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. 2017 Jan-Mar;40(1):22–30. doi: 10.1590/1678-4685-GMB-2016-0258

RNA-binding proteins and their role in the regulation of gene expression in Trypanosoma cruzi and Saccharomyces cerevisiae

Camila Oliveira 1, Helisson Faoro 1, Lysangela Ronalte Alves 1, Samuel Goldenberg 1
PMCID: PMC5409782  PMID: 28463381

Abstract

RNA-binding proteins (RBPs) have important functions in the regulation of gene expression. RBPs play key roles in post-transcriptional processes in all eukaryotes, such as splicing regulation, mRNA transport and modulation of mRNA translation and decay. RBPs assemble into different mRNA-protein complexes, which form messenger ribonucleoprotein complexes (mRNPs). Gene expression regulation in trypanosomatids occurs mainly at the post-transcriptional level and RBPs play a key role in all processes. However, the functional characterization of RBPs in Trypanosoma cruzi has been impaired due to the lack of reliable reverse genetic manipulation tools. The comparison of RBPs from Saccharomyces cerevisiae and T. cruzi might allow inferring on the function of these proteins based on the information available for the orthologous RNA-binding proteins from the S. cerevisiae model organism. In this review, we discuss the role of some RBPs from T. cruzi and their homologues in regulating gene expression in yeast.

Keywords: RNA-binding proteins, Trypanosoma cruzi, Saccharomyces cerevisiae, gene expression regulation

Introduction

Gene expression involves several events that occur at the transcriptional and post-transcriptional levels. The transcriptional control of gene expression has been extensively influenced by early work on bacterial transcription. However, in recent years, post-transcriptional events have gained much more attention. The pre-RNA undergoes extensive processing before the mRNA reaches its final destination and RNA-binding proteins (RBPs) associated to the RNA during its life-time play a key role in determining its fate in the cell. (Kishore et al., 2010). The association of proteins with mRNAs is very dynamic and prone to changes according to the environment. Consequently RBPs are involved in the stabilization or destabilization of mRNAs in response to stress or extracellular signals (Alves and Goldenberg, 2016).

The availability of high-throughput analysis techniques, such as proteomics, has enabled the characterization of several RBPs. Nevertheless, the RBP network assembly and the mechanism of the RNA regulon are still poorly explored, and further work is required to determine the identity of all of the proteins and their respective roles in post-transcriptional events (Lunde et al., 2007).

RBPs have one or multiple RNA-binding protein domains. The following are the best characterized RNA-binding domains: RNA Recognition Motif (RRM), K-homology domain (KH), RGG (Arg-Gly-Gly) box, zinc finger, double stranded RNA-binding domain (dsRBD), Pumilio/PUF domain and Piwi/Argonaute/Zwille (PAZ) domain (Finn et al., 2010).

The RRM is the most abundant domain and also the most studied in RBPs (Afroz et al., 2015). The information obtained from genome sequencing studies shows that RRM-containing proteins are present in all forms of life (Mari et al., 2005). RRMs typically comprise approximately 90 amino acids and consist of four antiparallel β-strands (eventually they can have one or two short additional strands), which form a β-sheet that is packed against two α-helices, adopting the typical β1α1β2β3α2β4 conformation. The β3 and β1 strands of the RRM contain the RNP1 and RNP2 signature sequences, respectively (Cléry and Allain, 2012). Additionally, two or more RRMs can be combined in the same molecule to recognize longer stretches of RNA, with increased sequence affinity and specificity (Cléry and Allain, 2012).

The hnRNP K-homology (KH) domain comprises three α-helices around the surface of a central antiparallel β-sheet. Eukaryotic type I and prokaryotic type II KH domains share a minimal βααβ core, with two additional α and β elements positioned either in C-terminal (type I, eukaryotes) or N-terminal (type II, prokaryotes) orientation to this core motif (Grishin, 2001). This structure directs four nucleic acid bases towards a groove inside the protein structure where hydrophobic interactions and a network of main chain and side chain hydrogen bonds mediate nucleobase recognition. So far, protein domains with a classical KH fold but lacking a conserved GxxG motif have shown no nucleic acid-binding activity, although they interact with other nucleic acid binding domains and can modulate their RNA binding activity (Valverde et al., 2008).

The RGG motif is an evolutionarily conserved sequence. In addition to the arginine and glycine repeats, aromatic residues are frequently observed in-between these sequences, and these residues may contribute to hydrophobic stacking within RNA bases. RGG/RG motives include RGG and RG repeats of varied lengths interspersed with spacers of different amino acids (Corley and Gready, 2008), and predicting the spacing that defines a functional RGG/RG motive is difficult. The structure of the RGG/RG has not been clearly defined due to its low sequence complexity.

Classical C2H2 ‘zinc finger’ proteins were identified as modular nucleic acid recognition elements, with two cysteine and two histidine residues that coordinate a zinc ion. Although mostly noted for their role as DNA-binding transcription factors, C2H2 zinc fingers were identified in the transcription factor IIIA (TFIIIA) (Vincent, 1986). TFIIIA contains nine C2H2 zinc fingers, which are used to recognize RNA and DNA targets. The zinc finger folds into a small domain comprising two β strands followed by one α helix. More recently, the C2H2 class of zinc finger protein has been shown to bind preferentially to RNA targets. These zinc fingers are characterized by three cysteine residues and one histidine residue that coordinate the zinc ion and form the Cys-X7-8-Cys-X5-Cys-X3-His sequence (Hall, 2005).

The dsRBD is a conserved protein domain of approximately 65–70 amino acids which binds to double-stranded or highly structured RNAs (Finn et al., 2010). The dsRBD was first recognized as a conserved protein domain based on the similarities between Drosophila Staufen, human TAR-RNA binding protein (TRBP) and Xenopus laevis RNA-binding protein A (XlrbpA). The central function of dsRBDs is to bind to dsRNA regions, which is primarily achieved by recognizing specific RNA shapes. In addition to this major function, dsRBDs with protein-protein interaction properties have been reported to participate in the regulation of protein subcellular localization, suggesting that the participation of dsRBDs in nucleocytoplasmic trafficking is likely to represent a widespread auxiliary function of this type of RNA-binding domain (Banerjee and Barraud, 2014).

Pumilio is a family of sequence-specific RNA-binding proteins that regulate translation of the mRNA targets and also appear to interact with mRNA regulatory systems (Edwards, 2015). RNA recognition by Pumilio occurs through the PUF domain, named after its members Pumilio and FBF. Full-length Pumilio is a relatively large protein (156 kDa in Drosophila); however, only a fraction of the Pumilio protein (a 37 kDa fragment close to the protein C-terminus) is required for RNA binding, translational repression, and recruitment of other proteins. The PUF domain contains multiple tandem repeats of 35–39 amino acids which recognize specific RNA bases (Abbasi et al., 2011).

The PAZ domain is found in Dicer and Argonaute proteins, two protein families with key roles in RNAi mechanisms. The PAZ domain consists of two subdomains, one of which displays OB-like folding (oligonucleotide/oligosaccharide binding). Hence, the PAZ motif might bind to single-stranded nucleic acids (Yan et al., 2003). Crystallographic studies combined with biochemical approaches showed that the PAZ domain binds to ssRNAs with low affinity in a sequence-independent manner. A remarkable feature of the PAZ domain is that it can recognize the 3’-ends of ssRNAs. Both miRNAs and distinct types of small interfering RNAs (siRNA) are processed by the sequential action of RNase III enzymes (Drosha and Dicer in mammals, or Dicer alone in yeast and plants), which characteristically leave two 3’-overhangs on the processed products (Hutvagner and Simard, 2008).

RNA-binding proteins in Trypanosomatids

The regulation of gene expression in trypanosomatids occurs mainly by post-transcriptional mechanisms. These protozoans present several peculiarities, such as a less condensed chromatin structure, polycistronic transcription, a trans-splicing mechanism, and the absence of canonical RNA polymerase II promoters. Genome analysis of the TriTryp database (containing genome sequences of the pathogenic T. cruzi, Leishmania major and Trypanosoma brucei) shows several RNA-binding proteins. Nonetheless, a comprehensive characterization of RNA-protein interactions remains elusive (Clayton and Shapira, 2007).

In 2005, De Gaudenzi and co-workers described approximately 80 proteins with RRM domains in T. cruzi, but few were functionally characterized (Table 1) (De Gaudenzi et al., 2005). Another comprehensive study was conducted to characterize ribonucleoprotein complexes (mRNPs) in T. cruzi (Alves et al., 2010). In this study, several RBPs were identified by proteomics, using polysomal and polysome-free fractions of exponentially growing epimastigotes and epimastigotes under conditions of nutritional stress.

Table 1. RNA binding proteins characterized in Trypanosoma cruzi.

Protein Function Ref. Domain
SR62 mRNA processing/stability Názer et al. (2011) SR-related
ZC3H39 Regulator of a specific subset of mRNAs Alves et al., 2014 CCCH
UBP1 mRNA destabilizing factor D’Orso and Frasch (2002) RRM
UBP2 mRNA destabilizing factor D’Orso and Frasch (2002) RRM
PUF6 mRNA destabilizing factor Dallagiovanna et al. (2008) Pumilio
ZFP1 Involved in differentiation Mörking et al. (2004) CCCH
ZFP2 Involved in differentiation Mörking et al. (2004, 2012) CCCH
ZFP3 Involved in differentiation, translation regulator Mörking et al. (2004) CCCH
RBP40 Regulator of a specific subset of mRNAs Guerra-Slompo et al. (2012) RRM
RBP19 Involved in differentiation Pérez-Díaz et al. (2012, 2013) RRM
DRBD4/PTB2 Involved regulation of splicing De Gaudenzi et al., (2016) RRM
PABP1 Involved in translation Batista et al. (1994) RRM
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The life cycle of T. cruzi involves two hosts (triatomine insects and mammals) and comprises four morphological stages, two replicative (epimastigotes in the insects and amastigotes in the mammalian cells) and two infective forms (metacyclic trypomastigotes in the insects and bloodstream trypomastigotes in mammals). The epimastigotes differentiate in the midgut of the insect host and become metacyclic trypomastigotes, which are released in the excreta when the triatomine feeds on blood. The parasites penetrate the body of the mammalian host through the damaged skin or mucosa and invade different cell types. Within the cells, the parasites differentiate into amastigotes)De Souza, 2002).

RNAi in T. cruzi and yeast

The canonical RNAi machinery comprises three main components: Dicer, Argonaute, and RNA-dependent RNA polymerase. Argonaute proteins contain two conserved domains, the PAZ and Piwi domains. These proteins are components of the RNA-induced silencing complex (RISC) (Liu et al., 2004). Fungi, such as Ascomycetes, Basidiomycetyes, and Zygomycetes present the RNA silencing components in the genome, while few ascomycete and basidiomycete fungi apparently lost these components (Nakayashiki et al., 2006).

Saccharomyces cerevisiae, T.a cruzi, L. major and Plasmodium falciparum do not have the RNAi machinery, which seems to have been lost or excessively simplified. However, an ORF encoding for an AGO/PIWI protein expressed in all stages of the life cycle of T. cruzi was recently described (Garcia-Silva et al., 2010). The results showed that the TcPIWI-tryp is a canonical Argonaute in its domain architecture (Garcia-Silva et al., 2010). Moreover, it was shown that the most represented sRNAs interacting with TcPIWI-tryp derived from rRNAs, which corresponded to known miRNAs of higher eukaryotes, indicating a possible evolutionary pathway of known canonical sncRNAs from structural RNAs (Garcia-Silva et al., 2014).

RBPs with RRM domain in T. cruzi

Some RBPs play an important role during the differentiation of the parasite by regulating the expression of specific transcripts. TcUBP-1 recognizes the AU-rich instability element located in the 3’-untranslated region (UTR) of mucin SMUG mRNAs (D’Orso and Frasch, 2002). TcUBP-2 binds to poly(U)-RNA and is differentially expressed during parasite development. Both proteins interact in the same complex and are implicated in controlling T. cruzi SMUG mucin mRNA levels. In addition, they are located preferentially in the polysomal fraction (D’Orso and Frasch, 2002).

TcRBP40 binds to AG-rich regions in the 3’-UTR of target mRNAs. Microarray data indicate that this protein binds to mRNAs encoding various transmembrane proteins. The TcRBP40 protein location varies throughout the parasite's life cycle. In the epimastigote stage It is localized in reservosomes, which are trypanosomatid organelles associated to protein and lipid storage, and in amastigotes and trypomastigotes it is dispersed in the cytoplasm, suggesting a potential gene regulatory function (Guerra-Slompo et al., 2012).

TcRBP19 is differentially expressed during the life cycle of T. cruzi and is not detected only in the amastigote stage. Regulation of TcRBP19 is mediated by the 3’-UTR region, and the overexpression of TcRBP19 affects the T. cruzi life cycle and ability for infection (Pérez-Díaz et al., 2012, 2013). Recently, De Gaudenzi et al. (2016), showed that TcDRBD4/PTB2 is an essential multifunctional RBP, involved in regulation of splicing, preventing trans-splicing and decreasing both UBP1 and UBP2 proteins expression.

TcPABP1 was first characterized in 1994 by Batista et al. (1994), showing that this protein has been conserved throughout eukaryotic evolution. This Poly (A) binding protein has been more extensively described in T. brucei than in T. cruzi. PABP1 and PABP2 are localized in different sets of granules in response to inhibition of either translation or trans-splicing. PABP2 co-localized with the marker DHH1 into RNP granules, which are similar to P-bodies, and in nuclear periphery granules, whereas PABP1 is localized in heat shock induced stress granules (Kramer et al., 2013).

RBPs with PUF domains in T. cruzi

The PUF family of RNA-binding proteins regulates their target mRNAs by binding to their 3’-UTR. In T. cruzi, the TcPUF6 protein is involved in the degradation of specific mRNAs, especially those that are upregulated in the infective trypomastigote form (Dallagiovanna et al., 2008).

RBPs with the CCCH zinc finger domain in T. cruzi

The T. cruzi proteins TcZFP1 and TcZFP2 have been characterized and contain the C2H2 domain. TcZFP1 binds specifically to oligoribonucleotides containing cytosine-rich sequences. This type of repetitive sequence is present in untranslated regions of many mRNAs in trypanosomatids (Mörking et al., 2004). Ribonomic analysis showed that the targets of the protein TcZFP2 are associated with parasite-host interactions, for which expression is down-regulated in the replicative forms, indicating that TcZFP2 protein might act by destabilizing its targets (Mörking et al., 2012). The protein TcZC3H39 sequesters highly expressed mRNAs and their associated ribosomes, slowing translation under stress conditions. In addition, the transcript content is changed in normal and stressful conditions, and most of its targets code for cytochrome c oxidase enzymes (COX) and ribosomal proteins, presenting evidence for the RNA regulon theory (Alves et al., 2014).

Other RBP domains in T. cruzi

Some RBPs involved in mRNA metabolism can be relocalized to the nucleolus in T. cruzi as a specific stress response. TcSR62 is an RBP that belongs to the SR-related protein family, which is implicated in several functions related to mRNA metabolism. TcSR62 is involved in mRNA processing/stability, since its overexpression in T. brucei affects the mRNA trans-splicing process and leads to a decreased abundance of several mRNAs (Názer et al., 2011).

When mRNAs are not translated, they are compartmentalized into cytoplasmic structures named RNA granules. These RNA granules comprise the ‘processing bodies’ (‘P-bodies’) and the stress granules. Several RBPs have been implicated in the assembly and/or maintenance of these structures. TcDHH1, a putative DEAD-box RNA helicase, is involved in multiple RNA-related processes in various eukaryotes and accumulates in stress granules and P-bodies of yeast, animal cells and T. brucei (Kramer et al., 2010). In T. cruzi, DHH1 is present in heavy protein complexes, which are not associated with the polysome complexes, and is located diffusely in the cytoplasm under normal conditions. However, DHH1 forms cytoplasmic granules upon nutritional stress or treatment with drugs that dissociate the polysomes (Holetz et al., 2010).

RNA-binding proteins in yeast

The RNA-RBP complexes can be identified by RBP immunoaffinity purification (RIP), where the proteins are purified together with the bound RNAs, and the associated RNAs can then be identified. CLIP (cross-linking and immuno-precipitation) is a method that can directly determine the binding sites of RBPs onto mRNA. A substantial number of mRNA-binding proteins from yeast were identified from studies on the mechanisms of biogenesis, localization, translation and degradation of mRNAs (Mitchell et al., 2013).

RBPs with an RRM domain in S. cerevisiae

RBPs with RRM domains are well characterized in S. cerevisiae. This is the case of PABP1 (Poly-A binding protein), which contains four RRM domains (Figure 1), and is found in the cytoplasm, where it is associated with mRNA poly-A tails, stimulating translation initiation and regulating mRNA stability (Amrani et al., 1997).

Figure 1. Structural prediction of ScPab1 (A) and TcPabp1 (B) proteins (Phyre2 program).

Figure 1

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The second best studied protein in yeast is PUB1, which has three RRMs and can be located both in the nucleus and the cytoplasm, and is associated with poly(U) sequences (Anderson et al., 1993). PUB1 is involved in the stabilization of mRNAs containing ARE (“AU-rich elements”), and it is also involved in the process of nonsense-mediated mRNA decay (NMD) (Ruiz-Echevarría and Peltz, 2000).

The ScPRP24 protein also contains three RRM domains and is involved in the formation and organization of the spliceosome complex (Shannon and Guthrie, 1991). Moreover, the RRM domains 2 and 3 of ScPRP24 stabilize the U6 RNA and allow it to complete the U4/U6 RNA interaction, thereby influencing the association and dissociation of U4 and U6 RNAs with ScPRP24 (Vidaver et al., 1999).

RBPs with PUF domain in S. cerevisiae

Yeast possesses six PUF proteins (named PUF1–PUF6), and these proteins modulate mRNA stability through association with the 3’-UTR of their target mRNAs. For example, PUF1p activity involves recognition of UGUA sequences and surrounding sequences by PUF proteins. PUF also regulates several mitochondrial proteins, such as PMP1, PMP2, PMP3, and AST1. These mRNAs have been associated with PUF1p and/or PUF2p and encode membrane-associated proteins involved in proton transport (Ulbricht and Olivas, 2008). PUF3 promotes the deadenylation of Cox17 (Olivas and Parker, 2000), while PUF4 and PUF5 act on the deadenylation and decay of HO, a specific endonuclease that stimulates mating-type switching in budding yeast (Tadauchi et al., 2001). Interestingly, PUF6 (Figure 2) acts on the regulation of Ash1, which represses HO in cells to block mating-type switching (Gu et al., 2004).

Figure 2. Structural prediction of ScPuf6 (A) and TcPuf6 (B) proteins (Phyre2 program).

Figure 2

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RBPs with zinc finger CCCH domains in S. cerevisiae

CTH1 (Figure 3) and CTH2 were first described in yeast. Both proteins can play a role in mRNA activation or degradation of mRNA targets involved in iron homeostasis (Thompson et al., 1996).

Figure 3. Structural prediction of ScCth1 (A) and TcZC3h39 (B) proteins (Phyre2 program).

Figure 3

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Two zinc finger proteins, MSN2 and MSN4, function as transcriptional activators (Estruch and Carlson 1993), and under stress conditions both proteins can activate one or more genes involved in the protective response following different types of stress (Martínez-Pastor et al., 1996).

Other RBP domains in S. cerevisiae

There are many other RBPs that have been characterized. For example, SCP160 is a protein that has 14 repeats of the KH domain (Figure 4) and is associated with polyribosome bound mRNPs (Lang and Fridovich-Keil, 2000). Interestingly, this protein also participates in the formation of P-bodies, since it appears to prevent P-bodies formation under normal conditions (Weidner et al., 2014).

Figure 4. Structural prediction of ScScp160 protein (Phyre2 program).

Figure 4

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RBPs orthology between T. cruzi and S. cerevisiae

To investigate if the RBP proteins of T. cruzi are present in S. cerevisiae we performed an orthology analysis. The RBP amino acid sequences from T. brucei (De Gaudenzi et al., 2005) were used to identify RBPs in T. cruzi through best reciprocal Blast hit analysis, resulting in 61 proteins with identity ranging from 87.04 to 30.38%. The identified proteins were then compared to all encoded proteins of S. cerevisiae genome using the same approach. A total of 20 T. cruzi proteins were found orthologous in S. cerevisiae, but the overall identity was lower, ranging from 44.44 to 22.17% (Table 2). Despite the low identity between T. cruzi and S. cerevisiae proteins, domain analysis showed that the proteins had related RBP domains, suggesting that these proteins are indeed orthologous between these two organisms.

Table 2. Orthology analysis of RNA-binding proteins between T. cruzi and S. cerevisiae.

Trypanosoma cruzi id (Tc) Domains Saccharomyces cerevisiae id (Sc) Domains Tc length Sc length Tc qcovhsp Sc qcovhsp pident
TcCLB.506885.70 RRM sp|P04147|PABP RRM 570 577 94 92 38.52
TcCLB.511741.40 RRM sp|P40561|SGN1 RRM 231 250 39 35 43.33
TcCLB.504431.90 RRM sp|P40567|MSL1 RRM 114 111 76 76 32.58
TcCLB.503577.20 Zinc Finger sp|Q06102|YTH1 Zinc Finger 233 208 11 12 44
TcCLB.504071.80 RRM sp|Q08920|NCBP2 RRM 188 208 60 68 40.85
TcCLB.511303.60 Eukaryotic translation initiation factor eIF2A / RRM sp|P06103|EIF3B Eukaryotic translation initiation factor eIF2A /RRM 696 763 90 83 22.17
TcCLB.511367.60 La / RRM sp|P33399|LHP1 La / RRM 333 275 56 73 33.18
TcCLB.508299.89 RRM sp|P53743|ESF2 RRM 238 316 44 34 32.41
TcCLB.511863.20 RRM sp|P32605|RU1A RRM 371 298 27 33 27.72
TcCLB.507037.20 RRM sp|P37838|NOP4 RRM 486 685 70 53 27.59
TcCLB.507515.60 RRM sp|P40565|IST3 RRM 156 148 40 43 44.44
TcCLB.504045.114 Tryptophan synthase alpha chain / RRM sp|P00931|TRP Tryptophan synthase alpha chain / RRM 185 707 54 14 25.23
TcCLB.510657.160 RRM sp|Q08208|NOP12 RRM 421 459 50 48 24.68
TcCLB.503897.90 RRM sp|Q06106|MRD1 RRM 878 887 99 77 27.14
TcCLB.504157.10 RRM sp|P34167|IF4B RRM 450 436 20 21 34.38
TcCLB.508409.80 MIF4G / RRM sp|P39935|IF4F1 MIF4G / RRM 501 952 27 11 25.66
TcCLB.506693.30 RRM sp|Q00539|NAM8 RRM 243 523 30 17 38.64
TcCLB.511127.10 RRM sp|Q00916|RU17 RRM 240 300 33 26 33.75
TcCLB.508567.100 Adaptin N terminal region / RRM sp|P38065|AP2A Adaptin N terminal region / RRM 1405 1025 11 14 24.38
TcCLB.511867.180 PUB sp|P32900|SKG6 Transmembrane alpha-helix domain 365 734 37 16 23.53
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Concluding remarks

RBPs are key players in gene expression regulation in all organisms. They allow the cells to change their expression profile very rapidly to respond to different types of stimuli. The fast response is particularly important in the case of unicellular organisms, such as trypanosomatids and yeast, that rapidly need to adapt to environmental changes to survive.

Despite the phylogenetic distance, in some cases, the function of a protein of interest is conserved. S cerevisiae is a powerful biological model because it is a simple eukaryote whose genome is easily manipulated and, therefore, can be used to obtain hints about the function of genes in another organism (Table 2). For example, the T. cruzi TcJ6 protein is a homologue of the Sis1 protein from S. cerevisiae, and these proteins are involved in translation initiation in both organisms (Salmon et al., 2001). For instance, Mantilla et al. (2015) used S. cerevisiae to complement mutants for the T. cruzi protein TcP5CDH to study the proline metabolic pathway of the parasite.

The study of RBPs proteins and their function in unicellular eukaryotes should pave the way to enlighten the regulatory role of these proteins in higher eukaryotes.

Footnotes

Associate Editor: Angela M. Vianna-Morgante

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