Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data

Bhavya Papudeshi; Michael J. Roach; Vijini Mallawaarachchi; George Bouras; Susanna R. Grigson; Sarah K. Giles; Clarice M. Harker; Abbey L.K. Hutton; Anita Tarasenko; Laura K. Inglis; Alejandro A. Vega; Cole Souza; Lance Boling; Hamza Hajama; Ana Georgina Cobián Güemes; Anca M. Segall; Elizabeth A. Dinsdale; Robert A. Edwards

doi:10.1093/bioadv/vbaf004

Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data

Bhavya Papudeshi, Michael J. Roach, Vijini Mallawaarachchi, George Bouras, Susanna R. Grigson, Sarah K. Giles, Clarice M. Harker, Abbey L.K. Hutton, Anita Tarasenko, Laura K. Inglis, Alejandro A. Vega, Cole Souza, Lance Boling, Hamza Hajama, Ana Georgina Cobián Güemes, Anca M. Segall, Elizabeth A. Dinsdale, Robert A. Edwards

Research output: Contribution to journal › Article › peer-review

16 Downloads (Pure)

Abstract

Motivation: Phage therapy offers a viable alternative for bacterial infections amid rising antimicrobial resistance. Its success relies on selecting safe and effective phage candidates that require comprehensive genomic screening to identify potential risks. However, this process is often labor intensive and time-consuming, hindering rapid clinical deployment.

Results: We developed Sphae, an automated bioinformatics pipeline designed to streamline the therapeutic potential of a phage in under 10 minutes. Using Snakemake workflow manager, Sphae integrates tools for quality control, assembly, genome assessment, and annotation tailored specifically for phage biology. Sphae automates the detection of key genomic markers, including virulence factors, antimicrobial resistance genes, and lysogeny indicators such as integrase, recombinase, and transposase, which could preclude therapeutic use. Among the 65 phage sequences analyzed, 28 showed therapeutic potential, 8 failed due to low sequencing depth, 22 contained prophage or virulent markers, and 23 had multiple phage genomes. This workflow produces a report to assess phage safety and therapy suitability quickly. Sphae is scalable and portable, facilitating efficient deployment across most high-performance computing and cloud platforms, accelerating the genomic evaluation process.

Original language	English
Article number	vbaf004
Number of pages	12
Journal	Bioinformatics Advances
Volume	5
Issue number	1
DOIs	https://doi.org/10.1093/bioadv/vbaf004
Publication status	Published - 17 Jan 2025

Keywords

genome analysis
phage therapy
bioinformatics

Access to Document

10.1093/bioadv/vbaf004Licence: CC BY

Final published versionFinal published version, 1.48 MBLicence: CC BY

Cite this

Papudeshi, B., Roach, M. J., Mallawaarachchi, V., Bouras, G., Grigson, S. R., Giles, S. K., Harker, C. M., Hutton, A. L. K., Tarasenko, A., Inglis, L. K., Vega, A. A., Souza, C., Boling, L., Hajama, H., Cobián Güemes, A. G., Segall, A. M., Dinsdale, E. A., & Edwards, R. A. (2025). Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data. Bioinformatics Advances, 5(1), Article vbaf004. https://doi.org/10.1093/bioadv/vbaf004

@article{0d4d8907975c47fc8d4b4a7adb0fcc93,

title = "Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data",

abstract = "Motivation: Phage therapy offers a viable alternative for bacterial infections amid rising antimicrobial resistance. Its success relies on selecting safe and effective phage candidates that require comprehensive genomic screening to identify potential risks. However, this process is often labor intensive and time-consuming, hindering rapid clinical deployment. Results: We developed Sphae, an automated bioinformatics pipeline designed to streamline the therapeutic potential of a phage in under 10 minutes. Using Snakemake workflow manager, Sphae integrates tools for quality control, assembly, genome assessment, and annotation tailored specifically for phage biology. Sphae automates the detection of key genomic markers, including virulence factors, antimicrobial resistance genes, and lysogeny indicators such as integrase, recombinase, and transposase, which could preclude therapeutic use. Among the 65 phage sequences analyzed, 28 showed therapeutic potential, 8 failed due to low sequencing depth, 22 contained prophage or virulent markers, and 23 had multiple phage genomes. This workflow produces a report to assess phage safety and therapy suitability quickly. Sphae is scalable and portable, facilitating efficient deployment across most high-performance computing and cloud platforms, accelerating the genomic evaluation process.",

keywords = "genome analysis, phage therapy, bioinformatics",

author = "Bhavya Papudeshi and Roach, {Michael J.} and Vijini Mallawaarachchi and George Bouras and Grigson, {Susanna R.} and Giles, {Sarah K.} and Harker, {Clarice M.} and Hutton, {Abbey L.K.} and Anita Tarasenko and Inglis, {Laura K.} and Vega, {Alejandro A.} and Cole Souza and Lance Boling and Hamza Hajama and {Cobi{\'a}n G{\"u}emes}, {Ana Georgina} and Segall, {Anca M.} and Dinsdale, {Elizabeth A.} and Edwards, {Robert A.}",

year = "2025",

month = jan,

day = "17",

doi = "10.1093/bioadv/vbaf004",

language = "English",

volume = "5",

journal = "Bioinformatics Advances",

issn = "2635-0041",

publisher = "Oxford University Press",

number = "1",

}

Papudeshi, B, Roach, MJ , Mallawaarachchi, V, Bouras, G, Grigson, SR , Giles, SK, Harker, CM, Hutton, ALK, Tarasenko, A, Inglis, LK, Vega, AA, Souza, C, Boling, L, Hajama, H, Cobián Güemes, AG, Segall, AM, Dinsdale, EA & Edwards, RA 2025, 'Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data', Bioinformatics Advances, vol. 5, no. 1, vbaf004. https://doi.org/10.1093/bioadv/vbaf004

TY - JOUR

T1 - Sphae

T2 - an automated toolkit for predicting phage therapy candidates from sequencing data

AU - Papudeshi, Bhavya

AU - Roach, Michael J.

AU - Mallawaarachchi, Vijini

AU - Bouras, George

AU - Grigson, Susanna R.

AU - Giles, Sarah K.

AU - Harker, Clarice M.

AU - Hutton, Abbey L.K.

AU - Tarasenko, Anita

AU - Inglis, Laura K.

AU - Vega, Alejandro A.

AU - Souza, Cole

AU - Boling, Lance

AU - Hajama, Hamza

AU - Cobián Güemes, Ana Georgina

AU - Segall, Anca M.

AU - Dinsdale, Elizabeth A.

AU - Edwards, Robert A.

PY - 2025/1/17

Y1 - 2025/1/17

N2 - Motivation: Phage therapy offers a viable alternative for bacterial infections amid rising antimicrobial resistance. Its success relies on selecting safe and effective phage candidates that require comprehensive genomic screening to identify potential risks. However, this process is often labor intensive and time-consuming, hindering rapid clinical deployment. Results: We developed Sphae, an automated bioinformatics pipeline designed to streamline the therapeutic potential of a phage in under 10 minutes. Using Snakemake workflow manager, Sphae integrates tools for quality control, assembly, genome assessment, and annotation tailored specifically for phage biology. Sphae automates the detection of key genomic markers, including virulence factors, antimicrobial resistance genes, and lysogeny indicators such as integrase, recombinase, and transposase, which could preclude therapeutic use. Among the 65 phage sequences analyzed, 28 showed therapeutic potential, 8 failed due to low sequencing depth, 22 contained prophage or virulent markers, and 23 had multiple phage genomes. This workflow produces a report to assess phage safety and therapy suitability quickly. Sphae is scalable and portable, facilitating efficient deployment across most high-performance computing and cloud platforms, accelerating the genomic evaluation process.

AB - Motivation: Phage therapy offers a viable alternative for bacterial infections amid rising antimicrobial resistance. Its success relies on selecting safe and effective phage candidates that require comprehensive genomic screening to identify potential risks. However, this process is often labor intensive and time-consuming, hindering rapid clinical deployment. Results: We developed Sphae, an automated bioinformatics pipeline designed to streamline the therapeutic potential of a phage in under 10 minutes. Using Snakemake workflow manager, Sphae integrates tools for quality control, assembly, genome assessment, and annotation tailored specifically for phage biology. Sphae automates the detection of key genomic markers, including virulence factors, antimicrobial resistance genes, and lysogeny indicators such as integrase, recombinase, and transposase, which could preclude therapeutic use. Among the 65 phage sequences analyzed, 28 showed therapeutic potential, 8 failed due to low sequencing depth, 22 contained prophage or virulent markers, and 23 had multiple phage genomes. This workflow produces a report to assess phage safety and therapy suitability quickly. Sphae is scalable and portable, facilitating efficient deployment across most high-performance computing and cloud platforms, accelerating the genomic evaluation process.

KW - genome analysis

KW - phage therapy

KW - bioinformatics

UR - http://www.scopus.com/inward/record.url?scp=85216973437&partnerID=8YFLogxK

UR - http://purl.org/au-research/grants/ARC/DP220102915

U2 - 10.1093/bioadv/vbaf004

DO - 10.1093/bioadv/vbaf004

M3 - Article

AN - SCOPUS:85216973437

SN - 2635-0041

VL - 5

JO - Bioinformatics Advances

JF - Bioinformatics Advances

IS - 1

M1 - vbaf004

ER -

Sphae: an automated toolkit for predicting phage therapy candidates from sequencing data

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this