Sara Sandrini

Microbial endocrinology: how stress influences susceptibility to infection

A holistic approach to understanding the mechanisms by which stress influences the pathogenesis of infectious disease has resulted in the development of the field of microbial endocrinology. This transdisciplinary field represents the intersection of microbiology with mammalian endocrinology and neurophysiology, and is based on the tenet that microorganisms have evolved systems for using neurohormones, which are widely distributed throughout nature, as environmental cues to initiate growth and pathogenic processes. This review reveals that responsiveness to human stress hormones is widespread in the microbial world and documents recent advances in microbial endocrinology.

Elucidation of the Mechanism by Which Catecholamine Stress Hormones Liberate Iron from the Innate Immune Defense Proteins Transferrin and Lactoferrin

The ability of catecholamine stress hormones and inotropes to stimulate the growth of infectious bacteria is now well established. A major element of the growth induction process has been shown to involve the catecholamines binding to the high-affinity ferric-iron-binding proteins transferrin (Tf) and lactoferrin, which then enables bacterial acquisition of normally inaccessible sequestered host iron. The nature of the mechanism(s) by which the stress hormones perturb iron binding of these key innate immune defense proteins has not been fully elucidated. The present study employed electron paramagnetic resonance spectroscopy and chemical iron-binding analyses to demonstrate that catecholamine stress hormones form direct complexes with the ferric iron within transferrin and lactoferrin. Moreover, these complexes were shown to result in the reduction of Fe(III) to Fe(II) and the loss of protein-complexed iron. The use of bacterial ferric iron uptake mutants further showed that both the Fe(II) and Fe(III) released from the Tf could be directly used as bacterial nutrient sources. We also analyzed the transferrin-catecholamine interactions in human serum and found that therapeutically relevant concentrations of stress hormones and inotropes could directly affect the iron binding of serum-transferrin so that the normally highly bacteriostatic tissue fluid became significantly more supportive of the growth of bacteria. The relevance of these catecholamine-transferrin/lactoferrin interactions to the infectious disease process is considered.

Pseudomonas aeruginosa-Catecholamine Inotrope Interactions: A Contributory Factor in the Development of Ventilator-Associated Pneumonia?

BACKGROUND Ventilated patients receiving intensive care are at significant risk of acquiring a ventilator-associated pneumonia that is associated with significant morbidity and mortality. Despite intensive research, it is still unclear why Pseudomonas aeruginosa, a microbe that rarely causes pneumonia outside of intensive care, is responsible for so many of these infections. METHODS We investigated whether medications frequently prescribed to patients in the ICU, the catecholamine inotropes, were affecting the growth and virulence of P aeruginosa . Effects of clinically attainable concentrations of inotropes on P aeruginosa pathogenicity were explored using in vitro growth and virulence assays and an ex vivo model of infection using ciliated human respiratory epithelium. RESULTS We found that inotropes were potent stimulators of P aeruginosa growth, producing upto 50-fold increases in bacterial numbers via a mechanism involving inotrope delivery of transferrin-ron,internalization of the inotrope, and upregulation of the key pseudomonal siderophore pyoverdine.Inotropes also markedly increased biofilm formation on endotracheal tubing and enhanced the biofilm production and toxicity of P aeruginosa in its interaction with respiratory epithelium.Importantly, catecholamine inotropes also facilitated the rapid recovery of P aeruginosa from tobramycin antibiotic challenge. We also tested out the effect of the inotropes vasopressin and phenylephrine on the growth and virulence of P aeruginosa and found that, in contrast to the catecholamines,these drugs had no stimulatory effect. CONCLUSIONS Collectively, our results suggest that catecholamine inotrope-bacterial interactions may be an unexpected contributory factor to the development of P aeruginosa -ventilator-associated pneumonia.

Composition of the Lectin Pathway of Complement in Gallus gallus: Absence of Mannan-Binding Lectin-Associated Serine Protease-1 in Birds

The lectin pathway of complement is activated by multimolecular complexes that recognize and bind to microbial polysaccharides. These complexes comprise a multimeric carbohydrate recognition subunit (either mannan-binding lectin (MBL) or a ficolin), three MBL-associated serine proteases (MASP-1, -2, and -3), and MAp19 (a truncated product of the MASP-2 gene). In this study we report the cloning of chicken MASP-2, MASP-3, and MAp19 and the organization of their genes and those for chicken MBL and a novel ficolin. Mammals usually possess two MBL genes and two or three ficolin genes, but chickens have only one of each, both of which represent the undiversified ancestors of the mammalian genes. The primary structure of chicken MASP-2 is 54% identical with those of the human and mouse MASP-2, and the organization of its gene is the same as in mammals. MASP-3 is even more conserved; chicken MASP-3 shares ∼75% of its residues with human and Xenopus MASP-3. It is more widely expressed than other lectin pathway components, suggesting a possible function of MASP-3 different from those of the other components. In mammals, MASP-1 and MASP-3 are alternatively spliced products of a single structural gene. We demonstrate the absence of MASP-1 in birds, possibly caused by the loss of MASP-1-specific exons during phylogeny. Despite the lack of MASP-1-like enzymatic activity in sera of chicken and other birds, avian lectin pathway complexes efficiently activate C4.

Respiratory Syncytial Virus Increases the Virulence of Streptococcus pneumoniae by Binding to Penicillin Binding Protein 1a. A New Paradigm in Respiratory Infection

RATIONALE Respiratory syncytial virus (RSV) and Streptococcus pneumoniae are major respiratory pathogens. Coinfection with RSV and S. pneumoniae is associated with severe and often fatal pneumonia but the molecular basis for this remains unclear. OBJECTIVES To determine if interaction between RSV and pneumococci enhances pneumococcal virulence. METHODS We used confocal microscopy and Western blot to identify the receptors involved in direct binding of RSV and pneumococci, the effects of which were studied in both in vivo and in vitro models of infection. Human ciliated respiratory epithelial cell cultures were infected with RSV for 72 hours and then challenged with pneumococci. Pneumococci were collected after 2 hours exposure and changes in gene expression determined using quantitative real-time polymerase chain reaction. MEASUREMENTS AND MAIN RESULTS Following incubation with RSV or purified G protein, pneumococci demonstrated a significant increase in the inflammatory response and bacterial adherence to human ciliated epithelial cultures and markedly increased virulence in a pneumonia model in mice. This was associated with extensive changes in the pneumococcal transcriptome and significant up-regulation in the expression of key pneumococcal virulence genes, including the gene for the pneumococcal toxin, pneumolysin. We show that mechanistically this is caused by RSV G glycoprotein binding penicillin binding protein 1a. CONCLUSIONS The direct interaction between a respiratory virus protein and the pneumococcus resulting in increased bacterial virulence and worsening disease outcome is a new paradigm in respiratory infection.

Microbial endocrinology: host-bacteria communication within the gut microbiome

The human body is home to trillions of micro-organisms, which are increasingly being shown to have significant effects on a variety of disease states. Evidence exists that a bidirectional communication is taking place between us and our microbiome co-habitants, and that this dialogue is capable of influencing our health in a variety of ways. This review considers how host hormonal signals shape the microbiome, and what in return the microbiome residents may be signalling to their hosts.

Host stress hormone norepinephrine stimulates pneumococcal growth, biofilm formation and virulence gene expression

BackgroundHost signals are being shown to have a major impact on the bacterial phenotype. One of them is the endogenously produced catecholamine stress hormones, which are also used therapeutically as inotropes. Recent work form our laboratories have found that stress hormones can markedly increase bacterial growth and virulence. This report reveals that Streptococcus pneumoniae, a commensal that can also be a major cause of community acquired and nosocomial pneumonia, is highly inotrope responsive. Therapeutic levels of the stress hormone norepinephrine increased pneumococcal growth via a mechanism involving provision of iron from serum-transferrin and inotrope uptake, as well as enhancing expression of key genes in central metabolism and virulence. Collectively, our data suggests that Streptococcus pneumoniae recognises host stress as an environmental cue to initiate growth and pathogenic processes.ResultsEffects of a clinically attainable concentration of norepinephrine on S. pneumoniae pathogenicity were explored using in vitro growth and virulence assays, and RT-PCR gene expression profiling of genes involved in metabolism and virulence.We found that norepinephrine was a potent stimulator of growth, via a mechanism involving norepinephrine-delivery of transferrin-iron and internalisation of the inotrope. Stress hormone exposure also markedly increased biofilm formation. Importantly, gene profiling showed that norepinephrine significantly enhanced expression of genes involved in central metabolism and host colonisation. Analysis of the response of the pneumococcal pspA and pspC mutants to the stress hormone showed them to have a central involvement in the catecholamine response mechanism.ConclusionsCollectively, our evidence suggests that the pneumococcus has mechanisms to recognise and process host stress hormones to augment its virulence properties. The ability to respond to host stress signals may be important for the pneumococcal transition from colonization to invasion mode, which is key to its capacity to cause life-threatening pneumonia, septicaemia and meningitis.

Mutation design and strain background influence the phenotype of Escherichia coli luxS mutants

Previous analyses of luxS in Escherichia coli have used different strain backgrounds and design formats to produce the luxS mutation, resulting in luxS mutants with confusingly dissimilar phenotypes. This study therefore investigates the roles that strain background and mutational design strategy have upon the phenotype of the pathogenic E. coli luxS mutant. We inactivated luxS in three E. coli backgrounds: enteropathogenic E. coli E2348‐69, and enterohaemorrhagic strains Sakai and NCTC12900. To investigate the influence of mutational design strategy, four mutation formats were used: antibiotic resistance insertion methodologies as previously employed, using tetracycline and chloramphenicol resistance cassettes, and non‐polar strategies creating deletion and premature termination mutations. Our study showed that the E. coli luxS phenotype was markedly dependent on strain background: in some strains disruption of luxS caused significant metabolic stress or no stress at all. How the luxS mutation was constructed also shaped its phenotype: non‐polar mutants were very similar to wild type, while mutations made using the antibiotic insertion methodologies produced phenotypes defective in growth and virulence. Proteomic profiling of our luxS mutants showed only a few proteins were differentially expressed and those that were altered suggested a metabolic rather than communication role for the E. coli luxS gene product.

Mechanisms by Which Catecholamines Induce Growth in Gram-Negative and Gram-Positive Human Pathogens

Iron is essential for the growth of most bacteria, and its availability can determine the outcome of an infection. Pathogenic bacteria have evolved a variety of mechanisms to acquire this essential nutrient from host iron sequestering proteins such as transferrin and lactoferrin. Recently, this array of bacterial iron scavenging mechanisms has also been shown to include opportunistic use of catecholamine stress hormones and inotropes to directly acquire iron from transferrin and lactoferrin. Other mechanisms include catecholamine induction of novel bacterial growth inducers. This chapter considers in detail the several mechanisms by which catecholamines can stimulate the growth of infectious bacteria.