1, p = 0 91 Median SF-36 physical function, IQR 41, 27-48 48, 39-

1, p = 0.91 Median SF-36 physical function, IQR 41, 27-48 48, 39-52 Paired t44 = 3.1, p = 0.003 Median SF-36 mental function, IQR 39, 29-48 Tariquidar datasheet 51, 39-56 Paired t44 = 4.7, p = 3 × 10-5 Median current fatigue by VAS, IQR 69, 49-77 19, 10-51 Paired t43 = -7.2, p = 6 × 10-9 Abbreviations: IQR = inter-quartile range, VAS = visual analogue scale (0-100). Using metagenomic

sequencing to identify viral signatures Serum samples from the affected and unaffected twins were pooled separately and enriched for viral particles. This resulted in four samples to be sequenced in order to detect RNA and DNA viruses: a DNA sample and a cDNA sample for pooled samples from affected and unaffected twins. Sanger sequencing was performed from all four samples, resulting in a total of 1,549 Liproxstatin-1 nmr sequences from affected twins and 1,513 from unaffected twins. Automated BLAST searches followed by manual inspection showed that all reads from the unaffected twins were from background contamination (mostly human or bacterial) or from reagents used for the library preparation (Figure 1). A small number of sequences showed no or selleck inhibitor only insignificant BLAST hits but manual

inspection did not reveal any artifacts and these could represent low abundance viral sequences. In contrast, the sequences from the pool of affected twins showed multiple hits to two known human viruses. In total, 168/1,549 sequences showed a significant BLAST identity to GB virus C (GBV-C) and 15/1,549 to hepatitis C virus. The numbers Thiamet G of sequences were relatively high indicating that one or more affected twins had high copy numbers for these viruses. No other significant hits to human viruses were observed. Figure 1 Comparison of BLAST results from Sanger reads (post-assembly) that were classified with high confidence from twins affected with chronic fatiguing illness (panel A) and their unaffected co-twins (panel B). The results show a large viral fraction in affected samples and no

viral sequences in unaffected samples. A next-generation sequencing technology, Roche 454 FLX, was used to search for rare viruses in samples from affected twins. A total of 53,985 sequence reads (9.1 Mb) were produced from the DNA sample and 305,191 reads (59.5 Mb) from the RNA (+RT) sample. The six-fold difference in the numbers of reads was most likely caused by different efficiencies of the 454 library preparation and the amounts of DNA obtained. The reads were analyzed using our BLAST search pipeline, both unassembled and assembled (together with the Sanger reads after removal of most human sequences) using the miraEST assembler. The assembly results are shown in Tables 2, 3, and 4. The BLAST results are summarized in Figure 2 and Additional file 1 Figures S1 and S2.

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