Fan Yu scite author profile

Porphyromonas gingivalis, an oral bacterium associated with periodontal disease, requires haemin for growth. Although several multigenic clusters encoding haemin-uptake systems are present on the genome of P. gingivalis, little is known regarding their transcriptional organization and expression. This study identified a 23 kDa iron-regulated haemin-binding protein encoded by a larger than previously reported variant of hmuY. It was shown that the hmu locus is larger than previously reported and is composed of six genes, hmuYRSTUV, encoding a novel hybrid haemin-uptake system. The locus has an operonic organization and the transcriptional start site is located 292 bp upstream of hmuY. The data indicate that the regulation of the operon is iron-dependent. Interestingly, differential regulation within the operon was demonstrated, resulting in excess of the hmuYR message encoding the outer-membrane proteins when compared to the full-length transcript. In addition, the hmuY transcript is more prevalent than the hmuR transcript. Secondary structure analysis of the hmuYRSTUV mRNA predicted the formation of several potential stem-loops in the 59 ends of hmuR-and hmuS-specific mRNAs, consistent with the differential regulation observed. Finally, it was demonstrated that haemin binding and uptake are elevated in iron-depleted conditions and are reduced 45 % and 70 %, respectively, in an hmu-deficient strain when compared to the parental strain, indicating that the hmu locus plays a major role in haemin acquisition in P. gingivalis. Since homologues of the hmu locus were also found in Bacteroides fragilis, Bacteroides thetaiotaomicron and Prevotella intermedia, these findings may have implications for a better understanding of haemin acquisition in those organisms as well.

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Role of Porphyromonas gingivalis FeoB2 in Metal Uptake and Oxidative Stress Protection

Miyazaki

Anaya

et al. 2006

Infect Immun

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Porphyromonas gingivalis, a gram-negative anaerobic bacterium, is a recognized periodontopathogen. It exhibits a high degree of aerotolerance and is able to survive in host cells, indicating that efficient oxidative stress protection mechanisms must be present in this organism. Manganese homeostasis plays a major role in oxidative stress protection in a variety of organisms; however, the transport and role of this metal in P. gingivalis is not well understood. Analysis of the genome of P. gingivalis W83 revealed the presence of two genes encoding homologs of a ferrous iron transport protein, FeoB1 and FeoB2. FeoB2 has been implicated in manganese accumulation in P. gingivalis. We sought to determine the role of the FeoB2 protein in metal transport as well as its contribution to resistance to oxygen radicals. Quantitative reverse transcriptase PCR analyses demonstrated that expression of feoB2 is induced in the presence of oxygen. The role of FeoB2 was investigated using an isogenic mutant strain deficient in the putative transporter. We characterized the FeoB2-mediated metal transport using 55 Fe 2؉ and 54 Mn 2؉ . The FeoB2-deficient mutant had dramatically reduced rates of manganese uptake (0.028 pmol/min/10 7 bacteria) compared with the parental strain (0.33 pmol/min/10 7 bacteria) (after 20 min of uptake using 50 nM of 54 Mn 2؉ ). The iron uptake rates, however, were higher in the mutant strain (0.75 pmol/min/10 7 bacteria) than in the wild type (0.39 pmol/min/10 7 bacteria). Interestingly, reduced survival rates were also noted for the mutant strain after exposure to H 2 O 2 and to atmospheric oxygen compared to the parental strain cultured under the same conditions. In addition, in vitro infection of host cells with the wild type, the FeoB2-deficient mutant, and the same-site revertant revealed that the mutant had a significantly decreased capability for intracellular survival in the host cells compared to the wild-type strain. Our results demonstrate that feoB2 encodes a major manganese transporter required for protection of the bacterium from oxidative stress generated by atmospheric oxygen and H 2 O 2 . Furthermore, we show that FeoB2 and acquisition of manganese are required for intracellular survival of P. gingivalis in host cells.

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Intact Protein Quantitation Using Pseudoisobaric Dimethyl Labeling

Fang

Xiao

et al. 2016

Anal. Chem.

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Protein structural and functional studies rely on complete qualitative and quantitative information on protein species (proteoforms); thus, it is important to quantify differentially expressed proteins at their molecular level. Here we report our development of universal pseudoisobaric dimethyl labeling (pIDL) of amino groups at both the N-terminal and lysine residues for relative quantitation of intact proteins. Initial proof-of-principle study was conducted on standard protein myoglobin and hepatocellular proteomes (HepG2 vs LO2). The amino groups from both the N-terminal and lysine were dimethylated with HXHO (X = (13)C or C) and NaBY3CN (Y = H or D). At the standard protein level, labeling efficiency, effect of product ion size, and mass resolution on quantitation accuracy were explored; and a good linear quantitation dynamic range up to 50-fold was obtained. For the hepatocellular proteome samples, 33 proteins were quantified with RSD ≤ 10% from one-dimensional reversed phase liquid chromatography-tandem mass spectrometry (RPLC-MS/MS) analysis of the 1:1 mixed samples. The method in this study can be extended to quantitation of other intact proteome systems. The universal "one-pot" dimethyl labeling of all the amino groups in a protein without the need of preblocking of those on the lysine residues is made possible by protein identification and quantitation analysis using ProteinGoggle 2.0 with customized databases of both precursor and product ions containing heavy isotopes.

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Top-down protein identification using isotopic envelope fingerprinting

Xiao

Tian

2017

Journal of Proteomics

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Outer membrane proteome of Prevotella intermedia 17: Identification of thioredoxin and iron‐repressible hemin uptake loci

Anaya

Lewis

2007

Proteomics

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Although hemin is an indispensable nutrient for the oral pathogen Prevotella intermedia, not much is known regarding the molecular mechanisms of hemin acquisition. The availability of the genomic sequence of the bacterium allowed us to apply proteomic approaches to identify proteins that may be mediating the hemin acquisition process. As hemin acquisition mechanisms have been shown to be induced in iron-depleted conditions, we applied proteomic approaches to detect those proteins whose expressions were affected by iron. We analyzed 40 protein spots and identified 19 such proteins. Interestingly, two proteins drastically upregulated in iron-depleted conditions, PIN0009 and PINA0611, are homologs of hemin uptake receptors in other bacteria. PIN0009 is predicted to be an outer membrane lipoprotein. It is encoded by a gene that is the first of a seven-gene genomic locus encoding proteins of a novel hemin acquisition system. The second protein, PINA0611, is a homolog of numerous TonB-dependent outer membrane receptors including outer membrane iron uptake receptors of various Gram-negative bacteria. There was also another protein, regulated by iron, that was previously demonstrated to bind hemoglobin in P. intermedia. Finally, we identified a thioredoxin-like protein that has a novel outer membrane location.

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Fan Yu

Transcriptional organization, regulation and role of the Porphyromonas gingivalis W83 hmu haemin-uptake locus

Role of Porphyromonas gingivalis FeoB2 in Metal Uptake and Oxidative Stress Protection

Intact Protein Quantitation Using Pseudoisobaric Dimethyl Labeling

Top-down protein identification using isotopic envelope fingerprinting

Outer membrane proteome of Prevotella intermedia 17: Identification of thioredoxin and iron‐repressible hemin uptake loci

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