Matthew T. Montgomery
University of Pittsburgh
Network
Latest external collaboration on country level. Dive into details by clicking on the dots.
Publication
Featured researches published by Matthew T. Montgomery.
Nature microbiology | 2017
Rebekah M. Dedrick; Deborah Jacobs-Sera; Carlos Bustamante; Rebecca A. Garlena; Travis N. Mavrich; Welkin H. Pope; Juan C. Cervantes Reyes; Daniel A. Russell; Tamarah L. Adair; Richard Alvey; J. Alfred Bonilla; Jerald S. Bricker; Bryony R. Brown; Deanna Byrnes; Steven G. Cresawn; William B. Davis; Leon A. Dickson; Nicholas P. Edgington; Ann M. Findley; Urszula Golebiewska; Julianne H. Grose; Cory F. Hayes; Lee E. Hughes; Keith W. Hutchison; Sharon Isern; Allison Johnson; Margaret A. Kenna; Karen Klyczek; Catherine M. Mageeney; Scott F. Michael
Temperate phages are common, and prophages are abundant residents of sequenced bacterial genomes. Mycobacteriophages are viruses that infect mycobacterial hosts including Mycobacterium tuberculosis and Mycobacterium smegmatis, encompass substantial genetic diversity and are commonly temperate. Characterization of ten Cluster N temperate mycobacteriophages revealed at least five distinct prophage-expressed viral defence systems that interfere with the infection of lytic and temperate phages that are either closely related (homotypic defence) or unrelated (heterotypic defence) to the prophage. Target specificity is unpredictable, ranging from a single target phage to one-third of those tested. The defence systems include a single-subunit restriction system, a heterotypic exclusion system and a predicted (p)ppGpp synthetase, which blocks lytic phage growth, promotes bacterial survival and enables efficient lysogeny. The predicted (p)ppGpp synthetase coded by the Phrann prophage defends against phage Tweety infection, but Tweety codes for a tetrapeptide repeat protein, gp54, which acts as a highly effective counter-defence system. Prophage-mediated viral defence offers an efficient mechanism for bacterial success in host–virus dynamics, and counter-defence promotes phage co-evolution.
Genome Announcements | 2016
Matthew T. Montgomery; Welkin H. Pope; Zachary M. Arnold; Aleksandra Basina; Ankitha M. Iyer; Ty H. Stoner; Naomi S. Kasturiarachi; Catherine A. Pressimone; Johnathon G. Schiebel; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Gordonia phages Bowser and Schwabeltier are newly isolated phages infecting Gordonia terrae 3612. Bowser and Schwabeltier have similar siphoviral morphologies and their genomes are related to each other, but not to other phages. Their lysis cassettes are atypically situated among virion tail genes, and Bowser encodes two tyrosine integrases.
Genome Announcements | 2017
Welkin H. Pope; Matthew T. Montgomery; J. Alfred Bonilla; Randall J. DeJong; Rebecca A. Garlena; Carlos Bustamante; Karen Klyczek; Daniel A. Russell; John T. Wertz; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT We report here the genome sequences of 38 newly isolated bacteriophages using Gordonia terrae 3612 (ATCC 25594) and Gordonia neofelifaecis NRRL59395 as bacterial hosts. All of the phages are double-stranded DNA (dsDNA) tail phages with siphoviral morphologies, with genome sizes ranging from 17,118 bp to 93,843 bp and spanning considerable nucleotide sequence diversity.
Genome Announcements | 2016
Welkin H. Pope; Armaan F. Akbar; Taylor N. Ayers; Selena G. Belohoubek; Connie F. Chung; Allison C. Hartman; Tejus Kayiti; Cecilia M. Kessler; Philipp I. Koman; Grigoriy A. Kotovskiy; Taylor M. Morgan; Rebecca M. Rohac; Gabriela M. Silva; Charles E. Willis; Katherine A. Milliken; Kathleen A. Shedlock; Ann-Catherine J. Stanton; Chelsea L. Toner; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT We describe three newly isolated phages—Obliviate, UmaThurman, and Guacamole—that infect Gordonia terrae 3612. The three genomes are related to one another but are not closely related to other previously sequenced phages or prophages. The three phages are predicted to use integration-dependent immunity systems as described in several mycobacteriophages.
Genome Announcements | 2016
Welkin H. Pope; Aleks K. Brown; Daniel J. Fisher; Nicholas H. Okwiya; Kaitlyn A. Savage; Brian A. German; Jill E. McDonnell; Claire E. Schafer; Victor J. Yu; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Lucky10 is a newly isolated phage of Gordonia terrae 3612 that was recovered from a soil sample in Pittsburgh, PA. Lucky10 has siphoviral morphology and a double-stranded DNA (dsDNA) genome of 42,979 bp, with 70 predicted protein-coding genes. Lucky10 shows little similarity to previously reported Gordonia phages.
Genome Announcements | 2016
Welkin H. Pope; Jameson P. Davis; Sirinya O’Shea; Anastasia C. Pfeiffer; Alexandra N. Rich; Jason C. Xue; Kathleen A. Shedlock; Ann-Catherine J. Stanton; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Hotorobo, Woes, and Monty are newly isolated bacteriophages of Gordonia terrae 3612. The three phages are related, and their genomes are similarly sized (76,972 bp, 73,752 bp, and 75,680 bp for Hotorobo, Woes, and Monty, respectively) and organized. They have extremely long tails and among the longest tape measure protein genes described to date.
Genome Announcements | 2016
Welkin H. Pope; Sharanya Bandla; Alexandra K. Colbert; Fiona G. Eichinger; Michelle B. Gamburg; Stavroula G. Horiates; Jerrica M. Jamison; Dana R. Julian; Whitney A. Moore; Pranav Murthy; Meghan C. Powell; Sydney V. Smith; Nadia Mezghani; Katherine A. Milliken; Paige K. Thompson; Chelsea L. Toner; Megan C. Ulbrich; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Gordonia phages BaxterFox, Kita, Nymphadora, and Yeezy are newly characterized phages of Gordonia terrae, isolated from soil samples in Pittsburgh, Pennsylvania. These phages have genome lengths between 50,346 and 53,717 bp, and encode on average 84 predicted proteins. All have G+C content of 66.6%.
Genome Announcements | 2016
Welkin H. Pope; Anshika Bandyopadhyay; Meghan L. Carlton; Meghan T. Kane; Niyati J. Panchal; Yvonne C. Pham; Zachary J. Reynolds; Michael S. Sapienza; Brian A. German; Jill E. McDonnell; Claire E. Schafer; Victor J. Yu; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Gordonia bacteriophage Yvonnetastic was isolated from soil in Pittsburgh, PA, using Gordonia terrae 3612 as a host. Yvonnetastic has siphoviral morphology and a genome of 98,136 bp, with 198 predicted protein-coding genes and five tRNA genes. Yvonnetastic does not share substantial sequence similarity with other sequenced bacteriophage genomes.
Genome Announcements | 2016
Welkin H. Pope; Madeline J. Guido; Pragnya Iyengar; Jonathan T. Nigra; Matthew B. Serbin; Naomi S. Kasturiarachi; Catherine A. Pressimone; Johnathon G. Schiebel; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT Emalyn is a newly isolated bacteriophage of Gordonia terrae 3612 and has a double-stranded DNA genome 43,982 bp long with 67 predicted protein-encoding genes, 32 of which we can assign putative functions. Emalyn has a prolate capsid and has extensive nucleotide similarity with several previously sequenced phages.
Genome Announcements | 2016
Welkin H. Pope; Emily N. Berryman; Kaitlyn M. Forrest; Lilliana McHale; Anthony T. Wertz; Zenas Zhuang; Naomi S. Kasturiarachi; Catherine A. Pressimone; Johnathon G. Schiebel; Emily C. Furbee; Sarah R. Grubb; Marcie H. Warner; Matthew T. Montgomery; Rebecca A. Garlena; Daniel A. Russell; Deborah Jacobs-Sera; Graham F. Hatfull
ABSTRACT BetterKatz is a bacteriophage isolated from a soil sample collected in Pittsburgh, Pennsylvania using the host Gordonia terrae 3612. BetterKatzs genome is 50,636 bp long and contains 75 predicted protein-coding genes, 35 of which have been assigned putative functions. BetterKatz is not closely related to other sequenced Gordonia phages.
