ABSTRACT
Leptospirosis is a global zoonotic bacterial disease which is a threat for humans and most mammals. Bacterin vaccines for leptospirosis are available however they are severely limited in cross protection between serogroups. Leptospira typically colonize the kidneys of reservoir hosts where they are subsequently shed in the urine and persist in the environment and can thus be indirectly or directly transmitted to incidental hosts. Leptospira borgpetersenii serovar Hardjo is the primary cause of leptospirosis in cattle which can result in abortion, unhealthy calves, and rebreed problems. This dataset comprises proteomic profiles of four strains of L. borgpetersenii serovar Hardjo propagated at the routinely utilized culture temperature of 29 °C, and a newly achieved culture temperature of 37 °C, which more closely emulates the temperature of an infected host. The strains analyzed include JB197 (established strain that causes Hardjo atypical acute disease in the hamster model of leptospirosis), HB203 (established strain, causes typical chronic disease in hamsters), as well as TC129 and TC273 (recently isolated strains from the central United States). Differential expression profiles were detected not only between strains but also within strains between culture temperatures. Mass spectrometry data are available via ProteomeXchange with identifier PXD032831.
ABSTRACT
Leptospirosis is a global zoonotic disease affecting humans and livestock species. Bacterin vaccines lack cross protection between serogroups, and include multiple serovars propagated at 29°C. Recent work demonstrated substantial variation in the transcriptome of identical species and serovars of Leptospira. Here, substantial differences in protein abundance profiles were identified in Leptospira borgpetersenii serovar Hardjo; strain HB203, which was isolated in the 1980s, compared to newer strains TC129 and TC273 isolated in 2016, and whether they were propagated at the routine temperature of 29°C, compared to 37°C which more closely emulates host infection. While 388 and 385 significantly differentially expressed (DE) proteins (FDR of 0.01) were identified in HB203 versus TC129, and HB203 versus TC273 when propagated at 29°C respectively, only 66 and 4 DE proteins were identified in HB203 versus TC129, and HB203 versus TC273 when propagated at 37°C respectively. Within each strain comparing temperatures, HB203 had 524 significantly DE proteins, TC129 had 347 DE proteins, and TC273 had 569 DE proteins. Data are available via ProteomeXchange with identifier PXD032831. Results highlight significant differential protein expression amongst identical serovars of L. borgpetersenii suggesting that bacterin vaccine design can benefit from consideration of strains employed and effects of temperature on growth.
ABSTRACT
Leptospirosis is a worldwide zoonosis caused by pathogenic species of the genus Leptospira. The recent application of CRISPR interference (CRISPRi) to Leptospira facilitates targeted gene silencing and provides a new tool to investigate pathogenic mechanisms of leptospirosis. CRISPRi relies on the expression of a catalytically “dead” Cas9 (dCas9) and a single-guide RNA (sgRNA). Previously, our group generated a LipL32 and a double LigA/LigB (LigAB) mutant, which, in the current study, are characterized by whole-cell proteomics in comparison with control leptospires harboring plasmid expressing dCas9 alone. Comparison of control and LigAB mutant leptospires identified 46 significantly differentially expressed (DE) proteins, including 27 proteins that were less abundant and 19 proteins that were more abundant in the LigAB mutant compared with the control. Comparison of the control and LipL32 mutant leptospires identified 243 DE proteins, of which 84 proteins were more abundant and 159 were less abundant in the LipL32 mutant strain. Significantly increased amounts of known virulence impactors and surface membrane receptors, including LipL45, LipL31, LigB, and LipL41, were identified. The virulence of LipL32 and LigAB mutants were evaluated in the hamster model of leptospirosis; the LigAB mutant was unable to cause acute disease although mutant leptospires could still be recovered from target organs, albeit at a significantly lower bacterial burden (<850 and <16-fold in liver and kidney, respectively, in comparison with control), indicating attenuation of virulence and a shift to chronic bacterial persistence. Notably, the LipL32 mutant displayed augmented virulence as evidenced by early onset of clinical symptoms and increased numbers of circulating foamy macrophages. Validation of LipL32 and LigAB mutants recovered from liver and kidney in the presence or absence of antibiotic selection revealed high plasmid stability and, by extension, gene silencing in vivo. Collectively, this work emphasizes the advantages and feasibility of using CRISPRi technology to evaluate and characterize virulence factors of leptospires and their respective host–pathogen interactions in animal models of leptospirosis. Importantly, it also provides insight into the requirements of LigA and LigB for acute disease and explores the impact of silencing expression of lipL32, which resulted in substantial changes in amounts of outer membrane proteins.
ABSTRACT
Background: Leptospirosis is a zoonotic, bacterial disease, posing significant health risks to humans, livestock, and companion animals around the world. Symptoms range from asymptomatic to multi-organ failure in severe cases. Complex species-specific interactions exist between animal hosts and the infecting species, serovar, and strain of pathogen. Leptospira borgpetersenii serovar Hardjo strains HB203 and JB197 have a high level of genetic homology but cause different clinical presentation in the hamster model of infection; HB203 colonizes the kidney and presents with chronic shedding while JB197 causes severe organ failure and mortality. This study examines the transcriptome of L. borgpetersenii and characterizes differential gene expression profiles of strains HB203 and JB197 cultured at temperatures during routine laboratory conditions (29°C) and encountered during host infection (37°C). Methodology/Principal findings: L. borgpetersenii serovar Hardjo strains JB197 and HB203 were isolated from the kidneys of experimentally infected hamsters and maintained at 29°C and 37°C. RNAseq revealed distinct gene expression profiles; 440 genes were differentially expressed (DE) between JB197 and HB203 at 29°C, and 179 genes were DE between strains at 37°C. Comparison of JB197 cultured at 29°C and 37°C identified 135 DE genes while 41 genes were DE in HB203 with those same culture conditions. The consistent DE of ligB, which encodes the outer membrane virulence factor LigB, was validated by immunoblotting and 2D-DIGE. Differential expression of lipopolysaccharide was also observed between JB197 and HB203. Conclusions/Significance: Investigation of the L. borgpetersenii JB197 and HB203 transcriptome provides unique insight into the mechanistic differences between acute and chronic disease. Characterizing the nuances of strain to strain differences and investigating the environmental sensitivity of Leptospira to temperature is critical to the development and progress of leptospirosis prevention and treatment technologies, and is an important consideration when serovars are selected and propagated for use as bacterin vaccines as well as for the identification of novel therapeutic targets.
ABSTRACT
Carotenoid-protein complex (CPC) was isolated from chromoplast-enriched suspensions of cassava storage root (CSR) using size exclusion chromatography and characterized. Peptide sequences (LC_MS/MS spectrum) obtained from CPC and their corresponding proteins were obtained using publically available databases. Small Heat Shock Proteins (sHSPs) were the most abundant proteins identified in the CPC. Western blot analysis showed that Fribrillin and Or-protein were present in chromoplast-enriched suspensions of yellow root but not in the complex or white root. Results from qRT-PCR helped identify an isoform of HSP21 possessing four single point mutations in the intense yellow CSR that may be responsible for increased sequestration of b-carotene.