Impact of pre-analytical handling on bone marrow mRNA gene expression.

Large clinical trials on leukaemia, require the transport of bone marrow (BM) from participating clinics to central diagnostic laboratories. We have investigated the impact of RNA extraction protocols and time delays between sample aspiration and RNA extraction on RNA quality and gene expression profiles. Intact RNA can be extracted from BM samples stored at room temperature for up to 48 h. Gene expression analyses using Affymetrix U95Av2 GeneChips and a custom-designed cDNA array in parallel showed that even short-term storage of BM has dramatic effects on mRNA expression of individual transcripts. Many probe sets/genes showed either reproducible deregulation (18.8%, analysis of variance <0.05), or inconsistent expression that differed from patient to patient (38.4%). Moderate alterations were observed in 42.8% genes, with a maximum fold change <2.0 in all experiments and at all time points. These profound effects complicate the use of unstabilized, shipped BM samples for gene expression analyses. The comparison of a variety of RNA stabilization reagents (e.g. PAXgene) resulted in partial conservation of the mRNA expression patterns. Immediate density centrifugation or erythrocyte lysis and freezing at -80 degrees C represent simple procedures that reliably preserved mRNA gene expression patterns in BM.

Characterization of viral-cellular fusion transcripts in a large series of HPV16 and 18 positive anogenital lesions.

Persistent high risk type human papillomavirus (HR-HPVs) infections induce dysplasia or cancer of the anogenital tract, most notably of the uterine cervix. The viral genome usually persists and replicates as an episomal molecule in early dysplasia, whereas in advanced dysplasia or cervical cancer HPV genomes are frequently integrated into the chromosomal DNA of the host cell. Previous studies suggested that modification of critical cellular sequences by integration of HPV genomes might significantly contribute to the neoplastic transformation of anogenital epithelia (insertional mutagenesis). This prompted us to characterize the integration loci of high risk HPV genomes in a large set of genital lesions. We amplified E6/E7 oncogene transcripts derived from integrated HPV16 and HPV18 genomes and characterized in detail the co-transcribed cellular sequences of 64 primary genital lesions and five cervical cancer cell lines. Database analyses of the cellular parts of these fusion transcripts revealed 51 different integration loci, including 26 transcribed genes (14 known genes, 12 EST sequences with unknown gene function). Seventeen sequences showed similarity to repetitive elements, and 26 sequences did not show any database match other than genomic sequence. Chromosomal integration loci were distributed over almost all human chromosomes. Although we found HPV sequences integrated into cancer related genes and close to fragile sites, no preferential site or integration motif could be identified. These data demonstrate that target directed insertional mutagenesis might occur in few HPV-induced anogenital lesions, however, it is rather the exception than the rule.