Ticks and Tick-Borne Diseases (Nov 2023)

Functional analysis of Rickettsia monacensis strain humboldt folA dihydrofolate reductase gene via complementation assay

  • Brandon Hill,
  • Ben Schafer,
  • Nolan Vargas,
  • Danny Zamora,
  • Rohan Shrotri,
  • Sarahi Perez,
  • Geoffrey Farmer,
  • Aren Avon,
  • Anirudh Pai,
  • Hirotada Mori,
  • Jianmin Zhong

Journal volume & issue
Vol. 14, no. 6
p. 102217

Abstract

Read online

Nutritive symbiosis between bacteria and ticks is observed across a range of ecological contexts; however, little characterization on the molecular components responsible for this symbiosis has been done. Previous studies in our lab demonstrated that Rickettsia monacensis str. Humboldt (strain Humboldt) can synthesize folate de novo via the folate biosynthesis pathway involving folA, folC, folE, folKP, and ptpS genes. In this study, expression of the strain Humboldt folA gene within a folA mutant Escherichia coli construct was used to functionally characterize the strain Humboldt folA folate gene in vivo. The strain Humboldt folA folate gene was subcloned into a TransBac vector and transformed into a folA mutant E. coli construct. The mutant containing strain Humboldt folA subclone and a pFE604 clone of the knocked-out folA gene was cured of pFE604. Curing of the folA mutant E. coli construct was successful using acridine orange and 43.5 °C incubation temperature. The plasmid curing assay showed curing efficiency of the folA mutant at 100%. Functional complementation was assessed by growth phenotype on minimal media with and without IPTG between strain Humboldt folA and E. coli folA. Large and homogenous wild-type colony growth was observed for both strain Humboldt and E. coli folA on minimal media with 0.1 mM IPTG, wild-type growth for strain Humboldt folA and pin-point growth for E. coli folA on 0.01 mM IPTG, and pin-point growth without IPTG for both strain Humboldt and E. coli folA. This study provides evidence substantiating the in vivo functionality of strain Humboldt folA in producing functional gene products for folate biosynthesis.

Keywords