Patent Description:
In examining the structure and physiology of an organism, tissue or cell, it is often desirable to determine its genetic content. The genetic framework of an organism is encoded in the double-stranded sequence of nucleotide bases in the deoxyribonucleic acid (DNA) which is contained in the somatic and germ cells of the organism. The genetic content of a particular segment of DNA, or genes, is typically manifested upon production of the protein which the gene encodes. In order to produce a protein, a complementary copy of one strand of the DNA double helix is produced by RNA polymerase enzymes, resulting in a specific sequence of ribonucleic acid (RNA). This particular type of RNA, since it contains the genetic message from the DNA for production of a protein, is called messenger RNA (mRNA).

Within a given cell, tissue or organism, there exist myriad mRNA species, each encoding a separate and specific protein. This fact provides a powerful tool to investigators interested in studying genetic expression in a tissue or cell. mRNA molecules may be isolated and further manipulated by various molecular biological techniques, thereby allowing the elucidation of the full functional genetic content of a cell, tissue or organism.

One common approach to the study of gene expression is the production of complementary DNA (cDNA) clones. In this technique, the mRNA molecules from an organism are isolated from an extract of the cells or tissues of the organism. This isolation often employs solid chromatography matrices, such as cellulose or agarose, to which oligomers of thymidine (T) have been complexed. Since the <NUM>' termini on most eukaryotic mRNA molecules contain a string of adenosine (A) bases, and since A base pairs with T, the mRNA molecules can be rapidly purified from other molecules and substances in the tissue or cell extract. From these purified mRNA molecules, cDNA copies may be made using the enzyme RT, which results in the production of single-stranded cDNA molecules. This reaction is typically referred to as the first strand reaction. The single-stranded cDNAs may then be converted into a complete double-stranded DNA copy (i.e. a double-stranded cDNA) of the original mRNA (and thus of the original double-stranded DNA sequence, encoding this mRNA, contained in the genome of the organism) by the action of a DNA polymerase. The protein-specific double-stranded cDNAs can then be inserted into a plasmid or viral vector, which is then introduced into a host bacterial, yeast, animal or plant cell. The host cells are then grown in culture media, resulting in a population of host cells containing (or in many cases, expressing) the gene of interest.

This entire process, from isolation of mRNA from a source organism or tissue to insertion of the cDNA into a plasmid or vector to growth of host cell populations containing the isolated gene, is termed "cDNA cloning. " The set of cDNAs prepared from a given source of mRNAs is called a "cDNA library. " The cDNA clones in a cDNA library correspond to the genes transcribed in the source tissue. Analysis of a cDNA library can yield much information on the pattern of gene expression in the organism or tissue from which it was derived.

Moloney Murine Leukemia Virus (M-MLV) RT is one of the retroviral RT which has been studied in the past. It contains a single subunit of <NUM> kDa with RNA-dependent DNA polymerase and RNase H activity. This enzyme has been cloned and expressed in a fully active form in E. Human Immunodeficiency Virus (HIV) RT is a heterodimer of p66 and p51 subunits in which the smaller subunit is derived from the larger by proteolytic cleavage. The p66 subunit has both a RNA-dependent DNA polymerase and an RNase H domain, while the p51 subunit has only a DNA polymerase domain. Active HIV p66/p51 RT has been cloned and expressed successfully in a number of expression hosts, including E. Within the HIV p66/p51 heterodimer, the <NUM>-kD subunit is catalytically inactive, and the <NUM>-kD subunit has both DNA polymerase and RNase H activity.

An important factor which influences the efficiency of reverse transcription is the ability of RNA to form secondary structures (loops) or the presence of highly stable GC zones. Such secondary structures can form, for example, when regions of RNA molecules have sufficient complementarity to hybridize and form double stranded RNA. Generally, the formation of RNA secondary structures can be reduced by raising the temperature of solutions which contain the RNA molecules. Thus, in many instances, it is necessary to reverse transcribe RNA at high temperatures above <NUM>, even above <NUM> and close to <NUM>. However, art known RTs generally lose activity and stability when they are incubated at high temperatures much above <NUM>.

The following documents should also be considered as relevant state of the art:.

The present invention is focused on solving the above cited problem and it refers to a M-MLV RT having increased thermal stability even at high temperatures above <NUM>, as compared to wild type M-MLV.

The present invention provides a RT enzyme, compositions comprising the same and methods useful in overcoming limitations of reverse transcription. In general, the present invention provides a modified or mutated RT such that the thermostability and/or fidelity of the enzyme are increased or enhanced. More particularly, the present invention is directed to the double M-MLV mutant A154C and D224C, wherein a disulphide bond is formed between the thiol groups of the two cysteine amino acids at the amino acid positions <NUM> and <NUM> (hereinafter the "RT of the invention" or "RTSS"). Surprisingly, the RT of the invention shows a high thermal stability, even at temperatures above <NUM> to <NUM>.

Particularly, such as it can be seen in the results provided in the present invention:.

Consequently, the first embodiment of the present invention refers to a M-MLV RT having increased thermal stability as compared to wild type M-MLV reverse transcriptase, characterized in that it comprises the mutation alanine to cysteine at the amino acid position <NUM> of the SEQ ID NO: <NUM> (A154C) and the mutation aspartic acid to cysteine at the amino acid position <NUM> of the SEQ ID NO: <NUM> (D224C), wherein a disulphide bond is formed between the thiol groups of the two cysteine amino acids at the amino acid positions <NUM> and <NUM>.

The second embodiment of the present invention refers to an isolated nucleic acid molecule or vector comprising a nucleotide sequence encoding the RT of the invention.

The third embodiment of the present invention refers to a recombinant host cell which comprises the above cited nucleic acid molecule or vector.

The fourth embodiment of the present invention refers to a composition comprising the RT of the invention.

The fifth embodiment of the present invention refers to a kit adapted for making, amplifying or sequencing nucleic acid molecules comprising a first container which in turn comprises at least the RT of the invention.

The sixth embodiment of the present invention refers to an in vitro method of reverse transcription to generate complementary DNA (cDNA) from a nucleic acid template molecule, comprising mixing the nucleic acid template with at least the RT of the invention, and incubating the mixture under conditions sufficient to make nucleic acid molecules complementary to all or a portion of the template.

The seventh embodiment of the present invention refers to an in vitro method for sequencing a nucleic acid molecule comprising, mixing the nucleic acid template to be sequenced with one or more primers, with at least the RT of the invention, one or more nucleotides and one or more terminating agents; incubating the mixture under conditions sufficient to synthesize a population of molecules complementary to all or a portion of the molecule being sequenced; and separating the population to determine the nucleotide sequence of all or a portion of the molecule being sequenced.

The eight embodiment of the present invention refers to an in vitro method for amplifying a nucleic acid template molecule, comprising mixing the nucleic acid template with at least the RT of the invention and one or more DNA polymerases, and incubating the mixture under conditions sufficient to amplify nucleic acid molecules complementary to all or a portion of the template.

The ninth embodiment of the present invention refers to the in vitro use of the RT of the invention to generate complementary DNA (cDNA) from a nucleic acid template molecule, for sequencing a nucleic acid molecule or for amplifying a nucleic acid template molecule.

In a preferred embodiment, the method for amplifying a nucleic acid template molecule comprises a polymerase chain reaction (PCR), preferably quantitative PCR (qPCR) or reverse transcription polymerase chain reaction (RT-PCR).

In a preferred embodiment, the methods of the invention are performed at a temperature above <NUM>, preferably above <NUM>.

In a preferred embodiment, the RT of the invention is characterized by the SEQ ID NO: <NUM>, which comprises the residues <NUM>-<NUM> of wild type M-MLV RT with mutations A154C and D224C, and further comprises the N-terminal extension of sequence MGSSHHHHHHSSGLEVLFQGP:
<IMG>.

For the purpose of the present invention the following terms are defined:.

DNA sequence for Recombinant Hyperstable RT (RTSS) was synthesized by GenScript (Hong-Kong), and codons were optimized for expression in E. coli cells. The recombinant sequence corresponding to residues <NUM>-<NUM> of the wild type Moloney Murine Leukemia Virus RT, with the mutations A154C and D224C, preferably fused to a His-Tag in the N-terminal and a 3C protease site for cleavage of His tag, was cloned in a vector derived from the p-ET15b plasmid. The final sequence expressed was the SEQ ID NO: <NUM>.

The plasmid was transformed in an E. coli BL21 DE3 strain and cultured at <NUM> in LB medium until DO <NUM> and induced with <NUM> Isopropyl β- D -<NUM>-thiogalactopyranoside (IPTG). After induction, culture temperature was lowered down to <NUM>. After <NUM> hours, cells were harvested and cell pellet was stored frozen at -<NUM> C.

Pellet was resuspended in buffer <NUM> Hepes, <NUM> NaCl, <NUM> Imidazole, pH <NUM> and loaded in a His-Trap column (GE Healthcare). Elution was performed with buffer <NUM> Hepes, <NUM> NaCl, <NUM> Imidazole, pH <NUM> and the enzyme was dialyzed first against buffer <NUM> Hepes, <NUM> NaCl, <NUM> cysteine, <NUM> cystine, pH <NUM> for <NUM> hours (for disulfide bond formation) and after that against buffer <NUM> Hepes, <NUM> NaCl, 2pH <NUM> at 4C. Finally, the enzyme was aliquoted, frozen in liquid nitrogen and stored at -<NUM> C.

Thermal denaturation of RTSS was followed by tryptophan fluorescence emission. RTWT, and RTH- which is known to be more stable that the wild type version, were also analysed for comparison (<FIG>). To understand the role of disulphide bond formation, the RTSS enzyme without disulphide bond formation (RTSSX), dialyzed without cysteine and cysteine during purification, was also characterized (<FIG>).

Curves were recorded from <NUM> to <NUM>. Enzyme concentrations were <NUM>, excitation wavelength was <NUM> and fluorescence emission was recorded at <NUM> (tryptophan emission).

Unfolding curves were fitted to two or three-state equations depending on the case.

For the simplest model, a two-state equation where: <MAT>.

F is the spectroscopic signal, T corresponds to the absolute temperature, FN and FD, the spectroscopic signals of native and denatured enzymes at a temperature (T0) vary linearly with temperature with slopes mN and mD.

ΔG, free energy of the unfolding process, corresponds to: <MAT>.

Tm is the melting temperature (Temperature where <NUM> % of the molecules are in a folded state and <NUM> % in a denatured state). ΔH enthalpy change and ΔCp the heat capacity both considered at the melting temperature.

The melting temperature and the extension of the transition at a Temperature (expressed as a Fluorescence decrease) are the most powerful indicators of thermal stability.

The results obtained are shown in Table <NUM>. In order to interpret the results, it is important to note that the greater the Tm, and the lower the loss of fluorescence in a transition, the greater the stability of a protein.

The unfolding for the enzyme RTWT is a two-step process with a Tm of <NUM>. The mutant RTH- is much more stable, with a first transition characterized by a Tm of <NUM> with and a second denaturation at <NUM>. The highest stability was provided by the RTSS comprising disulphide bond. RTSS is not only defined by their higher Tm1 and Tm2 (<NUM> and <NUM>, respectively) but for the much smaller extent of the first transition (see <FIG> the small descending of fluorescence during this change of state). The most likely explanation for this fact is that the onset of unfolding that occurs locally at this temperature is restricted to a small portion of the protein, due to the disulphide bond presence. As it will be seen in the functional experiments performed by q-PCR, this higher thermal stability correlates with the ability of the RTSS enzyme to develop its retrotranscriptase activity at a higher temperature, compared for example with RTWT.

Consequently, the presence of two specific mutations A154C and D224C, along with the formation of the disulphide bond in those specific positions, give rise to an increase in the stability of the RT of the invention.

The thermal denaturation of the RTSSX, followed by emission of fluorescence, reveals that, already at very low temperatures, the RTSSX is in a partially unfolded state, as can be seen by the low fluorescence signal compared with the other enzymes. In addition, the enzyme with the unformed disulphide bond completely lacks detectable retrotranscriptase activity.

RNA extraction of stool samples from patients with suspicious of rotavirus diarrhea was performed using INVISORB® Spin Universal kit (Stratec) following manufacture's protocol. <NUM>-fold serial dilutions of RNA extracted were prepared in TE 1X low EDTA buffer. RNA extract dilutions were stored at -<NUM> until Real Time RT-PCR testing.

Extracted RNA were used for one step Real Time PCR using different RT enzymes: RTH-, RTSS, RTSSX, RTWT, Tetro Reverse Transcriptase M-MLV and SuperScript™ IV Reverse Retrotranscriptase.

The Real RT-PCR assay was performed by using SensiFAST®Probe No-ROX Kit (Bioline meridian Bioscience). Each 20µl reaction mixture contained 10µl of 2x SensiFAST™ Probe No-ROX Mix, <NUM> (each) forward and reverse primer, <NUM> probe, nuclease-free water, 100Units of selected retrotranscriptase and 5µl of extracted RNA. Primers and probe were designed for specific Rotavirus A detection generating a multiple sequence alignment with MAFFT and confirming the specificity of the selected sequence using BLAST.

Custom primers and probes were ordered from IDT (Integrated DNA Technologies, Iowa, USA).

After adding to the reaction mixture the different RTs, the enzymes were pre incubated at different temperatures. Enzyme incubation, retrotranscriptation and amplification were carried out on a CFX96 Touch®Real-Time PCR Detection System (BioRad). Thermocycling conditions consisted of <NUM> at <NUM>-<NUM> for RT (depending on purpose experiment), polymerase activation at <NUM> for <NUM>; followed by up to <NUM> cycles of denaturation at <NUM> for <NUM> seconds and annealing/extension at <NUM> for <NUM> seconds.

Experiments of functional assays consist of small RNA fragments reverse transcription coupled with DNA amplification in which the different RTs were previously incubated at different temperatures. Pre incubation mimics conditions of working at high temperature with strong secondary RNA or full length cDNA synthesis. The purpose of this analysis is to check that RTSS was able to work at increased temperatures and to compare its functionality with other different RTs in terms of Ct displacement value and presence of amplification and therefore its ability to generate cDNA from very little input RNA.

On the first evaluation studies RTSS was compared with the RTSSX, RTH-, RTWT, and Tetro Reverse Transcriptase M-MLV. On the first experiment all RTs were pre incubated during <NUM> at <NUM>, <NUM> or <NUM>. The conditions for reverse transcription step were <NUM> minutes to different temperatures ranging from <NUM> to <NUM>. The results obtained were shown in Table <NUM> and <FIG>. RTSS was able to carry out retrotranscription and amplification through all conditions tested, even at highest temperatures. These experiments demonstrate that the thermostability is due to strategic mutations located in A154C and D224C in combination with disulfide bond formation.

Table <NUM>. Evaluation of ability to work at increased temperature at a range of pre incubation and reverse transcription temperatures for selected RTs.

The results obtained with Real Time RT PCR from <NUM>-fold dilutions of nucleic acid from positive rotavirus sample with RTSS and RTWT comparison at different incubations times is shown in Table <NUM>. Corresponding amplification plot (<FIG>) shows that RTSS presents more reproducible results than RTWT over a range of high temperatures (<NUM>-<NUM>).

Table <NUM>. RTSS sensitivity evaluation vs RTWT. The RTs were pre incubated during <NUM> minutes along a different range of high temperatures (<NUM>-<NUM>). The conditions of the retrotranscription step were <NUM>, at <NUM>.

Regarding verification studies comparing RTSS vs. SuperScript™ IV, the experiments performed were based on pre incubations of RTs at different point of temperatures during <NUM> minutes (Table <NUM>). The results demonstrate that in the <NUM>-<NUM> range, loss of activity is much more important for SuperScript™ IV. Above <NUM>, RTSS works as well as SuperScript™ IV with high concentration RNA samples and better with low concentration RNA samples.

Table <NUM>. RTSS sensitivity evaluation comparing vs. SuperScript™ IV.

When RTSS was subjected to high pre incubation temperatures (<NUM>-<NUM>), it displays high stability (Table <NUM>).

Table <NUM>. Thermostability experiments with RTSS at very high temperatures. The time of preincubation is <NUM> minutes. Conditions of retrotranscriptation step were <NUM> minutes at <NUM>.

One of the high temperatures was chosen (<NUM>) and we performed the experiment using SuperScript™ IV as a reference thermostability enzyme. Loss of activitiy is much more evident in SuperScript™ IV than in RTSS at very high temperatures (Table <NUM>, <FIG>).

Table <NUM>. Very high temperature activity RTSS vs. SuperScript™ IV comparison.

Claim 1:
A Moloney Murine Leukemia Virus (M-MLV) reverse transcriptase having increased thermal stability as compared to wild type M-MLV reverse transcriptase, characterized in that it comprises the mutation alanine to cysteine at the amino acid position <NUM> of the SEQ ID NO: <NUM> (A154C) and the mutation aspartic acid to cysteine at the amino acid position <NUM> of the SEQ ID NO: <NUM> (D224C), wherein a disulfide bond is formed between the thiol groups of the two cysteine amino acids at the amino acid positions <NUM> and <NUM>.