Your search keyword '"Bontemps Gallo, Sébastien"' showing total 5 results

1. The arginine deaminase system plays distinct roles in Borrelia burgdorferi and Borrelia hermsii.

Author

Richards, Crystal L., Raffel, Sandra J., Bontemps-Gallo, Sébastien, Dulebohn, Daniel P., Herbert, Tessa C., and Gherardini, Frank C.

Subjects

LYME disease, BORRELIA burgdorferi, ARGININE deiminase, AMINO acid transport, RELAPSING fever, OPERONS, TICK-borne diseases

Abstract

Borrelia species are amino acid auxotrophs that utilize di- and tri- peptides obtained through their oligopeptide transport system to supply amino acids for replicative growth during their enzootic cycles. However, Borrelia species from both the Lyme disease (LD) and relapsing fever (RF) groups harbor an amino acid transport and catabolism system, the Arginine Deiminase System (ADI), that could potentially augment intracellular L-arginine required for growth. RF spirochetes contain a "complete", four gene ADI (arcA, B, D, and C) while LD spirochetes harbor arcA, B, and sometimes D but lack arcC (encoding carbamate kinase). In this study, we evaluated the role of the ADI system in bacterial survival and virulence and discovered important differences in RF and LD ADIs. Both in vitro and in a murine model of infection, B. hermsii cells significantly reduced extracellular L-arginine levels and that reduction was dependent on arginine deiminase expression. Conversely, B. burgdorferi did not reduce the concentration of L-arginine during in vitro growth experiments nor during infection of the mammalian host, suggesting a fundamental difference in the ability to directly utilize L-arginine compared to B. hermsii. Further experiments using a panel of mutants generated in both B. burgdorferi and B. hermsii, identified important differences in growth characteristics and ADI transcription and protein expression. We also found that the ADI system plays a key role in blood and spleen colonization in RF spirochetes. In this study we have identified divergent metabolic strategies in two closely related human pathogens, that ultimately impacts the host-pathogen interface during infection. Author summary: Reports of tick-borne diseases have been steadily increasing in the US and the number of Lyme disease cases caused by B. burgdorferi have tripled since the late 1990's. Although less common, cases of tick-borne relapsing fever, caused by B. hermsii and B. turicatae in the US, have increased as well. While transmitted by different ticks and maintained in unique enzootic cycles, the closely related spirochetes B. burgdorferi and B. hermsii share numerous genetic features including a truncated and streamlined capacity for metabolic activity. In this study we combine genetic and biochemical assays to define the role of the ADI in the infective cycles of B. burgdorferi and B. hermsii. When we compared B. burgdorferi and B. hermsii, we identified important differences in their respective ADI's including operon arrangement, sensitivity to L-arginine and L-ornithine levels, as well as gene and protein expression. In addition, we show that arginine deiminase is required to reduce host L-arginine levels during murine infection with B. hermsii. This study provides new insights into the metabolic activities of two medically relevant spirochetes and highlights the dynamic nature of host-pathogen interactions. [ABSTRACT FROM AUTHOR]

Published

2022

2. A refined model of how Yersinia pestis produces a transmissible infection in its flea vector.

Author

Dewitte, Amélie, Bouvenot, Typhanie, Pierre, François, Ricard, Isabelle, Pradel, Elizabeth, Barois, Nicolas, Hujeux, Anaïs, Bontemps-Gallo, Sébastien, and Sebbane, Florent

Subjects

YERSINIA pestis, FLEAS, ECTOPARASITES, GENETIC techniques, INFECTION, MASS production

Abstract

In flea-borne plague, blockage of the flea's foregut by Yersinia pestis hastens transmission to the mammalian host. Based on microscopy observations, we first suggest that flea blockage results from primary infection of the foregut and not from midgut colonization. In this model, flea infection is characterized by the recurrent production of a mass that fills the lumen of the proventriculus and encompasses a large number of Y. pestis. This recurrence phase ends when the proventricular cast is hard enough to block blood ingestion. We further showed that ymt (known to be essential for flea infection) is crucial for cast production, whereas the hmsHFRS operon (known to be essential for the formation of the biofilm that blocks the gut) is needed for cast consolidation. By screening a library of mutants (each lacking a locus previously known to be upregulated in the flea gut) for biofilm formation, we found that rpiA is important for flea blockage but not for colonization of the midgut. This locus may initially be required to resist toxic compounds within the proventricular cast. However, once the bacterium has adapted to the flea, rpiA helps to form the biofilm that consolidates the proventricular cast. Lastly, we used genetic techniques to demonstrate that ribose-5-phosphate isomerase activity (due to the recent gain of a second copy of rpiA (y2892)) accentuated blockage but not midgut colonization. It is noteworthy that rpiA is an ancestral gene, hmsHFRS and rpiA2 were acquired by the recent ancestor of Y. pestis, and ymt was acquired by Y. pestis itself. Our present results (i) highlight the physiopathological and molecular mechanisms leading to flea blockage, (ii) show that the role of a gene like rpiA changes in space and in time during an infection, and (iii) emphasize that evolution is a gradual process punctuated by sudden jumps. Author summary: Plague is a deadly flea-borne disease caused by the bacillus Yersinia pestis. This bacterium blocks the flea's foregut (proventriculus) to increase its likelihood of being regurgitated by fleas trying to take a blood meal. Understanding the mechanisms leading to flea blockage may help to find ways of controlling plague. Here, we propose a model in which blockage results from primary infection of the foregut and not from midgut colonization. In the proventriculus, Y. pestis induces, resists and then consolidates the formation of a bactericidal matrix that can be recurrently dislodged by a blood meal before it becomes firmly anchored to the proventriculus and thus definitively obstructs it. Induction, resistance, and then consolidation of the mass in the proventriculus were made possible by the sequential acquisition of genetic material by the ancestors of Y. pestis and by Y. pestis itself–emphasizing that evolution is a gradual process punctuated by sudden jumps. [ABSTRACT FROM AUTHOR]

Published

2020

3. Genomic and phenotypic characterization of Borrelia afzelii BO23 and Borrelia garinii CIP 103362.

Author

Bontemps-Gallo, Sébastien, Lawrence, Kevin A., Richards, Crystal L., and Gherardini, Frank C.

Subjects

*BORRELIA, *LYME disease, *RELAPSING fever, *TICK-borne diseases

Abstract

In recent years, the number of Lyme disease or borreliosis cases in Eurasia has been dramatically increasing. This tick-borne disease is caused by Borrelia burgdorferi sensu lato, which includes B. burgdorferi sensu stricto, the main species found in North America, and B. afzelii and B. garinii, which are primarily responsible for the disease in Eurasia. Currently, research on Lyme disease has focused mainly on B. burgdorferi while B. afzelii and B. garinii, which cause disease with distinctly different symptoms, are less studied. The purpose of this study is to evaluate B. afzelii BO23 and B. garinii CIP 103362 as model organisms to study Eurasian Lyme disease. To begin our analyses, we sequenced, annotated the chromosomes of both species and compared them to B. burgdorferi strain B31. We also assayed shuttle vector, pBSV2, for transformation efficacy and demonstrated that these strains can be cultured on solid media. In addition, we characterized how physicochemical parameters (e.g., oxygen, osmolarity, oxidative stress) affect both growth and motility of the bacteria. Finally, we describe each strain’s antibiotic susceptibility and accessed their ability to infect mice. In conclusion, B. afzelii BO23 was more practical for in vitro and in vivo studies than B. garinii CIP 103362. [ABSTRACT FROM AUTHOR]

Published

2018

4. Two Different Virulence-Related Regulatory Pathways in Borrelia burgdorferi Are Directly Affected by Osmotic Fluxes in the Blood Meal of Feeding Ixodes Ticks.

Author

Bontemps-Gallo, Sébastien, Lawrence, Kevin, and Gherardini, Frank C.

Subjects

*LYME disease, *BORRELIA burgdorferi, *VIRULENCE of bacteria, *OSMOREGULATION, *IXODES, *BLOOD meal as feed, *GENETICS

Abstract

Lyme disease, caused by Borrelia burgdorferi, is a vector-borne illness that requires the bacteria to adapt to distinctly different environments in its tick vector and various mammalian hosts. Effective colonization (acquisition phase) of a tick requires the bacteria to adapt to tick midgut physiology. Successful transmission (transmission phase) to a mammal requires the bacteria to sense and respond to the midgut environmental cues and up-regulate key virulence factors before transmission to a new host. Data presented here suggest that one environmental signal that appears to affect both phases of the infective cycle is osmolarity. While constant in the blood, interstitial fluid and tissue of a mammalian host (300 mOsm), osmolarity fluctuates in the midgut of feeding Ixodes scapularis. Measured osmolarity of the blood meal isolated from the midgut of a feeding tick fluctuates from an initial osmolarity of 600 mOsm to blood-like osmolarity of 300 mOsm. After feeding, the midgut osmolarity rebounded to 600 mOsm. Remarkably, these changes affect the two independent regulatory networks that promote acquisition (Hk1-Rrp1) and transmission (Rrp2-RpoN-RpoS) of B. burgdorferi. Increased osmolarity affected morphology and motility of wild-type strains, and lysed Hk1 and Rrp1 mutant strains. At low osmolarity, Borrelia cells express increased levels of RpoN-RpoS-dependent virulence factors (OspC, DbpA) required for the mammalian infection. Our results strongly suggest that osmolarity is an important part of the recognized signals that allow the bacteria to adjust gene expression during the acquisition and transmission phases of the infective cycle of B. burgdorferi. [ABSTRACT FROM AUTHOR]

Published

2016

5. Correction: The arginine deaminase system plays distinct roles in Borrelia burgdorferi and Borrelia hermsii.

Author

Richards, Crystal L., Raffel, Sandra J., Bontemps-Gallo, Sébastien, Dulebohn, Daniel P., Herbert, Tessa C., and Gherardini, Frank C.

Subjects

BORRELIA burgdorferi, ARGININE, ARGININE deiminase, CASTOR bean tick

Published

2022