Subcellular localization and Egl-mediated transport of telomeric retrotransposon HeT-A ribonucleoprotein particles in the Drosophila germline and early embryogenesis

The study of the telomeric complex in oogenesis and early development is important for understanding the mechanisms which maintain genome integrity. Telomeric transcripts are the key components of the telomeric complex and are essential for regulation of telomere function. We study the biogenesis of transcripts generated by the major Drosophila telomere repeat HeT-A in oogenesis and early development with disrupted telomeric repeat silencing. In wild type ovaries, HeT-A expression is downregulated by the Piwi-interacting RNAs (piRNAs). By repressing piRNA pathway, we show that overexpressed HeT-A transcripts interact with their product, RNA-binding protein Gag-HeT-A, forming ribonucleoprotein particles (RNPs) during oogenesis and early embryonic development. Moreover, during early stages of oogenesis, in the nuclei of dividing cystoblasts, HeT-A RNP form spherical structures, which supposedly represent the retrotransposition complexes participating in telomere elongation. During the later stages of oogenesis, abundant HeT-A RNP are detected in the cytoplasm and nuclei of the nurse cells, as well as in the cytoplasm of the oocyte. Further on, we demonstrate that HeT-A products co-localize with the transporter protein Egalitarian (Egl) both in wild type ovaries and upon piRNA loss. This finding suggests a role of Egl in the transportation of the HeT-A RNP to the oocyte using a dynein motor. Following germline piRNA depletion, abundant maternal HeT-A RNP interacts with Egl resulting in ectopic accumulation of Egl close to the centrosomes during the syncytial stage of embryogenesis. Given the essential role of Egl in the proper localization of numerous patterning mRNAs, we suggest that its abnormal localization likely leads to impaired embryonic axis specification typical for piRNA pathway mutants.


Introduction
Telomeres are DNA-protein complexes that protect the ends of linear eukaryotic chromosomes. In most species telomeric repeats are synthesized by telomerase consisting of reverse transcriptase and an RNA template. Telomere-associated proteins form the telomere protection shelterin complex [1]. Recently it was found that telomeric repeats are transcribed and give rise to long non-coding RNAs, TERRA [2]. TERRA molecules interact with shelterin proteins, telomerase, chromatin remodeling factors and localize near telomeres suggesting a structural role in telomere architecture [3]. However, TERRA may also bind and regulate different genic targets indicating its role as an epigenetic factor in gene expression [4]. Moreover, the large network of TERRA interacting proteins suggests that TERRA plays a significant role not only in telomere regulation but also in various cellular pathways [4,5]. However, the functional significance of most interactions between TERRA and its partners remains poorly understood.
Using Drosophila we conducted a systematic study of the biogenesis and function of telomeric transcripts and their associated proteins in the female germline and in early development. Telomerase was not found in the Drosophila genome [6]. A unique feature of Drosophila telomeres is that they are composed of LINE (long interspersed nuclear element) retrotransposons; namely, HeT-A, TART and TAHRE, among which HeT-A is the most abundant [7]. Despite the different nature of telomeric repeats between Drosophila and species encoding telomerase, the basic mechanisms of telomere maintenance are similar [8]. Drosophila telomeric protein complex is structurally different from human shelterin, but is functionally analogous and protects the chromosome ends from degradation and fusion [9,10]. Transcription of telomeric repeats is a conserved feature described in all studied species. Telomeric transcripts in Drosophila were described a decade earlier than human TERRA [11,12]. The Drosophila telomeric transcriptome in the germline consists of both long retrotransposon transcripts and small RNAs [13,14]. HeT-A and TART produce multiple sense and antisense transcripts, the latter containing multiple introns [14][15][16]. Unusual regulatory regions of HeT-A and TART retrotransposons drive the bidirectional transcription [16,17]. HeT-A sense transcripts may be considered as functional analogues of both the telomerase RNA template and TERRA RNA. Clearly, the expression of telomeric elements must be strictly controlled to ensure regulation of telomere length. In Drosophila ovaries, such control is mediated by a distinct mechanism of RNA interference, the piRNA (PIWI interacting RNA) pathway. In the germline, antisense transcripts of telomeric retrotransposons serve as piRNA precursors, regulating the abundance of sense coding transcripts [13,14]. In the presence of piRNAs, the expression of telomeric repeats is repressed, while mutations in piRNA pathway genes lead to a drastic accumulation of telomeric transcripts and an increased rate of heritable terminal retrotranspositions [13]. piRNA pathway disruption strongly affects telomeric chromatin state and HeT-A expression in the germline leading to severe developmental defects [18][19][20][21].
Telomeres have certain features of heterochromatin, therefore, their transcriptional activity in a normal cell is repressed. Increased level of telomere transcription in response to telomere damage may be a part of telomere signaling affecting various cellular processes [22]. An important question in Drosophila telomere biology is whether the level of HeT-A RNA could play a role in cellular response to the state of telomeres. To address this question, it is critical to examine the HeT-A RNA and HeT-A Gag biogenesis in normal development and with telomere dysfunctions.
Previously, we have shown that the mechanisms of chromosome end protection are closely related to the silencing of telomeric repeats: upon depletion of the piRNA pathway components and other factors suppressing HeT-A expression, abundant long telomeric RNAs accumulate in the germline, then transported to the oocyte and form aggregates at the mitotic spindles during the syncytial stage of embryogenesis [20]. This phenotype is accompanied by severe mitotic defects, chromosome missegregation and leads to early embryonic lethality [20,21]. However, the functional link between accumulation of telomeric transcripts upon telomere dysfunction and developmental defects remained unclear. To advance the understanding of the interplay between dysfunctional telomeres and various cellular pathways, we explored the localization and functional interactions of abundant HeT-A RNA and Gag protein in the germline and early development upon piRNA pathway disruption.
RNA-binding proteins are involved in RNA metabolism at different stages of its life cycle, from transcription to degradation. Transcripts and proteins encoded by HeT-A and TART were detected at different stages of germline development in wild type Drosophila strains as well as upon depletion of telomere silencing components [20,23,24]. Despite being crucial for telomere targeting and lengthening, the biogenesis of Drosophila telomeric RNP in the germline and in early development is still poorly understood since most studies are focused on either HeT-A and TART RNA or their protein products separately.
Due to robust piRNA-mediated silencing in the germline, telomeric retrotransposon products are present at very low levels in wild type ovaries. Even in the Gaiano strain which is characterized by increased HeT-A and TART copy numbers [25], HeT-A Gag protein is barely detected in germ cells [23], which can be explained by enhanced production of HeT-A piRNAs in Gaiano ovaries [26]. Valuable data on Drosophila telomeric RNP were recently obtained from studies of somatic tissues. HeT-A spherical particles consisting of HeT-A Gag and HeT-A RNA were discovered in proliferating neuroblasts where they associate with telomeres undergoing DNA replication and are considered a prerequisite for somatic HeT-A transposition [27].
Here, we show that upon piRNA loss overexpressed HeT-A transcripts interact with the RNA-binding protein Gag-HeT-A, which they encode, and that they form RNP particles during most of their life cycle in oogenesis and early embryogenesis. In germarium, HeT-A RNP form spherical structures in the nuclei of dividing cystoblasts and seem to be the intermediates of telomere elongation in the germline. It has been shown that interaction of HeT-A RNPs with the main carrier protein Egalitarian (Egl) [28] is required for their transport into the oocyte. Here, we describe for the first time the life cycle of maternal HeT-A RNP in early development. Retention of Egl at HeT-A RNP causes its ectopic localization at syncytial stage of embryogenesis which likely impairs embryonic development in the piRNA pathway mutants.

RNA FISH and immunostaining
RNA FISH combined with immunostaining was carried out according to the previously described procedure [20] with modifications. After fixation, ovaries or dechorionized embryos were incubated in PBS containing 50 ug/ml proteinase K for 6 or 2 min, respectively. Proteinase K treatment was omitted in case of further staining for cytoplasmic proteins in the ovaries. Digoxigenin (DIG)-labeled antisense HeT-A riboprobe containing a fragment of the ORF (nucleotides 4330-4690 of GenBank sequence DMU06920) was used. The specificity of this probe was previously confirmed by Northern blotting and in situ hybridization with polytene chromosomes of salivary glands [19,26]. To amplify hybridization signal, we incubated the sample with anti-DIG-fluorescein (FITC) antibodies (Roche), followed by incubation with anti-FITC Alexa Fluor 488 antibodies (Life Technologies). Blocking solution was supplemented with 3% BSA before immunostaining. Samples were mounted in Vectashield Antifade Mounting Medium with DAPI (Vector Laboratories). Images were captured using Zeiss LSM 510 Meta or Olympus FV10i confocal microscopes and analyzed using ImageJ and Adobe Photoshop.

HeT-A RNA and HeT-A Gag are co-localized in ovaries and form HeT-A RNPs at different stages of oogenesis
RNA biogenesis is orchestrated by RNA-binding proteins that determine the localization, lifetime and the specificity of transcript interactions. Therefore, in order to understand the role of telomeric coding RNAs, it is first necessary to identify their protein partners. Direct recognition of the retrotransposon transcript by the protein it encodes was discovered for human retrotransposon LINE-1 (L1) and is referred to as cis-preference [32,33]. We suggested that the Drosophila telomeric protein Gag, encoded by HeT-A, interacts with HeT-A RNA forming RNP in the germline. Recombinant engineering of epitope tags and inducible tissue-specific expression of transgene containing full-length HeT-A have made detection and purification of HeT-A Gag complexes routine [29]. Due to the activity of the piRNA pathway and other telomere silencing mechanisms, expression of HeT-A is strongly repressed in the germline [13,20]. Indeed, HeT-A Gag is not detectable by Western blotting in the ovaries of GIII and transgenic strains expressing HeT-A-HA in contrast to somatic tissues (S1 Fig). However, upon piRNA loss, caused by depletion of the RNA helicase Spindle-E (SpnE) [34], abundant HeT-A Gag accumulates in the ovaries (Part A in S1 Fig). To get an insight into the biogenesis and pathological significance of abundant telomeric RNAs and proteins generated upon telomere dysfunction, we characterized their localization during oogenesis and first hours of development after germline knockdown (GLKD) of spnE.
To determine whether HeT-A Gag associates with HeT-A RNA, a RIP experiment followed by RT-qPCR of co-precipitated RNA was performed. Ovarian lysates expressing HeT-A Gag-HA upon spnE_GLKD were immunoprecipitated with a/HA antibodies. Ovaries of spnE_GLKD lacking the UAS-HeT-A-HA transgene were used as controls ( Fig 1A). HeT-A transcripts are significantly enriched in the HeT-A Gag-HA precipitate ( Fig 1A). Interestingly, endogenous TART RNA was also present in this complex suggesting that HeT-A RNPs are multicomponent complexes.
Next, we analyzed the co-localization of HeT-A RNA and Gag protein at different stages of oogenesis upon spnE_GLKD using RNA fluorescence in situ hybridization (FISH) combined with immunostaining. In the germarium region 2A, HeT-A transcripts co-localize with Gagpositive particles forming spherical RNPs of 1-2 microns in size (Fig 1B) resembling those discovered in brain cells [27]. Numerous HeT-A spheres observed in the nuclei of dividing cystoblasts are presumably intermediates of the telomere elongation complex, in agreement with the high rate of telomeric attachments in spnE mutants [13]. We failed to detect spherical HeT-A RNPs in the female germ cells of GIII strain (Parts B and C in S1 Fig). Taking into  (Fig 1C), however, only some of them co-localize with telomeres stained for telomere-specific proteins HOAP or HipHop [36,37] (Fig 1D and  In the nurse cell cytoplasm, some of the HeT-A RNP foci form large aggregates of irregular shape differed from nuclear spherical particles ( Fig 1E). HeT-A Gag-HA staining was also revealed in the perinuclear ribonucleoprotein structure-the nuage. However, immunostaining of HeT-A Gag and a nuage component Vasa shows only partial colocalization of these proteins (Part A in S3 Fig). HeT-A Gag staining is more diffuse and found not only around the nucleus but also in the nucleus close to the envelope. Most likely, nuclear import of abundant HeT-A Gag is accompanied by its sequestration in the nuage.
In accordance with RIP, TART sense transcripts co-localize with aggregates of HeT-A RNP in the nurse cell cytoplasm (Fig 1F). In nurse cell nuclei, TART transcripts are revealed nearby telomeres but not in the HeT-A spheres ( Fig 1G).
All these data taken together suggest that HeT-A RNA and HeT-A Gag form RNPs of different structures at different stages of oogenesis upon loss of piRNA silencing.
In order to demonstrate direct interaction between the HeT-A Gag protein and its RNA template (cis-preference rule) we took advantage of another transgenic strain containing a HeT-A copy, tagged by the MS2 bacteriophage hairpins, and encoding for Gag-HA. Combined MS2 RNA FISH and HA-immunostaining shows colocalization of transgenic RNA and protein in the nuclei and cytoplasm of germ cells (Fig 2). Distribution patterns of transgenic HeT-A RNPs are similar to that of endogenous HeT-As. However, due to the lower sensitivity of the MS2 probe, we used HeT-A ORF probe in further experiments. To rule out artifacts due to nonspecific MS2 RNA probe hybridization we performed control experiment. The MS2 probe does not recognize nontagged HeT-A-HA RNA in transgenic ovaries expressing HeT-A Gag-HA upon spnE_GLKD (Fig 2C).
We conclude that HeT-A RNA and Gag form RNP according to the cis-preference rule.

HeT-A RNPs interact with Egl in ovaries and form granules in the cytoplasm of nurse cells and oocyte
Upon piRNA pathway disruption, HeT-A products accumulate in the oocyte from the early stages of oogenesis, suggesting that some mechanism provides their relocation from the nurse cells to oocyte [13,24] (Part A in S2 Fig). Egl, a protein that interacts with the dynein motor complex, is a major carrier which provides the transportation and localization of maternal RNAs at different stages of oogenesis [28,31,38]. Egl is essential for oocyte determination since in Egl mutants all 16 germ cells of the egg chamber become nurse cells [39,40]. We therefore suggested that Egl might be involved in HeT-A RNA localization. In ovaries with double piwi, egl GLKD, HeT-A specific localization is not observed (Fig 3A). Both HeT-A RNA and dynein accumulated in the cytoplasm of nurse cells. HeT-A delocalization is likely caused by the severe disorganization of microtubules caused by Egl depletion [39,40]. Based on this observation, we focused on examining the role of Egl in HeT-A RNP transport.
To determine whether Egl directly associates with HeT-A RNAs, we performed RIP followed by RT-qPCR. RIP was performed on ovaries with a HeT-A overexpression or wild type background. Lysates of spnE GLKD ovaries expressing HeT-A Gag-HA were immunoprecipitated with a/Egl or normal rabbit serum. Alternatively, Egl-GFP was immunoprecipitated using rabbit a/GFP or normal rabbit IgG from ovary lysate of Egl-GFP strain at a wild type background. As expected, nanos (nos), oskar (osk) and gurken (grk) mRNAs are associated with Egl-BicD complex in wild type ovaries (S4 Fig) [38]. It is worth noting, that association of nos, osk and grk transcripts with Egl is not affected by spnE_GLKD (S4 Fig). However, HeT-A RNA enrichment was insignificant in both cases, and HeT-A Gag is undetectable in Egl-BicD complex (S4 Fig). Of note, the majority of HeT-A Gag is present in an insoluble pellet after tissue lysis indicating its strong tendency to aggregate.
We suggested that if Egl does not associate directly with HeT-A RNA, it probably interacts with HeT-A Gag, and that this interaction is sensitive to the stringent purification conditions used in RIP (see Materials and methods). Co-IP experiments on spnE_GLKD ovaries using an  We proposed that in the wild type ovaries, HeT-A RNP also interact with Egl and therefore performed Egl and HeT-A Gag immunostaining combined with HeT-A RNA FISH on ovaries of the GIII strain, which is characterized by an increased HeT-A copy number [25]. Egl was previously shown to be localized at the posterior pole of oocytes at stages 9-10 of oogenesis [31,38]. Despite the low level of HeT-A Gag in GIII ovaries, we detected its enrichment at the posterior pole and co-localization with Egl ( Fig 3D). This result confirms Egl association with endogenous HeT-A Gag in wild type ovaries.
Taken together, our data indicate that Egl carrier function is required for translocation and localization of HeT-A RNP in the oocyte upon HeT-A overexpression caused by piRNA loss. The experiment using the GIII strain indicates that probably the same mechanism operates in a wild type background.

Association of abundant HeT-A RNP with Egl causes ectopic accumulation of Egl near to centrosomes in early embryos upon piRNA loss
Previously, we reported, that maternal HeT-A transcripts and transgenic HeT-A Gag-HA form aggregates around centrosomes during blastoderm formation in spnE_GLKD background [20,29]. Specific localization of HeT-A RNA is dependent on microtubules since disruption of microtubules caused delocalization of HeT-A transcripts [29]. Similarly, endogenous HeT-A RNA and HeT-A Gag form granules and accumulate around centrosomes in 0-2-hour old embryos collected from spnE_GLKD females (Fig 4A and 4B). At this stage, HeT-A transcripts do not co-localize with the telomeres of mitotic chromosomes suggesting a non-telomeric role for HeT-A RNA.
First, we addressed a question whether HeT-A RNA and HeT-A Gag form RNP in early embryos. A RIP experiment was performed on lysates of 0-2-hour old embryos of a transgenic strain expressing UAS-HeT-A-HA in the germline upon spnE_GLKD. As a control, embryo lysates from non-transgenic spnE_GLKD flies were used (Fig 4C). HeT-A transcripts are significantly enriched in HeT-A Gag-HA precipitate from 0-2-hour embryos. Similar to RIP data on ovaries, TART RNA is also present in HeT-A RNPs of early embryos.
Next, we asked if Egl associates with HeT-A Gag during early embryogenesis. Co-IP using the lysate of 0-2-hour old embryos from spnE_GLKD flies expressing HeT-A Gag-HA shows that Egl co-purifies with transgenic HeT-A Gag-HA (Fig 5A). Immunostaining reveals co-localization of endogenous HeT-A Gag and Egl near the spindle poles in 0-2-hour old embryos upon spnE_GLKD while in wild type, Egl is evenly distributed in the syncytial embryo interior (Fig 5B and 5C). These data suggest that interaction with HeT-A Gag may cause Egl retention and its ectopic localization in early embryos with spnE_GLKD background.
It is known that mRNA stem-loop elements are important for recognition by protein carriers [41][42][43]. We suggested that the hairpin structure detected in the HeT-A 3'UTR (untranslated region) is presumably involved in the HeT-A RNA localization, and therefore, generated transgenic strain, encoding HeT-A transcripts with impaired hairpin structure (S6 Fig). The mutated HeT-A construct contains sequences of bacteriophage MS2 hairpins which allowed us to specifically detect transgenic transcripts using an MS2 probe. Transgenic strains containing HeTA-HA-mut_ms2 construct were used to decipher the role of the identified structural motif in the transport and localization of HeT-A mRNA. In spnE GLKD ovaries, HeT-A-HA-mut_ms2 transcripts colocalize with HeT-A Gag-HA and Egl and accumulate in the oocyte just like endogenous HeT-A RNA (Part C in S6 Fig). In early embryos, HeT-A-HA-mut_m s2 RNAs localize near to the centrosomes stained with gamma-tubulin (Part D in S6 Fig). Similar to endogenous HeT-A Gag, Gag-HA encoded by HeT-A-HA-mut_ms2 transgenic RNA co-localizes with Egl close to spindle poles (Part E in S6 Fig.). These data show that this particular hairpin structure is dispensable for Eglmediated transportation and localization of HeT-A RNA in ovaries and embryos.

Discussion
In this study, we describe the life cycle of maternal telomeric RNPs in Drosophila. To study the localization of telomeric RNA in oogenesis and early development, we focused on the major telomere repeat HeT-A which is overexpressed upon piRNA pathway disruption. It was shown that in the ovaries and embryos HeT-A transcripts interact with the RNA-binding protein Gag-HeT-A that they encode forming RNP complexes. Using tagged transgenic HeT-A, we confirmed that this interaction occurs according to the cis-preference rule discovered previously for the human L1 retrotransposon [32,33].
HeT-A RNPs form structures with different characteristics during oogenesis upon piRNA loss. In the early stages of oogenesis, during cystoblast cell divisions, nuclear HeT-A RNPs form spherical particles which are seemingly participate in telomere elongation. HeT-A spheres were revealed in germarium germ cells with spnE depletion, but not in wild type ovaries. This fact is in agreement with extremely low levels of HeT-A expression and therefore, low transposition rate to chromosome termini in wild type flies [13,35]. Accumulation of HeT-A spheres in cystoblast nuclei is in accordance with the observation that identical telomeric attachments to the terminally truncated chromosomes have been identified in several descendants from the same female bearing a heterozygous spnE mutation, suggesting that terminal elongation occurs at premeiotic stages of oogenesis [13]. The germarium region where we have seen HeT-A spheres, and where expression of HeT-A-lacZ transgene was previously detected [19], corresponds to the so-called "Piwi-less pocket", a small developmental window when transposons escape host control and can transpose [44]. Interestingly, telomeres appear to be elongated at the same stage suggesting that telomere length control and transposon regulation are coupled.
During later stages of oogenesis in spnE deficient ovaries, numerous spherical HeT-A RNPs are also detected in the nuclei of terminally differentiated nurse cells, with only a few of them associated with telomeres. We speculate that HeT-A RNPs could act here independently of telomere elongation and be involved in dysfunctional telomere signaling. Indeed, mammalian telomeric factors are able to localize outside telomeres, where they can regulate the transcription of various genes [22].
In the cytoplasm of nurse cells, HeT-A products form irregularly shaped aggregates which appear to be the transportation cargoes. Thus, only a portion of HeT-A RNPs generated in the nurse cells are translocated into nucleus while others are transported into the oocyte. It is noteworthy, that compositionally and functionally distinct L1 RNPs were also revealed in human cells [45]. Taking into account the strong tendency of HeT-A Gag to aggregate, one may suggest that formation of regular spherical particles revealed in the nuclei is compartment-specific and requires additional factors.
HeT-A Gag co-IP in combination with RNA FISH and immunostaining suggests that the Egl-dynein carrier complex provides migration of cytoplasmic HeT-A RNPs in the germline. In piRNA pathway mutant, cytoplasmic aggregates consisting of dynein, Egl and BicD proteins, as well as transcripts of bicoid, grk and retrotransposon I-element were detected in both nurse cells and the oocyte [46]. We also show that cytoplasmic HeT-A RNPs co-localize with Egl. Seemingly, HeT-A RNPs can catalyze the aggregation of their interactors. If this is the case, interaction between Egl-BicD complex and HeT-A RNP particles can promote the formation of Egl-positive granules upon HeT-A overexpression caused by the piRNA loss.
Telomere targeting is an essential but not the only function of HeT-A RNPs. Maternal telomeric RNPs transported to the oocyte have a specific destination during early development.
HeT-A RNPs accumulate near to the centrosomes in 0-2-hour old syncytial embryos suggesting some interplay between telomeric and mitotic machinery. Indeed, HeT-A overexpression in the germline is followed by the severe mitotic defects during early development that leads to the embryonic lethality [20]. Physical interaction between HeT-A RNPs and transportation pathway components may be in part responsible for the developmental defects that accompany HeT-A overexpression. Indeed, Egl and BicD associate with dynein motors and mediate transport of RNAs essential for the initial oocyte specification and subsequent embryonic patterning [31,38,39,41]. Egl retention at centrosomes in complex with HeT-A RNP may lead to mis-localization of its typical cargoes, nos and osk mRNAs, observed in early embryos upon piRNA pathway disruption [47,48]. Indeed, we show that upon spnE_GLKD nos, osk and grk transcripts are still loaded into Egl-BicD complex. However, Egl aggregation and its ectopic localization caused by interaction with abundant HeT-A Gag could affect the localization pattern of developmental mRNAs leading to embryonic axis defects observed upon piRNA loss [47,49,50]. We speculate that the abundant telomeric RNPs generated upon telomere dysfunction could cause developmental arrest of such embryos, thus protecting genome integrity.
The exact nature of the signal responsible for HeT-A RNP enrichment in the oocyte remains elusive. The stem-loop structure in the 3' UTR of maternal mRNAs mediates transport of these RNAs from the nurse cells into the oocyte and their specific localization in early embryos [28]. Egl despite lacking a canonical RNA-binding domain is an RNA-binding protein capable of direct recognition of RNA localization signals within transcripts of grk, hairy, K10, and the I-element retrotransposon [28]. However, our data show weak if any HeT-A RNA binding to Egl. In addition, mutation of a hairpin in the 3'UTR of HeT-A, that is similar to Egl-bound hairpins of certain mRNAs, did not affect HeT-A localization. The interaction of HeT-A Gag with Egl-BicD-microtubule transport components was instead revealed which supports the idea that protein-protein interactions are essential for HeT-A RNP transportation by the Egl-BicD complex.
Further dissection of the biochemical composition of HeT-A RNPs during oogenesis and early development will increase understanding of the telomeric retrotransposition mechanism as well as non-telomeric functions of HeT-A products. Other telomeric retroelements represented by a few copies per genome, TART and TAHRE, encode reverse transcriptases which are likely critical for HeT-A retrotranspositions. It is known that transiently expressed HeT-A and TART Gag proteins are able to form telomere-associated structures in cultured cells; TART Gag moves to telomeres only when co-expressed with HeT-A Gag [51]. Moreover, colocalization of HeT-A Gag and TART Pol proteins was observed by immunostaining in neuroblast nuclei [23]. According to our data, TART transcripts along with HeT-A RNA are bound to HeT-A Gag supporting the idea that HeT-A RNP is a core of the multicomponent telomeric RNP complex. The role of proteins encoded by TART and TAHRE in telomere targeting and retrotransposition remains to be determined.

Conclusions
We show that upon piRNA depletion transcripts of telomeric retrotransposon HeT-A interact with the HeT-A Gag protein, that they encode, according to the cis-preference rule, to form RNP particles during oogenesis and early embryogenesis. Our data suggest that HeT-A RNPs are multicomponent complexes which are present both in the nuclei and cytoplasm of germ cells, and in preblastoderm embryos. Spherical HeT-A RNPs found in the germ cells of germarium supposedly perform telomere elongation. Cytoplasmic HeT-A aggregates interact with carrier protein Egl which mediates the transportation of the HeT-A RNPs to the oocyte.
HeT-A Gag-Egl complex is detected in early embryos near to centrosomes after HeT-A overexpression caused by piRNA pathway disruption. Interaction between HeT-A RNP and Egl carrier protein which is essential for embryonic axis specification likely impairs embryonic development in piRNA pathway mutants. RT-qPCR analysis of RNA precipitated with anti-Egl relative to negative control (normal rabbit IgG) from ovary lysates of nosGal4; UAS-HeT-A-HA; UAS-spnE_sh flies. rp49 was used for normalization. Western blot analysis of co-immunoprecipitated proteins is shown to the right. The antibodies used for Western blotting are indicated to the right. The antibodies used for co-IP are indicated above the IP lanes. Lane designation: input (total lysate), pellet (insoluble fraction), IP (precipitates). Anti-Egl immunoprecipitates both Egl and BicD proteins but not HeT-A Gag which is enriched in insoluble fraction. (B) RT-qPCR analysis of RNA precipitated with anti-GFP relative to negative control (normal rabbit IgG) from ovary lysates of w; tub-Egl-GFP flies. Western blot analysis of co-immunoprecipitated proteins is shown to the right; the indications are as in (A). Anti-GFP immunoprecipitates both Egl-GFP and Egl as well as BicD indicating that Egl-BicD is an oligomeric complex. For RIP panels, the error bars represent SEM of 2 biological replicas.