Borrelia burgdorferi, the cause of Lyme disease, produces excessive amounts of membrane lipoproteins such as outer surface protein A (OspA) when grown in vitro, and consequently many low or moderately abundant proteins are underrepresented when cell lysates are examined by 2-DE. We analyzed the B. burgdorferi B31 proteome computationally and by IPG or modified NEPHGE after subcellular fractionation into membrane-associated and soluble proteins. The B. burgdorferi B31 theoretical proteome is comprised of 1623 proteins and has a mean pI of 8.36 and a median pI of 9.03 with 68% of the proteome possessing a pI >/=7.5. Separation of soluble proteins by IPG resulted in 205 individual spots and identification of 78 protein spots by MALDI-TOF MS. Separation by modified NEPHGE routinely resulted in approximately 185 soluble and 160 membrane protein spots with the identification of 88 individual protein spots combined by MALDI-TOF MS. Homologues to GroEL and aminopeptidase I were present in greater amounts in the membrane faction, with enolase at nearly equivalent amounts in the soluble and membrane fractions. Identification of proteins isolated and separated by such methods will enable future determination of proteome changes in membrane and soluble protein fractions as spirochetes adapt to their changing environments.
Members of the Borrelia burgdorferi paralogous gene family 54 (pgf 54) are regulated by conditions simulating mammalian infection and are thought to be instrumental in borrelial host survival and pathogenesis. To explore the activities of these genes in vivo, a comprehensive analysis of pgf 54 genes BBA64, BBA65, and BBA66 was performed to assess the genetic stability, host antibody responses, and kinetics of gene expression in the murine model of persistent infection. DNA sequencing of pgf 54 genes obtained from reisolates at 1 year postinfection demonstrated that all genes of this family are stable and do not undergo recombination to generate variant antigens during persistent infection. Antibodies against BBA64 and BBA66 appeared soon after infection and were detectable throughout the infection, suggesting that there was gene expression during infection. However, quantitative reverse transcription-PCR revealed that BBA64 gene expression was considerably decreased in Borrelia residing in the mouse ear tissue compared to the expression in cultured spirochetes by 20 days postinfection and that the levels of expression remained low throughout the infection. Conversely, transcription of the BBA65 and BBA66 genes was increased, and both of these genes were continuously expressed until 100 days postinfection; this was followed by periods of differential expression late in infection. The expression profile of the BBA64 gene suggests that this gene has an important role during tick-to-host transmission and early infection, whereas the expression profile of the BBA65 and BBA66 genes suggests that these genes have a role in persistent infection. The differential regulation of pgf 54 genes observed during infection may help confer a survival advantage during persistent infection, influencing mechanisms for B. burgdorferi dissemination, tissue tropism, or evasion of the adaptive immune response.
SummaryWhen Borrelia burgdorferi (Bb) is transmitted from a tick vector to a mammalian host the spirochaete alters gene expression, allowing for adaptation to the new host. We evaluated the regulation of paralogous gene family (pgf) 54 members in response to environmental cues and focused our efforts on determining the molecular mechanisms influencing bba66 expression. By qRT-PCR, bba65, bba66, bba71 and bba73 displayed regulation similar to ospC under mammalian-like conditions. Of the pgf 54 members, bba66 demonstrated the greatest and second greatest change in expression in response to pH or temperature shift respectively. Furthermore, Bb-infected mice and patients with early disseminated Lyme disease produced detectable antibodies to BBA66. A protein(s) active in Bb at pH 7 was able to interact with the bba66 upstream region and was specific as bba64 and ospC promoters were unable to outcompete for binding. bba66 promoter mapping revealed putative s 70 and s S consensus sequences, enabling us to narrow the protein binding site to a region within an imperfect inverted repeat upstream of the -35 region. Moreover, BBA66 production is associated with an infectious phenotype, and loss of either s N or s S resulted in loss of BBA66. Promoter-GFP fusion analysis indicated that the s 70 and/or s S consensus sequences alone were not sufficient to initiate transcription and a portion of the upstream inverted repeat was required. These results suggest a primary role for BBA66 in Bb transmission and infection.
Git1p mediates the transport of the phospholipid metabolite, glycerophosphoinositol, into Saccharomyces cerevisiae. We report that phosphate limitation and inositol limitation affect GIT1 expression and Git1p transport activity via distinct mechanisms that involve multiple transcription factors. GIT1 transcript levels and Git1p activity are greater in cells starved for phosphate, with or without inositol limitation, than in cells only limited for inositol. Furthermore, the kinetics of GIT1 transcript accumulation and Git1p activity upon transfer of cells to phosphate starvation media are different from those obtained upon transfer of cells to inositolfree media. Pho2p and Pho4p are required for GIT1 expression and for Git1p transport activity under all growth conditions tested. In contrast, Ino2p and Ino4p are required for full GIT1 expression when inositol is limiting, with or without phosphate limitation, but not when only phosphate is limiting. Greatly reduced transport activity was detected in ino2⌬ and ino4⌬ cells under all growth conditions. A 300-base pair region of the GIT1 promoter containing potential Pho4p binding sites was shown to be required for full GIT1 expression. Git1p appears to act as a H ؉ -symporter, and neither inositol nor phosphate effectively compete with glycerophosphoinositol for transport by Git1p. Glycerophosphoinositol was shown previously to support the growth of an inositol auxotroph. Remarkably, we now report that glycerophosphoinositol can act as the sole source of phosphate for the cell, providing functional relevance for the regulation of Git1p transport activity by phosphate.
bThe impact of the Borrelia burgdorferi surface-localized immunogenic lipoprotein BBA66 on vector and host infection was evaluated by inactivating the encoding gene, bba66, and characterizing the mutant phenotype throughout the natural mouse-tickmouse cycle. The BBA66-deficient mutant isolate, Bb ⌬A66 , remained infectious in mice by needle inoculation of cultured organisms, but differences in spirochete burden and pathology in the tibiotarsal joint were observed relative to the parental wild-type (WT) strain. Ixodes scapularis larvae successfully acquired Bb ⌬A66 following feeding on infected mice, and the organisms persisted in these ticks through the molt to nymphs. A series of tick transmission experiments (n ؍ 7) demonstrated that the ability of Bb ⌬A66 -infected nymphs to infect laboratory mice was significantly impaired compared to that of mice fed upon by WT-infected ticks. trans-complementation of Bb ⌬A66 with an intact copy of bba66 restored the WT infectious phenotype in mice via tick transmission. These results suggest a role for BBA66 in facilitating B. burgdorferi dissemination and transmission from the tick vector to the mammalian host as part of the disease process for Lyme borreliosis.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.