Abstract: A peptide domain necessary for an interaction between an envelope of a virus belonging to an HERV-W interference group and an hASCT receptor comprises (i) an N-terminus motif having an amino acid sequence selected from the group consisting of: SEQ ID No. 1 to SEQ ID No. 29, (ii) a C-terminus motif having an amino acid sequence selected from the group consisting of: SEQ ID No. 30 to SEQ ID No. 40, and (iii) at least one motif between the N-terminus and the C-terminus, and having an amino acid sequence selected from the group consisting of: SEQ ID No. 41, SEQ ID No. 42 and SEQ ID No. 73.

Abstract: A peptide domain necessary for an interaction between an envelope of a virus belonging to an HERV-W interference group and an hASCT receptor comprises (i) an N-terminus motif having an amino acid sequence selected from the group consisting of: SEQ ID No. 1 to SEQ ID No. 29, (ii) a C-terminus motif having an amino acid sequence selected from the group consisting of: SEQ ID No. 30 to SEQ ID No. 40, and (iii) at least one motif between the N-terminus and the C-terminus, and having an amino acid sequence selected from the group consisting of: SEQ ID No. 41, SEQ ID No. 42 and SEQ ID No. 73.

Abstract: RNA may be transcribed using a nucleotide reagent as the promoter. The reagent may enable RNA to be transcribed without sequence specification and without protein cofactors, by means of an RNA polymerase that is known to be DNA-dependent such as the RNA polymerase of the phage T7, or by means of new, mutated RNA polymerase with the ability to synthesize a transcription product of polynucleotide matrix with a higher yield when the matrix is RNA than when the matrix is DNA. This type of RNA polymerase can be obtained by effecting mutations on a coding gene for a wild-type RNA polymerase, and then by selecting the mutated RNA polymerase with the ability. The invention can be applied notably to the detection, synthesis or quantification of RNA.

Abstract: The invention relates to a peptide domain required for interaction between the envelope of a virus pertaining to the HERV-W interference group and a hASCT receptor, comprising an N end point and a C end point. Said peptide domain is defined, at the N end point thereof, by a pattern formed by the amino acids L (Z)-proline-cysteine-X-cysteine in which Z is any amino acid, is a whole number between 2 and 30, and X is any amino acid, and at the C end point thereof, by a pattern formed by the amino acids serine-aspartic acid-Xa-Xb-Xc-Xd-Xe-aspartic acid-Xf-Xg-(Z) in which Xa, Xb, Xc, Xd, Xe, Xf, Xg are any amino acids, Z is any amino acid, B is a whole number between 15 and 25, preferably 20.

Abstract: The present invention relates to a method for generating transcripts from: at least one RNA sequence to be amplified comprising a “primer” region and a region of interest, and an amplification primer comprising a promoter region, and a region capable of hybridizing to said “primer” region of the RNA sequence to be amplified, said method being carried out at constant temperature, and comprising the following steps: a) said primer is hybridized with the RNA to be amplified, b) the primer is extended by means of a reverse transcriptase enzymatic activity in order to generate a complementary deoxyribonucleic acid (cDNA) sequence of the RNA to be amplified, c) the RNA to be amplified, hybridized to said cDNA, is cleaved by means of an enzyme that has a ribonuclease H activity, so as to obtain fragments of RNA to be amplified, hybridized to said cDNA, d) the ends of said fragments of RNA to be amplified are extended by means of a reverse transcriptase and strand displacement enzyme, so as to obtain RNA-DNA/DNA hybr

Abstract: RNA may be transcribed using a nucleotide reagent as the promoter. The reagent may enable RNA to be transcribed without sequence specification and without protein cofactors, by means of an RNA polymerase that is known to be DNA-dependent such as the RNA polymerase of the phage T7, or by means of new, mutated RNA polymerase with the ability to synthesize a transcription product of polynucleotide matrix with a higher yield when the matrix is RNA than when the matrix is DNA. This type of RNA polymerase can be obtained by effecting mutations on a coding gene for a wild-type RNA polymerase, and then by selecting the mutated RNA polymerase with the ability. The invention can be applied notably to the detection, synthesis or quantification of RNA.

Abstract: The invention concerns a nucleotide sequence coding for a modified protein of interest, said protein of interest having, after purification and immobilization, at least the same biological activity as the native protein of interest and being directly usable, said sequence comprising at least a gene coding for said protein of interest, a nucleotide fragment, called polyK, coding for a succession of at least six lysine residues, and a nucleotide fragment, called polyH, coding for a succession of at least six histidine residues; a vector comprising such a sequence; and a method for obtaining a purifiable and immobilized modified protein of interest.

Abstract: Disclosed is a process for transcribing RNA using a nucleotide reagent as the promoter. Such a reagent enables any type of RNA to be transcribed without sequence specification and without protein cofactors, by means of an RNA polymerase that is known to be DNA-dependent such as the RNA polymerase of the phage T7, or by means of new, mutated RNA polymerase with the ability to synthesize a transcription product of a polynucleotide matrix with a higher yield when the matrix is RNA than when said matrix is DNA. This type of RNA polymerase can be obtained by effecting mutations on a coding gene for a wild-type RNA polymerase, and then by selecting the mutated RNA polymerase with said ability. The invention can be applied notably to the detection, synthesis or quantification of RNA.

Abstract: Disclosed is a process for transcribing RNA using a nucleotide reagent as the promoter. Such a reagent enables any type of RNA to be transcribed without sequence specification and without protein cofactors, by means of an RNA polymerase that is known to be DNA-dependent such as the RNA polymerase of the phage T7, or by means of new, mutated RNA polymerase with the ability to synthesize a transcription product of a polynucleotide matrix with a higher yield when the matrix is RNA than when said matrix is DNA. This type of RNA polvmerase can be obtained by effecting mutations on a coding gene for a wild-type RNA polvmerase and then by selecting the mutated RNA polymerase with said abilitv The invention can be applied notably to the detection, synthesis or quantification of RNA.

Abstract: An RNA amplification method is particularly useful for diagnosing bacterial or viral infections or genetic disorders and for cell typing. The method includes the steps of denaturing a solution containing RNA, synthesizing a first cDNA strand from a suitable primer in the presence of reverse transcriptase, denaturing the heteroduplex formed, synthesizing a second cDNA strand from a second primer in the presence of DNA polymerase and then subjecting the cDNA formed to a sufficient number of amplification cycles. All the reactants and solvents are first placed in the same container to provide a single manipulation step that avoids the risk of contamination.

Abstract: An RNA amplification method is particularly useful for diagnosing bacterial or viral infections or genetic disorders and for cell typing. The method includes the steps of denaturing a solution containing RNA, synthesizing a first cDNA strand from a suitable primer in the presence of reverse transcriptase, denaturing the heteroduplex formed, synthesizing a second cDNA strand from a second primer in the presence of DNA polymerase and then subjecting the cDNA formed to a sufficient number of amplification cycles. All the reactants and solvents are first placed in the same container to provide a single manipulation step that avoids the risk of contamination.

Abstract: An RNA amplification method is particularly useful for diagnosing bacterial or viral infections or genetic disorders and for cell typing. The method includes the steps of denaturing a solution containing RNA, synthesizing a first cDNA strand from a suitable primer in the presence of reverse transcriptase, denaturing the heteroduplex formed, synthesizing a second cDNA strand from a second primer in the presence of DNA polymerase and then subjecting the cDNA formed to a sufficient number of amplification cycles. All the reactants and solvents are first placed in the same container to provide a single manipulation step that avoids the risk of contamination.