To identify a dsRBD protein partner for Dcr-1, we searched the conserved domain database [
37] for all
Drosophila proteins that contain dsRBDs. The protein encoded by the gene CG6866 has two dsRBDs, which are most closely related to dsRBD 1 and 2 of R2D2, suggesting that the two genes are paralogs (A). CG6866 and R2D2 are 37% similar and 25% identical in the region of the two dsRBDs. A third dsRBD at the C-terminus of CG6866 was detected using the PFam collection of protein sequence motifs. This truncated domain deviates from the canonical dsRBD sequence. Because loss of CG6866 function de-silences both endogenous silencing and reporter expression in vivo (below), we named the gene
loquacious (loqs).loqs is located on the left arm of Chromosome 2 at polytene band 34B9.
loqs produces at least three different mRNA isoforms through alternative splicing (B). The shortest transcript,
loqs RNA splice variant A (RA), encodes a 419-amino-acid protein, Loqs protein isoform A (PA), with a predicted molecular mass of 45 kDa. The transcript
loqs RNA splice variant B (RB) contains one additional exon and encodes a protein of 465 amino acids, Loqs protein isoform B (PB), with a predicted molecular mass of 50 kDa. These two mRNA species were identified as cDNAs in the
Drosophila genome sequencing project and annotated in FlyBase [
38] among the
Drosophila proteins that contain dsRBDs. Using non-quantitative RT-PCR, we detected a third splice variant,
loqs RNA splice variant C (RC), in which an alternative splice acceptor site for exon 4 is used (B, C, and D). Use of the alternative splice site creates a 5′-extended fourth exon and changes the reading frame, resulting in a truncated protein, Loqs protein isoform C (PC), 383 amino acids long (C). Loqs PC has a predicted molecular mass of 41 kDa and lacks the entire third dsRBD of Loqs PA and PB (B).
loqs RA is the predominant mRNA species in dissected testes, whereas
loqs RB is the most abundant species in ovaries. Both isoforms are expressed in the carcasses of males and females after removal of the gonads (D and data not shown). Using two independent antibodies raised against an N-terminal Loqs peptide, but not using pre-immune sera, we detected a candidate protein for Loqs PC in S2 cells (see below), suggesting that the three
loqs transcripts give rise to distinct Loqs protein isoforms.
Thibault and co-workers reported a mutant allele of CG6866,
loqsf00791, recovered in a large-scale piggyBac transposon mutagenesis screen of
Drosophila [
39]. The f00791 piggyBac inserted 57 nucleotides upstream of the
loqs transcription start site (E); although annotated as lethal, homozygous mutant
loqsf00791 flies are viable but completely female sterile. Precise excision of the f00791 piggyBac transposon fully reverted the female sterility (data not shown). Analysis by quantitative RT-PCR using primers that amplify all three
loqs mRNA splice variants (see
Materials and Methods) showed that somatic female
loqsf00791 tissues express approximately 5-fold (4.76 ± 0.24;
n = 3) less
loqs mRNA than wild-type, while
loqsf00791 mutant ovaries express approximately 40-fold (42 ± 0.33;
n = 3) less
loqs mRNA than wild-type ovaries. Testes express approximately 3-fold (2.9 ± 0.5;
n = 3) less
loqs mRNA in the
loqsf00791 mutant than in wild type. These data suggest that the mutant phenotype should be strongest in ovaries, consistent with the mutation causing female sterility as its most obvious defect.
In Vivo, Normal Pre-miRNA Processing Requires Loqs
To assess the function of loqs in miRNA biogenesis, we isolated total RNA from loqsf00791 males and determined the steady-state levels of mature and pre-miRNA for miR-277 and bantam (A), which are both expressed in adult tissues. We detected a 100-fold increase in pre-miR-277 and a 12-fold increase in pre-bantam RNAs in homozygous mutant loqsf00791 males, but not in heterozygous loqsf00791 or heterozygous or homozygous r2d2 mutant males. In contrast, the amount of mature miR-277 or bantam was only slightly reduced in the loqsf00791 homozygotes.
Since loqs mRNA expression is lowest in the ovaries of loqsf00791 mutant flies, we analyzed the levels of pre-miR-7 and mature miR-7, a miRNA that is expressed in whole males, manually dissected ovaries, and the female carcasses remaining after removing the ovaries (B). While pre-miR-7 increased in all loqsf00791 homozygous mutant tissues, relative to wild-type or loqs heterozygotes, the disruption of miR-7 production in ovaries was striking: not only did pre-miR-7 accumulate, but also mature miR-7 was dramatically reduced. These data suggest that Loqs protein function is required for the maturation of miRNA and demonstrate a direct correlation between loqs mutant allele strength and disruption of miRNA processing.
Loqs Is Required for Pre-miRNA Processing in Drosophila S2 Cells
To confirm the function of loqs in pre-miRNA processing, we depleted cultured Drosophila S2 cells of loqs mRNA by RNAi (C). Eight days after incubating S2 cells with dsRNA corresponding to the first 300 nucleotides of the loqs coding sequence, we determined the steady-state levels of pre-miRNA and mature miRNA for miR-277 and bantam. Relative to an unrelated dsRNA control, dsRNA corresponding to dcr-1 caused a approximately 9-fold and approximately 23-fold increase in steady-state pre-miR-277 and bantam levels, respectively, and dsRNA corresponding to loqs caused a approximately 2-fold and approximately 6-fold increase in steady-state pre-miR-277 and bantam levels, respectively. In these experiments, RNAi of dcr-1 more completely depleted Dcr-1 protein than RNAi of loqs reduced Loqs protein (D). RNAi of dcr-2,r2d2, or drosha did not alter pre-miRNA levels for either miR-277 or bantam, nor did it alter Dcr-1 or Loqs levels. The Drosha/Pasha protein complex functions before pre-miRNA processing, converting primary miRNA (pri-miRNA) to pre-miRNA. Consistent with the idea that Loqs functions with Dcr-1 to convert pre-miRNA to mature miRNA, RNAi of drosha together with loqs alleviated the high pre-miRNA levels observed for RNAi of loqs alone, demonstrating that Loqs acts after Drosha.
Next, we examined processing of 20 nM exogenous pre-
let-7 into mature
let-7 in lysates from ovaries or S2 cells (). Initial velocities were calculated for each reaction to permit comparison of processing rates (see
Materials and Methods). Lysate from homozygous
loqsf00791 mutant ovaries processed pre-
let-7 RNA to mature
let-7 approximately 19-fold more slowly than wild-type ovary lysate (A). Moreover, lysate prepared from S2 cells soaked with a green fluoresecent protein (GFP) control dsRNA (GFP[RNAi]) or
drosha dsRNA (
drosha[RNAi]) accurately and efficiently converted exogenous pre-
let-7 RNA into mature
let-7. In contrast, both
dcr-1(RNAi) and
loqs(RNAi) S2 cell lysates converted pre-miRNA to mature miRNA approximately 5- and approximately 4-fold, respectively, more slowly than the control lysate (B). Thus, Loqs is required for production in vivo of normal levels of miR-7, miR-277, and
bantam, and the efficient conversion of pre-
let-7 to mature
let-7 in vitro. Together, these four miRNAs include both miRNAs found on the 5′ and on the 3′ side of the pre-miRNA stem, suggesting a general role for Loqs in pre-miRNA processing.
Reduction of R2D2 protein by RNAi destabilizes Dcr-2; conversely, RNAi of Dcr-2 renders R2D2 unstable [
21]. In contrast, RNAi of
loqs in S2 cells reduced Dcr-1 protein levels by no more than 15% (D and E), suggesting that Loqs functions together with Dcr-1 in pre-miRNA processing, rather than that Loqs is simply needed to stabilize Dcr-1 protein. However,
loqsf00791 mutant ovaries, which lack detectable Loqs protein, contain 70% less Dcr-1 than wild-type (E). A role for Loqs in both Dcr-1 function and in Dcr-1 stability suggests that the two proteins physically interact, like R2D2 and Dcr-2. Therefore, we tested if Dcr-1 and Loqs are components of a common complex.
A Dcr-1 Protein Complex Contains Loqs
We expressed in S2 cells myc-tagged versions for two protein isoforms of Loqs, Loqs PA and Loqs PB, and immunoprecipitated the tagged proteins with anti-myc monoclonal antibodies. We analyzed the immunoprecipitated protein by Western blotting using a polyclonal anti-Dcr-1 antibody. A shows that Dcr-1 protein co-immunoprecipitated with myc-tagged Loqs. When myc-tagged GFP was expressed in place of myc-tagged Loqs, no Dcr-1 protein was recovered in the anti-myc immunoprecipitate. Similarly, an affinity purified, polyclonal antibody directed against the N-terminus of endogenous Loqs protein also co-immunoprecipitated Dcr-1 protein (A). This interaction was resistant to treatment with RNase A (data not shown). We could not detect co-immunoprecipitation of Dcr-2 with myc-tagged Loqs PB under conditions where Dcr-1 was readily detected (B), but we cannot exclude that Dcr-2 is a substoichiometric component of a complex that contains both Dcr-1 and Loqs (see below).
When immunoprecipitated with anti-Dcr-1 antibody, both myc-tagged Loqs protein isoforms—PA and PB—associated with Dcr-1 (C). Moreover, the antibody against endogenous Loqs protein detected two bands corresponding in size to Loqs PA and Loqs PB in the proteins immunoprecipitated with the anti-Dcr-1 antibody (D). Loqs PB comprises only approximately 22% of the total Loqs protein in S2 cells, but corresponded to approximately 95% of the Loqs associated with Dcr-1. Loqs PA, which is expressed at comparable levels in S2 cells, accounts for most of the remaining Loqs associated with Dcr-1. In contrast, the putative Loqs PC protein comprises the majority of S2 cell Loqs, but was not recovered in the Dcr-1 immunoprecipitate. Intriguingly, Loqs PA and PB contain a third dsRBD that Loqs PC lacks; perhaps this third dsRBD is required for the association of Loqs with Dcr-1.
The immunoprecipitated Dcr-1–Loqs complexes accurately converted pre-miRNA to mature miRNA (). Pre-miRNA processing by the immunoprecipitates was efficient and accurate when we used the anti-Dcr-1 antibody (A), and when we used anti-myc antibody and expressed myc-tagged Loqs, but not when we used the anti-myc antibody and expressed myc-tagged GFP (A and B). Thus, Dcr-1 and Loqs co-associate in a complex capable of converting pre-miRNA into mature miRNA. Our data also demonstrate that an N-terminal tandem myc tag does not perturb Loqs function in pre-miRNA cleavage.
Next, we estimated the size of the pre-miRNA processing complex by gel filtration chromatography. Pre-miRNA processing activity chromatographed as a broad approximately 525-kDa peak that overlapped the peaks of both Dcr-1 and Loqs proteins (A and B). Dcr-1 protein chromatographed as an approximately 480-kDa complex that overlapped the peak of Loqs PB, which chromatographed as an approximately 630-kDa complex. The Loqs PB isoform accounts for most of the Dcr-1-associated Loqs in S2 cells (see D). The apparent size of the Dcr-1 complex suggests that it is either associated with proteins in addition to Loqs or that the complex has an elongated shape that increases its apparent molecular weight. Pre-miRNA processing activity, Loqs, and Dcr-1 were all well resolved from the approximately 230-kDa peak of Dcr-2 (theoretical mass = 197.7 kDa), which corresponds to the Dcr-2/R2D2 heterodimer (theoretical mass = 232.7 kDa). Although the peaks of Loqs and Dcr-1 do not co-migrate, Dcr-1 was stably associated with Loqs after gel filtration: Dcr-1 and Loqs reciprocally co-immunoprecipitated from the pooled peak Dcr-1 fractions (C). Loqs was not detected in the Dcr-2 peak by this method (data not shown). Loqs PC, which did not associate with Dcr-1 in immunoprecipitation, chromatographed as a 58-kDa protein, suggesting that it is a free monomeric protein (data not shown).
A Loqs Mutation Reduces Silencing of a miRNA-Controlled Reporter Transgene In Vivo
The
loqsf00791 mutation caused pre-miRNAs to accumulate in the soma and the germ line and strongly reduced mature miR-7 levels in the female germ line, suggesting that Loqs function is required for miRNA-directed silencing in vivo. We introduced a miRNA-regulated yellow fluorescent protein (YFP) reporter into
loqsf00791 homozygous mutant flies. This transgenic reporter expresses in the eye a YFP mRNA bearing four miR-277 binding sites in its 3′ UTR. The four miRNA-binding sites pair with all but the central three nucleotides of miR-277 and are, therefore, predicted to repress reporter mRNA translation rather than trigger mRNA cleavage (A). YFP fluorescence was readily detected in the eye and antennae in control flies in which the 3′ UTR of the YFP transgene lacked the four miR-277 binding sites (A). When the reporter contained the miR-277 binding sites, YFP expression was repressed in the eye but readily visible in the antennae, indicating that miR-277 is expressed in the eye (
loqs/CyO, A and B). This expression was verified independently by Northern blots of RNA isolated from eyes dissected away from other tissues of the head (data not shown). Silencing of the miR-277-responsive YFP reporter in the eye was reduced in
loqsf00791 homozygous mutant flies (
loqs/
loqs, A, B and C). As a control, we examined the effect of a strong
r2d2 mutation on YFP reporter expression (A and C). We measured the maximum fluorescence intensity in each eye for all four genotypes. C shows that there was a significant (
P < 1.9 × 10
−7) increase in YFP fluorescence in eyes homozygous for the weak hypomorphic allele
loqsf00791. This allele reduced miR-277 levels in the soma approximately 2-fold (see B); fluorescence in the eye of homozygous mutant
loqs flies was 1.8 ± 0.17 (average maximum intensity ± standard deviation;
n = 13) times greater than in the eyes of their age-matched heterozygous siblings. In contrast, flies homozygous for a strong hypomorphic
r2d2 mutation show only a modest change in fluorescence (1.1 ± 0.09;
n = 13;
P < 0.025). The Dcr-2 partner protein R2D2 is required for RNAi triggered by exogenous dsRNA [
21] or transgenes expressing long dsRNA hairpins (see below and ). We conclude that the reduced levels of Loqs protein in the
loqsf00791 mutant lead to a statistically significant reduction in miRNA-directed silencing and that the Loqs paralog R2D2 plays little, if any, role in miRNA function.
Loqs Participates in Silencing Triggered by Long dsRNAIn Vivo
dsRNA transcribed as an inverted repeat (IR) triggers silencing of corresponding mRNAs in flies [
23,
40]. For IR-silencing of the
white gene, whose gene product is required to produce the red pigment that colors fly eyes, the extent of silencing is proportionate to the number of copies of the IR-
white transgene [
23,
40] (A), but is relatively insensitive to the number of copies of
white present (TD and PDZ, unpublished). RNAi in
Drosophila requires both Dcr-2, which transforms long dsRNA into siRNA, and R2D2, which collaborates with Dcr-2 to load siRNA into RISC. Thus, IR-silencing of
white mRNA is lost in both
dcr-2 [
23] and
r2d2 mutant flies (B). We quantified the extent of
white silencing by extracting the eye pigment in acidic ethanol and measuring its absorbance at 480 nm (E and
S1). Loss of R2D2 function in flies expressing one (or two) copies of the
white IR transgene and two copies of the endogenous
white locus restored red pigment levels to 74 ± 13 (or 73 ± 15 for two copies of IR-
white) percent of wild-type flies lacking the
white-IR.
loqsf00791 mutant flies were also defective in IR-triggered
white silencing, but to a much smaller extent (C and E). The
loqsf00791 mutation restored pigment levels in flies carrying one copy of the
white IR-expressing transgene to 12 ± 2% of wild-type and to 8 ± 0.6% for flies carrying two copies of the
white-IR (
n = 5; C and E).
loqsf00791 heterozygotes were statistically indistinguishable from wild-type flies bearing one copy of IR-
white, whose eye pigment concentration was 4 ± 0.5 (or 2 ± 0.6 for two copies of IR-
white) percent of wild-type in the absence of the IR-
white transgene.
Insertion of a mini-
white-expressing piggyBac transposon causes the
loqsf00791 allele. Thus,
loqsf00791 heterozygotes have two copies of the endogenous
white locus and one copy of mini-
white;
loqsf00791 homozygotes have two copies of endogenous
white and two copies of mini-
white. The presence of this additional copy of mini-
white does not account for the darker red color of
white-silenced
loqsf00791 flies, because
loqsf00791 heterozygotes bearing two copies of
white, one copy of mini-
white (in the piggyBac transposon inserted at
loqs), and one copy of a P-element expressing mini-
white are effectively silenced by IR-
white (D). In the absence of the IR-
white transgene, the total amount of
white expression in these flies is higher than in
loqsf00791 homozygotes (D). Thus, reduction of Loqs function accounts for the partial desilencing of
white in this system. The modest loss of silencing in the
loqsf00791 mutant flies may reflect the incomplete loss of Loqs protein in this allele. However, Carthew and co-workers previously reported that a
dcr-1 null mutation leads to a similar, partial loss of
white IR-silencing [
23]. The small eye phenotype of
dcr-1 null mutants unfortunately renders a quantitative comparison to
loqsf00791 impossible. We propose that—as for pre-miRNA processing—Dcr-1 and Loqs act together to enhance silencing by siRNAs.
Silencing of the Endogenous Stellate Locus Requires Loqs
loqsf00791 males are incompletely fertile. When Oregon R females were mated to
loqsf00791 homozygous mutant males, only 17% of embryos hatched (
n = 479); for
loqsf00791 heterozygous males, 47% of embryos hatched (
n = 466). Ninety percent of embryos hatched (
n = 753) for wild-type Oregon R males. Genes required for RNA silencing often reduce male fertility, because the X-linked gene
Ste is epigenetically silenced in testes by dsRNA derived from the bi-directionally transcribed
Suppressor of Stellate (Su(Ste)) locus [
41].
Ste silencing is genetically similar, but not identical, to RNAi, in that like RNAi it requires the function of the gene
armitage(armi) [
24], but unlike RNAi does not require
r2d2 (VVV and PDZ, unpublished data). In the absence of
Ste silencing, Stellate protein accumulates as protein crystals in the testes.
loqsf00791 mutants contain Stellate crystals in their testes (), much like
armi72.1 mutants, identifying a second role for
loqs in silencing by endogenous RNA triggers, distinct from its function in miRNA biogenesis.
A Germ-Line Stem Cell Defect in loqsf00791 Mutant Females
The
loqs gene has a critical function in oogenesis, as
loqsf00791 females have small ovaries (A) and are completely sterile.
Drosophila ovaries comprise ovarioles that contain developmentally ordered egg chambers, which are produced continuously in the adult by germ-line stem cell division. As a result, mutations that block stem cell division or maintenance lead to ovarioles containing few egg chambers.
loqsf00791 mutant females lay no eggs. Whereas wild-type females contain 7 ± 0.8 (
n = 15) previtellogenic egg chambers per ovariole,
loqsf00791 contain only 3 ± 0.8 (
n = 20). Excision of the
piggybac transposon in
loqsf00791 restores fertility, demonstrating that these defects reflect loss of Loqs function. The mature oocytes in
loqsf00791 ovarioles have normal dorsal appendages, indicating that dorsoventral patterning is normal. In contrast, mutations in
armi, spnE, and
aub disrupt both dorsoventral and anteroposterior patterning [
42–44]. These mutations all disrupt RNAi and
Ste silencing, but display no global defects in miRNA biogenesis or function, unlike
loqs [
24,
41,
45,
46].
Oogenesis is initiated in the germarium, which contains the germ-line stem cells as well as the early germ-line cysts that will form egg chambers. In
loqsf00791 mutant ovarioles, the germaria generally contain a limited number of cells that stain for Vasa, indicating that they are of germ-line origin (B). No mitotic figures were observed, nor were separate cysts. Germ-line stem cells and their daughter cells, the cystoblasts, are characterized by the presence of a spherical structure, the spectrosome, that stains intensely with anti-Spectrin antibodies [
47–
49]. We stained wild-type and
loqsf00791 germaria with anti-α-Spectrin antibodies (C and
S2). We could not detect spectrosomes in the
loqs mutant germaria, suggesting that in these germaria, dissected from flies 3–4 d old, no stem cells remained. Stem cells must have originally been present, because
loqs mutant ovaries produce some late-stage oocytes. Thus, most of the original stem cells may have died or differentiated into cystoblasts without renewing the stem cell pool. At present, we cannot distinguish between these alternatives. We conclude that
loqsf00791 mutants, which are defective in three distinct types of RNA silencing, fail to maintain germ-line stem cells.
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