[Specific aspects for virus safety of raw materials for cellular-based medicinal products]. / Spezifische Aspekte zur Virussicherheit von Produktionshilfsstoffen für somatische Zelltherapie-Arzneimittel.

Virus safety of cell-based medicinal products is a particular challenge. These products are frequently manufactured using various human- or animal-derived starting and raw materials (serum and feeder-cells) in cell culture, which are possible sources for viral contamination. For living or proliferating cells, no methods for virus inactivation (such as heat or chemical treatment) can be used and the options for testing these medicinal products for all possible viral contaminations are very limited. As a consequence, other safety measures, in particular careful selection and testing of starting and raw materials, are very important. For raw materials, attention should be paid to cell-culture additives of biological origin, such as human and bovine serum and porcine trypsin. Whenever possible, manufacturing steps for inactivation and removal of viruses should be introduced as an additional safety measure. In addition, recombinant products from animal cell cultures (such as growth factors, monoclonal antibodies for cell sorting, viral vectors) are used and have to be tested for virus safety.

Characterization of Parvovirus B19 genotype 2 in KU812Ep6 cells.

An infectious parvovirus B19 (B19V) genotype 2 variant was identified as a high-titer contaminant in a human plasma donation. Genome analysis revealed a 138-bp insertion within the p6 promoter. The inserted sequence was represented by an additional 30 bp from the end of the inverted terminal repeat adjacent to a 108-bp element found also, in inverted orientation, at the extreme right end of the unique sequence of the genome. However, despite the profound variations in the promoter region, the pattern of gene expression and DNA replication did not differ between genotype 1 and genotype 2 in permissive erythroid KU812Ep6 cells. Capsid proteins of both genotypes differ in their amino acid sequences. However, equivalent kinetics of virus inactivation at 56 degrees C or pH 4 indicated a comparable physicochemical stability of virus capsids. Sera from six individuals infected by B19V genotype 1 were investigated on cross-neutralization of B19V genotype 2 in vitro. Similar neutralization of both B19V genotypes was observed in sera from three individuals, while the sera from three other individuals showed weaker cross-neutralization for genotype 2. In conclusion, the in vitro replication characteristics and physical stability of B19V capsids are very similar between human parvovirus B19 genotypes 1 and 2, and cross-neutralization indicates a close antigenic relation of genotypes 1 and 2.

The early transcription factor GATA-2 is expressed in classical Hodgkin's lymphoma.

Hodgkin/Reed-Sternberg (HRS) cells of classical Hodgkin's lymphoma (cHL) are thought to be derived from germinal centre B-cells in almost all cases. However, expression profiling has revealed that HRS cells do not show a germinal centre B-cell-like phenotype. Although the nature of this aberrant phenotype and the underlying molecular mechanisms remain largely unknown, it has been reported that the activity of NOTCH1 plays an important role in the growth and survival of HRS cells. In some leukaemic cell lines, the effect of Notch signalling is mediated by the early transcription factor GATA-2. This and the fact that HRS cells lack expression of PU.1, which can repress Gata-2, led to an investigation of GATA-2 expression in HRS cells. GATA-2 expression was found in all the cHL-derived cell lines studied, but not in a Burkitt lymphoma-derived cell line. In addition, 50% of biopsies from patients with cHL contained GATA-2-expressing HRS cells. In contrast, neither normal germinal centre B-cells nor malignant cells of nodular lymphocyte-predominant Hodgkin's lymphoma, Burkitt lymphoma or diffuse large B-cell lymphoma expressed GATA-2. Thus, GATA-2 expression was found specifically in HRS cells of cHL, suggesting that GATA-2 is important in establishing the abnormal B-cell phenotype of HRS cells.

Different susceptibility of B19 virus and mice minute virus to low pH treatment.

BACKGROUND: Parvoviridae are small nonenveloped viruses that are known to be highly resistant to physico-chemical treatments. Because low pH is frequently applied to process intermediates or final products, the impact of such conditions on the human erythrovirus B19 (B19V) and the mouse parvovirus (mice minute virus, MMV) was assessed, which is often used as a model for B19V. Owing to the lack of a suitable cultivation and/or detection system for B19V no such data exist so far. STUDY DESIGN AND METHODS: Virus inactivation was monitored by decrease of infectivity and loss of capsid integrity. Infectious B19V was quantified by detection of virus-specific messenger RNA from Ku812Ep6 cells. To measure capsid integrity, endonucleases were added after exposure to low pH and the encapsidated (endonuclease-protected) virus DNA was quantified by real-time PCR. RESULTS: B19V was inactivated greater than 5 log after 2 hours at pH 4, whereas MMV was resistant over 9 hours. Infectivity data strongly correlated with data obtained by the endonuclease assay. Capsid disintegration was observed in immunoglobulin G as well as in different albumin solutions. Temperature and pH showed concerted impact on B19V capsid disintegration. CONCLUSION: Our data show that B19V is much more vulnerable toward low pH conditions than MMV. Together with the previously reported susceptibility of B19V toward wet heat conditions, low pH is the second treatment where erythrovirus B19V is less resistant than viruses from the parvovirus genus.