late endosomes or in transitional yolk bodies. In mature yolk bodies, however, 44KP and VCP are segregated from vitellin, the crystallized storage form of vitellogenin; 44KP and VCP reside in the non-crystalline cortex, surrounding the vitellin core in nature yolk bodies.

Internalization and recycling of vitellogenin receptor in the mosquito oocyte

The major yolk protein precursor in mosquito oocytes, vitellogenin (Vg), is internalized by a 205-kDa membrane-bound receptor (VgR). Recently, VgR has been isolated permitting the production of polyclonal anti-VgR antibodies. To elucidate the pathway of VgR internalization and recycling in mosquito oocytes during Vg uptake, we carried out an immunogold electron-microscopic study, labeling both Vg and VgR in ultrathin frozen sections of ovarian tissue. VgR immunolabeling demonstrated that the oocyte plasma membrane was subdivided into microdomains, with VgR being located between and at the lower portions of the oocyte microvilli. During the early stages of internalization, Vg and VgR were observed together in coated pits, coated vesicles, and early endosomes. Fusion of early endosomes created transitional yolk bodies (TYB) in which Vg and VgR became segregated. VgR label was present in the numerous tubular compartments that protruded from the TYBs. These tubular organelles extended to and fused with the plasma membrane, suggesting that they represented the vehicle for VgR recycling. Vg label was not observed in the tubular compartments. Instead, Vg accumulated in the core of the TYB, a region free of VgR label. Mature yolk bodies (MYB) were heavily labeled for Vg, but completely lacked any VgR label, indicating that MYB are storage compartments that do not participate in receptor recycling. Thus, our immunocytochemical data clearly visualize the steps in Vg/VgR internalization, dissociation, sorting, and recycling of the receptor to the plasma membrane.

Extensive sequence conservation among insect, nematode, and vertebrate vitellogenins reveals ancient common ancestry

The eggs of most oviparous animals are provisioned with a class of protein called vitellogenin (Vg) which is stored as the major component of yolk. Until recently, deduced amino acid sequences were available only from vertebrate and nematode Vgs, which proved to be homologous. The sequences of several insect Vgs are now known, but early attempts at pairwise alignments with vertebrate and nematode Vgs have been problematic, leading to conflicting conclusions about how closely insect Vgs are related to the others. In this paper we demonstrate that insect Vg sequences can be confidently aligned with one another along their entire lengths and with multiple vertebrate and nematode Vg sequences along most of their spans. Although divergence is high, conservation among insect, vertebrate, and nematode Vg sequences is widespread with a preponderance of glycine, proline, and cysteine residues among strictly conserved amino acids, establishing conclusively that Vgs from the three phyla are homologous. Areas of least-certain alignment are primarily in and around insect and vertebrate polyserine domains which are not homologous. Phylogenetic reconstructions of Vgs based on sequence identities indicate that the insect lineage is the most diverged and that the mammalian serum protein, apolipoprotein B-100, arose from a Vg ancestor after the nematode/vertebrate divergence.