TTV MIRNA SEQUENCES AS AN EARLY MARKER FOR THE FUTURE DEVELOPMENT OF CANCER AND AS A TARGET FOR CANCER TREATMENT AND PREVENTION

Abstract
Described are TTV miRNAs and probes and primers comprising part of said TTV miRNA polynucleic acid. The use of said compounds for diagnosis of cancer or predisposition of cancer is also described.
Description
REFERENCE TO SEQUENCE LISTING, TABLE OR COMPUTER PROGRAM

The Sequence Listing is concurrently submitted herewith with the specification as an ASCII formatted text file via EFS-Web with a file name of Sequence Listing.txt with a creation date of Dec. 9, 2015, and a size of 32.9 kilobytes. The Sequence Listing filed via EFS-Web is part of the specification and is hereby incorporated in its entirety by reference herein.


TECHNICAL FIELD

The present invention relates to novel TTV miRNA as well as probes and primers comprising part of said novel TTV miRNA polynucleic acid. Finally, the present invention relates to the use of said compounds as an early marker for the future development of cancer.


BACKGROUND

Torque Teno Virus (TTV) is a viral species belonging to the family Anelloviridae, genus Alphatorquevirus. Viruses classified into this specie present a circular, single stranded DNA (ssDNA) genome of 3.7-3.8 Kb of length, and are non-enveloped [2,3]. They were first discovered in 1997 in a patient presenting post-transfusion non A to G hepatitis [1]. A high divergence in the nucleotide sequence among different TTV strains is observed, reaching to more than 70% in some cases. Although the genomic organization is also variable, all of them contain a non-coding region, spanning 1.2 Kb [22]. The non-coding region has been demonstrated to harbour a promoter in its 3′ end [4] and a highly conserved region of 70 bp within this 3′ end is hypothesized to be the origin of replication of the viruses. It is estimated that more than 90% of humans are infected with one or more TTV strains. The number of different isolates (more than 200), their ubiquity and the lack of reliable and simple techniques to differentiate between them, have made it difficult to obtain enough epidemiological evidence in support of a causative relationship between TTV infection and a specific disease [23-28]. TTV viruses are known to infect several human tissues [21]. Limited data are available on the replication cycle, and even less on the function of the proteins encoded by these viruses.


MicroRNAs (miRNA) are small RNA molecules ranging between 19 and 29 nt and usually of 22 nt in length. They mediate post-transcriptional gene silencing (PTGS) by inducing cleavage, destabilization or translational inhibition of a target messenger RNA (mRNA) [9,10,11,12]. They do that by guiding the RISC complex to a concrete mRNA, interacting with it by base pairing. This interaction is thought to be mediated mainly by a perfect match between the target mRNA 3′ untranslated region (UTR) and the miRNA “seed” (nucleotides from 2 to 7) [7,8,80], whereas a perfect match means that each of the “seed” nucleotides hybridizes by a Watson and Crick pairing with respective nucleotides of the target mRNA. In contrast, recent findings suggest that non-perfect matches (no Watson and Crick pairing or seeds containing one mismatch) in this region are more abundant than perfect matches [6]. The same study suggests that miRNA-mRNA pairings in coding sequences (CDS) are as abundant as those in 3′UTRs. Moreover, they demonstrate that some miRNAs tend to hybridize with mRNAs in a region totally different from the seed, and they are still able to exert PTGS. To increase even more the complexity of the miRNA-based gene expression regulation, in the last few years some examples of transcriptional gene silencing (TGS) and transcriptional gene activation (known as RNA activation (RNAa)) mediated by miRNA have appeared [29-33]. While the mechanisms mediating these two events are still poorly understood, it cannot be discarded that TGS and RNAa are general features of some miRNA. The number of known endogenous human miRNAs has increased very fast in the last few years. The number of mature miRNA annotated in miRBase is 2042 [13-16]. In addition, a large number of virally encoded miRNA has also been shown to use the cellular miRNA silencing machinery. Since the discovery of the first human viral encoded miRNA [5] its number has increased to 157 [13-16]. The majority of these miRNA are encoded by DNA viruses, especially those belonging to Herpesviridae and Polyomaviridae families. Recently, a bovine oncogenic RNA virus (Bovine Leukemia Virus) was reported to encode 8 mature miRNA, demonstrating that this type of viruses also can express them. Despite the large number of viral miRNA discovered, the function of most of them still remains elusive, although in the last years some reports have shed light over this issue. For instance, miRNAs encoded by both Polyoma and Herpes viruses have been demonstrated to help these viruses to escape the host immune response, by regulating viral [17] or host [18,19] protein expression. Another important finding was made some months ago when it was demonstrated that Epstein-Barr virus-encoded miRNAs are sufficient to transform cells by themselves [20], suggesting that viral miRNAs could be able to mediate an oncogenic process under the adequate conditions. Very recently, it was shown that TTV encode for miRNA's, and the role of one of this miRNA's in interferon signalling inhibition was demonstrated [78]


APC (Adenomatous Polyposis coli) is a very important tumour suppressor, especially in the context of colorectal cancer. Virtually all colorectal cancers carry inactivating APC mutations or epigenetic changes inactivating the transcription of this gene. Its tumour suppressor activity is thought to be mediated by its function in inhibition of wnt signalling, although it has also been implicated in migration and correct mitotic spindle assembly.


SUMMARY OF THE INVENTION

The technical problem underlying the present invention is to provide means (or markers) for diagnosis of cancer or diagnosis of a disposition to said disease. Another technical problem is to provide means for preventing cancer development and cancer recurrence by inhibiting a specific target.


The solution to said technical problem is achieved by providing the embodiments characterized in the claims.


Few aspects are known concerning the interaction between TTVs and their host. In the studies resulting in the present invention it was elucidated that TTV encode miRNAs, as well as their significance for the TTV infection and pathogenicity, mainly focusing on their possible role in cancer. Pre-miRNAs expressed by TTV strains are provided. The miRNA are transcribed from the non-coding region of the virus, in both sense and antisense orientations. Some miRNAs encoded in both orientations can, directly or indirectly, downregulate the tumor suppressor Adenomatous Polyposis Coli (APC) at the mRNA level. Surprisingly, the inventors identified a link between TTV and tumour suppressor regulation and this finding suggests a role of TTV in cancer development. This work represents the first molecular link between TTV and cancer.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1: TTV-HD14a genomic organization and pre-miRNA location


(A) TTV-HD14a. The numbers over the lines indicate the nucleotide number. NCR—Non-coding region. (B) Details of the non-coding region. The numbers indicate the nucleotide number. The hairpins over the line indicate the pre-miRNA encoded in sense orientation. The hairpins under the line indicate the pre-miRNA encoded in antisense orientation. The names over and under the hairpins are the names given to the pre-miRNA.



FIG. 2: Schematic representation of the plasmids used for transfection and Northern Blots showing the pre-miRNA and mature miRNA


(A) Schematic representation of the plasmids containing the CMV promoter and the non coding region (NCR) in sense (+) or antisense (−) orientation. The constructs are named pCDNA3.1(+)-TTV-HD14a-NCR-Sense and pCDNA3.1(+)-TTV-HD14a-NCR-AntiSense, respectively. The numbers over and under the lines indicate the nucleotide number. The hairpins and the vertical lines indicate the pre-miRNA in sense or antisense orientation. The names of the pre-miRNA are written below the lines.


(B-E) Northern blots showing the results with the indicated probes and transfections (Sense—HEK293TT cells transfected with pCDNA3.1(+)-TTV-HD14a-NCR-Sense. Anti-sense—HEK293TT cells transfected with pCDNA3.1(+)-TTV-HD14a-NCR-AntiSense. Mock—HEK293TT cells transfected with pCDNA3.1(+)). Probe sequences are listed in Table 4.



FIG. 3: Complementarity of TTV-HD14a-mir-2-5p with APC mRNA and TTV-HD14a-ASmir-2-3p with the APC promoters and APC mRNA down-regulation in transfected cells


(A) Complementarity between TTV-HD14a-mir-2-5p (1, 2 and 3) TTV-HD14a-mir-2-3p(4) with APC mRNA. Positions relative to APC transcript variant 2(NCBI accession number: NM 001127510.2; SEQ ID NO:82).


(B, C and D) Complementarity between TTV-HD14a-ASmir-2-3p and APC promoters 1, 2 and 3, respectively, as stored in EPDNew Human. The shown positions relate to the transcription start site (TSS) in reference to EPD New Human (EPDNew Human names: APC_1, APC_2 and APC_3).


(E) Relative expression levels of APC as measured by qPCR (Mean for Sense=0.747 and for AntiSense=0.650). ΔCt was calculated respect to HPRT. ΔΔCt was calculated respect to mock transfected cells. Differential values were normalized to 1. Sense—Relative values for HEK 293TT cells transfected with pCDNA3.1(+)-TTVHD14a-NCR-Sense. Antisense—Relative values for HEK293TT cells transfected with pCDNA3.1(+)-TTVHD14a-NCR-AntiSense. Mock—Relative values for HEK293TT cells transfected with pCDNA3.1(+). TTV-HD14a—Relative values for cells transfected with the full-length TTV-HD14a virus. +-SD; N=6. Statistical significance calculated using unpaired two-tailed Student T-Test.



FIG. 4: GAPDH expression (see Example 6 for details)


Relative expression levels of GAPDH as measured by qPCR. ΔCt was calculated respect to HPRT. ΔΔCt was calculated respect to mock transfected cells. Differential values were normalized to 1. Sense—Relative values for HEK 293TT cells transfected with pCDNA3.1(+)-TTVHD14a-NCR-Sense. Antisense—Relative values for HEK293TT cells transfected with pCDNA3.1(+)-TTVHD14a-NCR-AntiSense. Mock—Relative values for HEK293TT cells transfected with pCDNA3.1(+). TTV-HD14a—Relative values for cells transfected with the full-length TTV-HD14a virus. +-SD; N=6. Statistical significance calculated using unpaired two-tailed Student T-Test.



FIG. 5: Wnt upregulation by TTV-HD14a miRNA's


HEK293TT were transfected in a 24 well format with 300 ng of TTV-HD14a virus or pCDNA-3.1(−)-TTV-HD14a-NCR(2820-3516)Sense (referred in the graphic as “Sense”) or pCDNA-3.1(−)-TTV-HD14a-NCR(3516-2820)-AntiSense (referred in the graphic as “Antisense”) or pCDNA3.1(−) (referred in the graphic as “Vector”) or Silencer siAPC (Life technologies) plus 60 ng of TOPFLASH vector (provided by M.Boutros lab) and 5 ng of CMV-renilla. Luciferase activity was measured 72 h after transfection. (A) Firefly luciferase units normalized to Renilla luciferase (B) Fold change respect to vector.





Accordingly, the present invention relates to a TTV polynucleic acid comprising: (a) a nucleotide sequence depicted in Table 1, 2a or 2b; (b) a nucleotide sequence having at least 60% identity to the nucleotide sequence of (a) and containing the nucleotide sequence CATCCYY (with Y=C or T); (c) a fragment of the nucleotide sequence of (a) or (b) and containing the nucleotide sequence CATCCYY (with Y=C or T); or (d) a nucleotide sequence which is complementary to any of said nucleotide sequences.


A further embodiment of the present invention relates to a TTV polynucleic acid, wherein the TTV polynucleic acid is a mature TTV miRNA molecule consisting of 19 to 29 nt, preferably about 22 nt, and comprise the nucleotide sequence CATCCY (with Y=C or T) or CAUCCYY (with Y: C or U). In a preferred embodiment the mature TTV miRNA molecule according to the invention (a) is a nucleotide sequence underlined in Table 2a or 2b; (b) consists of a nucleotide sequence having at least 60%, preferably at least 80%, most preferably at least 90% identity to the nucleotide sequence of (a) underlined in Table 2A or 2B and comprises the nucleotide sequence CATCCYY (with Y=C or T) or CAUCCYY (with Y: C or U);(c) is a fragment of a nucleotide sequence of (a) underlined in Table 2A or 2B and comprises the nucleotide sequence CATCCYY (with Y=C or T) or CAUCCYY (with Y: C or U) or (d) is a nucleotide sequence being complementary to a nucleotide sequence of (a), (b) or (c). In the context of the present invention a “mature TTV miRNA” is a polynucleic acid of an miRNA derived from a TTV.


The term “polynucleic acid” refers to a single-stranded or double-stranded nucleic acid sequence. A polynucleic acid may consist of deoxyribonucleotides or ribonucleotides, nucleotide analogues or modified nucleotides or may have been adapted for diagnostic or therapeutic purposes. A polynucleic acid may also comprise a double stranded cDNA clone which can be used, for example, for cloning purposes. In the following statements and findings made on the DNA level apply to the RNA level accordingly and vice versa.


The TTV polynucleic acid and the mature TTV miRNA of the invention can be prepared according to well-known routine methods, for example, by (a) isolating the entire DNA or, preferably, RNA from a sample, (b) detecting the TTV sequence by hybridization or PCR and (c) cloning of the TTV sequence into a vector (d) by synthesis of the respective nucleotides of the miRNA sequence.


Also included within the present invention are sequence variants of the polynucleic acid and the mature TTV miRNA molecules of the invention containing either deletions and/or insertions of one or more nucleotides, especially insertions or deletions of one or more codons, mainly at the extremities of oligonucleotides (either 3′ or 5′) and which show at least 60%, 70%, 80%, 90%, 95% or 98% identity to said polynucleic acid sequence of the invention and contain the consensus sequence CATCCYY (with Y=C or T). Polynucleic acid sequences according to the present invention which are similar to the sequence as shown in Table 1, 2a or 2b can be characterized and isolated according to any of the techniques known in the art, such as amplification by means of sequence-specific primers, hybridization with sequence-specific probes under more or less stringent conditions, sequence determination of the genetic information of TTV etc. The variants and fragments of the TTV polynucleic acid sequences of the present invention are still able to interfere with or inhibit the expression of their target gene, for example APC.


In a particular preferred embodiment the TTV polynucleic acid sequence (if DNA) contains the consensus sequence CATCCYY (with Y=C or T), i.e. CATCCCC, CATCCCT, CATCCTC or CATCCTT. In another particular preferred embodiment the TTV polynucleic acid sequence (if RNA) contains the consensus sequence CAUCCYY (with Y=C or U), i.e. CAUCCCC, CAUCCCU, CAUCCUC or CAUCCUU. In this regard particular reference is made to Table 2b below.


In a particular preferred embodiment the inventors show how the most conserved seed motif (AUCCUC) has three additional possible interaction sites within APC mRNA in addition to the previously described for TTV-HD14a-mir-2-3p. In this regard particular reference is made to Table 8 below. Therefore, in a further embodiment the invention relates to variants of the polynucleic acid as described above which comprise the seed motif AUCCCUC and bind to at least one of the interaction sites within APC mRNA shown in Table 8 and, preferably, downregulate APC.


Also included in the present invention are analogous miRNAs in other human TT virus types and variants and in similarly structured single-stranded DNA viruses of the human or animal origin. Anelloviruses have been demonstrated in domestic animals in part with similar nucleotide sequences as human TT viruses [77].


Furthermore, the present invention relates to an oligonucleotide primer comprising part of the TTV polynucleic acid of the present invention, said primer being capable of acting as primer for specifically sequencing or specifically amplifying a certain TTV miRNA.


The term “primer” refers to a single stranded DNA oligonucleotide sequence capable of acting as a point of initiation for synthesis of a primer extension product which is complementary to the nucleic acid strand to be copied. The length and the sequence of the primer must be such that they allow to specifically prime the synthesis of the extension products. Preferably the primer is at least about 10, preferably at least 15 nucleotides. Specific length and sequence will depend on the complexity of the required DNA or RNA targets, as well as on the conditions of primer use such as temperature, ionic strength etc. The amplification primers do not have to match exactly with the corresponding template sequence to warrant proper amplification. The amplification method used can be either polymerase chain reaction (PCR), ligase chain reaction (LCR), nucleic acid sequence-based amplification (NASBA), transcription-based amplification system (TAS), strand displacement amplification (SDA) or amplification by means of Qβ replicase or any other suitable method to amplify nucleic acid molecules using primer extension. During amplification or synthesis, the amplified products can be conveniently labelled either using labelled primers or by incorporating labelled nucleotides. Labels may be isotopic (32p, 35S, etc.) or non-isotopic (biotin, digoxigenin, etc.).


The present invention also relates to an oligonucleotide probe comprising part of the TTV polynucleic acid of the present invention, said probe being capable of acting as a hybridization probe for specific detection of a certain TTV miRNA in vitro and in vivo.


The term “probe” refers to single stranded sequence-specific oligonucleotides which have a sequence which is complementary to the target sequence of the TTV polynucleic acid to be detected. Preferably, these probes are about 5 to 50 nucleotides long, more preferably from about 10 to 25 nucleotides. The probe can be fixed to a solid support, i.e., any substrate to which an oligonucleotide probe can be coupled, provided that it retains its hybridization characteristics and provided that the background level of hybridization remains low. Usually the solid substrate will be a microtiter plate, a membrane (e.g. nylon or nitrocellulose) or a microsphere (bead). Prior to application to the membrane or fixation it may be convenient to modify the nucleic acid probe in order to facilitate fixation or improve the hybridization efficiency. Such modifications may encompass homopolymer tailing, coupling with different reactive groups such as aliphatic groups, NHz groups, SH groups, carboxylic groups, or coupling with biotin or haptens.


In an embodiment of the invention the probe is an anti-miR oligonucleotide. An anti-miR oligonucleotide is a single-stranded RNA complementary to the miRNA molecule according to the invention. It can be delivered in its RNA form or being expressed from a vector, using a polymerase III promoter. Such an anti-miR oligonucleotide can be used for inhibiting the miRNA of the present invention. Methods for inhibiting miRNA by anti-miRs are described by Stenvang et al. in [81], which publication is incorporated by reference.


A further embodiment of the invention are miRNA sponges. A miRNA sponge is a messenger RNA with several, preferably 6-8, perfect complementary binding sites to the polynucleotide acid, i.e. mature TTV miRNA, of the invention. The binding sites can also include mismatches in the nucleotides from 10 to 13 of the mature TTV miRNA, to avoid direct RNA slicing and degradation which makes them more effective.


A further embodiment of the invention are tough decoy inhibitors. A tough decoy inhibitor is a miRNA consisting of a hairpin comprising a large internal bulge exposing two of the miRNA interaction sites of APC shown in Table 8 with imperfect baise-pairing with the TTV miRNA of the invention. The design of such a tough decoy inhibitor and methods of suppressing miRNA by a tough decoy inhibitor are described in [82] and [83] which are incorporated by reference.


The anti-miR, miRNA spounge and tough decoy inhibitor according to the invention are inhibitors of the TTV polynucleic acid as described above, in a preferred embodiment of a mature TTV miRNA shown underlined in Table 2A and 2B, which prevent the interaction between the TTV polynucleic acid and APC such that APC is not downregulated.


The present invention also relates to a vector containing a TTV polynucleic acid, oligonucleotide primer, oligonucleotide probe, anti-miR, miRNA sponge or tough decoy inhibitor of the invention allowing, e.g., expression, mutagenesis or a modification of a sequence by recombination of DNA sequences. Preferably, the vectors are plasmids, cosmids, viruses, bacteriophages and other vectors usually used in the field of genetic engineering. Vectors suitable for use in the present invention include, but are not limited to the T7-based expression vector for expression in mammalian cells and baculovirus-derived vectors for expression in insect cells. Preferably, the polynucleic acid of the invention or part thereof is operatively linked to the regulatory elements in the recombinant vector of the invention that guarantee the transcription and synthesis of an mRNA in prokaryotic and/or eukaryotic cells that can be translated. The nucleotide sequence to be transcribed can be operably linked to a promoter like a T7, metallothionein I or polyhedrin promoter.


The present invention also relates to recombinant host cells transiently or stably containing the TTV polynucleic acid (or fragments thereof) or vectors of the invention. A host cell is understood to be an organism that is capable to take up in vitro recombinant DNA and, if the case may be, to synthesize the polypeptids encoded by the polynucleotides of the invention. Preferably, these cells are prokaryotic or eukaryotic cells, for example mammalian cells, bacterial cells, insect cells or yeast cells.


The present invention also relates to a diagnostic kit containing a TTV polynucleic acid, an oligonucleotide primer, an oligonucleotide probe, a polypeptide and/or an antibody of the present invention.


For hybridization based assays, according to the hybridization solution (SSC, SSPE, etc.), the probes should be stringently hybridized to the target (with or without prior amplification) at their appropriate temperature in order to attain sufficient specificity. However, by slightly modifying the polynucleotide, (DNA and/or RNA) probes, either by adding or deleting one or a few nucleotides at their extremities (either 3′ or 5′), or substituting some non-essential nucleotides (i.e. nucleotides not essential to discriminate between types) by others (including modified nucleotides or inosine) these probes or variants thereof can be caused to hybridize specifically at the same hybridization conditions (i.e. the same temperature and the same hybridization solution). Also changing the amount (concentration) of probe used may be beneficial to obtain more specific hybridization results.


Suitable assay methods for purposes of the present invention to detect hybrids formed between the oligonucleotide probes and a TTV polynucleic acid in a sample may comprise any of the assay formats known in the art, such as the conventional dot-blot format, sandwich hybridization or reverse hybridization. For example, the detection can be accomplished using a dot blot format, the unlabelled amplified sample being bound to a membrane, the membrane being incorporated with at least one labelled probe under suitable hybridization and wash conditions, and the presence of bound probe being monitored. An alternative and preferred method is a “reverse” dot-blot format, in which the amplified sequence contains a label. In this format, the unlabelled oligonucleotide probes are bound to a solid support and exposed to the labelled sample under appropriate stringent hybridization and subsequent washing conditions. It is to be understood that also any other assay method which relies on the formation of a hybrid between the nucleic acids of the sample and the oligonucleotide probes according to the present invention may be used.


The present invention also relates to the use of a TTV polynucleic acid, an oligonucleotide primer, or an oligonucleotide probe of the present invention as an early marker for the future development of cancer, preferably colorectal or colon cancer.


Accordingly, an embodiment of the present invention relates to a method of detecting or diagnosing of colon cancer, comprising the steps of:


(a) isolating miRNA from a patients sample;


(b) sequencing the miRNA isolated in step (a); and


(c) determining, if an miRNA selected from the miRNA shown in Table 2B is present in the sample, whereas the presence of an miRNA shown in Table 2B indicates colon cancer.


For determining miRNA labelled oligonucleotides may be used.


Optionally, the method may comprise a further step (d) of quantifying the miRNA level in sample to distinguish between patients with colon cancer from healthy controls.


Preferably, in step (a) the miRNA is isolated from plasma or serum and the miRNA is quantified by using TaqMan miRNA qRT-PCR-assays as described in [86] which is incorporated by reference.


Alternatively, the miRNA may be isolated directly from the tumor and a miRNA sequencing may be performed to detect the miRNA or sections of any kind (e.g. cryo-sections, sections from paraffin embedded tissue) may be made directly on the tumor and an hybridization for the miRNA as described above may be performed in-situ.


Finally, the present invention also relates to the use of a TTV polynucleic acid of the present invention as a lead component for the development of a medicament for prevention or treatment of cancer, preferably colorectal or colon cancer. These medicaments may be inhibitors of any interaction between miRNAs and tumour suppressor genes to avoid cancer development or recurrence and cancer treatment. Thus, the specific TT virus miRNA or of its derivatives or of related miRNAs are useful for diagnostic, prevention or therapeutic applications in the cancer field.


Such inhibitor of an interaction between miRNA and tumor suppressor genes, for example APC, can be an anti-miR, A miRNA sponge or a tough decoy inhibitor as described above.


The inhibitor can be delivered to the tumor site by using an adeno associated virus (AAV) in order to deliver the inhibitor to counter effect the TTV miRNA according to the invention. An AAV gene therapy suitable for delivering one of the above miRNA inhibitors to the tumor is described in [84] which is incorporated by reference.


A further example of a suitable method for delivering the above inhibitors against TTV miRNA to a tumor is known as low pH-induced transmembrane structure (pHILP) [85]. This phILP construct consists of a peptide that crosses the plasma membrane only under acidic conditions which are typical of the tumor microenvironment. A peptide nucleic acid of an TTV miRNA inhibitor can be attached to this pHILP in order to be delivered specifically to cells in the tumor microenvironment. Preferably, this peptide is an anti-miR, which will cause the inhibition of the TTV miRNA according to the invention. A suitable method for delivering a TTV miRNA inhibitor with a pHILP construct is described in [85] which is incorporated by reference.


A further embodiment of the invention is a method of delivering a lead component for the development of a medicament for prevention or treatment of cancer, preferably colorectal cancer comprising the step of administrating to a patient suffering from a cancer, in particular colorectal cancer (a) a pharmaceutical composition comprising an adeno-associated virus expressing an inhibitor of the miRNA of the invention selected from the group consisting of anti-miR, miRNA sponge and tough decoy inhibitor of a miRNA interacting with a tumor suppressor gene and a pharmaceutically acceptable carrier or (b) a pharmaceutical composition comprising an inhibitor of the miRNA of the invention attached to a pHILP construct and a pharmaceutically acceptable carrier.


A further embodiment of the invention is (a) an adeno-associated virus for the use of delivering an inhibitor of TTV miRNA to tumor cells or (b) a pHILP construct for the use of delivering an inhibitor of a miRNA of the invention to tumor cells.


Preferably, the inhibitor to be delivered is selected from the group consisting of anti-miR, miRNA sponge and tough decoy inhibitor and is an inhibitor of a mature TTV miRNA as shown underlined in Table 2B which interacts with APC.


The following examples illustrate the invention and are not construed as any limitation of the invention.


Example 1
Material and Methods
(A) Cell Culture and Transfections

HEK293TT cells [76] cultured in Dulbeco's Eagle Modified Medium (DMEM Sigma) supplemented with 10% FBS, 1% Glutamax and 1% NGAA. Cells are transfected when 50% confluent, 24 h after seeding (7 million for T-75 flask and 800.000 per well for a 6 well plate). Transfections are performed using Lipofectamine and Plus reagent (Life Technologies, catalog n. 11514 and 18324) according to the manufacturer's instructions.


(B) Plasmid Construction

The TTV NCR is PCR amplified using suitable primers. For example, the TTV-HD14a NCR is PCR amplified using primers TT-ON9 5′ gattatggtacctttccaactacgactgggtgt (SEQ ID NO:83) and TT-ON10 5′ gattatggtacctctaccattcgtcaccgctgtt (SEQ ID NO:84) using pCDNA3.1(+)-TTV-HD14a as template (a plasmid containing full-length TTV-HD14a linearized and cloned into XbaI site). PCR product is run on a 1% agarose gel and DNA stained using ethidium bromide. Bands corresponding to the expected size (˜1200 bp) are cut and subsequently extracted from agarose using QIAEXII gel extraction kit (QIAGEN). 4 μg of pCDNA3.1(+) (Life technologies) are cut using KpnI and dephosphorylated using FastAP (Thermo scientific). PCR product is cut using the same procedure, but not dephosphorylated. Cut plasmid and PCR products are cleaned up by using QIAEXII gel extraction kit.


Ligation of the plasmid and the amplified fragment corresponding to the TTV NCR, for example TTV-HD14a NCR, is performed using T4DNA ligase (Thermo Scientific) Ligation product is transformed into NovaBlue Singles competent cells (Merck Millipore) according to the manufacturer instructions, and seeded in LB agar plates supplemented with ampicillin as selection marker. Plates are incubated 20 hours at 37° C. Single colonies are picked and seeded in LB medium supplemented with ampicillin. These cultures are incubated 20 hours. Plasmid is extracted using PureLink Quick Plasmid Miniprep Kit (Life technologies). 1 μg of each plasmid are double cut with SacI and NheI (Thermo Scientific). Cut products are run in 1% agarose gels. The restriction strategy allows us to distinguish between inserts clones in the sense and antisense orientation. Two positive plasmids, one containing the sense and the other one the antisense insert, are chosen and sent for sequencing. After confirming the sequence, plasmids are prepared for transfection by using Plasmid Maxi Kit (Qiagen).


(C) RNA Extraction and DNAse Treatment

Cells are harvested 48-72 h post-transfection. Cells are homogenized using QiaShreder (Qiagen) according to manufacturer instructions. Lysates are then subjected to RNA extraction using miRNAeasy mini kit or RNAeasy mini kit (Qiagen) depending on the purpose of the RNA (for miRNA Northern blot or for RT-qPCR), according to manufacturer instructions.


After elution, RNA samples are treated with RQ1 Dnase (Promega) according to manufacturer instructions, with the addition of RNasin (Promega). Phenol-Chloroform extraction followed by ethanol precipitation is performed, and the resulting pellet is resuspended in DEPC water. RNA quality and concentration are tested using NanoDrop 2000c (Thermo Scientific).


(D) Probes Labeling

Custom DNA oligos are ordered to Sigma (Table 4). Probes are 3′ biotin labeled.


10 pmoles of each probe are incubated with 4 U of Terminal Deoxynucleotidyl transferase (TdT) and 2,5 nanomoles of Biotin-11-dUTP (Thermo Scientific) in 1×TdT buffer, overnight. Probes are subjected to Isoamyl alcohol-Chloroform extraction and the total volume is used for subsequent hybridization.


(E) Northern Blot

30-50 μg of total RNA per sample are separated by electrophoresis using 15% polyacrylamide (29:1) gels cast in 7M urea and buffered with 1×TBE using a MiniProtean cell (Bio-Rad). The electrophoresis buffer is 0.5×TBE. Gels are stained with EtBr.


For blotting, gels are placed over a sheet of nylon hybridization membrane (Hybond-NX®, Amersham/Pharmacia) pre-wetted in 0.5×TBE. This is then sandwiched between pieces of 3MM Whatman filter paper (one layer under the membrane and three over the gel), also pre-wetted in 0.5×TBE and placed in a Trans-Blot SD semidry transfer cell (Bio-Rad). Excess liquid and air bubbles are squeezed from the sandwich by rolling the surface with a pipette. Electrophoretic transfer of RNA from the gel to the membrane is carried out at 400 W for 60-90″min. After transfer, RNA is crosslinked to the membrane by ultraviolet exposure using Stratalinker (Stratagene).


Membranes are cut as needed and hybridized with the appropriated biotin labeled probe (Table 4) o/n in Ultrahyb Oligo buffer (Life technologies) at 42° C. After hybridization, 4 washes are performed; the first one with 2×SSC 30 min at 42° C., the second one with 2×SSC 0.5% SDS 30 min at 42° C. and the last two with 2×SSC 0.5% SDS 30 min at 55° C. Hybridization signals are detected using BrightStar BioDetect Kit (Life technologies) according to the manufacturer instructions. Film used: (Fiji).


(F) RT-qPCR

1 μg of RNA is used to make cDNA with superscript III and RnaseOUT (Life technologies) according to manufacturer instructions. cDNA is diluted 1:10. qPCR is performed using Taqman fast master mix and Taqman expression assays, in a qPCR machine StepOne plus (Applied Biosystems).


(G) Pre-miRNA Prediction and Mature miRNA Prediction


V-mir is set to default configuration, changing the sequence type to circular. CID-miRNA is run on the web-based tool, using the default run configuration for Homo sapiens. Mature Bayes is run on the web-based tool.


(H) miRNA Target Predictions


DIANA microT 3.0 is run on the web-based tool (no options are given for this program). RNA hybrid is run using constraint nucleotide configuration, from nucleotide 2 to 8 of the miRNA. G:U pairs are allowed.









TABLE 1







Predicted pre-miRNA from TTV-HD14a using CID-miRNA and V-


mir that match three criteria: being predicted by both


programs, score over 150 for V-mir and located in the non-


coding region of the virus.











Group
Orientation
Length
Starting nucleotide
Name





S2
sense
69
3135
TTV-HD14a-mir-1









Sequence and secondary structure



       g         ----   a----  a      cu



5′gccuc gaccccccc    ucg     cc gaaucg  c



  ||||| |||||||||    |||     || ||||||



3′cgggg cuggggggg    ggc     gg cuuagc  g



       g         cucc   gucca  -      gc














S3
Sense
78
3420
TTV-HD14a-mir-2 









Sequence and secondary structure



              ac         -  a   c   gugua



5′gcugugacguca  gucacgugg gg gga ggc     a



  ||||||||||||  ||||||||| || ||| |||     c



3′cggcacugcagu  cagugcacu cc ccu cug     c



              c-         a  -   a   aaggc














AS3
Antisense
63
3576
TTV-HD14a-ASmir-1 









Sequence and secondary structure



        -  ac  c  a--     u      u



5′ccgccg cu  gu ac   cuucc cuuuuu u



  |||||| ||  || ||   ||||| |||||| u



3′ggcggu ga  ca ug   gaagg gaaaaa a



        a  a-  c  aag     c      c














AS1
Antisense 
80
3497
TTV-HD14a-ASmir-2









Sequence and secondary structure



     c          -       gau     u   uuc  gg



5′ggc gugacgucag gucacgu   gggga gac   cg  u



  ||| |||||||||| |||||||   ||||| |||   ||  u



3′ccg cacugcaguu cagugca   ccccu cug   gc  a



     a          g       ---     c   cc-  ac
















TABLE 2A







Initial pre-miRNA predicted from different TTV strains grouped according to sequence


homology. The predicted mature miRNA are underlined.











Pre-miRNA Alignment



Group
name







Sense1
TTV-HD16a-mir-3                                                   GGCCGCCATTTTAAGTAA--





GGCGGAAGCAACTCCACTTTCTCACAAAATGGCGGCGGAGCACTTCCGGCTTGCCCAAAATGGCCGCC





TTV-sle2057-mir1                                                  --CCGCCATTTTAAGTAA--





GGCGGAAGCAGCTCCACTTTCTCACAAAATGGCGGCGGAGCACTTCCGGCTTGCCCAAAATGGCGG--





TTV-HD23a-mir-1                                                   --CCGCCATTTTAAGTAA--





GGCGGAAGCAGCTCCACCCTCTCACATAATGGCGGCGGAGCACTCCCGGCTTGCCCAAAATGGCGG--





TTV-Sanban-mir-1                            -GCCGCCATTTTAAGTAA--GGCGGAAGCAGCTCGGCATA--




TACAAAATGTCGGCGGAGCACTTCCGGCTTACCCAAAATGAAGGC-




                   ****************   ********** ***   *        ***  **** ************




******* *********   *







Sense2
TTV-HD14a-mir-1     GCCTCGGACCCCCCCTCGACCAGAATCGCTCGCGCGATTCGGACCTG--




CGGCCTCGGGGGGGTCGGGGGC




TTV-CT30E-mir-1     -CCTCGGACCCCCCCCCGACCCGAATCGCTCGCGCGATTCGGACCTG--




CGGCCTCGGGGGGGGTCGGGG-




TTV-HD16a-mir-2-    -CCTCGGACCCCCGCTCGTGCTGACGCGCTTGCGCGCGTCAGACCACTTCGGGCTCGCGGGG----




------




                     ************ * **  * **  * ** *****  ** ****    *** **** ****







Sense3
TTV-HD14a-mir-2    GCTGTGACGTCAACG-TCACGTGGG-GAGGACGGCGTGTAACCCGGAAGTCATCCCCA-





TCACGTGACCTGACGTCACGGC--





TTV-Sanban-mir-2   ------ACGTCACAAGTCACGTGGGGAGGGTTGGCGTATAGCCCGGAAGTCAATCCT-





CCCACGTGGCCTGTCACGT------





TTV-HD23a-mir-2




GCAGCTACGTCACAAGTCACCTGACTGGGGAGGAGTTACATCCCGGAAGTTCTCCTCGGTCACGTGACTGTACACGTGACTGC




TTV-s1e2057-mir-2  ------




ACGTCACAAGTCACCTGACTGGGGAGGAGTCACAACCCGGAAGTCCTCTTCGGTCACGTGACTAGTCACGT------




             ******    **** **     **  *      * *********          ****** *







AS1
TTV-HD14a-ASmir-2    ----GGCCGTGACGT-CAG-GTCACGTGAT-GGGGATGACTTCCGGGTTACACGCCGTCCTCC-





CCACGTGACGT-TGACGTCACAGCC





TTV-CT30E-ASmir-3    -------CGTGACGT-CAGAGTCACGTGACCAGGGATG-CTTCCGGGTTTAGGCACGCCCCCA-




TCACGTGTCTC-AAACGTCACG




TTV-HD23a-ASmir-1    GCAGTCACGTGTA---CA--




GTCACGTGACCGAGGAGAACTTCCGGGATGTAACTCCTCCCCAGTCAGGTGACTTGTGACGTAGCTGC-




TTV-sle2057-ASmir-1  ------ACGTGAC---TA--





GTCACGTGACCGAAGAGGACTTCCGGGTTGTGACTCCTCCCCAGTCAGGTGACTTGTGACGT





TTV-HD16a-ASmir-1    ------ACGTGAC---CA--GTTACGTGGTTGAGGAT-





ACTTCAGTGTTTAAGTACCTCCCCAGTCACGTGACTTATGACGT-------





                            ****      *  ** *****      *    **** * * *         ** *




** *** *    **** 







AS2
TTV-HD16a-ASmir-2    ---GCCATTTTGGGCAAG--CCG--





GAAGTGCTCCGCCGCCATTTTGTGAGAAAGTGGAGTTGCTTCCGCCTTACTTAAAATGGC---





TTV-sle2057-ASmir-2  -CCGCCATTTTGGGCAAG--CCG--





GAAGTGCTCCGCCGCCATTTTGTGAGAAAGTGGAGCTGCTTCCGCCTTACTTAAAATGGCGG-





TTV-HD23a-ASmir-2    -CCGCCATTTTGGGCAAG--CCG--




GGAGTGCTCCGCCGCCATTATGTGAGAGGGTGGAGCTGCTTCCGCCTTACTTAAAATGGCGG-




TTV-Sanban-ASmir-2   GCCTTCATTTTGGGTAAG--CCG--GAAGTGCTCCGCCGACATTTTGT--




ATATGCCGAGCTGCTTCCGCCTTACTTAAAATGGCGGC




TTV-tth8-ASmir-2     ----CCATTTTGAGTAGGTGTGGCTGATGGTGACCTTTGAACTCACGCCACCGTCCG------





CCTCAAC--TACTTAAGATGG----





TTV-TWH-ASmir-3      ----CCATTTTGTGTAGCTTCCGTCGAGGATGACCTTTAACCTCTA-CGTCAATCCTGA----





CGTCAGC--TACTTAAAATGG----





******* * * * * * ** * *




** * ******* ****







AS3
TTV-HD14a-ASmir-1 CCGCCGCTAC-GTCACACTTCCTCTTTTTTTTACAAAAAGCGGAAGGAAGTCACAAGATGGCGG




TTV-CT30E-ASmir-2 CCGCCGCTACTGTCATACTTCCTCTTTTTTTTTGAAAAAGCGGAAGGAAGTCACAAGATGGCGG




                  ********** *********************  ******************************







Pre-
TTV-Sanban-mir-3



mIRNA
GCCGGGGGGCTGCCGCCCCCCCCGGGGAAAGGGGGGGGCCCCCCCCGGGGGGGGGTTTGCCCCCCGGC



failed to
TTV-CT30E-mir-2



be
GTCGTGACGTTTGAGACACGTGATGGGGGCGTGCCTAAACCCGGAAGCATCCCTGGTCACGTGACTCTGACGTCACGGC



classified
TTV-CT30E-mir-3 GCGGGGGGGCGGCCGCGTTCGCGCGCCGCCCACCAGGGGGTGCTGCGCGCCCCCCCCCGCGC



into any
TTV-HD16a-mir-1



group
GTGCCTACCTCTTAAGGTCACCAAGCACTCCGAGCGTCAGCGAGGAGTGCGACCCTTGGGGGTGGGTGC




TTV-HD16a-mir-3




GGCCGCCATTTTAAGTAAGGCGGAAGCAACTCCACTTTCTCACAAAATGGCGGCGGAGCACTTCCGGCTTGCCCAAAATGGCCGCC




TTV-Sanban-ASmir-1




GCCGGGGGGCAAACCCCCCCCCGGGGGGGGCCCCCCCCTTTCCCCGGGGGGGGCGGCAGCCCCCCGGC




TTV-Sanban-ASmir-3




CCAGAAGGCGGCGGCCTCGTACTCCTGCTGCCAGTCTTGGCTGCTGGGTACGGGTTTTGGGGCCCTGTCTGG




TTV-CT30E-ASmir-1




CGCGCATGCGCGGTGGGTTTAGCACGGGGGGGGGCCGGGGGGGCGGAGCCCCCCCGGGGGGGGGCCCCGCGCATGCGCG




TTV-CT30E-ASmir-4 GGGGGGTCCGAGGCGTCCGGCGCAGCGCGAAGCGCGTAGCGCCGGACCCCGAGGAAGTTGCCCC

















TABLE 2B







TTV mature miRNA present in the TCGA small RNA sequencing


datasets of colon adenocarcinoma with similarity in the


nucleotides from 1 to 7 (comprising the seed (nt 2 to 7)) to


TTV-HD14a-mir-2-3p . The TTV miRNA are shown in the context of


the pre-miRNA sequence. The identical conserved nucleotides from


1 to 7 (comprising the seed (nt 2 to 7)) are boxed. Positions


containing identical nucleotides are marked by a (*) and


positions containing nucleotides originated by a transition are


marked by (°). They are classified in groups according to their


pre-miRNA sequence. In all cases, the 3p mature miRNA is


underlined. The seed is written in italicized letters. The box 3


contains the consensus sequence for the nucleotides from 1 to 7.


A — adenine, T — thymine, C — cytosine, G — guanine, Y — C or T.


Seed of a miRNA: nucleotides 2 to 7 of the mature form of the miRNA [80]










TTV pre-




miRNA



Box
related to
TTV Sequence












1
TTV-HD14a


embedded image







2
TTV-HD18a


embedded image








embedded image







3
Consensus sequence for the nucleotides from 1 to 7 (comprising the seed (nt 2-7))
Common to all the TTV embedded image
















TABLE 3







Genes predicted to be down-regulated by the TTV-HD14a and at


least two other TTV strains miRNA. Notice that some strains


have more than one putative miRNA that is predicted to down-


regulate some of the genes.












Number of TTV
Number of TTV




isolates
miRNA



NCBI
predicted to
predicted to



accession
down-regulate
down-regulate


Gene
number
it
it













APC2
NM_005883.2
4 (Out of 9)
8


SOX4
NM_003107.2
3 (Out of 9)
3


TNRC6B
NM_001162501.1
4 (Out of 9)
7


BNC2
NM_017637.5
3(Out of 9)
4


ONECUT2
NM_004852.2
5(Out of 9)
7


BCL11a
NM_022893.3
3 (Out of 9)
3


SLIT1
NM_003061.2
3 (Out of 9)
3


MLL
NM_153827.4
5 (Out of 9)
8


MACF1
NM_012090.5
8 (Out of 9)
12


DST
NM_001144769.2
9 (Out of 9)
13


CREB5
NM_182898.2
3 (Out of 9)
3


CHD5
NM_015557.2
3 (Out of 9)
4


SSRP1
NM_003146.2
3 (Out of 9)
3


MINK1
NM_001197104.1
5 (Out of 9)
5
















TABLE 4







Probes








Probe name
Sequence





HD14a-mir-1-5p
5′agcgattctggtcgagggggggtccgag



gc-Probe





HD14a-mir-1-3p
5′gcccccgacccccccgaggccgcaggtc



cgaatgcg-





HD14a-mir-2-5p
5′acacgccgtcctccccacgtgacgttga



cgtcacagc-





HD14a-mir-2-3p
5′gccgtgacgtcaggtcacgtgatgggga



tgacttccg-





HD14a-ASmir-1-
5′aagaggaagtgtgacgtagcggcgg-



Probe





5p HD14a-
5′cgccatcttgtgacttccttccgcttt-



Probe





ASmir-1-3p
5′cggaagtcatccccatcacgtgacctga



cgtcacggc-





HD14a-ASmir-2-
5′gctgtgacgtcaacgtcacgtggggagg



acggcgtgt-





5p HD14a-
5′cactacctgcacgaacagcactttggag



cccccag-





ASmir-2-3p hsa-
5′ccgggggctcgggaagtgctagctcagc



agtaggt-





mir-93-5p







text missing or illegible when filed







text missing or illegible when filed indicates data missing or illegible when filed







Example 2
miRNA Prediction

To address the question about the possible function of the non-coding region (NCR) of TTVs beyond its promoter activity, the inventors had the idea that it also generates non-coding RNAs, such as miRNAs. Therefore, they used available miRNA prediction algorithms, with which they identified several candidate pre-miRNAs in the NCR of some TTVs. The inventors chose to use two of such algorithms: CID-miRNA [34] and Vmir [35-36]. The first one was chosen because of its high specificity and the second one because of its higher sensitivity. To consider a pre-miRNA structure as a candidate, they used the criterion that it should be predicted by both programs, with a cut-off value over 125 for the V-mir program and that it had to be located in the NCR of the virus. After filtering, only 4 pre-miRNA candidates (Table 1 and FIG. 1B), two in sense orientation and two in antisense orientation, were considered as putative pre-miRNA and were further evaluated.


In order to check the conservation of the pre-miRNA sequences among different TTV isolates, the inventors performed the same prediction in seven different strains: TTV-HD16a (FR751476, version FR751476.1 GI:339511352, 07.07.2011), TTV-C3T0F (AB064597, version AB064597.1 GI:17827196, 25.06.2008), TTV-HD23a (FR751500, version FR751500.1 GI:339511376, 07.07.2011), TTV-YonKc197 (AB038624, version AB038624.1 GI:7415899, 20.09.2000), TTV-SANBAN (AB025946, version AB025946.2 GI:5572683, 03.11.2009), TTV-Sle2057 (AM712030, version AM712030.1 GI:156104055, 19.02.2008) and TTV-tth8 (AJ620231, version AJ620231.1 GI:49203022, 03.02.2009(GenBank accession numbers and versions in brackets) They then grouped the resulting pre-miRNA in different classes (Table 2A), according to their sequence similarity. As can be observed, the conservation of the sequences is rather poor, being strange the total identity between two pre-miRNA from different strains.


Mature- and pre-miRNAs similar to TTV-HD14a pre-miRNA that contain a mature miRNA with an equal or similar seed to that of TTV-HD14a-3p miRNA which also includes TTV-HD18a-like pre-miRNAs were found within patients by screening TGCA datasets. These miRNAs are shown in Table 2B. The similarity within the nucleotides 1 to 8 of these miRNAs with that of TTV-HD14a miRNAs indicates, that these miRNAs are downregulating APC as well.


Example 3
TTV-HD14a can Transcribe Four Precursor miRNA Encoded in its NCR

To address the question whether the predicted pre-miRNAs could be processed, the NCR of TTV-HD14a was cloned downstream of the CMV promoter, in sense or antisense orientation, using the plasmid pCDNA3.1(+)-zeo as scaffold (FIG. 2A). The inventors then transfected HEK293TT cells with these plasmids and performed Northern Blot hybridization with specific probes against the 3′ or 5′arm of each putative pre-miRNA (Table 4) (FIG. 2B-E). The inventors could clearly detect bands that match the expected size for a pre-miRNA with the probes directed against the 3′ and 5′arm of TTV-HD14a-mir-2 and TTV-HD14a-ASmir-2. Moreover, the inventors were able to detect a transcript matching the expected size for a mature miRNA within the 5′arm of TTV-HD14a-mir-2. On the other hand, the inventors were able to detect transcripts matching the expected sizes with the probes directed against the 3′arm only of TTV-HD14a-mir-1 and TTV-HD14a-ASmir-1.


These results demonstrate that TTV-HD14a encodes for several precursor miRNA in both orientations; and at least one of them can be processed into a mature miRNA.


Example 4
Target Prediction

It is well known that the major feature of miRNA is down-regulating gene expression in a post-transcriptional manner. It is also known that this effect is caused by the mature form of the miRNAs, and not by their precursors. Although the inventors were not able to see any mature miRNA for three of the pre-miRNA, they think that low expression levels of these miRNAs rather than their absence might be the reason of this. In any case, it is necessary to identify the sequence of the mature miRNA to perform accurate predictions, and this is hard to determine by experimental methods different from miRNA-seq. To overcome this problem, the inventors decided to use an in-silico mature miRNA predictor, Mature Bayes [37]. This program predicts the mature miRNA from a pre-miRNA sequence. After doing that with all the predicted miRNA precursors (Table 2), they used DIANA-microT-3.0 [38-39] to predict possible targets. They reasoned that, despite the variability in their sequences, the putative TTV mature miRNAs should have some targets in common. So, after performing the predictions, the inventors compared the results among the different TTV strains and considered as good candidates the targets that were predicted for some miRNAs belonging to TTV-HD14a and, at least, two more TTV strains. Candidate targets are listed in Table 3.


In addition to this approach, the inventors performed a direct comparison of the predicted mature miRNA from TTV-HD14a with the CDS, 3′UTR and promoter regions of several tumor suppressor genes using RNA Hybrid [40]. This program allows to directly detecting the complementary sequence of a given miRNA within a gene, independently of the conservation or localization of complementary sequence. This is useful, as most of the other prediction programs do not take into account the CDS or promoter region of the genes, while it has been demonstrated that a seed pairing with the first one can mediate PTGS and with the second one can cause TGS or RNAa [11,12,29-33]. The inventors found seed complementarity between the APC gene and TTV-HD14a-mir-2-5p in three different points within the APC mRNA sequence, two in the CDS and one in the 3′UTR (FIGS. 3A-1, 2 and 3). In addition, a possible interaction site between TTV-HD14a-mir-2-3p and APC mRNA was present in the CDS (FIG. 3A-4). The inventors also found complementarity between the TTV-HD14a-ASmir-2-3p and three of the four promoters listed for APC in the Eukaryotic Promoter Database New Human (EPD New Human) [59](accession names APC_1, APC_2 APC_3 and APC_4) (FIG. 3B-D).


Example 5
APC is Down-Regulated after Transfection with pCDNA3.1(+)-TTVHD14a-NCR-Sense

To check the possible APC down-regulation mediated by the TTV-HD14a miRNA the inventors transiently transfected HEK293TT cells with the constructs encoding the miRNA, with the full length TTV-HD14a virus or mock transfected them, followed by RT-qPCR (FIG. 3E+F). APC down-regulation by the miRNA itself as well as by the full length genome (coding for the miRNA) is significant in comparison to the mock transfected.


Example 6
GAPDH Up-Regulation by TTV miRNA

After transfection with pCDNA3.1(+)-TTV-HD14a-NCZ-Sense, which is intended to produce 4 mature miRNAs (TTV-HD14a-mir-1-5p, TTV-HD14a-mir-1-3p, TTV-HD14a-mir-2-5p and TTV-HD14a-mir-2-3p), the inventors can observe a statistically significant increase of GAPDH transcript:


GAPDH (Glyceraldehyde-3-phosphate-dehydrogenase) is a gene usually used as internal control (housekeeping gene), at the mRNA and protein levels, because its levels of expression are very constant among very different conditions.


GAPDH is up-regulated in the majority of cancers and under hypoxic conditions [72, 73, 74]. The inventors suggest that the TTV miRNA dependent up-regulation of GAPDH is mediated indirectly by APC down-regulation.


Example 7
Microarray Analysis Reveals the Landscape of TTV-HD14a miRNA's Induced Alterations

72 h after transfection of cells with the two different constructs, the full-length TTV HD14a genome or an empty plasmid RNA was isolated and microarray analysis was performed. Table 5 includes all the genes that were consistently deregulated between the transfection with the constructs and with the full-length virus.









TABLE 5







Genes differentially expressed between cells


transfected with a plasmid encoding for TTV-HD14a NCR in sense


orientation in comparison to mock transfected cells









ILLUMINA _ID
GENE_SYMBOL
Description












5550379
CAV1
caveolin 1, caveolae protein, 22 kDa


1230465
HNRNPK
heterogeneous nuclear ribonucleoprotein K


4230673
GRM2
glutamate receptor, metabotropic 2


7160327
ARPC2
actin related protein 2/3 complex, subunit 2, 34 kDa


4640161
C17orf97
chromosome 17 open reading frame 97


2640142
C17orf97
chromosome 17 open reading frame 97


70403
C14orf45
chromosome 14 open reading frame 45


7510097
CMTM1
CKLF-like MARVEL transmembrane domain containing 1


4850736
CMTM1
CKLF-like MARVEL transmembrane domain containing 1


6290358
TPX2
TPX2, microtubule-associated, homolog (Xenopus laevis)


7150270
LRRC26
leucine rich repeat containing 26


6420441
LOC728416
hypothetical LOC728416


2140541
LRRC26
leucine rich repeat containing 26


6220053
FAM57B
family with sequence similarity 57, member B


3520128
TUBG2
tubulin, gamma 2


1410470
FAM71E1
family with sequence similarity 71, member E1


2490433
RNF32
ring finger protein 32


650717
C22orf23
chromosome 22 open reading frame 23


4070424
C16orf93
chromosome 16 open reading frame 93


4860068
STX1A
syntaxin 1A (brain)


2940739
RASSF1
Ras association (RaIGDS/AF-6) domain family member 1


2370538
KRCC1
lysine-rich coiled-coil 1


6130047
CCDC151
coiled-coil domain containing 151


1240731
RFPL3S
RFPL3 antisense RNA (non-protein coding)


650689
CLIP3
CAP-GLY domain containing linker protein 3


7320402
APBB3
amyloid beta (A4) precursor protein-binding, family B, member 3


450204
ALG9
asparagine-linked glycosylation 9, alpha-1,2-mannosyltransferase homolog (S. cerevisiae)


1240523
RPL41
ribosomal protein L41


1940561
CGRRF1
cell growth regulator with ring finger domain 1


6290609
RPS15
ribosomal protein S15


1090564
TMEM175
transmembrane protein 175


5820494
ZNF177
zinc finger protein 177


7560731
SNORA64
small nucleolar RNA, H/ACA box 64


7550021
TTC25
tetratricopeptide repeat domain 25


2350477
LRRC6
leucine rich repeat containing 6


2480364
DPP7
dipeptidyl-peptidase 7


3180678
HNRNPH2
heterogeneous nuclear ribonucleoprotein H2 (H)


3400164
C21orf2
chromosome 21 open reading frame 2


730292
RNFT2
ring finger protein, transmembrane 2


7330474
MOBP
myelin-associated oligodendrocyte basic protein


6520241
FAM116B
family with sequence similarity 116, member B


270026
RASSF1
Ras association (RaIGDS/AF-6) domain family member 1


5560253
N6AMT1
N-6 adenine-specific DNA methyltransferase 1 (putative)


3520092
BAX
BCL2-associated X protein


6940181
FAM24B
family with sequence similarity 24, member B


7320750
ILVBL
ilvB (bacterial acetolactate synthase)-like


3840356
TRIM11
tripartite motif-containing 11


6350121
RASSF1
Ras association (RaIGDS/AF-6) domain family member 1


7400619
SPATA5L1
spermatogenesis associated 5-like 1


5270343
IQCC
IQ motif containing C


7320192
LOC100129148
hypothetical LOC100129148


3140689
KIAA1407
KIAA1407


1990593
IRX6
iroquois homeobox 6


5340725
DYNLRB2
dynein, light chain, roadblock-type 2


4120279
APBB3
amyloid beta (A4) precursor protein-binding, family B, member 3


5910397
LIAS
lipoic acid synthetase


3130035
FAM149B1
family with sequence similarity 149, member B1


2570707
N6AMT1
N-6 adenine-specific DNA methyltransferase 1 (putative)


2900725
CYP27B1
cytochrome P450, family 27, subfamily B, polypeptide 1


7400246
BCDIN3D
BCDIN3 domain containing


5080010
LOC401431
hypothetical LOC401431


830681
C14orf45
chromosome 14 open reading frame 45


5910041
RPL23AP7
ribosomal protein L23a pseudogene 7


1820739
CDK20
cyclin-dependent kinase 20


6350672
PHF21B
PHD finger protein 21B


1170022
C17orf81
chromosome 17 open reading frame 81


4640095
RPL9
ribosomal protein L9


5390497
C7orf53
chromosome 7 open reading frame 53


4490348
C9orf6
chromosome 9 open reading frame 6


6040156
C6orf52
chromosome 6 open reading frame 52


2480735
KIAA1731
KIAA1731


4180408
SNORD55
small nucleolar RNA, C/D box 55


6660451
NDUFB4
NADH dehydrogenase (ubiquinone) 1 beta subcomplex, 4, 15 kDa


4150561
AASDH
aminoadipate-semialdehyde dehydrogenase


6840291
FOXN4
forkhead box N4


3850754
KIAA1683
KIAA1683


3800400
LDHAL6B
lactate dehydrogenase A-like 6B


540403
LRP5L
low density lipoprotein receptor-related protein 5-like


5360139
LOC100128221
similar to hCG2041787


2810674
TRIM4
tripartite motif-containing 4


3780450
BANP
BTG3 associated nuclear protein


5690280
FXR2
fragile X mental retardation, autosomal homolog 2


1580750
LOC100130828
hypothetical LOC100130828


4610433
ANGPTL4
angiopoietin-like 4


3120452
MTMR10
myotubularin related protein 10


2750465
C19orf61
chromosome 19 open reading frame 61


2470270
DUS4L
dihydrouridine synthase 4-like (S. cerevisiae)


3370288
CBX6
chromobox homolog 6


7210092
TRIT1
tRNA isopentenyltransferase 1


1580021
TCTEX1D2
Tctexl domain containing 2


540041
CASC1
cancer susceptibility candidate 1


2030152
MOBP
myelin-associated oligodendrocyte basic protein


2650678
RSPH3
radial spoke 3 homolog (Chlamydomonas)


620414
HSD17810
hydroxysteroid (17-beta) dehydrogenase 10


5360326
SIP1
survival of motor neuron protein interacting protein 1


5860709
C9orf9
chromosome 9 open reading frame 9


5960709
APITD1
apoptosis-inducing, TAF9-like domain 1


6100014
MRPL47
mitochondrial ribosomal protein L47


4150059
HNRNPH2
heterogeneous nuclear ribonucleoprotein H2 (H)


5820500
C1orf35
chromosome 1 open reading frame 35


3610148
EVI5L
ecotropic viral integration site 5-like


3170494
PPP2R3B
protein phosphatase 2, regulatory subunit B, beta


2810112
RRAGC
Ras-related GTP binding C


5260692
ZRSR2
zinc finger (CCCH type), RNA-binding motif and serine/arginine rich 2


10543
PNCK
pregnancy up-regulated non-ubiquitously expressed CaM kinase


940021
PEX11B
peroxisomal biogenesis factor 11 beta


5340703
KRCC1
lysine-rich coiled-coil 1


70019
SUGP2
SURP and G patch domain containing 2


7150433
TCTEX1D2
Tctexl domain containing 2


3140634
MECR
mitochondrial trans-2-enoyl-CoA reductase


4050040
TUBB3
tubulin, beta 3


940576
ZSCAN21
zinc finger and SCAN domain containing 21


4390687
POMT1
protein-O-mannosyltransferase 1


6520687
SLC7A9
solute carrier family 7 (cationic amino acid transporter, y + system), member 9


2750280
CDK5R1
cyclin-dependent kinase 5, regulatory subunit 1 (p35)


4210113
CMTM2
CKLF-like MARVEL transmembrane domain containing 2


940435
TRIM8
tripartite motif-containing 8


4850593
TRIM46
tripartite motif-containing 46


7550110
BAX
BCL2-associated X protein


1070541
MYH3
myosin, heavy chain 3, skeletal muscle, embryonic


1740576
LMF2
lipase maturation factor 2


6650593
CEL
carboxyl ester lipase (bile salt-stimulated lipase)


7050326
CDKN2D
cyclin-dependent kinase inhibitor 2D (p19, inhibits CDK4)


1430673
SDCBP2
syndecan binding protein (syntenin) 2


2600392
CENPA
centromere protein A


7380634
C20orf20
chromosome 20 open reading frame 20


1740392
COMMD10
COMM domain containing 10


3710746
OXSM
3-oxoacyl-ACP synthase, mitochondrial


7550626
BIRC5
baculoviral IAP repeat-containing 5


6020719
RAB23
RAB23, member RAS oncogene family


6400524
LOC390705
protein phosphatase 2, regulatory subunit B, beta pseudogene


5290148
GPT2
glutamic pyruvate transaminase (alanine aminotransferase) 2


3290296
MRPS14
mitochondrial ribosomal protein S14


770044
FBXO15
F-box protein 15


380079
SPATA7
spermatogenesis associated 7


4590154
ZDHHC8
zinc finger, DHHC-type containing 8


6770673
SOCS2
suppressor of cytokine signaling 2


3940309
CDAN1
congenital dyserythropoietic anemia, type I


1470348
RAGE
renal tumor antigen


3990259
TMEM91
transmembrane protein 91


730475
PIN4
protein (peptidylprolyl cis/trans isomerase) NIMA-interacting, 4 (parvulin)


5670075
PAFAH1B1
platelet-activating factor acetylhydrolase 1b, regulatory subunit 1 (45 kDa)


4670082
RGS5
regulator of G-protein signaling 5


7210438
ATRIP
ATR interacting protein


7000333
ASB6
ankyrin repeat and SOCS box-containing 6


3420180
ZNF202
zinc finger protein 202


2760181
COQ3
coenzyme Q3 homolog, methyltransferase (S. cerevisiae)


3120093
EFCAB6
EF-hand calcium binding domain 6


3140202
MYPOP
Myb-related transcription factor, partner of profilin


7380670
MYB
v-myb myeloblastosis viral oncogene homolog (avian)


6100609
UAP1L1
UDP-N-acteylglucosamine pyrophosphorylase 1-like 1


6520059
SNF8
SNF8, ESCRT-II complex subunit, homolog (S. cerevisiae)


6350070
SCNM1
sodium channel modifier 1


430402
ABCA3
ATP-binding cassette, sub-family A (ABC1), member 3


6580402
UBE2H
ubiquitin-conjugating enzyme E2H (UBC8 homolog, yeast)


6280482
NIP7
nuclear import 7 homolog (S. cerevisiae)


4260609
C2orf74
chromosome 2 open reading frame 74


6100056
HSD17810
hydroxysteroid (17-beta) dehydrogenase 10


3890561
IFT20
intraflagellar transport 20 homolog (Chlamydomonas)


5900491
ZNF34
zinc finger protein 34


4730204
FCRLB
Fc receptor-like B


450309
DDX49
DEAD (Asp-Glu-Ala-Asp) box polypeptide 49


2060274
PREB
prolactin regulatory element binding


4890692
LOC285943
hypothetical protein LOC285943


3130326
MSH5
mutS homolog 5 (E. coli)


3440403
DHDDS
dehydrodolichyl diphosphate synthase


1170121
MRPL4
mitochondrial ribosomal protein L4


2600470
WDR60
WD repeat domain 60


1690711
SNAPC2
small nuclear RNA activating complex, polypeptide 2, 45 kDa


5080367
CKLF
chemokine-like factor


730414
APOE
apolipoprotein E


3290446
RPL36
ribosomal protein L36


5900286
ZFP90
zinc finger protein 90 homolog (mouse)


7610079
HSF2BP
heat shock transcription factor 2 binding protein


4480477
SBSN
Suprabasin


540519
NAGLU
N-acetylglucosaminidase, alpha


6020209
CYTSA
cytospin A


6100072
DENND2A
DENN/MADD domain containing 2A


4890382
ILVBL
ilvB (bacterial acetolactate synthase)-like


2810082
C20orf111
chromosome 20 open reading frame 111


5220309
RILPL1
Rab interacting lysosomal protein-like 1


7040609
SIP1
survival of motor neuron protein interacting protein 1


520446
COMT
catechol-O-methyltransferase


4670021
NPEPL1
aminopeptidase-like 1


2850180
NUDT16L1
nudix (nucleoside diphosphate linked moiety X)-type motif 16-like 1


650048
MOBP
myelin-associated oligodendrocyte basic protein


3170725
C2orf79
chromosome 2 open reading frame 79


7210767
GAK
cyclin G associated kinase


240035
RUNDC3B
RUN domain containing 3B


1770519
PDRG1
p53 and DNA-damage regulated 1


2190743
RBM23
RNA binding motif protein 23


6620601
ZBTB40
zinc finger and BTB domain containing 40


3140280
C9orf6
chromosome 9 open reading frame 6


1820711
LOC100288144
hypothetical LOC100288144


6420632
MCCC1
methylcrotonoyl-CoA carboxylase 1 (alpha)


2760519
CKLF
chemokine-like factor


2490333
ZNF467
zinc finger protein 467


3890274
DPF2
D4, zinc and double PHD fingers family 2


4010452
SLC38A6
solute carrier family 38, member 6


5720154
ZBTB48
zinc finger and BTB domain containing 48


6960692
ZSCAN10
zinc finger and SCAN domain containing 10


6580075
TAF1D
TATA box binding protein (TBP)-associated factor, RNA polymerase I, D, 41 kDa


1580402
SLC35B2
solute carrier family 35, member B2


6200561
CCDC28B
coiled-coil domain containing 28B


1780095
RPL26L1
ribosomal protein L26-like 1


2100189
KCTD13
potassium channel tetramerisation domain containing 13


7610538
H1FX
H1 histone family, member X


6200253
THBS4
thrombospondin 4


3930170
CDK20
cyclin-dependent kinase 20


6560750
UBE3C
ubiquitin protein ligase E3C


870376
C9orf152
chromosome 9 open reading frame 152


4490544
LY6G6D
lymphocyte antigen 6 complex, locus G6D


1990674
NUP50
nucleoporin 50 kDa


240750
TEL02
TEL2, telomere maintenance 2, homolog (S. cerevisiae)


2630102
CCDC28B
coiled-coil domain containing 28B


7040131
DALRD3
DALR anticodon binding domain containing 3


6480209
RRAGD
Ras-related GTP binding D


6580521
UBAC2
UBA domain containing 2


7570315
MRPL45
mitochondrial ribosomal protein L45


6510397
WDR19
WD repeat domain 19


610735
LRRC43
leucine rich repeat containing 43


2190241
AP1M1
adaptor-related protein complex 1, mu 1 subunit


510370
SYCE2
synaptonemal complex central element protein 2


2360138
ATP6VOC
ATPase, H + transporting, lysosomal 16 kDa, V0 subunit c


4610201
SNORA10
small nucleolar RNA, H/ACA box 10


3180445
C14orf79
chromosome 14 open reading frame 79


4890647
C1orf25
chromosome 1 open reading frame 25


2810400
KLHL3
kelch-like 3 (Drosophila)


540221
NOP2
NOP2 nucleolar protein homolog (yeast)


6020458
NR2F2
nuclear receptor subfamily 2, group F, member 2


10626
TRNAU1AP
tRNA selenocysteine 1 associated protein 1


3060092
LAT2
linker for activation of T cells family, member 2


1850612
PARP2
poly (ADP-ribose) polymerase 2


3450521
ECM1
extracellular matrix protein 1


4920537
POLA2
polymerase (DNA directed), alpha 2 (70 kD subunit)


4760433
C16orf7
chromosome 16 open reading frame 7


3390373
TIMM22
translocase of inner mitochondrial membrane 22 homolog (yeast)


3710685
CARDS
caspase recruitment domain family, member 9


7100079
PHF8
PHD finger protein 8


150315
C21orf7
chromosome 21 open reading frame 7


6040703
TRIM39
tripartite motif-containing 39


6650451
MYCBP2
MYC binding protein 2


2750324
PRKCZ
protein kinase C, zeta


7400707
CIS
complement component 1, s subcomponent


1070474
P005
POC5 centriolar protein homolog (Chlamydomonas)


2350221
TSNAXIP1
translin-associated factor X interacting protein 1


2630561
RPL6
ribosomal protein L6


6330440
MSH5
mutS homolog 5 (E. coli)


4280048
WFDC3
WAP four-disulfide core domain 3


4860367
ATRIP
ATR interacting protein


1990196
DACT3
dapper, antagonist of beta-catenin, homolog 3 (Xenopus laevis)


4120427
PDX1
pancreatic and duodenal homeobox 1


240333
ETS1
v-ets erythroblastosis virus E26 oncogene homolog 1 (avian)


4850300
ARHGAP39
Rho GTPase activating protein 39


1710639
RBM4B
RNA binding motif protein 4B


6620278
ADI1
acireductone dioxygenase 1


3930577
HMGN2
high-mobility group nucleosomal binding domain 2


2490377
C17orf71
chromosome 17 open reading frame 71




asparagine-linked glycosylation 8, alpha-1,3-glucosyltransferase homolog


4850632
ALG8
(S. cerevisiae)


1780450
ASB6
ankyrin repeat and SOCS box-containing 6


2710546
COG4
component of oligomeric golgi complex 4


6620634
UBE2S
ubiquitin-conjugating enzyme E2S


5310358
TIA1
TIA1 cytotoxic granule-associated RNA binding protein


3610735
F12
coagulation factor XII (Hageman factor)


1500678
TFPT
TCF3 (E2A) fusion partner (in childhood Leukemia)


5220152
TMEM55B
transmembrane protein 55B


4260441
CLEC3B
C-type lectin domain family 3, member B


610358
PGS1
phosphatidylglycerophosphate synthase 1


6350181
LOC730183
hypothetical protein LOC730183


2100209
FAM24B
family with sequence similarity 24, member B


1070053
SUGP2
SURP and G patch domain containing 2


4590424
PDCD2L
programmed cell death 2-like


2470296
ZSCAN16
zinc finger and SCAN domain containing 16


1340411
CAMSAP1
calmodulin regulated spectrin-associated protein 1


4210500
PSG4
pregnancy specific beta-1-glycoprotein 4


6100196
ZNF653
zinc finger protein 653


270053
GABPA
GA binding protein transcription factor, alpha subunit 60 kDa


6770097
UBTD1
ubiquitin domain containing 1


4220184
LOC100289410
hypothetical LOC100289410


7330674
KIFC1
kinesin family member C1


3400202
GPATCH1
G patch domain containing 1


4900044
CDC7
cell division cycle 7 homolog (S. cerevisiae)


1470379
CCDC116
coiled-coil domain containing 116


650626
C16orf68
chromosome 16 open reading frame 68


1300521
INSM2
insulinoma-associated 2


2340180
TAGLN2
transgelin 2


2370064
ASGR1
asialoglycoprotein receptor 1


1070360
APITD1
apoptosis-inducing, TAF9-like domain 1


10075
ZNF768
zinc finger protein 768


5260639
ZNF330
zinc finger protein 330


5360682
IL17F
interleukin 17F


7570500
COQ5
coenzyme Q5 homolog, methyltransferase (S. cerevisiae)


3190246
CHN2
chimerin (chimaerin) 2


6350626
CCDC120
coiled-coil domain containing 120


6330358
C9orf98
chromosome 9 open reading frame 98


3800068
GTF2E1
general transcription factor IIE, polypeptide 1, alpha 56 kDa


6180598
NDUFAF1
NADH dehydrogenase (ubiquinone) 1 alpha subcomplex, assembly factor 1


4850674
PSAT1
phosphoserine aminotransferase 1


6590520
ZNF839
zinc finger protein 839


1090687
POLR1D
polymerase (RNA) I polypeptide D, 16 kDa


2680020
DAGLB
diacylglycerol lipase, beta


3440315
PPP2R3B
protein phosphatase 2, regulatory subunit B, beta


4260731
STMN1
stathmin 1


1450707
RING1
ring finger protein 1


380373
BANP
BTG3 associated nuclear protein


5900112
ZNF830
zinc finger protein 830


7160414
C7orf63
chromosome 7 open reading frame 63


4570500
CPNE1
copine I


2060427
SBDSP1
Shwachman-Bodian-Diamond syndrome pseudogene 1


4570292
PHF12
PHD finger protein 12


3710068
WARS
tryptophanyl-tRNA synthetase


4260044
SQSTM1
sequestosome 1


730687
TCHP
trichoplein, keratin filament binding


4900431
STUB1
STIP1 homology and U-box containing protein 1


6290239
ATP6V1B1
ATPase, H + transporting, lysosomal 56/58 kDa, V1 subunit B1


6620669
C3orf23
chromosome 3 open reading frame 23


5080431
NBPF3
neuroblastoma breakpoint family, member 3


510112
PTAFR
platelet-activating factor receptor


3520746
MTTP
microsomal triglyceride transfer protein


7560328
RAVER1
ribonucleoprotein, PTB-binding 1


3930754
PRR3
proline rich 3


2000100
ABI2
abl-interactor 2


5270239
TUBD1
tubulin, delta 1


460768
LOC285943
hypothetical protein LOC285943


5700722
TSSC1
tumor suppressing subtransferable candidate 1


1190129
SLMO2
slowmo homolog 2 (Drosophila)


1400601
TOX2
TOX high mobility group box family member 2


520114
PET112L
PET112-like (yeast)


5900020
C10orf110
chromosome 10 open reading frame 110


5860452
BNIP1
BCL2/adenovirus E1B 19 kDa interacting protein 1


6350075
CENPBD1
CENPB DNA-binding domains containing 1


4850296
HCFC1
host cell factor Cl (VP16-accessory protein)


5050735
TMEM62
transmembrane protein 62


3310681
LOC391578
MAF1 homolog (S. cerevisiae) pseudogene


7050612
TIAM2
T-cell lymphoma invasion and metastasis 2


10187
CNPY3
canopy 3 homolog (zebrafish)


3890398
WBP2
WW domain binding protein 2




pterin-4 alpha-carbinolamine dehydratase/dimerization cofactor of


4860184
PCBD1
hepatocyte nuclear factor 1 alpha


130037
PHF5A
PHD finger protein 5A


6350292
C1orf50
chromosome 1 open reading frame 50


6420296
MRPL2
mitochondrial ribosomal protein L2


7510687
SRCAP
Snf2-related CREBBP activator protein


5820333
RPUSD2
RNA pseudouridylate synthase domain containing 2


2190010
RACGAP1
Rac GTPase activating protein 1


2570288
SH3YL1
SH3 domain containing, Ysc84-like 1 (S. cerevisiae)


2070201
CCKBR
cholecystokinin B receptor


1570129
TRAFD1
TRAF-type zinc finger domain containing 1


610670
ISL2
ISL LIM homeobox 2


6370593
BCL7B
B-cell CLL/lymphoma 7B


4860291
HMGXB3
HMG box domain containing 3


2360601
NAA25
N(alpha)-acetyltransferase 25, NatB auxiliary subunit









With these genes also Gene ontology analyses were performed. The results are shown in Table 6. As can be seen, TTV miRNA might be deregulating several pathways important for cancer progression.









TABLE 6







Gene enrichment analysis












Category
Term
Genes
Count
%
P-Value















SP_PIR_KEYWORDS
ribosomal protein

custom-character

12
0.4
4.4E−4


SP_PIR_KEYWORDS
alternative

custom-character

159
5.0
7.4E−4



splicing






SP_PIR_KEYWORDS
ribonucleoprotein

custom-character

14
0.4
1.2E−3


SP_PIR_KEYWORDS
coiled coil

custom-character

54
1.7
1.3E−3


SP_PIR_KEYWORDS
zinc-finger

custom-character

46
1.4
3.2E−3


SP_PIR_KEYWORDS
nucleus

custom-character

95
3.0
5.5E−3


SP_PIR_KEYWORDS
cell cycle

custom-character

17
0.5
6.5E−3


SP_PIR_KEYWORDS
microtubule

custom-character

11
0.3
7.0E−3


SP_PIR_KEYWORDS
s-adenosyl-1-

custom-character

6
0.2
3.3E−2



methionine






SP_PIR_KEYWORDS
chromosomal

custom-character

7
0.2
4.0E−2



protein






SP_PIR_KEYWORDS
ligase

custom-character

11
0.3
4.0E−2


SP_PIR_KEYWORDS
cell division

custom-character

10
0.3
4.0E−2


SP_PIR_KEYWORDS
cytoplasm

custom-character

71
2.2
4.2E−2


SP_PIR_KEYWORDS
williams-beuren

custom-character

3
0.1
4.6E−2



syndrome






SP_PIR_KEYWORDS
zinc

custom-character

49
1.5
4.9E−2


SP_PIR_KEYWORDS
mitochondrion

custom-character

22
0.7
5.3E−2


SP_PIR_KEYWORDS
transit peptide

custom-character

14
0.4
7.1E−2


SP_PIR_KEYWORDS
acetylation

custom-character

56
1.7
7.6E−2


SP_PIR_KEYWORDS
plasma

custom-character

5
0.2
7.7E−2









Example 8
Screening the TCGA for TTV miRNA Associated with Cancer

The TCGA (The Cancer Genome Atlas) is an initiative of the NIH. The data stored within this repository consist of sequencing datasets from cancer and normal tissue extracted from patients. In this regard, the data extracted by this analysis can be considered as “in vivo”, since it comes directly from tumors of patients. In an effort to establish a relationship between TTV miRNA and cancer, the small-RNA sequencing data for colon adenocarcinoma, lung adenocarcinoma, breast carcinoma and hepatocellular carcinoma from the TCGA initiative was mapped against all the full-length TTV genomes included in the NCBI database plus several newly identified TTV from the inventors's laboratory. To exclude artifacts, miRNA taken into consideration complied to the following: mapping with 2 mismatches or less to TTV genomes and mapping in a region where the RNA is predicted to acquire the characteristic hairpin structure of a pre-miRNA (Table 7).












Small RNA sequencing datasets from patients with different malignancies were screened for the presence of TTV miRNA. TTV positive patients


were considered when having at least one read mapping to a TTV miRNA. Patients positive for TTV encoding a mature miRNA presenting the “consensus


sequence” where considered when having at least one read mapping to a TTV strain that encodes for a mature miRNA that contains the “consensus


sequence”. The “consensus sequence“, the TTV strains found in the TCGA containing the consensus sequence and the mature miRNA form these TTV


strains are listed in Table 2B.+













Total


Patients positive for TTV encoding




number of


a mature miRNA




patients
TTV positive
% of TTV positive
presenting the



Cancer type
screened
patients
patients
“consensus sequence”
%















Colon carcinoma
421
76
18,05225653
53
12,5890736


Hepatocellular
147
19
12,92517007
9
6,12244898


carcinoma







Lung
213
25
11,7370892
9
4,22535211


adenocarcinoma







(Ongoing)







Breast
141
11
7,80141844
1
0,70921986


carcinoma(ongoing)









TTV-HD14a-2-3p analogous miRNA (meaning, with 80% homology or more in the nucleotides from 1 to 7 of the miRNA, comprising the seed) (Table 2B) were found at higher frequency in colon cancer patients than in the other three type of cancer being screened so far.


The slight differences in the seed of the miRNA shown in Table 2B in respect to TTV-HD14a-mir-2-3p do not alter the predicted binding sites in APC mRNA. Thus, the miRNA shown in Table 2Bare also able to down-regulate APC (Table 8).


Table 8

It is shown how, despite the single nucleotide polymorphisms (SNP) found in the seed of diverse TTV miRNA's respect to the TTV-HD14a-mir-2-3p seed, the predicted interaction site with APC mRNA shown in FIG. 3 (A.4) would be conserved. (B) Here the inventors show


how the most conserved seed motif (AUCCUC) has three additional possible interaction sites within APC mRNA in addition to the previously described for TTV-HD14a-mir-2-3p.


Positions are shown in relation to the nucleotide number of APC transcript variant 2 mRNA (NCBI accession number: NM 001127510.2, SEQ ID NO:82)


Seed interaction sites are shown in black bold letters.


Sequence corresponding to APC mRNA are shown in italicized letters.









TABLE 8





Extrablatt







A- Conserved interaction site within APC miRNA of the TTV mRNA's containg a


similar seed to TTV-HD14a-mir-2-3p










Position within APC



Seed
mRNA (gi|306922385/ref|



Sequences
NM_001127510.21)
Interaction sites





AUCCCU
nt 5049-5069
APC   5′ U  UU    ---    G      A 3′




          AG  UUAC   ACCG GGGAUG




          UC  AGUG   UGGU CCCUAC




miRNA 3′ -  UC    CAC    -        5′





AUCCUC
nt 5045-5069
AFC   5′  A   U      ACA   G      A 3′




           UGU AGUUUU   CCG GGGAUG




miRNA      ACA GCAAGG   GGC UCCUAC




      3′ AC   U      C--          - 5′










B- Additional interaction sites with APC mRNA created by the transition of the


fifth nucleotide of the TTV-HD14a-mir-2-36 seed from C to T(U)










Position within APC



Seed
mRNA (gi|306922385/ref|



Sequences
NM_001127510.21)
Interaction sites





AUCCUC
nt 10347-10360
APC   5′ ----------A   CA       A 3′




                    GAU  GAGGGUG




                    CUA  CUCCUAC




miRNA 3′ AGUCCAGUGCA   --         5′





AUCCUC
nt 7890-7925
APC   5′ A     AAUCCA    AAAAGCAAAAAG        A 3′




           UCAG      GUGA            UGAGGAUG




           AGUC      CACU            ACUCCUAC




miRNA 3′ -     CAGUG     ------------          5′





AUCCUC
nt 8099-8129
APC   5′ -U  -   C  CUGUUUCUAAACA       U- 3′




           GG CAC UG             GAGGAUG




           CC GUG AC             CUCCUAC




miRNA 3′ GU  A   C  UA-----------          5′









This supports a causal role for this type of TTV miRNA of Table 2B in this disease or, at least, an association between them.


A significant increase in TTV load in cancer patients compared to normal controls has been demonstrated [44]. In the case of colon cancer, this increase in viral load would presumably be represented mainly by the TTV strains encoding for miRNA analogous to that of TTV-HD14a.


Example 9
Wnt Activation by a TTV miRNA

APC exerts its tumor suppressor activity by down-regulating canonical Wnt pathway, although other putative roles for this protein have been suggested. This effect is mediated by its participation in the “destruction complex”. The destruction complex is formed by APC, AXIN, and GSK3-beta, among others. This complex phosphorylates beta-catenin, allowing its ubiquitination and degradation by the proteasome. In the absence of any of the proteins of the destruction complex, its function is impaired. The final outcome is the cytoplasmic accumulation of beta-catenin, that can be then translocated into the nucleus, where it activates transcription of its target genes, together with the transcription factor TCF4 or LEF1. It is well documented that this pathway is upregulated in several malignancies, as well as in other diseases. Consequently, we thought that the APC down-regulation could lead to an activation of Wnt pathway. To check this, a gene reporter approach was used. HEK293TT cells were transfected with the plasmids encoding for TTV-HD14a miRNA, with the TTV-HD14a full genome, or mock transfected, together with a plasmid encoding for Firefly luciferase under the control of a minimum promoter and seven binding sites for the TCF4/beta catenin complex (TOPFLASH plasmid). Additionally, Renilla Luciferase under the control of CMV promoter was used for normalization purposes. An upregulation of wnt pathway resulted in cells with the plasmid encoding for the sense-miRNA or with the TTV-HD14a virus in comparison to mock transfected cells (FIG. 5).


CONCLUSIONS

The above results highlight the importance of the experimental findings as diagnostic method for TTV infection and identifies TTV miRNA as promising target for cancer prevention, treatment or recurrence.


It is known that TTV replicate in several tissues [21], but they only replicate in peripheral blood mononuclear cells when these cells are activated [42]. It was recently demonstrated that TTV replicate more efficiently when they are co-infecting cells with Epstein Barr virus [41].


Very few things are known about the molecular mechanisms mediating infection, replication and virus-host interaction of the TTVs. Here, the inventors provide evidence which supports that several TTVs encode miRNA and that some of them have a biologically relevant role, especially in relation to cancer development.


It has been shown in the present invention that the encoded miRNA of TTV-HD14a and Table 2B can down-regulate APC, an important tumor suppressor. Hence, being infected with any of the TTV's encoding for the miRNA's included in the present invention could represent a risk factor for the development of colon cancer, as well as many other cancer types.


To support these findings, the inventors detected TTV miRNA's that down-regulate APC in a higher frequency in colon adenocarcinoma patients in comparison to other three types of cancer (lung adenocarcinoma, hepatocellular carcinoma and breast invasive carcinoma). Consequently, TTV miRNA's presented here represent a target for the prevention of colon cancer, as well as a putative biomarker for the early detection of a subset of these cancers.


REFERENCES



  • 1. Nishizawa, T., Okamoto, H., Konishi, K., Yoshizawa, H., Miyakawa, Y.& Mayumi, M. (1997). A novel DNA virus (TTV) associated with elevated transaminase levels in posttransfusion hepatitis of unknown etiology. Biochem Biophys Res Commun 241, 92-97.

  • 2. Okamoto, H., Nishizawa, T., Kato, N., Ukita, M., Ikeda, H., Iizuka, H., Miyakawa, Y. & Mayumi, M. (1998). Molecular cloning and characterization of a novel DNA virus (TTV) associated with posttransfusion hepatitis of unknown etiology. Hepatol Res 10, 1-16.

  • 3. Miyata, H., Tsunoda, H., Kazi, A., Yamada, A., Khan, M. A., Murakami, J., Kamahora, T., Shiraki, K. & Hino, S. (1999). Identification of a novel GC-rich 113-nucleotide region to complete the circular, singlestranded DNA genome of TT virus, the first human circovirus. J Virol 73, 3582-3586.

  • 4. Suzuki T, Suzuki R, Li J, Hijikata M, Matsuda M, Li T C, Matsuura Y, Mishiro S, Miyamura T (2004) Identification of basal promoter and enhancer elements in an untranslated region of the TT virus genome. J Virol 78: 10820-10824

  • 5. Sébastien Pfeffer, Mihaela Zavolan, Friedrich A. Grässer, Minchen Chien, James J. Russo, Jingyue Ju, Bino John, Anton J. Enright, Debora Marks, Chris Sander, and Thomas Tuschl (2004) Identification of Virus-Encoded MicroRNAs Science 304 (5671), 734. [DOI: 10.1126/science.10 96781]

  • 6. Aleksandra Helwak, Grzegorz Kudla, Tatiana Dudnakova, David Tollervey (2013) Mapping the Human miRNA Interactome by CLASH Reveals Frequent Noncanonical Binding. Cell 153, Issue 3, 654-665, ISSN 0092-8674

  • 7. Lewis B P, Shih I H, Jones-Rhoades M W, Bartel D P, Burge C B (2003) Prediction of mammalian microRNA targets. Cell 115: 787-798.

  • 8. J. Brennecke, A. Stark, R. B. Russell, S. M. Cohen (2005) Principles of microRNA-target recognition PLoS Biol., 3, p. e85

  • 9. Meister, G. et al (2004) Human Argonaute2 mediates RNA cleavage targeted by miRNAs and siRNAs. Mol. Cell 15, 185-197

  • 10. Pillai, R. S., Artus, C. G. & Filipowicz, W (2004) Tethering of human Ago proteins to mRNA mimics the miRNA-mediated repression of protein synthesis. RNA 10, 1518-1525

  • 11. Eulalio, A., Huntzinger, E. & Izaurralde, E (2008) Getting to the root of miRNA-mediated gene silencing. Cell 132, 9-14.

  • 12. Filipowicz, W., Bhattacharyya, S. N. & Sonenberg, N (2008) Mechanisms of post-transcriptional regulation by microRNAs: are the answers in sight? Nature Rev. Genet. 9, 102-114

  • 13. Kozomara A, Griffiths-Jones S (2011) miRBase: integrating microRNA annotation and deep-sequencing data. Kozomara A, Griffiths-Jones S. N 2011 39(Database Issue):D152-D157

  • 14. Griffiths-Jones S, Saini H K, van Dongen S, Enright A J. (2008) miRBase: tools for microRNA genomics. Nucleic Acids Res 36 (Database Issue):D154-D158

  • 15. Griffiths-Jones S, Grocock R J, van Dongen S, Bateman A, Enright A J. (2006) miRBase: microRNA sequences, targets and gene nomenclature. Nucleic Acids Res 34 (Database Issue):D140-D144

  • 16. The microRNA Registry.Griffiths-Jones S. (2004) Nucleic Acids Res 32(Database Issue):D109-D111

  • 17. Sullivan C S, Grundhoff A T, Tevethia S, Pipas J M, Ganem D (2005) SV40-encoded microRNAs regulate viral gene expression and reduce susceptibility to cytotoxic T cells. Nature 435:682-86

  • 18. Cullen, B. R. (2013). MicroRNAs as mediators of viral evasion of the immune system. Nature Immunology, 14(3), 205-210.

  • 19. Bauman, Y., Nachmani, D., Vitenshtein, A., Tsukerman, P., Drayman, N., Stern-Ginossar, N., . . . & Mandelboim, O. (2011). An identical miRNA of the human JC and BK polyoma viruses targets the stress-induced ligand ULBP3 to escape immune elimination. Cell host & microbe, 9(2), 93-102

  • 20. Vereide, D. T., Seto, E., Chiu, Y. F., Hayes, M., Tagawa, T., Grundhoff, A., . . . & Sugden, B. (2013). Epstein-Barr virus maintains lymphomas via its miRNAs.Oncogene.

  • 21. Okamoto, H., T. Nishizawa, M. Takahashi, S. Asabe, F. Tsuda, and A. Yoshikawa (2001) Heterogeneous distribution of TT virus of distinct genotypes in multiple tissues from infected humans. Virology 288:358-368.

  • 22. I. K. Mushahwar, J. C. Erker, A. S. Muerhoff, T. P. Leary, J. N. Simons, L. G. Birkenmeyer, M. L. Chalmers, T. J. Pilot-Matias, S. M. Desai (1999) Molecular and biophysical characterization of TT virus: Evidence for a new virus family infecting humans. Proc. Natl. Acad. Sci. 96: 3177-3182.

  • 23. Irving, W. L., J. K. Ball, S. Berridge, R. Curran, A. M. Grabowska, C. L. Jameson, K. R. Neal, S. D. Ryder, and B. J. Thomson (1999) TT virus infection in patients with hepatitis C: frequency, persistence and sequence heterogeneity. J. Infect. Dis. 180:27-34.

  • 24. de Villiers E M, Borkosky S S, Kimmel R, Gunst K, Fei J W (2011) The diversity of torque teno viruses: in vitro replication leads to the formation of additional replication-competent subviral molecules. J. Virol. 85:7284-7295.

  • 25. Jelcic I, Hotz-Wagenblatt A, Hunziker A, Zur Hausen H,de Villiers E M (2004) Isolation of multiple TT virus genotypes from spleen biopsy tissue from a Hodgkin's disease patient: genome reorganization and diversity in the hypervariable region. J. Virol. 78:7498-7507.

  • 26. Leppik L., Gunst K., Lehtinen M., Dillner J., Streker K., de Villiers E. M. (2007) In vivo and in vitro intragenomic rearrangement of TT viruses. J Virol81, 9346-9356.

  • 27. Ninomiya, M., et al (2007) Identification and genomic characterization of a novel human torque teno virus of 3.2 kb. J. Gen. Virol. 88:1939-1944.

  • 28. Ninomiya, M., M. Takahashi, T. Nishizawa, T. Shimosegawa, and H. Okamoto (2008) Development of PCR assays with nested primers specific for differential detection of three human anelloviruses and early acquisition of dual or triple infection during infancy. J. Clin. Microbiol. 46:507-514.

  • 29. Kim, D. H., Satrom, P., Sneve, O., & Rossi, J. J (2008). MicroRNA-directed transcriptional gene silencing in mammalian cells. Proceedings of the National Academy of Sciences, 105(42), 16230-16235.

  • 30. Sepramaniam, S., Ying, L. K., Armugam, A., Wintour, E. M., & Jeyaseelan, K (2012). MicroRNA-130a Represses Transcriptional Activity of Aquaporin 4 M1 Promoter. Journal of Biological Chemistry, 287(15), 12006-12015.

  • 31. Younger S T, Corey D R (2011) Transcriptional gene silencing in mammalian cells by miRNA mimics that target gene promoters. Nucleic Acids Res; 39:5682-91

  • 32. Huang V, Place R F, Portnoy V, Wang J, Qi Z, Jia Z, et al. Upregulation of Cyclin B1 by miRNA and its implications in cancer. Nucleic Acids Res 2011

  • 33. Place R F, Li L C, Pookot D, Noonan E J, Dahiva R. MicroRNA-373 induces expression of genes with complementary promoter sequences. Proc Natl Acad

  • 34. Tyagi, S., Vaz, C., Gupta, V., Bhatia, R., Maheshwari, S., Srinivasan, A., & Bhattacharya, A. (2008). CID-miRNA: a web server for prediction of novel miRNA precursors in human genome. Biochemical and biophysical research communications, 372(4), 831-834.

  • 35. Grundhoff, A. (2011). Computational prediction of viral miRNAs. In Antiviral RNAi (pp. 143-152). Humana Press.

  • 36. Grundhoff, A., Sullivan, C. S., & Ganem, D. (2006). A combined computational and microarray-based approach identifies novel microRNAs encoded by human gamma-herpesviruses. Rna, 12(5), 733-750.

  • 37. Gkirtzou, K., Tsamardinos, I., Tsakalides, P., & Poirazi, P. (2010). MatureBayes: a probabilistic algorithm for identifying the mature miRNA within novel precursors. PloS one, 5(8), e11843.

  • 38. M. Maragkakis; P. Alexiou; G. L. Papadopoulos; M. Reczko; T. Dalamagas; G. Giannopoulos; G. Goumas; E. Koukis; K. Kourtis; V. A. Simossis; P. Sethupathy; T. Vergoulis; N. Koziris; T. Sellis; P. Tsanakas; A. G. Hatzigeorgiou. Accurate microRNA target prediction correlates with protein repression levels. BMC Bioinformatics 2009, 10:295

  • 39.2/ M. Maragkakis; M. Reczko; V. A. Simossis; P. Alexiou; G. L. Papadopoulos; T. Dalamagas; G. Giannopoulos; G. Goumas; E. Koukis; K. Kourtis; T. Vergoulis; N. Koziris; T. Sellis; P. Tsanakas; A. G. Hatzigeorgiou. DIANA-microT web server: elucidating microRNA functions through target prediction. Nucleic Acids Research 2009 Jul. 1; 37(Web Server issue):W273-6

  • 40. Rehmsmeier, M., Steffen, P., HOchsmann, M., & Giegerich, R. (2004). Fast and effective prediction of microRNA/target duplexes. Rna, 10(10), 1507-1517

  • 41. Borkosky, S. S., Whitley, C., Kopp-Schneider, A., & Zur Hausen, H. (2012). Epstein-Barr Virus Stimulates Torque Teno Virus Replication: A Possible Relationship to Multiple Sclerosis. PloS one, 7(2), e32160

  • 42. Mariscal, L. F., López-Alcorocho, J. M., Rodrlguez-Iñigo, E., Ortiz-Movilla, N., de Lucas, S., Bartolomé, J., & Carreño, V. (2002). TT virus replicates in stimulated but not in nonstimulated peripheral blood mononuclear cells. Virology, 301(1), 121-129.

  • 43. Zur Hausen, H., & de Villiers, E. M. (2009). TT viruses: oncogenic or tumor-suppressive properties?. In TT Viruses (pp. 109-116). Springer Berlin Heidelberg.

  • 44. hong, S., Yeo, W., Tang, M. W., LIN, X. R., Mo, F., Ho, W. M.,& Johnson, P. J. (2001). Gross elevation of TT virus genome load in the peripheral blood mononuclear cells of cancer patients. Annals of the New York Academy of Sciences, 945(1), 84-92.

  • 45. Madsen, C. D., Eugen-Olsen, J., Kirk, O., Parner, J., Christensen, J. K., Brasholt, M. S.,& Krogsgaard, K. (2002). TTV viral load as a marker for immune reconstitution after initiation of HAART in HIV-infected patients. HIV Clinical Trials, 3(4), 287-295

  • 46. Thom, K., & Petrik, J. (2007). Progression towards AIDS leads to increased Torque teno virus and Torque teno minivirus titers in tissues of HIV infected individuals. Journal of medical virology, 79(1), 1-7.

  • 47. Van Es, J. H., Kirkpatrick, C., Van de Wetering, M., Molenaar, M., Miles, A., Kuipers, J., & Clevers, H. (1999). Identification of APC2, a homologue of the adenomatous polyposis coli tumour suppressor. Current biology, 9(2), 105-S2.

  • 48. Nakagawa, H., Murata, Y., Koyama, K., Fujiyama, A., Miyoshi, Y., Monden, M., & Nakamura, Y. (1998). Identification of a brain-specific APC homologue, APCL, and its interaction with β-catenin. Cancer research, 58(22), 5176-5181.

  • 49. Mokarram, P., Kumar, K., Brim, H., Naghibalhossaini, F., Saberi-Firoozi, M., Nouraie, M., & Ashktorab, H. (2009). Distinct high-profile methylated genes in colorectal cancer. PLoS One, 4(9), e7012.

  • 50. Chen, H. J., Lin, C. M., Lin, C. S., Perez-Olle, R., Leung, C. L., & Liem, R. K. (2006). The role of microtubule actin cross-linking factor 1 (MACF1) in the Wnt signaling pathway. Genes & development, 20(14), 1933-1945.

  • 51. Suozzi, K. C., Wu, X., & Fuchs, E. (2012). Spectraplakins: Master orchestrators of cytoskeletal dynamics. The Journal of cell biology, 197(4), 465-475.

  • 52. Zaoui, K., Benseddik, K., Daou, P., Salain, D., & Badache, A. (2010). ErbB2 receptor controls microtubule capture by recruiting ACF7 to the plasma membrane of migrating cells. Proceedings of the National Academy of Sciences, 107(43), 18517-18522.

  • 53. Aaltonen, L. A., Peltomaki, P., Leach, F. S., Sistonen, P., Pylkkanen, L., Mecklin, J. P., & Jen, J. (1993). Clues to the pathogenesis of familial colorectal cancer.Science, 260(5109),812-816

  • 54. Dreos, R., Ambrosini, G., Périer, R. C., & Bucher, P. (2013). EPD and EPDnew, high-quality promoter resources in the next-generation sequencing era. Nucleic acids research, 41(D1), D157-D164.

  • 55. Munemitsu, S., Albert, I., Souza, B., Rubinfeld, B., & Polakis, P. (1995). Regulation of intracellular beta-catenin levels by the adenomatous polyposis coli (APC) tumor-suppressor protein. Proceedings of the National Academy of Sciences, 92(7), 3046-3050.

  • 56. Grace, A., Butler, D., Gallagher, M., Al-Agha, R., Xin, Y., Leader, M., & Kay, E. (2002). APC gene expression in gastric carcinoma: an immunohistochemical study. Applied Immunohistochemistry & Molecular Morphology, 10(3), 221-224.

  • 57. Pérez-Sayáns, M., Suarez-Peñaranda, J. M., Herranz-Carnero, M., Gayoso-Diz, P., Barros-Angueira, F., Gándara-Rey, J. M., & García-García, A. (2012). The role of the adenomatous polyposis coli (APC) in oral squamous cell carcinoma. Oral oncology, 48(1),56-60.

  • 58. Lee, H. C., Kim, M., & Wands, J. R. (2006). Wnt/Frizzled signaling in hepatocellular carcinoma. Front Biosci, 11(5), 1901-1915.

  • 59. Reya, T.,& Clevers, H. (2005) Wnt signalling in stem cells and cancer. Nature, 434(7035), 843-850.

  • 60. Fodde, R., Smits, R., & Clevers, H. (2001). APC, signal transduction and genetic instability in colorectal cancer. Nature Reviews Cancer, 1(1), 55-67.

  • 61. Klaus, A., & Birchmeier, W. (2008). Wnt signalling and its impact on development and cancer. Nature Reviews Cancer, 8(5), 387-398.

  • 62. Chen, J., Rbcken, C., Lofton-Day, C., Schulz, H. U., Müller, O., Kutzner, N., . . . & Ebert, M. P. (2005). Molecular analysis of APC promoter methylation and protein expression in colorectal cancer metastasis. Carcinogenesis, 26(1), 37-43.

  • 63. Esteller, M., Sparks, A., Toyota, M., Sanchez-Cespedes, M., Capella, G., Peinado, M. A.,& Herman, J. G. (2000). Analysis of adenomatous polyposis coli promoter hypermethylation in human cancer. Cancer research, 60(16), 4366-4371.

  • 64. Arnold, C. N., Goel, A., Niedzwiecki, D., Dowell, J. M., Wasserman, L., Compton, C., . . . & Boland, C. R. (2004). APC promoter hypermethylation contributes to the loss of APC expression in colorectal cancers with allelic loss on 5q1. Cancer biology & therapy, 3(10),960-964.

  • 65. Samowitz, W. S., Slattery, M. L., Sweeney, C., Herrick, J., Wolff, R. K., & Albertsen, H. (2007). APC mutations and other genetic and epigenetic changes in colon cancer. Molecular cancer research, 5(2), 165-170.

  • 66. Nagel, R., le Sage, C., Diosdado, B., van der Waal, M., Vrielink, J. A. O., Bolijn, A., . . . & Agami, R. (2008). Regulation of the adenomatous polyposis coli gene by the miR-135 family in colorectal cancer. Cancer Research, 68(14), 5795-5802.

  • 67. Karreth, F. A., Tay, Y., Perna, D., Ala, U., Tan, S. M., Rust, A. G., & Pandolfi, P. P. (2011). In vivo identification of tumor-suppressive PTEN ceRNAs in an oncogenic BRAF-induced mouse model of melanoma. Cell, 147(2), 382-395.

  • 68. Liu, P., Ramachandran, S., Seyed, M. A., Scharer, C. D., Laycock, N., Dalton, W. B., & Moreno, C. S. (2006). Sex-determining region Y box 4 is a transforming oncogene in human prostate cancer cells. Cancer research, 66(8), 4011-4019.

  • 69. Bagchi, A., Papazoglu, C., Wu, Y., Capurso, D., Brodt, M., Francis, D., . . . & Mills, A. A. (2007). CHD5 Is a Tumor Suppressor at Human 1p36. Cell, 128(3), 459-475.

  • 70. Deshmukh, H., Yu, J., Shaik, J., MacDonald, T., Perry, A., Payton, J., & Nagarajan, R. (2011). Identification of transcriptional regulatory networks specific to pilocytic astrocytoma. BMC medical genomics, 4(1), 57.

  • 71. Botchkina, I. L., Rowehl, R. A., rivadeneira, D. E., karpeh, M. S., crawford, H., dufour, A., & botchkina, G. I. (2009). Phenotypic subpopulations of metastatic colon cancer stem cells: genomic analysis.Cancer Genomics-Proteomics, 6(1), 19-29.

  • 72. Revillion, F., Pawlowski, V., Hornez, L., & Peyrat, J. P. (2000). Glyceraldehyde-3-phosphate dehydrogenase gene expression in human breast cancer. European Journal of Cancer, 36(8), 1038-1042.

  • 73. Tokunaga, K., Nakamura, Y., Sakata, K., Fujimori, K., Ohkubo, M., Sawada, K., & Sakiyama, S. (1987). Enhanced expression of a glyceraldehyde-3-phosphate dehydrogenase gene in human lung cancers. Cancer research, 47(21), 5616-5619.

  • 74. Majmundar, A. J., Wong, W. J., & Simon, M. C. (2010). Hypoxia-inducible factors and the response to hypoxic stress. Molecular cell, 40(2), 294-309.

  • 75. Semenza, G. L. (2003). Targeting HIF-1 for cancer therapy. Nature Reviews Cancer, 3(10), 721-732.

  • 76. Buck, C. B., Thompson, C. D., Pang, Y. Y., Lowy, D. r., Schiller J. T. (2005) Maturation of papillomavirus capsids. J Virology 79(5), 2839-2846.

  • 77. Okamoto H., (2009). TT viruses in animals. Curr Top Microbiol Immunol 331:35-52.

  • 78. Kincaid, R. P., Burke, J. M., Cox, J. M., De Villiers, E. M., Sullivan C. S. (2013) A human Torque Teno virus encodes a miRNA that inhibits interferon signalling.PLoS Pathog 9(12): e1003818. doi:10.1371/journal.ppat.1003818

  • 79. Valeri N., et Al. (2014) MicroRNA-135b Promotes Cancer Progression by Acting as a Downstream Effector of Oncogenic Pathways in Colon Cancer. Cancer Cell, Volume 25, Issue 4, 469-483

  • 80. Farh K. K-H., et Al. (2005) The Widespread Impact of Mammalian MicroRNAs on mRNA Repression and Evolution. Science, Vol. 310 no. 5755, 1817-1821.

  • 81. Stenvang, J., et al., Inhibition of microRNA function by antimiR oligonucleotides. Silence, 2012. 3(1): p. 1.

  • 82 Haraguchi, T., Y. Ozaki, and H. Iba, Vectors expressing efficient RNA decoys achieve the long-term suppression of specific microRNA activity in mammalian cells. Nucleic acids research, 2009: p. gkp040.

  • 83. Bak, R. O., et al., Potent microRNA suppression by RNA Pol II-transcribed ‘Tough Decoy’inhibitors. RNA, 2013. 19(2): p. 280-293.

  • 84. Mingozzi, F. and K. A. High, Therapeutic in vivo gene transfer for genetic disease using AAV: progress and challenges. Nature reviews genetics, 2011. 12(5): p. 341-355.

  • 85. Cheng, C. J., et al., MicroRNA silencing for cancer therapy targeted to the tumour microenvironment. Nature, 2014.

  • 86. Mitchell, P. S., et al., Circulating microRNAs as stable blood-based markers for cancer detection. Proceedings of the National Academy of Sciences, 2008. 105(30): p. 10513-10518.


Claims
  • 1. A TTV miRNA encoded by a torque teno virus (TTV) polynucleic acid comprising: (a) a nucleotide sequence depicted in Table 1, 2a or 2b;(b) a nucleotide sequence having at least 60% identity to the nucleotide sequence of (a) and containing the nucleotide sequence CATCCYY (with Y: C or T); or(c) a fragment of the nucleotide sequence of (a) or (b) and containing the nucleotide sequence CATCCYY (with Y: C or T);
  • 2. The TTV miRNA of claim 1, wherein the miRNA is complementary to the polynucleic acid of claim 1 and comprises the nucleotide sequence CAUCCYY (with Y: C or U).
  • 3. The TTV miRNA of claim 2, wherein the miRNA consists of 19 to 29 nt.
  • 4. The TTV miRNA of claim 1, wherein the miRNA is a mature TTV molecule derived from a pre-miRNA sequence comprising: (a) a nucleotide sequence underlined in Table 2a or 2b;(b) a nucleotide sequence having at least 60% identity to the nucleotide sequence of (a) and containing the nucleotide sequence CATCCYY (with Y: C or T);(c) a fragment of the nucleotide sequence of (a) or (b) and containing the nucleotide sequence CATCCYY (with Y: C or T);(d) a nucleotide sequence of Table 1;(e) a nucleotide sequence having at least 80% identity to the nucleotide sequence of (d) and containing the nucleotide sequence CAUCCYY (with Y: C or U);(f) a fragment of the nucleotide sequence of (e) or (f) and containing the nucleotide sequence CAUCCYY (with Y: C or U); or(g) a nucleotide sequence being complementary to a nucleotide sequence of (a) to (f).
  • 5. A labelled oligonucleotide probe being capable of acting as a hybridization probe for specific detection of a nucleic acid of a certain TTV isolate and comprising 5 to 50 nucleotides complementary to a nucleotide sequence selected from (a) a nucleotide sequence in Table 1, Table 2a or 2b;(b) a nucleotide sequence having at least 60% identity to the nucleotide sequence of (a) and containing the nucleotide sequence CATCCYY (with Y: C or T) or CAUCCYY (with Y: C or U), respectively;(c) a fragment of the nucleotide sequence of (a) or (b) and containing the nucleotide sequence CATCCYY (with Y: C or T) or CAUCCYY (with Y: C or U), respectively; or(d) a nucleotide sequence being complementary to a nucleotide sequence of (a), (b) or (c).
  • 6. A vector comprising a TTV polynucleic acid selected from: (a) a nucleotide sequence in Table 1, Table 2a or 2b;(b) a nucleotide sequence having at least 60% identity to the nucleotide sequence of (a) and containing the nucleotide sequence CATCCYY (with Y: C or T) or CAUCCYY (with Y: C or U), respectively;(c) a fragment of the nucleotide sequence of (a) or (b) and containing the nucleotide sequence CATCCYY (with Y: C or T) or CAUCCYY (with Y: C or U), respectively; or(d) a nucleotide sequence being complementary to a nucleotide sequence of (a), (b) or (c).
  • 7. A method of diagnosing colon cancer comprising the steps of: (a) isolating miRNA from a patients sample;(b) sequencing the miRNA selected in step (a); and(c) determining if a miRNA selected from the miRNAs is complementary to a sequence shown in Table 2B is present in the sample, whereas the presence of an miRNA complementary to a sequence shown in Table 2B indicates colon cancer.
  • 8. A method of delivering a lead component for the development of medicament for treatment of colorectal cancer to a patient suffering from colorectal cancer comprising the step of administering an effective amount of an inhibitor of the miRNA of claim 1.
  • 9. The method of claim 8, wherein the inhibitor is selected from the group consisting of an anti-miR, a miRNA spounge and a tough decoy inhibitor.
  • 10. The method of claim 8, wherein a pHILP construct is administered which comprising an inhibitor of a miRNA of claim 1 attached thereto.
Priority Claims (2)
Number Date Country Kind
13003062.0 Jun 2013 EP regional
PCT/EP2014/062251 Jun 2014 EP regional
Parent Case Info

This application is a continuation of PCT/EP2014/078346, filed on Dec. 17, 2014; which claims the priority of PCT/EP2014/062251, filed on Jun. 12, 2014. This application is also a continuation-in-part of PCT/EP2014/062251, filed on Jun. 12, 2014, which claims the priority of EP 13003062.0, filed on Jun. 14, 2013. The contents of the above-identified applications are incorporated herein by reference in their entireties.

Related Publications (1)
Number Date Country
20160160216 A1 Jun 2016 US
Continuations (1)
Number Date Country
Parent PCT/EP2014/078346 Dec 2014 US
Child 14966110 US
Continuation in Parts (1)
Number Date Country
Parent PCT/EP2014/062251 Jun 2014 US
Child PCT/EP2014/078346 US