DNA fingerprinting transforms the art of cell authentication.

The increasing diversity of new cell cultures is seriously stretching the capabilities of traditional methods of identification. DNA fingerprinting is set to play an important role in increasing confidence in the authenticity of cultures in research and industry.

Multilocus DNA fingerprint analysis of cell banks: stability studies and culture identification in human B-lymphoblastoid and mammalian cell lines.

The technique of multilocus DNA fingerprinting has great potential for the authentication of animal cell cultures and in identification of cross-contamination. The Alec Jeffreys probes 33.6 and 33.15 were used as multilocus probes to demonstrate the consistent DNA fingerprint profiles in human peripheral blood and its derivative Epstein-Barr virus (EBV) transformed B-lymphoblastoid cultures maintained by repeated subculture for six months. However, fingerprint analysis of EBV transformed cultures generated from small numbers of cells showed that the majority (seven of eight cultures) had anomalous profiles. Some of these altered profiles shared common features not seen in the peripheral blood pattern. Analysis of seven murine hybridoma clones from a single fusion experiment revealed only two clones which could not be distinguished using probe 33.15. Further studies of master and distribution cell banks for eleven cell lines demonstrated consistent fingerprint profiles in all cases except one (U937). However, this cell line showed only minor differences in the master and distribution bank profiles. These data indicate that, while changes in fingerprint profile may be identified in exceptional instances, the multilocus fingerprinting method using probes 33.6 and 33.15 is a powerful and reliable tool in the quality control of animal cell cultures.

The quality control of cell banks using DNA fingerprinting.

Reproducibility in animal cell culture technology requires careful preparation and characterisation of banks of cell cultures. The two standard techniques used in the quality control of such banks are isoenzyme analysis and cytogenetics which require complex and time-consuming procedures to enable cell line identification. However, DNA fingerprinting is potentially a more powerful method of analysis which can detect mutation and intra-species cross-contamination. At the European Collection of Animal Cell Cultures (ECACC) multilocus fingerprint analysis using probes 33.6 and 33.15 has been assessed in the quality control of cell banks. This method has confirmed consistency between master and working banks, has proven useful over a wide species range and can differentiate closely related cell lines. The key advantage of this method is its ability to detect cross-contamination by cell lines from a wide range of species using a straightforward and economical test. In addition the reproducibility of DNA fingerprints indicates their possible role in cell line authentication procedures which are important for patent and product licence applications.

Ksp632I, a novel class-IIS restriction endonuclease from Kluyvera sp. strain 632 with the asymmetric hexanucleotide recognition sequence: 5'-CTCTTC(N)1-3' 3'-GAGAAG(N)4-5'.

A new class-IIS restriction endonuclease, Ksp632I, with novel sequence specificity has been discovered in a non-pathogenic species of Kluyvera. The presence of only a single site-specific activity in this Kluyvera sp. strain 632 enables Ksp632I to be isolated in highly purified form free of contaminating nucleases. Ksp632I recognition sites and cleavage positions were deduced using experimental and computer-assisted mapping and sequencing. The cleavage specificity corresponds to the sequence 5'-CTCTTCN decreases NNN-N-3' 3'-GAGAAGN-NNN increases N-5'. The enzyme recognizes an asymmetric hexanucleotide sequence and cleaves in the presence of Mg2+ ions specific phosphodiester bonds in both DNA strands, 1 and 4 nucleotides distal to the recognition sequence. The staggered cuts generate 5'-protruding ends with single-stranded 5'-phosphorylated trinucleotides. Several slow cleavage sites for Ksp632I were observed on lambda cI857Sam7 DNA. Ksp632I may complement other class-IIS enzymes in the universal restriction approach and may serve as a tool for generating defined unidirectional deletions or insertions.