Verification of Source Species for an Assembly
As a general principal one can distinguish between reports that a sample i) contains the expected species, ii) does not contain that species, and iii) has no information on this issue.
In particular the recent 18S rRNA analyses has many samples that did not pass that source validation test. However, that does not indicate that these samples are wrong, merely that the 18S analysis does not provide an answer. Accordingly, these are type iii results and a different analysis can validate the sample without conflict.
As we have more reports about each sample, some of them will inevitably conflict. From past experience, some of these reports will not be definite, but may be statements like, "sample <XXXX> is odd, maybe it is not a <SPECIES>." Therefore, each report, will have to classified as to whether it is a robust result or not.
Summary of Multiple Reports
Should there be multiple conflicting reports, analyses judged to be more definite/robust will be preferred. Reports that are specific to that sample are also preferred. The assumption is that if someone has specifically investigated one sample, that is likely a more accurate result than a general project wide analysis.
Samples with significantly conflicting status reports or which remain unvalidated will be flagged for detailed follow-up.
Worrisome Contamination
Significant contamination (other plant material) will be assessed using the same principles. However, the degree to which an analysis is considered definitive may differ between the two analyses.
Combined Assemblies
A report for a source sample used in a combined assembly may or may/not apply to the combined assembly. It will depend on whether the report is positive or negative. Similarly, a report on the combined assembly may or may not also apply to the source materials.
18S rRNA Analysis
To confirm sample source and purity, 1KP assemblies were compared by blastn to a reference set of 18S rRNA sequences derived from the SILVA SSU database (http://www.arb-silva.de/). Only SILVA entries with a clear 18S rRNA annotation in the NCBI nt database were used.
Nuclear 18S sequences were preferred because more reference sequences are available, ensuring a dense sampling across the Viridiplantae. Alignments to chloroplast and mitochondrial SSU sequences were detected by searching for the patterns chloroplast*, plastid, mitochondri* -- and subsequently ignored.
Short and low-identity alignments are not reliable for determining taxonomic sources as they may be taxonomically ambiguous, aligning well with sequences from distantly related species. Hence alignments shorter than 300 bp or with E-values above 10e-9 were also ignored.
Thank you to Shaungxiu Wu (???) and CAS Key Laboratory of Genome Sciences and Information, Beijing) and her group who have done this work.
Categories of Validation
Many 1KP samples contain non-plant sequences especially from bacterial, fungal, or insect sources. This kind of "contamination" is not a problem for most analyses and is described in our summaries as "harmless". It is reported when scaffolds are present for which the best alignments were to non-plant sequences.
A sample source is validated if the best alignments for all of the ribosomal scaffolds are to sequences from species within the same taxonomic family as the sample source. If the best alignment for one of the scaffolds match the expected source at either the genus or species level then this more precise validation was also noted.
Lastly, "worrisome" contamination was reported when a scaffold's best alignment was to a plant species (Viridiplantae, Glaucocystophyceae, Rhodophyceae, Cryptophyceae, Haptophyta, or Stramenopiles) outside of the expected source family. This status does not mean that a problem has occurred, only that more attention is warranted. Final status will be assigned after a manual inspection of the assemblies by plant experts within the 1KP consortium, which is ongoing and not yet complete.
Limitations of Method
Our analysis relies on ribosomal small sub-unit material being assembled from each sample. Because a significant fraction of a cell's RNA is ribosomal, this is likely to be a sensitive detector of contamination. However, if the contamination is from a closely related species, the sequences will co-assemble. Experimentally, we have found that this can happen when ribosome sequences differ by 2% or less. Such contamination will not be reported by our methodologies.
Comparison with Other Results - 1. Barkman
Todd Barkman has constructed trees with SABATH methyltransferase sequences and then manually decided whether samples are taxonomically misplaced. When results from his efforts are compared with the 18S RNA taxonomic validation they agree for 94% of samples.
Barkman's Classification | 18S Validated | Not Validated | No 18S Result |
---|---|---|---|
Taxonomically Good | 831 | 35 | 18 |
Problems/Questionable | 18 | 12 | 1 |
No Data | 376 | 25 | 11 |
His detailed report with an assessment for each assembly is available 1kp-Barkman.xlsx. The category codes are explained on the second sheet of the workbook. The above table groups categories 1-3 and 4-5. Also available is a spreadsheet listing samples which failed either source validation Sample Source Issues.xlsx.
Comparison with Other Results - 2. Mirarab
A number of samples have noticeably odd locations in the capstone test MAFFT tree produced by Siavash Mirarab. These are:
LVNW | Basal Eudicots | Cocculus laurifolius |
WPYJ | Magnoliids | Frankenia laevis |
DYFF | Core Eudicots/Asterids | Pycnanthemum tenuifolium |
XMQO | Basal Eudicots | Gunnera manicata |
JLLY | Core Eudicots/Rosids | Melaleuca quinquenervia |
CYVA | Basal Eudicots | Cimicifuga racemosa |
QJXB | Core Eudicots/Rosids | Wikstroemia indica |
FWBF | Core Eudicots | Alangium chinense |
FONV | Core Eudicots/Rosids | Greyia sutherlandii |
NPND | Basalmost angiosperms | Ceratophyllum demersum |
ULGV | Core Eudicots/Asterids | Morinda citrifolia |
JBGU | Core Eudicots | Amaranthus palmeri |
YMES | Monocots/Commelinids | Typhonium blumei |
JBLI | Eusporangiate Monilophytes | Bolbitis repanda |
FITN | Liverworts | Treubia lacunosa |
NIJU | Core Eudicots/Rosids | Heteropyxis natalensis |
UZNH | Core Eudicots/Asterids | Curtisia dentata |
IQJU | Hornworts | Anthoceros formosae |
FANS | Hornworts | Leiosporoceros dussii |
Comparison with Other Results - 3. Human Genome
For each of the datasets was mapped to a human genome reference (available at https://www.ncbi.nlm.nih.gov/assembly/GCF_000001405.29 ) using Bowtie 2 (version 2.2.4). Then the number of read-pairs that cleanly aligned was counted.
This provides a count of human-like reads in the library. For most samples these reads are small fraction of the total. However, a few cases have much larger counts suggesting that substantial contamination with human material may have occurred. A spreadsheet with details is here.
This technique is not intend to be perfect, but provides a rapid estimate. For RNA contamination the result wlll be an under-count, as introns will prevent the reads from aligning with the genome and being counted. Similarly, read-ends that do not align in the expected paired-end fashion are not counted.
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