Paolo Pasquali scite author profile

To investigate the relevance of zinc in host-pathogen interactions, we have constructed Salmonella enterica mutant strains in which the znuA gene, which encodes the periplasmic component of the ZnuABC high-affinity Zn 2؉ transporter, was deleted. This mutation does not alter the ability of Salmonella to grow in rich media but drastically reduces its ability to multiply in media deprived of zinc. In agreement with this phenotype, ZnuA accumulates only in bacteria cultivated in environments poor in zinc. In spite of the nearly millimolar intracellular concentration of zinc, we have found that znuA is highly expressed in intracellular salmonellae recovered either from cultivated cells or from the spleens of infected mice. We have also observed that znuA mutants are impaired in their ability to grow in Caco-2 epithelial cells and that bacteria starved for zinc display decreased ability to multiply in phagocytes. A dramatic reduction in the pathogenicity of the znuA mutants was observed in Salmonella-susceptible (BALB/c) or Salmonella-resistant (DBA-2) mice infected intraperitoneally or orally. This study shows that the amount of free metals available for bacterial growth within the infected animal is limited, despite the apparent elevated concentration of free metals within cells and in plasma and suggests that Salmonella exploits the ZnuABC zinc transporter to maximize zinc availability in such conditions. These results shed new light on the complex functions of zinc in vertebrate and bacterial physiology and pave the way for a better comprehension of pathogenic mechanisms in Salmonella infections.The ability of bacteria to colonize specific environments relies on their ability to obtain adequate supplies of the nutrients that are indispensable for their growth. Of particular relevance for human and animal health is to understand how bacterial pathogens face the problem of nutrient limitation in the infected host, an environment where several essential elements are not freely available for infectious microorganisms (44). Well-studied examples are the strategies adopted by pathogens to obtain iron within their host. In fact, iron availability in eukaryotes is strictly controlled by metal-binding proteins (i.e., ferritin, transferrin, and lactoferrin) which prevent its reactivity and limit the uptake ability by invasive microorganisms (40,42,43). Moreover, growth of intracellular bacteria is also controlled by specific pumps which remove iron from the bacterium-containing phagosomes (19, 48). As iron plays crucial catalytic roles in a large number of bacterial proteins, an adequate supply of this transition metal is necessary for bacterial survival and multiplication. Therefore, different pathogenic bacteria have evolved sophisticated strategies to acquire and utilize host iron, including the production of molecules (siderophores, hemophores, and membrane-associated pumps) characterized by an extraordinarily elevated iron affinity (40,42,43). The outcome of the competition for iron between the host cell and the micro...

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Role of Iron Uptake Systems in Pseudomonas aeruginosa Virulence and Airway Infection

Minandri

et al. 2016

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Pseudomonas aeruginosa is a leading cause of hospital-acquired pneumonia and chronic lung infections in cystic fibrosis patients. Iron is essential for bacterial growth, and P. aeruginosa expresses multiple iron uptake systems, whose role in lung infection deserves further investigation. P. aeruginosa Fe 3؉ uptake systems include the pyoverdine and pyochelin siderophores and two systems for heme uptake, all of which are dependent on the TonB energy transducer. P. aeruginosa also has the FeoB transporter for Fe 2؉ acquisition. To assess the roles of individual iron uptake systems in P. aeruginosa lung infection, single and double deletion mutants were generated in P. aeruginosa PAO1 and characterized in vitro, using iron-poor media and human serum, and in vivo, using a mouse model of lung infection. The iron uptake-null mutant (tonB1 feoB) and the Fe 3؉ transport mutant (tonB1) did not grow aerobically under low-iron conditions and were avirulent in the mouse model. Conversely, the wild type and the feoB, hasR phuR (heme uptake), and pchD (pyochelin) mutants grew in vitro and caused 60 to 90% mortality in mice. The pyoverdine mutant (pvdA) and the siderophore-null mutant (pvdA pchD) grew aerobically in iron-poor media but not in human serum, and they caused low mortality in mice (10 to 20%). To differentiate the roles of pyoverdine in iron uptake and virulence regulation, a pvdA fpvR double mutant defective in pyoverdine production but expressing wild-type levels of pyoverdine-regulated virulence factors was generated. Deletion of fpvR in the pvdA background partially restored the lethal phenotype, indicating that pyoverdine contributes to the pathogenesis of P. aeruginosa lung infection by combining iron transport and virulence-inducing capabilities.

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The Zur-Regulated ZinT Protein Is an Auxiliary Component of the High-Affinity ZnuABC Zinc Transporter That Facilitates Metal Recruitment during Severe Zinc Shortage

et al. 2010

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The pathways ensuring the efficient uptake of zinc are crucial for the ability of bacteria to multiply in the infected host. To better understand bacterial responses to zinc deficiency, we have investigated the role of the periplasmic protein ZinT in Salmonella enterica serovar Typhimurium. We have found that zinT expression is regulated by Zur and parallels that of ZnuA, the periplasmic component of the zinc transporter ZnuABC. Despite the fact that ZinT contributes to Salmonella growth in media containing little zinc, disruption of zinT does not significantly affect virulence in mice. The role of ZinT became clear using strains expressing a mutated form of ZnuA lacking a characteristic histidine-rich domain. In fact, Salmonella strains producing this modified form of ZnuA exhibited a ZinT-dependent capability to import zinc either in vitro or in infected mice, suggesting that ZinT and the histidine-rich region of ZnuA have redundant function. The hypothesis that ZinT and ZnuA cooperate in the process of zinc recruitment is supported by the observation that they form a stable binary complex in vitro. Although the presence of ZinT is not strictly required to ensure the functionality of the ZnuABC transporter, our data suggest that ZinT facilitates metal acquisition during severe zinc shortage.Transition metals are essential constituents of a huge number of proteins where they play catalytic or structural functions (4, 50). Therefore, all organisms possess complex machineries to ensure an adequate supply of these elements, while avoiding their potentially toxic intracellular accumulation. A large number of studies have documented the relevance of metals for microbial growth and resistance to a variety of stress conditions (23,42,50). In particular, it is well established that the pathways enabling bacteria to recruit metal ions are key for the ability of pathogens to multiply within the host and cause disease (42,43,44). The vast majority of studies concerning metal uptake and bacterial pathogenicity have focused on iron, but strong evidence is emerging that the efficient uptake of other transition metals plays an important role in the hostpathogen interaction (24, 54). In particular, recent observations suggest that zinc is not freely available within the host (3). After iron, zinc is the second most abundant transition metal ion in living organisms and plays catalytic and/or structural roles in enzymes of all six classes, several of which play functions essential for cell viability (12). Investigations initially carried out in Escherichia coli and then confirmed in other microorganisms have established that zinc homeostasis is finely controlled by the coordinated activity of import and export systems regulated by Zur and ZntR, two metalloproteins able to regulate gene transcription depending on their metallation state (36,40). Zur controls the expression of a few genes involved in bacterial response to zinc shortage, whereas ZntR regulates the expression of the zinc efflux pump ZntA. It is worth observing that,...

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Growth ofPseudomonas aeruginosain zinc poor environments is promoted by a nicotianamine‐related metallophore

Mastropasqua

D’Orazio

Cerasi

et al. 2017

Molecular Microbiology

136

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Previous studies have suggested that P. aeruginosa possesses redundant zinc uptake systems. To identify uncharacterized zinc transporters, we analyzed the genome-wide transcriptional responses of P. aeruginosa PA14 to zinc restriction. This approach led to the identification of an operon (zrmABCD) regulated by the zinc uptake regulator Zur, that encodes for a metallophore-mediated zinc import system. This operon includes the genes for an uncharacterized TonB-dependent Outer Membrane Protein (ZrmA) and for a putative nicotianamine synthase (ZrmB). The simultaneous inactivation of the ZnuABC transporter and of one of these two genes markedly decreases the ability of P. aeruginosa to grow in zinc-poor media and compromises intracellular zinc accumulation. Our data demonstrate that ZrmB is involved in the synthesis of a metallophore which is released outside the cell and mediates zinc uptake through the ZrmA receptor. We also show that alterations in zinc homeostasis severely affect the ability of P. aeruginosa to cause acute lung and systemic infections in C57BL/6 mice, likely due to the involvement of zinc in the expression of several virulence traits. These findings disclose a hitherto unappreciated role of zinc in P. aeruginosa pathogenicity and reveal that this microorganism can obtain zinc through a strategy resembling siderophore-mediated iron uptake.

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Paolo Pasquali

Zinc Sequestration by the Neutrophil Protein Calprotectin Enhances Salmonella Growth in the Inflamed Gut

High-Affinity Zn²⁺Uptake System ZnuABC Is Required for Bacterial Zinc Homeostasis in Intracellular Environments and Contributes to the Virulence ofSalmonella enterica

Role of Iron Uptake Systems in Pseudomonas aeruginosa Virulence and Airway Infection

The Zur-Regulated ZinT Protein Is an Auxiliary Component of the High-Affinity ZnuABC Zinc Transporter That Facilitates Metal Recruitment during Severe Zinc Shortage

Growth ofPseudomonas aeruginosain zinc poor environments is promoted by a nicotianamine‐related metallophore

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Paolo Pasquali

Zinc Sequestration by the Neutrophil Protein Calprotectin Enhances Salmonella Growth in the Inflamed Gut

High-Affinity Zn2+Uptake System ZnuABC Is Required for Bacterial Zinc Homeostasis in Intracellular Environments and Contributes to the Virulence ofSalmonella enterica

Role of Iron Uptake Systems in Pseudomonas aeruginosa Virulence and Airway Infection

The Zur-Regulated ZinT Protein Is an Auxiliary Component of the High-Affinity ZnuABC Zinc Transporter That Facilitates Metal Recruitment during Severe Zinc Shortage

Growth ofPseudomonas aeruginosain zinc poor environments is promoted by a nicotianamine‐related metallophore

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High-Affinity Zn²⁺Uptake System ZnuABC Is Required for Bacterial Zinc Homeostasis in Intracellular Environments and Contributes to the Virulence ofSalmonella enterica