Comparative proteomic and genomic analyses of Brucella abortus biofilm and planktonic cells

Tang, Taishan; Chen, Guoqiang; Xu, Ye; Zhao, Liang; Wang, Mengrui; Chen, Lu; Jiang, Yuan; Chang-yin, Zhang

doi:10.3892/mmr.2019.10888

Cited by 7 publications

(6 citation statements)

References 53 publications

(49 reference statements)

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“…Since 2012, some of these technological advances have been implemented, yet traditional methods have remained popular in Brucella proteomics. There have been frequent uses of 2D-PAGE and MALDI-TOF (-TOF) [ 25 , 26 , 27 , 28 , 29 , 30 ], sometimes utilizing DIGE to minimize gel-to-gel variation [ 31 , 32 ] or other fluorescent dyes for extended dynamic range [ 33 ]. Additionally, the unusual combination of 2D-PAGE with LC-MS/MS has been reported [ 34 ].…”

Section: Proteomics Technologies and Their Use For Brucementioning

confidence: 99%

Proteomics of Brucella

Poetsch

Marchesini

2020

Proteomes

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Brucella spp. are Gram negative intracellular bacteria responsible for brucellosis, a worldwide distributed zoonosis. A prominent aspect of the Brucella life cycle is its ability to invade, survive and multiply within host cells. Comprehensive approaches, such as proteomics, have aided in unravelling the molecular mechanisms underlying Brucella pathogenesis. Technological and methodological advancements such as increased instrument performance and multiplexed quantification have broadened the range of proteome studies, enabling new and improved analyses, providing deeper and more accurate proteome coverage. Indeed, proteomics has demonstrated its contribution to key research questions in Brucella biology, i.e., immunodominant proteins, host-cell interaction, stress response, antibiotic targets and resistance, protein secretion. Here, we review the proteomics of Brucella with a focus on more recent works and novel findings, ranging from reconfiguration of the intracellular bacterial proteome and studies on proteomic profiles of Brucella infected tissues, to the identification of Brucella extracellular proteins with putative roles in cell signaling and pathogenesis. In conclusion, proteomics has yielded copious new candidates and hypotheses that require future verification. It is expected that proteomics will continue to be an invaluable tool for Brucella and applications will further extend to the currently ill-explored aspects including, among others, protein processing and post-translational modification.

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Section: Proteomics Technologies and Their Use For Brucementioning

confidence: 99%

Proteomics of Brucella

Poetsch

Marchesini

2020

Proteomes

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“…We investigated the role of FtcR in the response of B. melitensis 16M biofilms to various conditions of environmental stress. Inconsistent with B. melitensis 16M in a planktonic state, the ftcR mutant showed a significant biofilm growth defect compared with that of the WT and complemented strains only under hyperosmotic stress; B. melitensis 16M did not show the same susceptibility to other stressors as the planktonic bacteria of the Δ ftcR strain, possibly highlighting the difference in the protective effects of the biofilm structure on bacteria and the bacteria in the planktonic state [ 11 , 14 , 15 ]. This biofilm phenotype was not a response to high concentrations of NaCl alone, because it was also observed when the biofilms were treated with other types of osmotic solutes.…”

Section: Discussionmentioning

confidence: 99%

“…Biofilms are formed by a complex process that initiates when microorganisms attach to a surface via an extracellular matrix and other adhesins that allow them to develop into large communities [ 13 ]. Compared to planktonic bacteria, biofilms have unique transcriptional and expressive programs [ 14 , 15 ]. Bacteria form a niche within these biofilms, exhibiting increased virulence and resistance to various hostile microenvironments [ 16 , 17 ].…”

Section: Introductionmentioning

confidence: 99%

The Flagellar Transcriptional Regulator FtcR Controls Brucella melitensis 16M Biofilm Formation via a betI-Mediated Pathway in Response to Hyperosmotic Stress

Guo

Deng

Song

et al. 2022

IJMS

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The expression of flagellar proteins in Brucella species likely evolved through genetic transference from other microorganisms, and contributed to virulence, adaptability, and biofilm formation. Despite significant progress in defining the molecular mechanisms behind flagellar gene expression, the genetic program controlling biofilm formation remains unclear. The flagellar transcriptional factor (FtcR) is a master regulator of the flagellar system’s expression, and is critical for B. melitensis 16M’s flagellar biogenesis and virulence. Here, we demonstrate that FtcR mediates biofilm formation under hyperosmotic stress. Chromatin immunoprecipitation with next-generation sequencing for FtcR and RNA sequencing of ftcR-mutant and wild-type strains revealed a core set of FtcR target genes. We identified a novel FtcR-binding site in the promoter region of the osmotic-stress-response regulator gene betI, which is important for the survival of B. melitensis 16M under hyperosmotic stress. Strikingly, this site autoregulates its expression to benefit biofilm bacteria’s survival under hyperosmotic stress. Moreover, biofilm reduction in ftcR mutants is independent of the flagellar target gene fliF. Collectively, our study provides new insights into the extent and functionality of flagellar-related transcriptional networks in biofilm formation, and presents phenotypic and evolutionary adaptations that alter the regulation of B. melitensis 16M to confer increased tolerance to hyperosmotic stress.

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“…Proteomic analysis of biofilms has been used to identify key proteins that are essential in complex biofilm networks, including; in the EPS ( Egorova et al., 2022 ) , required for temperature adaptation stress ( Lee and Wang, 2020 ) , required for adaptation to antimicrobial treatment ( MaChado and Coquet, 2016 ) , and that change with biofilm development ( Serra et al., 2008 ; Suriyanarayanan et al., 2018 ) and aging ( Rahman et al., 2022 ), and between planktonic and biofilm conditions ( Khan et al., 2019 ; Suryaletha et al., 2019 ; Llama-Palacios et al., 2020 ; Tang et al., 2020 ). These studies use a range of different mass spectrometry methodologies, including tandem liquid chromatography (LC-MS/MS) alone ( Lee and Wang, 2020 ) or coupled with nano-high performance liquid chromatography (HPLC) ( Egorova et al., 2022 ), lab-on-a-chip and XCT mass spectrometry ( MaChado and Coquet, 2016 ), tandem mass tag (TMT) mass spectrometry ( Rahman et al., 2022 ), fourier transform infrared spectroscopy (FT-IR) ( Serra et al., 2008 ), nano-LC/MS coupled with quadrupole-ToF (Q-ToF) ( Suryaletha et al., 2019 ) , iTRAQ labelling plus LC-MS/MS for quantitative proteomics, and matrix-assisted laser desorption ionisation time-of-flight (MALDI-ToF) mass spectrometry ( Llama-Palacios et al., 2020 ; Tang et al., 2020 ). MALDI-ToF analysis of bacteria is routinely used in clinical diagnostic laboratories to identify bacterial species, and this method is increasingly being developed to discriminate between isolates and their status as biofilm-producers or non-producers ( Caputo et al., 2018 ), which will aid in establishing effective antimicrobial therapy.…”

Section: Genetic and Molecular Analysis Techniquesmentioning

confidence: 99%

How to study biofilms: technological advancements in clinical biofilm research

Cleaver,

Garnett

2023

Front. Cell. Infect. Microbiol.

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Biofilm formation is an important survival strategy commonly used by bacteria and fungi, which are embedded in a protective extracellular matrix of organic polymers. They are ubiquitous in nature, including humans and other animals, and they can be surface- and non-surface-associated, making them capable of growing in and on many different parts of the body. Biofilms are also complex, forming polymicrobial communities that are difficult to eradicate due to their unique growth dynamics, and clinical infections associated with biofilms are a huge burden in the healthcare setting, as they are often difficult to diagnose and to treat. Our understanding of biofilm formation and development is a fast-paced and important research focus. This review aims to describe the advancements in clinical biofilm research, including both in vitro and in vivo biofilm models, imaging techniques and techniques to analyse the biological functions of the biofilm.

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Comparative proteomic and genomic analyses of Brucella abortus biofilm and planktonic cells

Cited by 7 publications

References 53 publications

Proteomics of Brucella

Proteomics of Brucella

The Flagellar Transcriptional Regulator FtcR Controls Brucella melitensis 16M Biofilm Formation via a betI-Mediated Pathway in Response to Hyperosmotic Stress

How to study biofilms: technological advancements in clinical biofilm research

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