Dynamic miRNA-mRNA interactions coordinate gene expression in adult Anopheles gambiae
Authors:
Xiaonan Fu aff001; Pengcheng Liu aff002; George Dimopoulos aff003; Jinsong Zhu aff002
Authors place of work:
The Interdisciplinary Ph.D. Program in Genetics, Bioinformatics, and Computational Biology, Virginia Tech, Blacksburg, Virginia, United States of America
aff001; Department of Biochemistry, Virginia Tech, Blacksburg, Virginia, United States of America
aff002; W. Harry Feinstone Department of Molecular Microbiology and Immunology, Bloomberg School of Public Health, Johns Hopkins University, Baltimore, Maryland, United States of America
aff003
Published in the journal:
Dynamic miRNA-mRNA interactions coordinate gene expression in adult Anopheles gambiae. PLoS Genet 16(4): e32767. doi:10.1371/journal.pgen.1008765
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1008765
Summary
microRNAs (miRNAs) are increasingly recognized as important regulators of many biological processes in mosquitoes, vectors of numerous devastating infectious diseases. Identification of bona fide targets remains the bottleneck for functional studies of miRNAs. In this study, we used CLEAR-CLIP assays to systematically analyze miRNA-mRNA interactions in adult female Anopheles gambiae mosquitoes. Thousands of miRNA-target pairs were captured after direct ligation of the miRNA and its cognate target transcript in endogenous Argonaute–miRNA–mRNA complexes. Using two interactions detected in this manner, miR-309-SIX4 and let-7-kr-h1, we demonstrated the reliability of this experimental approach in identifying in vivo gene regulation by miRNAs. The miRNA-mRNA interaction dataset provided an invaluable opportunity to decipher targeting rules of mosquito miRNAs. Enriched motifs in the diverse targets of each miRNA indicated that the majority of mosquito miRNAs rely on seed-based canonical target recognition, while noncanonical miRNA binding sites are widespread and often contain motifs complementary to the central or 3’ ends of miRNAs. The time-lapse study of miRNA-target interactomes in adult female mosquitoes revealed dynamic miRNA regulation of gene expression in response to varying nutritional sources and physiological demands. Interestingly, some miRNAs exhibited flexibility to use distinct sequences at different stages for target recognition. Furthermore, many miRNA-mRNA interactions displayed stage-specific patterns, especially for those genes involved in metabolism, suggesting that miRNAs play critical roles in precise control of gene expression to cope with enormous physiological demands associated with egg production. The global mapping of miRNA-target interactions contributes to our understanding of miRNA targeting specificity in non-model organisms. It also provides a roadmap for additional studies focused on regulatory functions of miRNAs in Anopheles gambiae.
Keywords:
Gene expression – Sequence motif analysis – Messenger RNA – Blood – MicroRNAs – Luciferase – RNA sequencing – Mosquitoes
Introduction
Mosquito-borne infectious diseases, such as malaria, dengue, chikungunya, and Zika, pose an increasing threat to public health in many tropical and subtropical regions of the world [1]. Female mosquitoes transmit the causative pathogens while taking blood from humans to acquire nutrition for egg production. Decoding complex gene regulation that governs mosquito reproduction could potentially open new avenues to develop effective disease control strategies.
Hematophagous mosquitoes have evolved regulatory mechanisms to adapt to different nutritional sources and to coordinate metabolic and reproductive processes [2, 3]. The first gonotrophic cycle in anautogenous mosquitoes consists of the previtellogenic period and vitellogenic period, separated by blood-feeding. In the early hours after eclosion, adult mosquitoes rely on nutrient reserves (mainly glycogen and lipids) accumulated during the larval stage until they could find plant nectar or fruit juice [4]. During the remaining previtellogenic period, mosquitoes use carbohydrates of nectar to synthesize trehalose for immediate usage and store surplus nutrients in the form of glycogen and lipids [5]. By 72 hours post-eclosion (PE), female mosquitoes have completed previtellogenic maturation under the control of juvenile hormone (JH) and become competent for massive yolk protein synthesis and deposition [6, 7]. The development of oocytes then enters a state-of-arrest that persists until a protein-rich blood meal is taken. Teneral reserves and energy stored during the previtellogenic period are critically important for the fate of developing oocytes [8, 9]. The vitellogenic period is controlled by 20-hydroxyecdysone (20E), the levels of which are elevated shortly after blood ingestion. A female mosquito can take in a blood meal that is greater than its body weight. Amino acids derived from blood proteins are used for the synthesis of yolk protein precursors and provide fuel to meet massive energy demand during vitellogenesis [10].
Metabolic activities in female mosquitoes thus must synchronize accordingly with interchanging energy sources. Indeed, transcriptomic analyses in the yellow fever mosquito Aedes aegypti have confirmed that substantial physiological changes during vitellogenesis are accompanied by significant changes in the expression of metabolic genes [6, 11]. Expression of key enzymes in glycolysis and glycogen/sugar metabolism is relatively strong in the first 24 h after eclosion and then declines considerably in the rest of the previtellogenic period [12]. Their expression is greatly up-regulated after a blood meal, exceeding the maximal mRNA levels in the previtellogenic mosquitoes. Enzymes involved in lipid metabolism exhibit a similar expression pattern in the first gonotrophic cycle [13]. In addition to transcriptional regulation, recent studies have shown that several mosquito miRNAs play important roles in blood digestion and egg production [14–19]. However, the stage-specific regulations by miRNAs and global miRNA-mRNA interaction networks have not been well explored in female mosquitoes.
miRNAs belong to a class of small non-coding endogenous RNAs that act as post-transcriptional regulators of gene expression. Mature miRNAs are loaded onto the Argonaute (Ago) protein to form the miRNA-induced silencing complex (RISC). miRNA directs RISC to its target mRNA through Watson-Crick base pairing, promoting RNA degradation and translational inhibition [20]. The nature of miRNA targeting in animals is particularly complex as canonical miRNA:mRNA pairing only requires a 6-nt seed binding (nucleotides 2–7 of miRNA), although pairing to the 3’ end of miRNA can sometimes supplement canonical sites [21]. Because of the context-dependent nature of miRNA regulation, the mere presence of a miRNA-binding site does not warrant target regulation. The ability of RISC to bind and regulate specific targets is influenced by the number and position of target sites within an mRNA [22, 23], by RNA-binding proteins that limit miRNA access to target mRNA [24, 25], and by Ago-interacting proteins or post-translational modification of Ago [26–29].
To identify miRNA-target interactions in endogenous context, biochemical approaches are increasingly used to isolate miRNA effector complexes containing miRNA-mRNA duplexes [21, 30]. High-throughput sequencing of RNAs isolated by crosslinking and immunoprecipitation (CLIP) of Ago has been applied to identify transcriptome-wide miRNA targets in developing Caenorhabditis elegans, mouse brain, and the fat body of Ae. aegypti mosquitoes [31–33]. However, the CLIP data failed to explicitly expose the identity of miRNA bound to a certain site. An improved CLIP method, termed CLEAR (covalent ligation of endogenous Argonaute-bound RNAs)-CLIP, has an extra ligation step to join the miRNA and its targeted mRNA in purified RISC into one chimeric RNA molecule [34]. Analysis of the chimeric miRNA-target molecules allows for the systematic identification of miRNA-target interactions [35, 36]. In the present study, we applied CLEAR-CLIP to uncover thousands of miRNA-target interactions at several key stages of mosquito reproduction. We defined pairing rules for mosquito miRNAs and illustrated stage-specific motif usage in vivo. Importantly, the data analyses revealed that dynamic miRNA-mRNA interactions play important roles in metabolism, energy homeostasis, and egg maturation. This work provides a comprehensive view of dynamic miRNA targeting in Anopheles gambiae and presents a roadmap for additional functional studies.
Results
Mapping the miRNA-target interactions in An. gambiae using CLEAR-CLIP
We adopted a CLEAR-CLIP protocol [34] to identify miRNA-mRNA pairing in the An. gambiae RISC. After ultraviolet irradiation, lysates of mosquito abdomens were treated with RNase I to partially trim the RNAs crosslinked to Ago1 (S1 Fig). The Ago1-RNA complexes were purified using a specific AgAgo1 antibody and incubated with T4 RNA ligase 1 to facilitate direct ligation of miRNAs and target RNAs within the same complexes. The Ago1-miRNA-mRNA complexes (>130 kDa) were then isolated by size selection on an SDS-polyacrylamide gel. RNAs associated with Ago1 were extracted and processed for RNA sequencing to detect chimeric RNA molecules.
To test the specificity of miRNA-target ligation, we performed a control experiment where T4 RNA ligase 1 was omitted in the ligation of miRNAs to target mRNAs within RISC. This omission led to a 7.47-fold decrease in the number of total chimeric reads, compared with the standard procedure (S1 Table). In addition, we carried out a separate CLEAR-CLIP experiment by adding an equal amount of Escherichia coli total RNA to mosquito lysates before RNase I treatment and immunoprecipitation. In the mosquito-only samples, 2.37% of chimeric reads were mapped to the E. coli genome, presumably due to high homology between some mosquito RNAs and E. coli RNA sequences or because of bacterial RNA contamination from molecular reagents used in the experiments. By contrast, in the samples spiked with the bacterial RNA, 2.78% of chimeric reads were mapped to the E. coli genome (S2 Table). The results, therefore, suggested that the vast majority of detected miRNA-mRNA chimeras resulted from ligation of the miRNAs and mRNA targets within Ago1-miRNA-mRNA complexes.
To map miRNA-mRNA interactions in An. gambiae, we collected female mosquitoes at 3 h, 30 h and 120 h post eclosion (PE), and at 24 h and 48 h post a blood meal (PBM) to perform CLEAR-CLIP experiments (Fig 1A). We obtained 305,366,254 reads from a total of 16 CLEAR-CLIP libraries (S3 Table), including miRNA-mRNA chimeras (1.70%), mRNA “single reads” (77.07%), miRNAs “single reads” (10.30%) and other noncoding RNAs (10.96%). The mRNA “single reads” harbor Ago1 binding sites and are hereinafter referred to as Ago1 CLIP reads. The chimeras were detected in two orientations: miRNA-first and miRNA-last, depending on whether miRNA was located at the 5’ end of the chimeric read (Fig 1B). When mapping to the An. gambiae transcriptome, miRNA targets derived from the chimeric reads were mostly located in the 3’-untranslated regions (3’UTR; 42.32%) and coding regions (CDS; 47.01%), but were also present in the 5’-untranslated regions (5’UTR; 10.66%). Although the distributions varied at different time points, 3’UTR and CDS remained the primary target regions of miRNAs. The Ago1 CLIP reads obtained in the same experiments exhibited similar distribution across the genic regions (Fig 1C).
Comparable to similar CLEAR-CLIP experiments using other organisms, uniquely mapped chimeras in this study were less than 3% of the total unique reads (S3 Table). Chimeras with the same miRNA and overlapping mRNA sites were clustered. In total, we have mapped 11,807 miRNA-mRNA interactions from 89,704 unique chimeric reads, involving 117 mature miRNAs and 4,755 mRNA transcripts in An. gambiae (S4 Table). Chimeric reads were combined with conventional CLIP reads from biological replicates to generate 40,919 Ago1-binding CLIP peaks. There was a significant correlation between miRNA abundance at each time point and miRNA frequency in chimeras (S2 Fig). The top five miRNAs in the miR-first chimeras, miR-8-3p, miR-14-3p, miR-989-3p, miR-34-5p, and miR-184-3p, were all known abundant miRNAs in adult female mosquitoes [37, 38].
Validation of the miRNA-target interactions defined by CLEAR-CLIP
Several lines of evidence further indicated that the chimeras stemmed from genuine mRNA-miRNA pairing in RISC rather than from proximity-induced ligation of non-specific RNAs in solution. In 75% of miRNA-mRNA interactions that were supported by at least 9 unique tags, target sequences in the chimeric reads overlapped with an Ago1 CLIP peak (S4 Table). In addition, target sequences in the chimeras (especially miR-first chimeras) were strongly enriched for canonical seed matches to their cognate miRNAs (Fig 1D). Moreover, the formation of miRNA-mRNAs chimeras seemed to favor stable miRNA-mRNA duplexes in RISC (Fig 1E). The mean predicted free energy between miRNAs and the matched target mRNAs in chimeras was 4.1 kcal/mol lower than that in randomly matched pairs (p<0.001).
Experimentally verified miRNA-target interactions are relatively limited in mosquitoes. Our CLEAR-CLIP data retrieved a known interaction between miR-309 and homeobox gene SIX4, which plays an important role in ovarian development in female Ae. aegypti mosquitoes [18]. Our recent study has shown that depletion of miR-309 in female An. gambiae mosquitoes also impairs ovarian development [38]. In the current experiment, 25 unique chimeric reads comprising miR-309 and SIX4 mRNA were detected and all came from the mosquitoes collected at 24 h PBM (Fig 1F). In the 3’ UTR of SIX4, an Ago1 binding site was detected predominantly at 24 h PBM; this site overlapped considerably with the miR-309 target site deduced from the chimeric reads, lending additional support to this stage-specific interaction (Fig 1G).
A total of 220 miR-309-target interactions were identified by CLEAR-CLIP assays, involving 204 mRNA transcripts. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis suggested that the miR-309 targets have important functions in post-embryonic morphogenesis and phosphate metabolic process. To validate the miR-309-involved interactions, we injected the antagomir for miR-309 (ant-miR-309) into newly emerged female mosquitoes to silence endogenous miR-309 (S3A Fig). Ovaries of female An. gambiae were collected at 24 h PBM and subjected to RNA-seq analysis. Compared with control antagomirs, ant-miR-309 significantly increased the abundance of those mRNAs that bear chimeras-defined miR-309 target sites (p = 0.024, Kolmogorov-Smirnov test) (Fig 2A). The increases were more robust (p = 0.004) for the target genes that were supported by both chimeric reads and overlapping Ago1 binding sites (Fig 2A). In line with the previous study in Ae. aegypti [18], both RNA-seq and quantitative RT-PCR confirmed that injection of ant-miR-309 caused a marked increase in the SIX4 transcript at 24 h PBM (S3B and S3C Fig).
In parallel, we performed ribosome footprinting to evaluate translational repression conferred by the binding sites of miR-309. Compared with control antagomirs, ant-miR-309 significantly enhanced ribosome associations of the transcripts harboring miR-309 target sites (Fig 2B). Translation efficiency (TE), which is defined as ribosome footprint density normalized to underlying mRNA abundance, also increased significantly after injection of anti-miR-309 (Fig 2C). Thus, the results indicated that miR-309 modulates the expression of its targets at 24 h PBM via both translational repression and mRNA decay.
To further assess the regulatory potential of the identified interactions, ten miR-309 targets that exhibited various pairing patterns with the seed sequence of miR-309 were selected for luciferase reporter assays (S3D Fig). DNA fragments containing the miR-309 binding sites were cloned individually into a luciferase reporter vector. HEK293 cells were transfected with the reporter constructs alone or together with miRNA mimics. Remarkably, the normalized luciferase activities of all 10 reporter constructs were significantly down-regulated by the miR-309 mimic, compared with the control mimic (Fig 2D). The miR-309 target site in the 3’ UTR of SIX4 mRNA conferred relatively strong repression of the reporter gene by the miR-309 mimic. Collectively, the miRNA perturbation experiments and reporter assays suggested that miRNA-mRNA chimeric reads, generated by CLEAR-CLIP and bolstered by overlapping Ago 1 binding sites, can reliably identify authentic miRNA-mRNA interactions in vivo.
Regulation of kr-h1 by let-7 during egg development
Another interaction that was experimentally confirmed in this study was the regulation of krüppel-homolog 1 (kr-h1) by let-7. Kr-h1, a juvenile hormone-induced transcription factor, has been shown to play a pivotal role in egg maturation in Ae. aegypti [39]. Our CLEAR-CLIP data suggested that let-7 and miR-2 directly regulate the expression of kr-h1 in adult female An. gambiae. Both let-7-kr-h1 and miR-2-kr-h1 chimeras were detected from mosquitoes collected at 120 h PE; let-7 seemed to target kr-h1 more vigorously than miR-2, based on the number of chimeric reads (Fig 3A and 3B). The target sites of let-7 and miR-2 were located in the 3’UTR and CDS of kr-h1, respectively.
Interactions of kr-h1 with miR-2 and let-7 were verified in luciferase reporter assays. Compared with scrambled control miRNAs, miR-2 and let-7 demonstrated significant repression of the luciferase reporter genes that carried their cognate target sequences identified in kr-h1 (Fig 3C and S4 Fig). To evaluate the contribution of both miRNAs to kr-h1 expression in vivo, we measured the Kr-h1 proteins after knocking down endogenous let-7 or miR-2 by injecting specific antagomirs into newly emerged mosquitoes. At 120 h PE, the levels of Kr-h1 increased by 45% after injection of ant-let-7 while the protein levels remained essentially unchanged after the ant-miR-2 treatment (Fig 3D). At 24 h PBM, ant-miR-2 showed no significant impact on the protein levels of Kr-h1 while the ant-let-7 treatment increased the expression of Kr-h1 by 3.65 fold, compared to the control (Fig 3D). Although the results suggested that let-7 is the major regulator of kr-h1, it is possible that the decrease in miR-2 levels, after injection of ant-miR-2, did not reach a critical threshold to cause any significant change in the expression of kr-h1 (S5 Fig). In the let-7-depleted female mosquitoes, primary follicles failed to increase in size after a blood meal, indicating that the development of oocytes was stalled (Fig 3E and 3F). In contrast, knockdown of the miR-2 expression has no significant effect on oocyte development after blood ingestion (Fig 3E and 3F). Different roles of let-7 and miR-2 in the regulation were also validated by the injection of miRNA mimics. The let-7 mimic, not the miR-2 mimic, caused a considerable decrease in Kr-h1 at 120 h PE and 24 h PBM and suppressed oocyte development after blood feeding (S6 Fig). Taken together, these results demonstrated that precise regulation of kr-h1 by let-7 is essential for egg maturation in An. gambiae, reminiscent of a similar role of this interaction in adult reproduction in migratory locust Locusta migratoria [40].
Diverse and stage-specific miRNA target site recognitions in An. gambiae
The experimentally identified miRNA-target interactions open the door to deciphering the rules of miRNA targeting in mosquitoes. Our CLEAR-CLIP analysis indicated that abundant miRNAs generally formed chimeras with multiple target mRNAs. To characterize the base-pairing patterns of miRNA-target interaction, we searched for overrepresented sequence elements in all the targets discovered for each miRNA. For most of the top expressed miRNAs, highly enriched sequence motifs emerged as complementary to the extended miRNA seed region (nucleotides 1–8 of miRNA) (Fig 4A and S7 Fig). Close inspection of the enriched motifs indicated that imperfect seed matches are quite common in mosquitoes. miR-184-3p displayed substantial mismatches at nucleotide 5 in the 5' region in pairing with its targets; for miR-309, considerable mismatches occurred at nucleotide 8 (Fig 4A). In contrast, many miRNAs seemed to favor seed-independent non-canonical pairing to determine their target specificity. Motifs found in the targets of miR-14-3p and miR-275-5p suggested that those two miRNAs prefer to use their 3’ regions for target recognition (Fig 4A). Interestingly, miR-275 and miR-306, which belong to the same family and share identical seed sequence, used opposite ends of miRNA to pair with their cognate targets (Fig 4A).
Next, unbiased de novo motif (7-mer) analyses were performed with miRNAs that participated in over 50 unique interactions to compare the enriched motifs for individual miRNAs at different time points. Some miRNAs, such as bantam-3p, miR-11-3p, miR-306, miR-308, miR-9b, and miR-9c-5p, consistently used the same sequences to recognize their targets at several time points (Fig 4B). Many miRNAs exhibited 1- or 2-nt shifts in their recognition sequences from one time point to another. For instance, miR-184-3p primarily used nucleotides 1–7 at 3 h PE for target recognition (Fig 4B). However, this miRNA relied on nucleotides 2–8 instead at 120 h PE and 24 h PBM. Moreover, miR-9a-5p appeared to use nucleotides 3–9 for pairing with its targets at 120 h PE but switched to nucleotides 1–7 at 24 h PBM (Fig 4B). This motif shift of miR-9a-5p was accompanied with drastic changes in its targets from 120 h PE to 24 h PBM (S8 and S9 Figs). Among 65 targets of miR-9a-5p detected at 24 h PBM, only 8 were also regulated by miR-9a-5p at 120 h PE. One possible reason for the motif shifts is the existence of miRNA isoforms. However, only miR-2b showed an isoform with a 2-nt truncation at the 5’ end, explaining the 2-nt motif shifting at 120 h PE. miRNA isoforms were not detected in other cases.
Sequences in the middle or 3’ end of some miRNAs seemed to also contribute to target recognition, according to the enriched motifs in miRNA targets. At 3 h PE, 10.7% of miR-14-3p targets carried sequences complementary to its extended seed region while 50.4% of the targets harbored a motif that matched to nucleotides 12–18, with an additional 9.9% of the miR-14-3p-target interactions necessitating base pairing of both regions (S10A Fig). Later at 48 h PBM, nucleotides 11–19 accounted for 79.1% of target recognition by miR-14-3p. Other miRNAs also displayed striking stage-specific changes in using their different sequences for target recognition. miR-276-3p mainly relied on nucleotides 1–7 for pairing with its targets at 3 h PE and switched to nucleotides 15–21 at 30 h PE (S10B Fig). At 120 h PE and 24 h PBM, miR-276-3p depended on the sequences at both 5’ and 3’ ends. The diverse pairing patterns of miR-14-3p and miR-276-3p were consistent with their vastly different targets retrieved at each stage during adult reproduction (S8 and S9 Figs). Collectively, the analyses revealed extensive non-canonical interactions between mosquito miRNAs and their mRNA targets, as well as stage-specific recognition patterns of some miRNAs.
Regulation of mosquito metabolism by miRNAs
We selected 7,025 chimera-defined interactions that were supported by Ago1 CLIP peaks to investigate the dynamics of miRNA-involved regulation during mosquito reproduction. To compare miRNA-mRNA interactions in different stages, the chimera-supported Ago1 binding peaks were normalized to mRNA abundance to take into consideration changes of mRNA levels. The normalized Ago1 CLIP signals were then analyzed using the self-organized map (SOM) algorithm to group large sets of interactions with similar patterns to simplify visualization. The 2-dimensional gridded heatmap revealed the stage-dependent and dynamic nature of miRNA-mRNA interactions in adult female mosquitoes. The similar patterns at 3 h PE and 30 h PE (R = 0.69) implied that many miRNAs-involved regulations persisted during the early previtellogenic stage (Fig 5A). Dramatic pattern shifts occurred later when female mosquitoes proceeded from preparatory phase (30 h PE) to the state-of-arrest (120 h PE), to active vitellogenic synthesis (24 h PBM), and to termination of vitellogenic stage (48 h PBM). Gene regulation by miRNAs was most prevalent at 120 h PE and 24 h PBM (Fig 5B).
Functional annotation of the identified miRNA target genes indicated that miRNAs in adult female mosquitoes modulate diverse molecular processes, including various metabolic functions (Fig 5B). The hierarchical clustering of these metabolism-related interactions revealed distinct interaction patterns at different stages during the first gonotrophic cycle (Fig 5C), suggesting that miRNAs make a major contribution to the precise regulation of energy homeostasis to deal with alternating energy sources and physiological demands in adult female mosquitoes.
The genes encoding glycogen/sugar metabolism (4 out of 17 enzyme-coding genes) and glycolysis (6 out of 28 enzyme-coding genes) exhibited particularly pronounced fluctuation in their interactions with miRNAs (Fig 6). Hours after eclosion, adult female mosquitoes reared in the laboratory generally rely on provided sucrose solution to meet their energy demand. Ingested sucrose is digested by α-glucosidases and converted into trehalose, the principal hemolymph sugar that provides circulating energy in flight and host-seeking. Extra sugars are converted into somatic energy reserves in the form of lipids and glycogen to support the imminent egg maturation following a blood meal. The miRNA regulation of glycogen metabolism and glycolysis, identified in this study, seems to be consistent with the stage-specific metabolic alteration associated with sugar feeding. Expression of trehalose-6-phosphate synthase (TPS) was inhibited by miR-34/-252/-275/-281 at 3 h PE, presumably before sugar feeding (Fig 6). Glycogen phosphorylase (GLY) catalyzes the rate-limiting step in glycogenolysis. Its expression was repressed first at 30 h PE by miR-2b-3p and miR-2-3p, and later at 120 h PE by miR-8-3p/-12-5p/-1889-5p (Fig 6). UTP-glucose-1-phosphate Uridylyltransferase (GALU), which catalyzes the formation of UDP-glucose for glycogen synthesis, was under the control of miR-12-5p and miR-281-5p at 120 h PE. The suppression of GALU was in accordance with the observed slowdown of glycogen synthesis once glycogen reaches a certain level in sugar-fed female mosquitoes [12]. Several key enzymes in glycolysis, such as enolase (ENO), pyruvate kinase (PYK), and pyruvate carboxylase (PYC), were primarily targeted by various miRNAs at 120 h PE and 24 h PBM (Fig 6). Notably, the phosphoenolpyruvate carboxykinase (PEPCK) gene, which governs a rate-controlling step of gluconeogenesis, was vigorously targeted by numerous miRNAs at 120 h PE (Fig 6).
In the sugar-fed mosquitoes, TAG is built up and stored as an energy reserve in intracellular droplets. After blood-feeding, the lipid droplets are diminished and TAG is mobilized to support oocyte development. Our study indicated that miRNA regulation of the genes involved in lipid metabolism displayed stage-specific manners. Enzymes required for fatty acid degradation, such as TAG lipase 1, acyl-CoA dehydrogenases (ACAD), very long-chain acyl-CoA dehydrogenase (VLCAD), were strongly regulated by miRNAs at 120 h PE to repress their gene expression (Fig 6). These interactions disappeared after blood ingestion. On the other hand, the three fatty acid synthase genes (FAS-1, FAS-2, and FAS-3) were the targets of multiple miRNAs. Inhibition of FAS-3 took place primarily at 120 h PE while strong repression of FAS-2 occurred at both 120 h PE and 24 h PBM. These data implied that miRNAs play a regulatory role in lipid metabolism during mosquito reproduction.
Drastic metabolic changes occur upon adult female mosquitoes take a blood meal. Generally, only 10–15% of the blood-derived amino acids are used by female mosquitoes to synthesize egg proteins [41]. The rest of amino acids is mostly deaminated and the carbon skeletons are used for instant energy production, synthesis of egg lipid, and building energy reserves. Expression of alanine-glyoxylate aminotransferase (AGXT), an aspartate aminotransferase (GOT2), and argininosuccinate lyase (ASL, a key enzyme in the urea cycle) was specifically repressed by various miRNAs at 120 h PE. The gene encoding another aspartate aminotransferase (GOT1) was selectively repressed by miRNAs at 24 h PBM, while the transcripts of phosphoserine aminotransferase (PSAT) and a branched-chain amino acid aminotransferase (BCAT2) were targeted by several miRNAs at both 120 h PE and 24 h PBM. The results implied that miRNAs participate in repressing the expression of amino acid metabolic enzymes in sugar-fed mosquitoes and that the de-repression of metabolic genes for individual amino acids may occur at different paces. Taken together, this study suggests that developmental patterns of miRNA-mRNA interactions define important regulatory roles of miRNAs in metabolism and energy homeostasis during mosquito reproduction.
Discussion
In this study, we performed CLEAR-CLIP experiments to generate a miRNA-mRNA interaction network during egg maturation in adult female mosquitoes. In addition to revealing target sites of miRNAs, this approach provided temporal patterns of individual miRNA-target interactions. Using miR-309 as an example, we experimentally validated its interaction with the targets identified by CLEAR-CLIP, including the miR-309-SIX4 interaction which has been well characterized in Ae. aegypti. The regulation of SIX4 by miR-309 in An. gambiae took place primarily at 24 h PBM, coinciding with a similar pattern in Ae. aegypti [18]. Moreover, we used the let-7-kr-h1 interaction to demonstrate that temporal patterns of interactions are instrumental for the functional elucidation of miRNAs. Furthermore, we used the CLEAR-CLIP data to compare the miRNA-target interactions in An. gambiae and Ae. aegypti. Ago1 binding sites have been identified by CLIP in the fat body of Ae. aegypti before and after blood feeding [33]. For those Ae. aegypti genes with identified Ago1 CLIP peaks, about 70% of their orthologs in An. gambiae also harbored Ago1 binding sites at the corresponding time points (S11 Fig). Given that we used mosquito abdomens consisted of several different tissues in the current study, the miRNA-mRNAs interactions appear to be highly conserved between the two mosquito species.
It came to our attention that the CLEAR-CLIP experiments failed to retrieve some previously identified miRNA-target interactions in An. gambiae, e.g. the regulation of secreted wingless-interacting molecule (swim) by miR-8 and the interaction between miR-1174 and the serine hydroxymethyltransferase gene [16, 17]. This implied that although the CLEAR-CLIP experiment generated substantial miRNA-mRNA chimeras, the miRNA-target interaction map that it produced was far from complete. Therefore, while the chimeric reads provided unambiguous miRNA-target interactions, the Ago1 CLIP peaks were a more reliable measurement of miRNA-target interactions at different stages during the first gonotrophic cycle. The limitation of this experiment mostly stemmed from low efficiency in RNA ligation under current experimental conditions (S3 Table). The low efficiency in RNA ligation is in accord with other published studies using the CLEAR-CLIP approach. In the studies of mouse brain or Caenorhabditis elegans, miRNA-mRNA chimeras also accounted for 1–3% of total reads [34–36]. Chimeras recovered in the current study preferentially contained shorter mRNA sequences (~42 nt), suggesting that proper trimming of mRNA cross-linked to Ago1 is crucial for chimera formation. Further optimization of the protocol is needed to improve coverage of global miRNA regulation of gene expression.
Mapping of miRNA-target interactions creates an opportunity for deciphering the pairing rules of mosquito miRNAs. The vast majority of miRNAs preferentially bind their targets through imperfect base-pairing with their seed region. Other miRNAs, however, rely on their central or 3’ region for target recognition. While paired seed sites are occasionally supplemented by the seed-distal 3’ pairing, the targets in many chimeric reads often show significant match exclusively with the seed-distal region, suggesting that sometimes seedless pairing is a major determinant of Ago target specificity. Some miRNAs, such as miR-14-3p, utilize their seed region, distal region or both to recognize different targets at the same reproductive stage. Although we cannot rule out the possibility that distinct recognition patterns occur in a tissue-specific manner, the flexible targeting mechanism greatly expands the target repertoire of a miRNA. Moreover, while miR-306 exploits canonical miRNA targeting, miR-275-5p (a member of the same miRNA family) shares the same seed sequence but is reliant on its 3’ end for target recognition. Further study is needed to investigate the role of miR-275-5p seed in its seedless pairing and to elucidate how miRISC recognizes miRNA targets that lack seed complementarity.
Another important observation of this study is the varying target recognition patterns of the same miRNAs at different stages in adult mosquitoes. The alterations include small shifting of recognition sites (1–2 nt), substitution by a distal region of miRNA, and addition of supplementary pairing. Sequences of miRNAs collected at different stages were largely identical, suggesting that the observed pattern changes may not be accredited to alternative miRNA processing. Nevertheless, the changes in pairing patterns of miRNAs led to drastic switches of miRNA targets at different stages in the first gonotrophic cycle, contributing to the detected dynamic miRNA-mRNA interactions. This was confirmed by target analyses of miR-9a-5p, miR-14-3p, and miR-276-3p (S8 Fig), and may also be extrapolated to other mosquito miRNAs. This strategy seemed to allow individual mosquito miRNAs to regulate a diverse array of target genes, in a stage-specific manner, especially when nutritional sources and physiological demands undergo significant changes in adult reproduction.
There is a growing body of evidence that target binding and silencing efficacy is governed by several local and global determinants [42]. Some miRNAs may possess an intrinsic ability to use various regions for the recognition of different targets. Alterations in overall target abundance and target repertoire at different stages may force these miRNAs to change their recognition patterns. Additionally, many target mRNAs carry multiple miRNA sites that overlap or are in close vicinity. Binding of a miRNA to a target site may be either enhanced or repressed by the changing miRNA milieu [43, 44]. Moreover, miRNA targeting activity has been recently reported to be influenced by the phosphorylation of Ago proteins in response to other cellular signals [45]. miRNA-target interactions are also modulated by other RNA binding proteins, the binding of which to the target mRNA exposes or occludes specific miRNA target sites [46, 47]. Drastic physiological changes take place during adult reproduction in female mosquitoes. Alterations of the abovementioned determinants in specific biological contexts could contribute to the observed changes in target recognition patterns of mosquito miRNAs. More studies are needed to elucidate mechanistic details of the pattern change.
miRNA-mRNA interactions that are defined by chimeras are particularly valuable for comprehensive analysis and functional interpretation of miRNAs. In this study, about 100 interactions were identified on average for each miRNA; the miRNA targets illustrated diverse roles of individual miRNAs in various biological processes. miR-8-3p, for example, is ubiquitously abundant in mosquitoes [17, 38, 48] and D. melanogaster [49, 50]. The CLEAR-CLIP experiment identified ~1,700 mRNA interactions with miR-8-3p in adult female mosquitoes. The target genes of miR-8-3p were involved in a variety of functions including lipid localization, regulation of cellular component size, wing disc development and glycolysis/gluconeogenesis (S12 Fig). This is in agreement with the reported roles of miR-8-3p in regulating lipid accumulation in Ae. aegypti [17] and affecting body size and metabolism in D. melanogaster [49]. Injection of miR-8-3p mimic into newly emerged female An. gambiae indeed substantially reduced the accumulation of TAG in sugar-fed adults before blood-feeding (S13 Fig). The observed phenotype is likely an accumulative effect of the misexpression of multiple miR-8-3p target genes.
The dynamic miRNA-mRNA interactomes implied that miRNAs regulate many stage-specific functions in adult mosquitoes. Mosquitoes are highly dependent on available nutrients to support biochemical processes required for reproduction. Nutrient mobilization and energy homeostasis are constantly adjusted to their nutritional and metabolic status to meet the fluctuating energy demand of a reproducing female mosquito. Our results suggested that miRNAs contribute greatly to this metabolic reprogramming. During the previtellogenic stage, female mosquitoes use plant sugars to build their energy storage in the forms of glycogen and TAG for imminent egg production. After a blood meal, in addition to the blood-derived nutrients, glycogen and TAG stored in the fat body are mobilized and depleted to meet tremendous energy expenditure required for oocyte maturation. Accordingly, both carbohydrate and lipid metabolism exhibit periodic changes throughout the mosquito reproductive cycle to adapt to varying nutrient sources and energy requirements. Many genes encoding key enzymes in glycolysis and lipid catabolism are transcriptionally downregulated at the end of the previtellogenic stage but show a significantly enhanced expression after blood ingestion (S14 Fig). These gene expression patterns in female mosquitoes are under the control of juvenile hormone and 20-hydroxyecdysone [12, 13, 51, 52]. Our study revealed that these genes were further repressed by miRNAs to diminish glycolysis and lipid degradation at 120 h PE and that these miRNA regulations vanished shortly after blood feeding. Interestingly, some enzymes required for glycogen and lipid synthesis were regulated by miRNAs in a similar fashion. Thus, fine-tuning of enzyme expression by miRNAs may confer precision to the temporal coordination of metabolism and maintain energy reserves at the desired level before a blood meal.
In summary, this study shows that miRNA-mRNA interaction maps vary in different biological settings. It highlights the importance of target validation under physiological conditions to appreciate miRNA function in vivo. The identified miRNA-mRNA interactions not only supply a roadmap for the functional investigation of mosquito miRNAs, but also provide valuable datasets to train in silico algorithms to significantly improve their predictive power.
Methods
Ethics statement
This study was carried out in strict accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health. The use of mice in this study has been approved by the Virginia Tech Institutional Animal Care and Use Committee (approval number: 17–162).
Mosquito rearing and tissue collection
Anopheles gambiae (G3 strain) mosquitoes were reared and maintained as previously described [53]. Newly emerged mosquitoes were fed with a 10% sucrose solution. Adult females were blood-fed five days after eclosion using anesthetized mice. Mosquitoes were collected at 3 and 30 h PE, and at 0, 24, and 48 h PBM. Abdomens of the mosquitoes were flash-frozen in liquid nitrogen and stored at -80°C until use.
Ago1 CLEAR-CLIP
Polyclonal antibody against An. gambiae Ago1 was produced by Fu et al. [38]. The CLEAR-CLIP libraries were prepared as previously described [34]. Briefly, abdomens from 100 female mosquitoes were ground in liquid nitrogen and UV-irradiated at a dose of 400 mJ/cm2 for three times. Following tissue lysis, lysates were centrifuged at 15,000 g for 15 min at 4°C. The supernatant was treated with 30 units of RQ1 DNase (Promega) and 2 units of RNase I (Ambion) for 3 min at 37°C. Ago1 antibody was immobilized on Protein A Dynabeads (Invitrogen) and incubated with the clear lysate for 60 min at 4°C. Precipitates were stringently washed twice with High-Salt buffer (50 mM Tris-HCl pH 7.5, 0.8 M NaCl, 0.5% NP-40, 2.5% glycerol, 5 mM β-mercaptoethanol), twice with Low-Salt buffer (50 mM Tris-HCl pH 7.5, 0.3 M NaCl, 0.5% NP-40, 2.5% glycerol, 5 mM β-mercaptoethanol), and twice with PNK (polynucleotide kinase) buffer (50 mM Tris-HCl pH 7.5, 10 mM MgCl2, 0.5% NP-40, 50 mM NaCl, 5 mM β-mercaptoethanol). RNAs on the beads were phosphorylated with T4 PNK (NEB) at 20°C for 150 min, and chimera ligation was then performed overnight at 16 °C with T4 RNA Ligase 1 (0.625 U/μl, NEB) in a 160 μl reaction. The 3'-phosphate was removed with Thermosensitive Alkaline Phosphatase (Promega) at 20°C for 45 min. Radiolabeled adenylated 3'-linker (5'-rAppAGATCGGAAGAGCACACGTCT-3') was prepared with Mth RNA-Ligase (NEB). The 3'-linker was ligated to the RNAs on the beads using truncated RNA Ligase 2 K227Q (NEB) at 16 °C for 6 h. After elution with NuPAGE LDS buffer (Life Technology), the Ago1-miRNA-mRNA complex (>130 kDa) was separated by SDS-PAGE (4–12% bis-tris) and transferred to a nitrocellulose membrane. The Ago1-bound RNAs were extracted from the membrane slice by proteinase K digestion (Ambion) and ligated with the 5'-RNA linker, followed by RT-PCR. The PCR amplification was performed as previously described [38], with an optimized condition to incorporate sequencing index (NEB) into each Illumina library.
De novo transcriptome assembly
Mosquito abdomens were collected at the same time points as in the CLEAR-CLIP experiments. mRNAs were extracted and subjected to RNA-seq analysis. Transcriptome shotgun assembly was completed following the PASA pipeline with default parameters [54]. An. gambiae transcript sequences used for mapping of miRNA targets have been deposited at DDBJ/ENA/GenBank under the accession GIBN00000000.
Identification of miRNA-mRNA chimeras
Paired-end sequencing of the CLEAR-CLIP libraries was conducted at Virginia Biocomplexity Institute using the Illumina HiSeq platform with a read length of 100 bp. All RNA sequencing data have been deposited in the NCBI SRA database under accession number SRP147279. Sequencing reads were processed to remove low-quality reads and trim 3’ adapter sequences using Flexbar [55]. A degenerate 3-nt barcode was included in the 5'-RNA linker to reduce preferential PCR duplication. These random barcodes were trimmed before mapping to An. gambiae transcripts. Reads shorter than 16 nt were discarded and reads with identical sequences were collapsed for further analysis. We searched miRNA sequences in the cleaned reads by using BLAST (v2.3.0) with e-value of less than 0.4 [56]. The remaining sequences next to miRNAs in the reads were extracted for mapping to the annotated An. gambiae transcripts with BLAST. Reads mapped to rRNA, tRNA and miRNA genes were removed.
Peak calling of CLIP clusters
Peak calling of CLIP clusters was performed as previously described by Zisoulis et al. [32], using pooled reads from biological replicates of each time point. Overlapping reads were grouped as a single cluster. Cubic spline interpolation (Scipy, http://www.scipy.org/) was then carried out to determine locations and heights of the peaks [57]. Significant peaks were retained if p-values were less than 0.01 based on Poisson distribution.
Calculation of binding free energy
The minimum binding free energy of each interaction was calculated by RNA hybrid with default settings [58]. Shuffled interactions, shuffled mRNAs and random mRNAs (generated by shuffle function in Perl) served as controls for the comparison of free energy distribution. The median free energy for each profile was calculated using R packages.
Antagomir treatment
Antagomirs of miR-309, miR-2, and let-7 were purchased from GENEPHARMA (Shanghai, China). Each antagomir was designed as the reverse complement of mature miRNA. Mosquitoes were anesthetized on ice at 12 h PE, and antagomirs were microinjected into the thorax at a dose of 15 pmol. Mosquitoes were then fed with a 10% sucrose solution for 3 days before further analysis.
Validation of the chimera-defined targets in miR-309 perturbation experiments
The mRNA-seq data were analyzed as previously reported [59]. The log2 fold-changes (ant-miR-309/control) were used to perform cumulative distribution function (CDF) analysis to compare the transcripts bearing the chimera-defined miR-309 target sites with those non-target transcripts. The CDFs were also plotted for miR-309 sites overlapping with Ago1 CLIP peaks.
To obtain ribosome footprints, Ribo-seq libraries were constructed using an ARTseq/TruSeq Ribo Profile Kit (Illumina). Briefly, 12-hour old adult female mosquitoes were injected with either antagomiR-309 or control antagomir. Ovaries were dissected at 24 h PBM from 10 injected mosquitoes for each replicate, and were then pulverized in polysome buffer with cycloheximide (0.1 μg/ml) on ice. Ribosome-protected mRNA fragments were purified from Trueseq nuclease-treated lysate using MicroSpin S-400 (GE Life Sciences). Ribosome RNAs were depleted using RiboMinus Kit (Invitrogen). Sample barcodes were incorporated into libraries by 7 cycles of PCR amplification. The libraries were gel-purified and pooled for a single-end 50 bp sequencing. In parallel, total mRNAs were extracted from an aliquot of the ovarian samples to construct cDNA libraries using NEBNext mRNA Library Prep Kit for Illumina sequencing.
Reads from Ribo-seq were processed to remove contaminating rRNA and tRNA using Bowtie. Changes were made to default parameter in removing rRNA reads: maximum mismatches allowed in seed (-n = 2), seed length (-l = 23) and maximum reported alignments (-k = 1). Bowtie was set to perform end-to-end alignment without mismatch to remove tRNA. Cleaned reads were mapped to the An. gambiae genome (AgamP4.4) using TopHat without looking for novel junctions. After mapping, read counts were calculated with HTSeq set [60] and analyzed with R package DEseq2 to perform ribosome association analysis. Translational efficiency was calculated by normalizing ribosome association against their mRNA levels utilizing RiboDiff [61].
Luciferase reporter assay
HEK293T cell line was grown in DMEM media (Gibco, Life Technologies) containing 10% (vol/vol) heat-inactivated FBS (Atlanta Biologicals) at 37°C in a humidified incubator supplied with 5% CO2. The psiCheck-2 reporters were constructed by inserting the 3′-UTR fragments that harbor putative miR-309 target sites into the psiCheck-2 vector (Promega). Thereafter, 100 ng of psiCheck-2 reporters with 100 nM of synthetic aae-miR-309 miScript miRNA Mimic (Qiagen) or AllStars Negative Control siRNA (Qiagen) were cotransfected into HEK293T cells by using FuGENE HD Transfection Reagent (Promega). Cells were collected and lysed at 48 h after transfection. Luciferase activities were measured using the dual-luciferase reporter assay system (Promega). Each sample was performed in triplicate and transfections were repeated three times.
Motif analysis
Overrepresented motifs were identified in chimeric reads using MEME with the following settings: -dna -mod zoops -maxw 7 -nmotifs 1. Motifs identified in targets of each miRNA were then aligned to the reverse-complemented miRNA sequence using FIMO [62], with the setting-output-pthresh 0.01. Fifty-six high-confidence motifs were generated with FIMO q-value (FDR) < 0.05, and MEME Bonferroni-corrected p-value < 0.05. We used Homer to perform de novo motif usage analysis across the time course. Only miRNAs with more than 30 unique chimeras-defined sites were considered. Background sequences totally five times the number of target sequences were randomly selected from other miRNA chimeras. The retained motifs were subsequently filtered (match score ≥ 0.3, information content per bp ≥ 1.5 and confidence ≥ 1.0). Heatmap showing the percentage of motif presence was created using the R pheatmap package.
Dynamics of miRNA-mRNA interactions
To analyze the temporal profile of miRNA-mRNA interactions, chimeras-supported Ago1 binding peaks were normalized to mRNA levels at individual time points as previously described [63]. RNA abundance was determined by RNA-seq in this study. Normalized data were loaded into Gene Expression Dynamics Inspector (GEDI v2.1) with the default parameter (26×25 grids) to perform dynamic analysis [64] and visualize pattern changes during adult reproduction. GEDI employs the SOM algorithm to assign interactions with similar trends into close tiles. The Z-score of individual interaction was plotted in R to validate the clustering. Metabolic interactions were classified based on functional annotation of An. gambiae genes using the eggNOG database (v3.0).
GO and KEGG enrichment analysis
The selected gene ID list was taken as an input for functional enrichment analysis with DAVID [65]. The top 5 ranked GO terms were chosen. Enrichment score was calculated as -log10(p-value).
Supporting information
S1 Fig [a]
Experimental procedure of CLEAR-CLIP.
S2 Fig [pdf]
miRNAs detected in the Ago1-RNA complexes and miRNA-mRNA chimeras.
S3 Fig [a]
Characterization of the putative targets of miR-309.
S4 Fig [bs]
Regulation of by let-7 and miR-2 in luciferase reporter assays.
S5 Fig [pdf]
The levels of let-7 and miR-2 were reduced in adult female mosquitoes after injection of antagomirs.
S6 Fig [a]
was downregulated by the let-7 mimic in adult mosquitoes.
S7 Fig [pdf]
Conserved motifs in the targets of . miRNAs.
S8 Fig [pdf]
Identified targets of miR-9a-5p, miR-14-3p, and miR-276-3p at different time points.
S9 Fig [pdf]
Functional annotation of miRNA targets at specified time points.
S10 Fig [a]
Stage-specific motif usages of miR-14-3p and miR-276-3p.
S11 Fig [2017]
Comparison of the miRNA-target interactions in and .
S12 Fig [pdf]
Functional annotation of the chimeras-defined targets of selected mosquito miRNAs.
S13 Fig [a]
Regulation of lipid metabolism by miR-8 and miR-14.
S14 Fig [pdf]
mRNA profiles of key genes involved in carbohydrate and lipid metabolic pathways in adult female . .
S1 Table [pdf]
Read statistics of CLEAR-CLIP with the omission of T4 RNA ligase 1.
S2 Table [pdf]
Read statistics of CLEAR-CLIP with spiked-in bacterial RNA.
S3 Table [pdf]
Read statistics for CLEAR-CLIP RNA-Seq libraries.
S4 Table [xlsx]
Chimeras and Ago1 CLIP Peaks.
S5 Table [pdf]
Primers used in this study.
S6 Table [pdf]
Description of metabolic genes showing distinct patterns of interactions with miRNAs.
S1 Appendix [pdf]
CLEAR-CLIP Protocol for . Mosquitoes.
Zdroje
1. Franklinos LHV, Jones KE, Redding DW, Abubakar I. The effect of global change on mosquito-borne disease. Lancet Infect Dis. 2019;19:e302–e12. Epub 2019/06/23. doi: 10.1016/S1473-3099(19)30161-6 31227327.
2. Hansen IA, Attardo GM, Rodriguez SD, Drake LL. Four-way regulation of mosquito yolk protein precursor genes by juvenile hormone-, ecdysone-, nutrient-, and insulin-like peptide signaling pathways. Front Physiol. 2014;5:103. doi: 10.3389/fphys.2014.00103 WOS:000346841400001. 24688471
3. Vanhandel E. Metabolism of Nutrients in the Adult Mosquito. Mosq News. 1984;44(4):573–9. WOS:A1984AAP4300025.
4. Telang A, Li Y, Noriega FG, Brown MR. Effects of larval nutrition on the endocrinology of mosquito egg development. The Journal of experimental biology. 2006;209(Pt 4):645–55. Epub 2006/02/02. doi: 10.1242/jeb.02026 16449559.
5. Thompson SN. Trehalose—The insect 'blood' sugar. Advances in Insect Physiology, Vol 31. 2003;31:205–85. doi: 10.1016/S0065-2806(03)31004-5 WOS:000187509900004.
6. Zou Z, Saha TT, Roy S, Shin SW, Backman TW, Girke T, et al. Juvenile hormone and its receptor, methoprene-tolerant, control the dynamics of mosquito gene expression. Proceedings of the National Academy of Sciences of the United States of America. 2013;110(24):E2173–81. Epub 2013/05/02. doi: 10.1073/pnas.1305293110 23633570; PubMed Central PMCID: PMC3683779.
7. Jindra M, Palli SR, Riddiford LM. The juvenile hormone signaling pathway in insect development. Annual review of entomology. 2013;58:181–204. Epub 2012/09/22. doi: 10.1146/annurev-ento-120811-153700 22994547.
8. Athenstaedt K, Daum G. The life cycle of neutral lipids: synthesis, storage and degradation. Cell Mol Life Sci. 2006;63(12):1355–69. doi: 10.1007/s00018-006-6016-8 WOS:000238531600002. 16649142
9. Steele JE. Glycogen-Phosphorylase in Insects. Insect Biochem. 1982;12(2):131–47. doi: 10.1016/0020-1790(82)90001-4 WOS:A1982NN86300001.
10. Zhou GL, Pennington JE, Wells MA. Utilization of pre-existing energy stores of female Aedes aegypti mosquitoes during the first gonotrophic cycle. Insect biochemistry and molecular biology. 2004;34(9):919–25. doi: 10.1016/j.ibmb.2004.05.009 WOS:000224001200004. 15350611
11. Bonizzoni M, Dunn WA, Campbell CL, Olson KE, Dimon MT, Marinotti O, et al. RNA-seq analyses of blood-induced changes in gene expression in the mosquito vector species, Aedes aegypti. BMC genomics. 2011;12:82. Epub 2011/02/01. doi: 10.1186/1471-2164-12-82 21276245; PubMed Central PMCID: PMC3042412.
12. Hou Y, Wang XL, Saha TT, Roy S, Zhao B, Raikhel AS, et al. Temporal Coordination of Carbohydrate Metabolism during Mosquito Reproduction. PLoS genetics. 2015;11(7):e1005309. Epub 2015/07/15. doi: 10.1371/journal.pgen.1005309 26158648; PubMed Central PMCID: PMC4497655.
13. Wang X, Hou Y, Saha TT, Pei G, Raikhel AS, Zou Z. Hormone and receptor interplay in the regulation of mosquito lipid metabolism. Proceedings of the National Academy of Sciences of the United States of America. 2017;114(13):E2709–E18. Epub 2017/03/16. doi: 10.1073/pnas.1619326114 28292900; PubMed Central PMCID: PMC5380040.
14. Bryant B, Macdonald W, Raikhel AS. microRNA miR-275 is indispensable for blood digestion and egg development in the mosquito Aedes aegypti. Proceedings of the National Academy of Sciences of the United States of America. 2010;107(52):22391–8. Epub 2010/12/01. doi: 10.1073/pnas.1016230107 21115818; PubMed Central PMCID: PMC3012520.
15. Ling L, Kokoza VA, Zhang C, Aksoy E, Raikhel AS. MicroRNA-277 targets insulin-like peptides 7 and 8 to control lipid metabolism and reproduction in Aedes aegypti mosquitoes. Proceedings of the National Academy of Sciences of the United States of America. 2017;114(38):E8017–E24. Epub 2017/09/07. doi: 10.1073/pnas.1710970114 28874536; PubMed Central PMCID: PMC5617303.
16. Liu S, Lucas KJ, Roy S, Ha J, Raikhel AS. Mosquito-specific microRNA-1174 targets serine hydroxymethyltransferase to control key functions in the gut. Proceedings of the National Academy of Sciences of the United States of America. 2014;111(40):14460–5. Epub 2014/09/24. doi: 10.1073/pnas.1416278111 25246546; PubMed Central PMCID: PMC4209991.
17. Lucas KJ, Roy S, Ha J, Gervaise AL, Kokoza VA, Raikhel AS. MicroRNA-8 targets the Wingless signaling pathway in the female mosquito fat body to regulate reproductive processes. Proceedings of the National Academy of Sciences of the United States of America. 2015;112(5):1440–5. Epub 2015/01/22. doi: 10.1073/pnas.1424408112 25605933; PubMed Central PMCID: PMC4321257.
18. Zhang Y, Zhao B, Roy S, Saha TT, Kokoza VA, Li M, et al. microRNA-309 targets the Homeobox gene SIX4 and controls ovarian development in the mosquito Aedes aegypti. Proceedings of the National Academy of Sciences of the United States of America. 2016;113(33):E4828–36. Epub 2016/08/05. doi: 10.1073/pnas.1609792113 27489347; PubMed Central PMCID: PMC4995966.
19. Zhao B, Lucas KJ, Saha TT, Ha J, Ling L, Kokoza VA, et al. MicroRNA-275 targets sarco/endoplasmic reticulum Ca2+ adenosine triphosphatase (SERCA) to control key functions in the mosquito gut. PLoS genetics. 2017;13(8):e1006943. Epub 2017/08/09. doi: 10.1371/journal.pgen.1006943 28787446; PubMed Central PMCID: PMC5560755.
20. Bushati N, Cohen SM. microRNA functions. Annual review of cell and developmental biology. 2007;23:175–205. Epub 2007/05/18. doi: 10.1146/annurev.cellbio.23.090506.123406 17506695.
21. Hausser J, Zavolan M. Identification and consequences of miRNA-target interactions—beyond repression of gene expression. Nature reviews Genetics. 2014;15(9):599–612. Epub 2014/07/16. doi: 10.1038/nrg3765 25022902.
22. Didiano D, Hobert O. Molecular architecture of a miRNA-regulated 3' UTR. Rna. 2008;14(7):1297–317. doi: 10.1261/rna.1082708 18463285; PubMed Central PMCID: PMC2441980.
23. Gu S, Jin L, Zhang F, Sarnow P, Kay MA. Biological basis for restriction of microRNA targets to the 3' untranslated region in mammalian mRNAs. Nature structural & molecular biology. 2009;16(2):144–50. doi: 10.1038/nsmb.1552 19182800; PubMed Central PMCID: PMC2713750.
24. Bhattacharyya SN, Habermacher R, Martine U, Closs EI, Filipowicz W. Relief of microRNA-mediated translational repression in human cells subjected to stress. Cell. 2006;125(6):1111–24. doi: 10.1016/j.cell.2006.04.031 16777601.
25. Kedde M, Strasser MJ, Boldajipour B, Oude Vrielink JA, Slanchev K, le Sage C, et al. RNA-binding protein Dnd1 inhibits microRNA access to target mRNA. Cell. 2007;131(7):1273–86. doi: 10.1016/j.cell.2007.11.034 18155131.
26. Hammell CM, Lubin I, Boag PR, Blackwell TK, Ambros V. nhl-2 Modulates microRNA activity in Caenorhabditis elegans. Cell. 2009;136(5):926–38. doi: 10.1016/j.cell.2009.01.053 19269369; PubMed Central PMCID: PMC2670343.
27. Johnston M, Hutvagner G. Posttranslational modification of Argonautes and their role in small RNA-mediated gene regulation. Silence. 2011;2:5. doi: 10.1186/1758-907X-2-5 21943311; PubMed Central PMCID: PMC3199228.
28. Neumuller RA, Betschinger J, Fischer A, Bushati N, Poernbacher I, Mechtler K, et al. Mei-P26 regulates microRNAs and cell growth in the Drosophila ovarian stem cell lineage. Nature. 2008;454(7201):241–5. doi: 10.1038/nature07014 18528333; PubMed Central PMCID: PMC2988194.
29. Rudel S, Wang Y, Lenobel R, Korner R, Hsiao HH, Urlaub H, et al. Phosphorylation of human Argonaute proteins affects small RNA binding. Nucleic acids research. 2011;39(6):2330–43. doi: 10.1093/nar/gkq1032 21071408; PubMed Central PMCID: PMC3064767.
30. Mittal N, Zavolan M. Seq and CLIP through the miRNA world. Genome biology. 2014;15(1):202. Epub 2014/01/28. doi: 10.1186/gb4151 24460822; PubMed Central PMCID: PMC4053862.
31. Chi SW, Zang JB, Mele A, Darnell RB. Argonaute HITS-CLIP decodes microRNA-mRNA interaction maps. Nature. 2009;460(7254):479–86. Epub 2009/06/19. doi: 10.1038/nature08170 19536157; PubMed Central PMCID: PMC2733940.
32. Zisoulis DG, Lovci MT, Wilbert ML, Hutt KR, Liang TY, Pasquinelli AE, et al. Comprehensive discovery of endogenous Argonaute binding sites in Caenorhabditis elegans. Nature structural & molecular biology. 2010;17(2):173–9. Epub 2010/01/12. doi: 10.1038/nsmb.1745 20062054; PubMed Central PMCID: PMC2834287.
33. Zhang X, Aksoy E, Girke T, Raikhel AS, Karginov FV. Transcriptome-wide microRNA and target dynamics in the fat body during the gonadotrophic cycle of Aedes aegypti. Proceedings of the National Academy of Sciences of the United States of America. 2017;114(10):E1895–E903. Epub 2017/02/23. doi: 10.1073/pnas.1701474114 28223504; PubMed Central PMCID: PMC5347622.
34. Moore MJ, Scheel TK, Luna JM, Park CY, Fak JJ, Nishiuchi E, et al. miRNA-target chimeras reveal miRNA 3'-end pairing as a major determinant of Argonaute target specificity. Nature communications. 2015;6:8864. Epub 2015/11/26. doi: 10.1038/ncomms9864 26602609; PubMed Central PMCID: PMC4674787.
35. Grosswendt S, Filipchyk A, Manzano M, Klironomos F, Schilling M, Herzog M, et al. Unambiguous identification of miRNA:target site interactions by different types of ligation reactions. Molecular cell. 2014;54(6):1042–54. Epub 2014/05/27. doi: 10.1016/j.molcel.2014.03.049 24857550; PubMed Central PMCID: PMC4181535.
36. Helwak A, Kudla G, Dudnakova T, Tollervey D. Mapping the human miRNA interactome by CLASH reveals frequent noncanonical binding. Cell. 2013;153(3):654–65. Epub 2013/04/30. doi: 10.1016/j.cell.2013.03.043 23622248; PubMed Central PMCID: PMC3650559.
37. Biryukova I, Ye T, Levashina E. Transcriptome-wide analysis of microRNA expression in the malaria mosquito Anopheles gambiae. BMC genomics. 2014;15:557. Epub 2014/07/07. doi: 10.1186/1471-2164-15-557 24997592; PubMed Central PMCID: PMC4112208.
38. Fu X, Dimopoulos G, Zhu J. Association of microRNAs with Argonaute proteins in the malaria mosquito Anopheles gambiae after blood ingestion. Scientific reports. 2017;7(1):6493. Epub 2017/07/28. doi: 10.1038/s41598-017-07013-1 28747726.
39. Ojani R, Fu X, Ahmed T, Liu P, Zhu J. Kruppel homologue 1 acts as a repressor and an activator in the transcriptional response to juvenile hormone in adult mosquitoes. Insect molecular biology. 2018;27(2):268–78. Epub 2018/01/10. doi: 10.1111/imb.12370 29314423; PubMed Central PMCID: PMC5837916.
40. Song J, Li W, Zhao H, Gao L, Fan Y, Zhou S. The microRNAs let-7 and miR-278 regulate insect metamorphosis and oogenesis by targeting the juvenile hormone early-response gene Kruppel-homolog 1. Development. 2018;145(24). Epub 2018/11/25. doi: 10.1242/dev.170670 30470705.
41. Zhou G, Flowers M, Friedrich K, Horton J, Pennington J, Wells MA. Metabolic fate of [14C]-labeled meal protein amino acids in Aedes aegypti mosquitoes. Journal of insect physiology. 2004;50(4):337–49. Epub 2004/04/15. doi: 10.1016/j.jinsphys.2004.02.003 15081827.
42. Gebert LFR, MacRae IJ. Regulation of microRNA function in animals. Nat Rev Mol Cell Biol. 2019;20(1):21–37. Epub 2018/08/16. doi: 10.1038/s41580-018-0045-7 30108335; PubMed Central PMCID: PMC6546304.
43. Grimson A, Farh KK, Johnston WK, Garrett-Engele P, Lim LP, Bartel DP. MicroRNA targeting specificity in mammals: determinants beyond seed pairing. Molecular cell. 2007;27(1):91–105. Epub 2007/07/07. doi: 10.1016/j.molcel.2007.06.017 17612493; PubMed Central PMCID: PMC3800283.
44. Yu J, Ryan DG, Getsios S, Oliveira-Fernandes M, Fatima A, Lavker RM. MicroRNA-184 antagonizes microRNA-205 to maintain SHIP2 levels in epithelia. Proceedings of the National Academy of Sciences of the United States of America. 2008;105(49):19300–5. Epub 2008/11/27. doi: 10.1073/pnas.0803992105 19033458; PubMed Central PMCID: PMC2587229.
45. Golden RJ, Chen B, Li T, Braun J, Manjunath H, Chen X, et al. An Argonaute phosphorylation cycle promotes microRNA-mediated silencing. Nature. 2017;542(7640):197–202. Epub 2017/01/24. doi: 10.1038/nature21025 28114302; PubMed Central PMCID: PMC5302127.
46. Ahuja D, Goyal A, Ray PS. Interplay between RNA-binding protein HuR and microRNA-125b regulates p53 mRNA translation in response to genotoxic stress. RNA biology. 2016;13(11):1152–65. Epub 2016/10/30. doi: 10.1080/15476286.2016.1229734 27592685; PubMed Central PMCID: PMC5100343.
47. Kedde M, van Kouwenhove M, Zwart W, Oude Vrielink JA, Elkon R, Agami R. A Pumilio-induced RNA structure switch in p27-3' UTR controls miR-221 and miR-222 accessibility. Nat Cell Biol. 2010;12(10):1014–20. Epub 2010/09/08. doi: 10.1038/ncb2105 20818387.
48. Lampe L, Levashina EA. MicroRNA Tissue Atlas of the Malaria Mosquito Anopheles gambiae. G3. 2018;8(1):185–93. Epub 2017/11/18. doi: 10.1534/g3.117.300170 29146584; PubMed Central PMCID: PMC5765347.
49. Jin H, Kim VN, Hyun S. Conserved microRNA miR-8 controls body size in response to steroid signaling in Drosophila. Genes & development. 2012;26(13):1427–32. Epub 2012/07/04. doi: 10.1101/gad.192872.112 22751499; PubMed Central PMCID: PMC3403011.
50. Wen J, Mohammed J, Bortolamiol-Becet D, Tsai H, Robine N, Westholm JO, et al. Diversity of miRNAs, siRNAs, and piRNAs across 25 Drosophila cell lines. Genome research. 2014;24(7):1236–50. Epub 2014/07/06. doi: 10.1101/gr.161554.113 24985917; PubMed Central PMCID: PMC4079977.
51. Roy S, Saha TT, Johnson L, Zhao B, Ha J, White KP, et al. Regulation of Gene Expression Patterns in Mosquito Reproduction. PLoS genetics. 2015;11(8):e1005450. Epub 2015/08/15. doi: 10.1371/journal.pgen.1005450 26274815; PubMed Central PMCID: PMC4537244.
52. Marinotti O, Calvo E, Nguyen QK, Dissanayake S, Ribeiro JM, James AA. Genome-wide analysis of gene expression in adult Anopheles gambiae. Insect molecular biology. 2006;15(1):1–12. Epub 2006/02/14. doi: 10.1111/j.1365-2583.2006.00610.x 16469063.
53. Mead EA, Li M, Tu Z, Zhu J. Translational regulation of Anopheles gambiae mRNAs in the midgut during Plasmodium falciparum infection. BMC genomics. 2012;13:366. Epub 2012/08/04. doi: 10.1186/1471-2164-13-366 22857387; PubMed Central PMCID: PMC3443010.
54. Haas BJ, Salzberg SL, Zhu W, Pertea M, Allen JE, Orvis J, et al. Automated eukaryotic gene structure annotation using EVidenceModeler and the Program to Assemble Spliced Alignments. Genome biology. 2008;9(1):R7. Epub 2008/01/15. doi: 10.1186/gb-2008-9-1-r7 18190707; PubMed Central PMCID: PMC2395244.
55. Dodt M, Roehr JT, Ahmed R, Dieterich C. FLEXBAR-Flexible Barcode and Adapter Processing for Next-Generation Sequencing Platforms. Biology. 2012;1(3):895–905. Epub 2012/01/01. doi: 10.3390/biology1030895 24832523; PubMed Central PMCID: PMC4009805.
56. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ. Basic local alignment search tool. Journal of molecular biology. 1990;215(3):403–10. Epub 1990/10/05. doi: 10.1016/S0022-2836(05)80360-2 2231712.
57. Haecker I, Gay LA, Yang Y, Hu J, Morse AM, McIntyre LM, et al. Ago HITS-CLIP expands understanding of Kaposi's sarcoma-associated herpesvirus miRNA function in primary effusion lymphomas. PLoS pathogens. 2012;8(8):e1002884. Epub 2012/08/29. doi: 10.1371/journal.ppat.1002884 22927820; PubMed Central PMCID: PMC3426530.
58. Kruger J, Rehmsmeier M. RNAhybrid: microRNA target prediction easy, fast and flexible. Nucleic acids research. 2006;34(Web Server issue):W451–4. Epub 2006/07/18. doi: 10.1093/nar/gkl243 16845047; PubMed Central PMCID: PMC1538877.
59. Ojani R, Liu P, Fu X, Zhu J. Protein kinase C modulates transcriptional activation by the juvenile hormone receptor methoprene-tolerant. Insect biochemistry and molecular biology. 2016;70:44–52. Epub 2015/12/23. doi: 10.1016/j.ibmb.2015.12.001 26689644; PubMed Central PMCID: PMC4767628.
60. Anders S, Pyl PT, Huber W. HTSeq—a Python framework to work with high-throughput sequencing data. Bioinformatics. 2015;31(2):166–9. Epub 2014/09/28. doi: 10.1093/bioinformatics/btu638 25260700; PubMed Central PMCID: PMC4287950.
61. Zhong Y, Karaletsos T, Drewe P, Sreedharan VT, Kuo D, Singh K, et al. RiboDiff: detecting changes of mRNA translation efficiency from ribosome footprints. Bioinformatics. 2017;33(1):139–41. Epub 2016/09/17. doi: 10.1093/bioinformatics/btw585 27634950; PubMed Central PMCID: PMC5198522.
62. Grant CE, Bailey TL, Noble WS. FIMO: scanning for occurrences of a given motif. Bioinformatics. 2011;27(7):1017–8. Epub 2011/02/19. doi: 10.1093/bioinformatics/btr064 21330290; PubMed Central PMCID: PMC3065696.
63. Hafner A, Stewart-Ornstein J, Purvis JE, Forrester WC, Bulyk ML, Lahav G. p53 pulses lead to distinct patterns of gene expression albeit similar DNA-binding dynamics. Nature structural & molecular biology. 2017;24(10):840–7. Epub 2017/08/22. doi: 10.1038/nsmb.3452 28825732; PubMed Central PMCID: PMC5629117.
64. Eichler GS, Huang S, Ingber DE. Gene Expression Dynamics Inspector (GEDI): for integrative analysis of expression profiles. Bioinformatics. 2003;19(17):2321–2. Epub 2003/11/25. doi: 10.1093/bioinformatics/btg307 14630665.
65. Huang da W, Sherman BT, Lempicki RA. Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources. Nature protocols. 2009;4(1):44–57. Epub 2009/01/10. doi: 10.1038/nprot.2008.211 19131956.
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