WO2004101819A1 - Method for the identification of cell lineages - Google Patents

Abstract

The invention relates to a method for identifying cell lineages, especially animal and human cell lineages, allowing fast and targeted identification of the cell lineages that are to be analyzed. According to the inventive method, a specific marker DNA comprising at least one random sequence is introduced into the cell lineage, and said marker DNA is detected by means of a suitable method via oligonucleotide hybridization. The marker DNA may contain other sequences or genes in addition to the random sequence/s, at least one random sequence having to be provided.

Description

 Method of identifying cell lines

The present invention relates to a method for identifying cell lines, in particular animal and human cell lines, which enables rapid and targeted identification of the cell lines to be examined. In the method according to the invention, a specific marker DNA, which has at least one random sequence, is introduced into the cell line, and this marker DNA is detected using a suitable method via oligonucleotide hybridization. In addition to the random sequence (s), of which at least one must be present, the marker DNA can also contain further sequences or genes.

Cross-contamination of cell cultures in general and especially human cell cultures is an everyday problem in the laboratory. It leads to a devaluation of the research results, jeopardizes the comparability of the results of different laboratories, reduces the reproducibility that is necessary in the industrial production of cell lines and can lead to unusable therapeutic products (Markovic, O. and Markovic, N., In Vitro Cell Dev. Biol. Anim, 34: 1-8, 1998).

In addition to contamination with other cells of the same origin, depending on the type of cell lines and cultures, there are also contaminations with bacteria, yeast, mold, parasites, mycoplasma and viruses. In many cases, contamination with bacteria, fungi or viruses can be identified due to a morphological change in the cell line, a changed growth, the discoloration of the culture medium or similar indications. Contamination with other cell lines, on the other hand, is problematic and can be morphologically very similar to the original culture. The introduced cells can, for example, proliferate faster and thus overgrow the original culture without this being noticed.

The phenomenon of contamination of cell cultures is described in numerous articles (Fogh, J., Holmgren, NB, and Ludovici, PP, In Vitro, 7: 26-41, 1971; Haiton, DM, Peterson, Jr. WD, and Hukku, B. ₅ In Vitro Cell Dev. Biol., 19: 16-24, 1983; Hay, RJ, Dev. Biol. Stand., 76: 25-37; 1992; Markovic, O. and Markovic, N. In Vitro Cell Dev. Biol. Anim, 34: 1-8, 1998; Dirks, W., MacLeod, RA, Jager, K., Milch, H. and Drexler, HG, Cell Mol. Bio., 45: 841-853, 1999).

A distinction between individual cell lines is possible, for example, by isoenzymatic characterization, but is also carried out with the aid of cytogenetic analyzes and DNA fingerprinting (Stacey, GN, Bolton, BJ, and Doyle, A., EXS, 58: 361-370 , 1991). Furthermore, staining with fluorescent antibodies is used as an additional method of identification.

In studies conducted in the United States, cross-species contamination and contamination with like-type cells of 17-36% have been found (Hay, R.J., Dev. Biol. Stand., 76: 25-37; 1992).

A more recent method for individualizing individual cell lines has been described by Tanabe (Tanabe, H., Nakagawa, Y., Minegishi, D., Kurematsu, M., Masui, T. and Mizusawa, H., Tiss. Cult. Res. Commun. , 18: 329-338, 1999). With the help of "short tandem repeat (STR)" regions, which represent highly polymorphic microsatellite markers in the human genome, PCR amplification enables rapid and accurate cell line identification for quality control. The publication describes the use of nine different loci that are used to analyze the STR profiles of human cell lines.

In addition to the important control of established cell cultures that are not transgenic, it is just as important for many research institutions to have a fast and reliable detection method available for genetically modified cell lines that do not differ morphologically practically and genetically only in the transgene.

To characterize the structure-function relationship of proteins, they are often expressed in natural and genetically modified form in tumor cell lines. The resulting new cell clones generally do not differ from one another externally. Since on the one hand there are no typical differences in the natural genome of the cell lines and on the other hand the structure of the genetically modified proteins to be examined or the genes coding for these proteins differ only minimally, it is not possible to do this without considerable effort Identify cell lines in case of confusion. The method previously used to identify the individual cell lines was to amplify a DNA or cDNA fragment which codes for the protein to be examined by (RT) - PCR and then to sequence it. Only the exact comparison of sequences makes it possible to distinguish the slight differences in the genetic information introduced into the transgenic cell line.

In molecular biology, in addition to the actual target protein, additional DNA sequences are often integrated into the cells to demonstrate successful transfection. These include the "green fluorescence protein" (GFP), various antibiotic resistance genes or genes that code for proteins that can cause a color reaction.

The methods for analyzing cell cultures described in the prior art are time-consuming, costly or, in the case of the STR multiplex system, restricted to a specific group of cell cultures and thus do not represent a universally applicable identification system for animal, human or other cell cultures which can be used cost-effectively and safely.

It is therefore an object of the present invention to provide a method for identifying cell lines, in particular animal and human cell lines, which enables rapid and targeted identification of the cell lines to be examined.

The problems of the prior art are solved by a method for identifying cell lines, wherein a specific marker DNA, which has at least one random sequence, is introduced into the cell line, and this marker DNA is detected using a suitable method via oligonucleotide hybridization , Here, the term "specific marker DNA" refers to its own, distinctive DNA section which is introduced into the corresponding cell line. In addition to the random sequence (s), of which at least one must be present, the marker DNA can also contain further sequences or genes.

A “random sequence” in the sense of the invention is to be understood as a sequence whose base sequence in the genome of the cell naturally occurs in a section of approximately 20 kb is not present upstream and downstream of the integration site of the marker DNA. Optimally, the random sequence does not even exist in the genome of the cell. A cell can contain several random sequences that can be inserted into the cell one after the other or simultaneously in a specific combination.

The method for detecting the marker DNA preferably comprises the use of labeled probes or PCR. In addition to the use of probes, this essentially means the use of specific primers which are complementary to the random sequence and which provide rapid identification using the polymerase chain reaction (PCR). Further detection methods are known in the prior art and include, among other things, the use of differently labeled probes or the use of newer technical methods which are suitable for detecting a random sequence in accordance with the invention.

The marker DNA preferably comprises between 10 and 500 nucleotides. The marker DNA particularly preferably comprises between 15 and 60 nucleotides. The random sequence according to the invention can be identical to the marker DNA or can also represent only a part thereof.

In a preferred embodiment, at least the random sequence of the introduced marker DNA is unique to the cell genome. However, successive labeling steps of cells should not be excluded.

Alternatively, a combination of at least two marker DNA sequences can be used. According to the understanding of the present invention, a marker DNA can contain several random sequences. Different marker DNAs can be combined in order to enable a specific marking of several successively marked cell lines. This enables derived cell lines to be unequivocally assigned to the original line.

In a preferred embodiment, the marker DNA is flanked by identical restriction enzyme sites. Alternatively, this marker DNA can also be flanked by various restriction enzyme sites. According to the invention, the cell lines to be identified can be selected from virally infected cells, bacterial cells, plant, fungal, animal and in particular human cells. Mixtures of cells can also be used. Examples of cell lines are lines from E. coli; Lactococcus lactis; Bacillus subtilis, Saccharomyces, Hansenula, Drosophila, Arabidopsis, monkey and human cell lines. Other lines are hybridoma lines and the like.

In a particularly preferred embodiment, the cell lines to be identified carry foreign genes (also referred to here as "gene of interest") which differ only slightly from one another in their sequence. The cell lines to be identified can also express foreign genes whose proteins differ only slightly from one another in their sequence. In this context, a slight sequence difference relates to the exchange of individual nucleotides, smaller sequence segments, individual amino acids or smaller amino acid sequences, which conventionally only enable the DNA sequence of the gene to be expressed to be identified with the aid of DNA sequencing after isolation.

The oligonucleotides used to detect the marker DNA are preferably both complementary to the marker DNA. Alternatively, at least one of the oligonucleotides used to detect the marker DNA is complementary to the marker DNA and the other oligonucleotide is complementary to a region outside the marker DNA.

On the one hand, this enables the establishment of a standard PCR if a second oligonucleotide sequence is used as the primer for the PCR, which originates from a vector region, and on the other hand the establishment of a user-specific PCR by using a primer which is complementary to the target -DNA is that which should be introduced into the cell line with the aid of the transfection.

The marker DNA and / or the random sequence is particularly preferably designed as an inverted repeat or palindrome. This means that the entire sequence of the marker DNA or only a part (such as the random sequence) of the marker DNA is repeated in mirror image.

Another aspect of the present invention relates to the use of marker DNA sequences which have a random sequence for identifying cell lines. A further embodiment relates to a transfection construct which comprises at least one marker DNA for introduction into a cell line, the marker DNA having at least one random sequence. The use of an already finished transfection construct, which enables a quick and unambiguous identification of the transfected cell lines, represents an enormous simplification for the user. His gene of interest only has to be introduced into the transfection construct with the aid of suitable restriction interfaces or with the help of homologous recombination, without that additional cloning of the marker DNA is necessary. In the present case, this is already on the transfection construct and thus enables the inventor to make available a whole range of different transfection vectors that can be used directly by the consumer.

A kit for identifying cell lines is preferred which contains at least the following components: a) a marker DNA which has at least one random sequence and b) an oligonucleotide which has a sequence which is at least partially complementary to the random sequence. Alternatively, the kit contains the following components: a) a vector set, the vectors having different marker DNA sequences each having at least one random sequence and b) oligonucleotides each having at least partially sequences complementary to the random sequences. The phrase "at least partially" refers to the fact that the primers on the one hand bind to the random sequence (or several random sequences) present in the marker DNA, but can also be partially complementary to other areas of the marker DNA. The kit can also contain the instructions for use required to carry out the corresponding identification.

pictures

1 shows the identification of four different cell lines by PCR with cell line-specific primers.

Fig. 2 shows a simplified process diagram for the subsequent incorporation of a marker DNA into an existing plasmid.

Figure 3 shows a possible way of synthesizing polylinker flanking marker DNA. Figure 4 shows another possible way of synthesizing polylinker-flanking marker DNA.

5 and 6 show vector constructs as used in Example 5.

Fig. 1 shows the photo of an agarose gel, which was taken after gel electrophoresis. The light bands represent the areas in which DNA molecules, separated according to their molecular weight, have accumulated. They are stained with ethidium bromide and are therefore visible under UV radiation. The investigation was carried out according to the method described in Example 1, the four cell lines being numbered 307 to 310 and the primers being numbered accordingly. Under the corresponding stringent PCR conditions, only the primer that has the exactly complementary random sequence binds to the marker DNA. The four transformed cell lines could thus be identified with a high degree of certainty. The standard additionally plotted on the left lane serves to estimate the size of the DNA identified in the PCR.

FIG. 2 schematically shows the process shown in Example 2 as a process diagram.

The two FIGS. 3 and 4 represent process sequences which are explained in more detail in example 4 as the first and third possibility.

Animal and human cell cultures can be transfected by various methods. There are basically two types of processes. In addition to viral integration of DNA into the genome of the target cell, the second group introduces DNA into the cell in various ways, which is then randomly or specifically integrated into the genome and with the help of a suitable selection pressure for stable integration of the transfected DNA is selected. In addition to the transfection systems with retroviral or adenoviral genes, an introduction of foreign DNA can also be carried out via calcium phosphate precipitation, with the help of DAE dextran, through liposomes or lipid-mediated methods, microinjection, electroporation, receptor-mediated gene transfer or ballistic Transfection can be achieved. Such cell lines genetically modified in this way can often not be distinguished from one another phenotypically. The present invention provides a method by which it is possible to identify cells transfected with different constructs using a simple PCR method. Analogously, suitable methods can be used to identify transfected cell lines of other origin.

For this purpose, either during the construction of the vector (construct) to be transfected, a marker DNA is introduced into the construct specifically via restriction sites or homologous recombination, or a set of standard transfection vectors into which the target gene can be cloned is made available to the consumer. In addition to the gene of interest, which is usually to be expressed in the transfected cell line, a marker DNA is provided at the 3 'end, which among other things. includes a random sequence. This random sequence is unique due to its randomly assembled nucleotide sequence and a corresponding length and can be used under very stringent conditions in the target cell with the help of e.g. PCR can be detected. If only a restriction enzyme interface or only a sequence for homologous recombination is used to integrate the marker DNA into the transfection vector, it makes sense to design the marker DNA in the form of inverted repeats so that, on the one hand, an amplification of the desired DNA in both possible integration orientations Section with corresponding primers outside the marker DNA and on the other hand an amplification of a DNA section of the marker DNA is possible by using only one primer (complementary to at least part of the random sequence). Since the size of the piece of DNA to be amplified can be specifically determined, the corresponding cell clone is unequivocally identified by first carrying out the PCR according to methods known in the prior art and then using conventional gel electrophoresis DNA pieces in the appropriate size can be detected quickly. The method described in the present invention thus offers rapid feasibility, which causes only low costs.

The term “hybridization” in the sense of the present invention is to be understood as binding to form a duplex structure of an oligonucleotide to a completely complementary sequence in the sense of the Watson-Crick base pairings in the sample DNA. Under "very stringent" hybridization conditions, such conditions are to be avoided. stand in which a hybridization at 60 ° C in 2.5 x SSC buffer, followed by several washing steps at 37 ° C in a lower buffer concentration and remains stable.

To carry out the PCR, it is conceivable that DNA is extracted from the corresponding cell clones by methods known in the prior art, in order to use them in the PCR in a suitable dilution, or to insert cells directly in the PCR, which by the corresponding denaturation step during the PCR reaction are destroyed and the DNA to be examined is released.

In addition to the identification of transgenic cell lines, the method of the present invention also offers the possibility for non-transgenic cell lines to be identified beyond doubt by the introduction of suitable marker DNA sections. The integration of a small segment of marker DNA enables different cell lines from different organs and organisms to be differentiated.

In contrast to the methods already known in the prior art, the labeling method of the present invention can provide an exceptionally wide variety of different marker DNA segments and is far superior to the conventional marker genes which require expression of the host cell.

To illustrate the present invention, four examples are explained in more detail, which, however, are not intended to limit the scope of protection. In the examples, animal cell lines are marked as examples. However, the method is basically equally applicable to all cell lines to be identified.

example 1

Using a PCR method with 5 'overhanging primers, 3' of the translated area was inserted into four plasmids which contained cDNA sequences for proteins which differed only in a few amino acids, a 21-base pair long sequence which varied in each case, that was generated randomly. The PCR products thus extended by 21 base pairs were cloned into the original vector. The sequence was then verified by DNA sequencing to rule out mutations in the PCR process. HEK293 cells were transfected with the four vectors. Individual cell lines that had stably integrated the vector construct into the genome were isolated by selection with the antibiotic G418 and single cell cloning. The cell lines established in this way were cultivated under standard conditions.

After proteinase K digestion, genomic DNA was isolated from the four selected cell lines by ethanol precipitation. The DNA obtained in this way was used in a PCR reaction with marker-specific primers and a primer which was identical for all cell lines and corresponded to a sequence section in the transfected DNA. Under the selected conditions, a PCR product could only be detected in the DNAs of the cell lines, which carried the sequence specific for the marker primer (FIG. 1).

Example 2

In order to avoid the occurrence of mutations by the PCR method and not to have to sequence the amplified product before it is cloned, Example 2 provides an alternative method. The marker DNA is inserted into the already existing plasmid construct. For this purpose, the marker DNA is restricted with an enzyme which cuts the vector polylinker in the 3 'region of the protein-coding cDNA region of the vector and clones behind the protein-coding region. In order to ensure that the subsequent PCR can be carried out easily, regardless of the insert orientation direction of the marker DNA, the marker DNA is joined twice directly behind one another in opposite directions (mirror image, inverted repeat) with a polylink notch region in front of it. This DNA fragment is cut with the desired restriction enzyme and ligated into the dephospholated vector cut with the same enzyme. (Fig. 2)

By introducing the marker sequence as an inverted repeat, it is possible to establish a standard PCR protocol that is independent of the sequence of the protein-coding region that may be transfected. For this standard protocol, a PCR is carried out with the marker primer on the one hand and the vector-specific primer located in the 3 'thereof on the other hand (see FIG. 2, standard PCR). This enables the use of the strictest possible PCR conditions and thereby minimizes the amplification of false positive bands. If a protein cDNA-specific primer is used, the user can establish a PCR protocol specific for his cDNA (see FIG. 2, user PCR). Example 3

A set of vectors is provided, which have a unique marker sequence behind the polylinker. Such a vector set can be used to clone protein-coding DNA regions directly into corresponding interfaces and thereby enables the inventive technique to be used quickly and without problems. Vectors containing a unique marker DNA are prepared by inserting a synthetic, double-stranded oligonucleotide with overhanging ends into the most distant from the transcription start site of the polylinker or another suitable interface in the immediate vicinity of the polylinker, which contains the marker DNA sequence in a mirror image arrangement and can therefore serve as a template for both the user PCR and the standard PCR with the same primer.

Example 4

Three different ways of producing the inverted repeat

Marker DNA sequence can be displayed in a polylinker.

a) First option

A DNA fragment is amplified by PCR, a vector with a suitable polylinker being selected as the template. One primer binds to one end of the polylinker. This primer is extended 5 'by the desired marker sequence and 5' by this marker sequence by a sequence coding for a restriction interface not present in the polylinker. The second primer starts inside the vector beyond the polylinker. The PCR product is restricted with the non-polylinker cutting enzyme. The large fragments are cleaned and ligated. The ligation product is cut with the outer enzyme located in the polylinker and ligated into a dephosphorylated vector cut with the same enzyme (FIG. 3).

b) Second option

The PCR approach is halved, half is cut with the enzyme not cutting in the polylinker and the outermost enzyme in the polylinker. The second half with the enzyme not cutting in the polylinker and the penultimate enzyme in the polylinker. The two restriction approaches are brought into a ligation with the vector cut with the two enzymes located in the outer polylinker region. c) Third option

A fully synthetic double-stranded DNA fragment containing the inverted repeat as a marker DNA sequence with overhanging ends is cloned into the central interface of a vector to be established, the polylinker of which contains each interface in a mirror image arrangement (FIG. 4 ).

Example 5

The following example relates to a further variant of the method and the method according to the invention. The enzyme X (and / or for example a receptor, such as the prostanoid receptor described, inter alia, in Biochem J. 2003 Apr 15; 371 (Pt 2): 443-9, in which His-81 to Ala mutants in the transmembrane domain 2 and Arg- 291 to Leu mutants in transmembrane domain 7 from the wild type) is of potential interest for a biotechnological process. Unfortunately, the enzyme catalyzes an undesirable side reaction that results in a loss of product quality. This side reaction can be suppressed by a single amino acid substitution within or near the active site without affecting the desired main reaction. A number of cDNA constructs were generated by site-directed mutagenesis which code for the same enzyme with only a single amino acid substitution in order to optimize the enzyme for the biotechnological process. All cDNAs were cloned into the same expression vector and cell lines were generated with these cDNAs in an identical cellular background. These cell lines differ in a single or very few known nucleotide exchanges in the transgene. Figure 5 shows the transgene of the wild type and an optimized enzyme. The cell lines can only be identified by SNP analysis or sequencing of the transgene. Switching the cell lines can cause serious damage if you use a cell line that carries the wild-type gene instead of the optimized enzyme.

In order to avoid the expensive and time-consuming identification by the SNP analysis or sequencing, a further palindromic DNA sequence was inserted into the vector together with the cDNA of the enzyme (FIG. 6). This small DNA sequence does not change the properties of the cell line that carries the transgene, nor does it change the properties of the enzyme gene or its expression. The small DNA sequence is specific for each of the cell lines and serves as the target for a specific PCR primer that is in Combination with a vector-specific primer or a transgene-specific primer allows unambiguous identification of the cell line in a single PCR reaction (FIG. 6) of unpurified genomic DNA. This enables the cell line that expresses the optimized enzyme to be identified quickly, conveniently and at low cost in a single PCR reaction at the beginning of each experiment or production cycle. This is an important aspect of quality control, for example.

The features of the invention disclosed in the preceding description and in the claims and drawings can be essential both individually and in any combination for realizing the invention in the various embodiments.

Claims

claims

1. DNA construct for transfection of cells, comprising a mutated foreign gene which differs only slightly in its sequence from other foreign genes to be examined, and a specific marker DNA lying outside the foreign gene, this marker DNA having at least one random sequence and this marker DNA comprises between 10 and 500 nucleotides.

2. DNA construct according to claim 1, wherein the marker DNA comprises between 15 and 60 nucleotides.

3. DNA construct according to claim 1 or 2, wherein the random sequence is unique to the cell genome.

4. DNA construct according to one of claims 1 to 3, wherein the marker DNA is flanked by identical or different restriction enzyme sites

5. DNA construct according to one of claims 1 to 4, wherein the marker DNA is designed as an inverted repeat or palindrome.

6. DNA construct according to one of claims 1 to 5, wherein the random sequence of the marker DNA is designed as an inverted repeat or palindrome.

7. DNA construct according to one of claims 1 to 6, wherein the marker DNA is flanked by identical or different restriction enzyme sites

8. DNA construct according to one of claims 1 to 7, wherein the sequence of the foreign gene to be examined differs from other foreign genes to be examined by the exchange of individual nucleotides, smaller sequence segments, or sequences coding for individual amino acids or smaller amino acid sequences.

9. A method for identifying animal cell lines, wherein a) a DNA construct according to one of claims 1 to 8 is introduced into the cell line, and b) the marker DNA is detected by means of a suitable method via PCR.

10. The method of claim 9, wherein the appropriate method of detecting the marker DNA comprises using labeled probes.

11. The method according to claim 9 or 10, wherein the marker DNA comprises between 10 and 500 nucleotides.

12. The method of claim 11, wherein the marker DNA comprises between 15 and 60 nucleotides.

13. The method according to any one of claims 9 to 12, wherein at least the random sequence is unique to the cell genome.

14. The method according to any one of claims 9 to 13, wherein combinations of at least two marker DNA sequences are used.

15. The method according to any one of claims 9 to 14, wherein the marker DNA is flanked by identical or different restriction enzyme sites.

16. The method according to any one of claims 9 to 15, wherein at least one of the oligonucleotides used for the detection of the marker DNA is complementary to the marker DNA and another oligonucleotide is complementary to a region outside the marker DNA.

17. The method according to any one of claims 9 to 16, wherein the marker DNA is designed as an inverted repeat or palindrome.

18. The method according to any one of claims 9 to 17, wherein the random sequence of the marker DNA is designed as an inverted repeat or palindrome.

19. A method for mutagenesis and detection of foreign genes, comprising suitable mutagenesis of a foreign gene in such a way that the sequence of the mutated foreign gene differs from other foreign genes to be selected by the exchange of individual nucleotides, smaller sequence segments, individual amino acids or smaller amino acid sequences,

Cloning the mutated foreign gene into a DNA construct which comprises a specific marker DNA lying outside the foreign gene, this marker DNA having at least one random sequence and this marker DNA comprising between 10 and 500 nucleotides,

Transfection of the resulting DNA construct into a cell, and detection of the mutated foreign gene via PCR using the marker DNA.

20. Kit for carrying out a method according to any one of claims 9 to 19, which contains at least the following components, a) a marker DNA which has at least one random sequence, b) an oligonucleotide which has an at least partially complementary sequence to the random sequence.

21. Kit for carrying out a method according to one of claims 9 to 19, which contains at least the following constituents, a) a vector set, the vectors having different marker DNA sequences which each have at least one random sequence, b) oligonucleotides, which in each case has sequences which are at least partially complementary to the random sequences.