PICRUSt[1] is a bioinformatics software package. The name is an abbreviation for Phylogenetic Investigation of Communities by Reconstruction of Unobserved States.

Original author(s)Morgan Langille, Jesse Zaneveld, Dan Knights, Joshua A Reyes, Jose C Clemente, Deron E Burkepile, Rebecca L Vega Thurber, Rob Knight, Robert G Beiko, Curtis Huttenhower
Developer(s)Morgan Langille, Jesse Zaneveld, Daniel McDonald, Greg Caporaso, Gavin Douglas
Initial release29 July 2013; 11 years ago (2013-07-29)
Written inPython, R
Websitepicrust.github.io/picrust/

The tool serves in the field of metagenomic analysis where it allows inference of the functional profile of a microbial community based on marker gene survey along one or more samples. In essence, PICRUSt takes a user supplied operational taxonomic unit table (typically referred to as an OTU table), representing the marker gene sequences (most commonly a 16S cluster) accompanied with its relative abundance in each of the samples. The output of PICRUSt is a sample by functional-gene-count matrix, telling the count of each functional-gene in each of the samples surveyed. The ability of PICRUSt to estimate the functional-gene profile for a given sample relies on a set of known sequenced genomes. This could also be thought of as an automated alternative to manually researching the gene families likely to be present in organisms whose sequences are found in a 16S ribosomal RNA amplicon library. The below description corresponds to the original version of PICRUSt, but a major update to this tool is currently being developed.[2]

Genome prediction algorithm

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In an initial preprocessing phase, PICRUSt constructs confidence intervals and point predictions for the number of copies of each gene family in each bacterial and archaeal strain in a reference tree, using organisms with sequenced genomes as a reference. More specifically, for each gene family, PICRUSt maps known gene copy numbers (from complete sequenced genomes) onto a reference tree of life. These gene family copy numbers are treated as continuous traits, and an evolutionary model constructed under the assumption of Brownian Motion. These evolutionary models can be constructed with either Maximum Likelihood, Relaxed Maximum Likelihood or Wagner Parsimony This evolutionary model is then used to predict both a point estimate and a confidence interval for the copy number of microorganisms without sequenced genomes. This 'genome prediction' step produces a large table of bacterial types (specifically operational taxonomic unit or OTUs) vs. gene family copy numbers. This table is distributed to end users. It is important to note that this prediction method is not the same as a nearest neighbor approach (i.e. just looking up the nearest sequenced genome), and was shown to give a small but significant improvement in accuracy over that strategy. However, nearest neighbor prediction is available as an option in PICRUSt.

Notably, while this functionality is typically used for prediction of gene copy numbers in bacteria, it could, in principle, be used for prediction of any other continuous trait given trait data for diverse organisms and a reference phylogeny.

Langille et al.[1] tested the accuracy of this genome prediction step using leave-one-out cross validation on the input set of sequenced genomes. Additional tests examined sensitivity to errors in phylogenetic inference, lack of genomic data, and the accuracy of the confidence intervals on gene content.

A similar step predicts the copy number of 16S rRNA genes.

Metagenome prediction algorithm

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When applying PICRUSt to a 16S rRNA gene library, PICRUSt matches reference operational taxonomic units against the tables, and retrieves a predicted 16S rRNA copy number and gene copy number for each gene family. The abundance of each OTU is divided by its predicted copy number (if a bacterium has multiple 16S copies, its apparent abundance in 16S rRNA data will be inflated), and then multiplied by the copy number of the gene family. This gives a prediction for the contribution of each OTU to the overall gene content of the sample (the metagenome). Finally, these individual contributions are summed together to produce an estimate of the genes present in the metagenome.

Langille et al., 2013[1] tested the accuracy of this genome prediction step by using previously reported datasets in which the same biological sample was subjected to 16S rRNA gene amplification and shotgun metagenomics. In these cases, the shotgun metagenomic results were taken as a representation of the 'true' community, and the 16S rRNA gene amplicon libraries fed into PICRUSt to attempt to predict those data. Test datasets included human microbiome samples from the Human Microbiome Project, soil samples, diverse mammalian samples, and samples from the Guerrero Negro microbial mats

The Nearest Sequenced Taxon Index

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Because PICRUSt, and evolutionary comparative genomics in general, depends on sequenced genomes, biological samples from well-studied environments (many sequenced genomes) will be better predicted than poorly studied environments. In order to assess how many genomes are available, PICRUSt optionally allows users to calculate a Nearest Sequenced Taxon Index (NSTI) for their samples. This index reflects the average phylogenetic distance between each 16S rRNA gene sequence in their sample, and a 16S rRNA gene sequence from a fully sequenced genome. In general, the lower the NSTI score, the more accurate PICRUSt's predictions are expected to be. For example,[1] showed that PICRUSt was much more accurate on diverse soil samples and samples from the Human Microbiome Project than on microbial mat samples from Guerrero Negro, which contained many bacteria without any sequenced relatives.

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Okuda et al., 2012[3] published a similar method that used a bounded k-Nearest Neighbor approach to predict virtual metagenomes. They validated their approach using 16S rRNA gene sequences extracted from shotgun metagenomes, and compared the predictions of their method against the full metagenome.

CopyRighter,[4] like PICRUSt, uses evolutionary modeling and phylogenetic trait prediction to estimate 16S rRNA gene sequence copy numbers for each bacterial and archaeal type in a sample, and then uses these estimates to correct estimates of community composition.

PanFP[5] presented a similar method, but based on genome predictions for each taxonomic group. Benchmarking showed highly similar performance to PICRUSt when compared on the same datasets. One advantage is that all OTUs, not just those in a reference phylogeny table can be used. One disadvantage is that confidence intervals and evolutionary models are not constructed.

PAPRICA[6] is a metagenome prediction tool based on placing input 16S rRNA gene sequences into a known phylogenetic tree based corresponding to reference genomes. The main prediction output corresponds to Enzyme Commission numbers.

Piphillin[7] is a tool produced by the company Second Genome that produces metagenome predictions based on nearest-neighbour clustering of input 16S rRNA gene sequences with 16S rRNA gene sequences from reference genomes. There is a web portal for running this tool on the Second Genome website. This tool is under continual development and undergoing validation as summarized in a 2020 publication.[8]

Tax4Fun[9] is a similar tool based on linking the 16S ribosomal RNA genes from all KEGG organisms with 16S rRNA gene sequences found in the SILVA ribosomal RNA database. Originally this tool was restricted to 16S rRNA gene sequences found within the SILVA database. However, the latest version of this tool, Tax4Fun2, can be used with OTUs or amplicon sequence variants from any clustering pipeline.

References

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  1. ^ a b c d Langille, Morgan G I; Zaneveld, Jesse; Caporaso, J Gregory; McDonald, Daniel; Knights, Dan; Reyes, Joshua A; Clemente, Jose C; Burkepile, Deron E; Vega Thurber, Rebecca L; Knight, Rob; Beiko, Robert G; Huttenhower, Curtis (2013). "Predictive functional profiling of microbial communities using 16S rRNA marker gene sequences" (PDF). Nature Biotechnology. 31 (9): 814–821. doi:10.1038/nbt.2676. ISSN 1087-0156. PMC 3819121. PMID 23975157.
  2. ^ Douglas, Gavin; Maffei, Vince; Zaneveld, Jesse; Yurgel, Svetlana; Brown, James; Taylor, Christopher; Huttenhower, Curtis; Langille, Morgan (2020). "PICRUSt2: An improved and customizable approach for metagenome inference". bioRxiv. doi:10.1101/672295.
  3. ^ Okuda, Shujiro; Tsuchiya, Yuki; Kiriyama, Chiho; Itoh, Masumi; Morisaki, Hisao (2012). "Okuda et al., 2012". Nature Communications. 3: 1203. doi:10.1038/ncomms2203. PMID 23149747.
  4. ^ Angly, Florent E; Dennis, Paul G; Skarshewski, Adam; Vanwonterghem, Inka; Hugenholtz, Philip; Tyson, Gene W (2014). "CopyRighter: a rapid tool for improving the accuracy of microbial community profiles through lineage-specific gene copy number correction". Microbiome. 2: 11. doi:10.1186/2049-2618-2-11. PMC 4021573. PMID 24708850.
  5. ^ Jun, Se-Ran; Robeson, Michael S.; Hauser, Loren J.; Schadt, Christopher W.; Gorin, Andrey A. (2015). "PanFP: pangenome-based functional profiles for microbial communities". BMC Research Notes. 8: 479. doi:10.1186/s13104-015-1462-8. PMC 4584126. PMID 26409790.
  6. ^ Bowman, Jeff; Ducklow, Hugh (2015). "Microbial Communities Can Be Described by Metabolic Structure: A General Framework and Application to a Seasonally Variable, Depth-Stratified Microbial Community from the Coastal West Antarctic Peninsula". PLOS ONE. 10 (8): e0135868. Bibcode:2015PLoSO..1035868B. doi:10.1371/journal.pone.0135868. PMC 4540456. PMID 26285202.
  7. ^ Iwai, Shoko; Weinmaier, Thomas; Schmidt, Brian; Albertson, Donna; Poloso, Neil; Dabbagh, Karim; DeSantis, Todd (2016). "Piphillin: Improved Prediction of Metagenomic Content by Direct Inference from Human Microbiomes". PLOS ONE. 11 (11): e0166104. Bibcode:2016PLoSO..1166104I. doi:10.1371/journal.pone.0166104. PMC 5098786. PMID 27820856.
  8. ^ Narayan, Nicole; Weinmaier, Thomas; Laserna-Mendieta, Emilio; Claesson, Marcus; Shanahan, Fergus; Dabbagh, Karim; Iwai, Shoko; DeSantis, Todd (2020). "Piphillin predicts metagenomic composition and dynamics from DADA2-corrected 16S rDNA sequences". BMC Genomics. 21 (1): 56. doi:10.1186/s12864-019-6427-1. PMC 6967091. PMID 31952477.
  9. ^ Aßhauer, Kathrin; Wemheuer, Bernd; Daniel, Rolf; Meinicke, Peter (2015). "Tax4Fun: predicting functional profiles from metagenomic 16S rRNA data". Bioinformatics. 31 (17): 2882–2884. doi:10.1093/bioinformatics/btv287. PMC 4547618. PMID 25957349.