Current management of late onset neonatal bacterial sepsis in five European countries

Late onset neonatal sepsis (LOS) has a high mortality and the optimal management is poorly defined. We aimed to evaluate new expert panel-derived criteria to define LOS and characterize the current management and antibiotic susceptibility of LOS-causing organisms in Europe. A prospective observational study enrolled infants aged 4 to 90 days in five European countries. Clinical and laboratory findings as well as empiric treatment were recorded and patients were followed until the end of antibiotic therapy. Failure was defined as a change of primary antibiotic, no resolution of clinical signs, appearance of new signs/pathogens or death. Antibiotic therapy was considered appropriate if the organism was susceptible to at least one empiric antibiotic. 113 infants (median age 14 days, 62 % ≤1500 g) were recruited; 61 % were culture proven cases (28 CoNS, 24 Enterobacteriaceae, 11 other Gram-positives and 6 Gram-negative non-fermentative organisms). The predictive value of the expert-panel criteria to identify patients with a culture proven LOS was 61 % (95 % CI 52 % to 70 %). Around one third of Enterobacteriaceae were resistant to ampicillin + or cefotaxime + gentamicin but only 10 % to meropenem. Empiric treatment contained a total of 43 different antibiotic regimens. All-cause mortality was 8 % with an additional 45 % classified as failure of empiric therapy, mainly due to change of primary antibiotics (42/60). Conclusions: The expert panel—derived diagnostic criteria performed well identifying a high rate of culture proven sepsis. Current management of LOS in Europe is extremely variable suggesting an urgent need of evidence-based guidelines.     

Best Evidence Medical and Health Professional Education (BEME) collaboration: A moving spotlight

Early this year, a Massachusetts Institute of Technology professor of philosophy presented a new theory of time that caught our interest. One of the key concepts that Professor Skow presented is the “moving spotlight” theory. As Skow asserts, the experiences had a year ago or 10 years ago are still just as real, they’re just “inaccessible” because they are now in a different part of spacetime. This was felt to be an elegant notion to inform this ‘spotlight’ piece on BEME (www.bemecollaboration.org).     

Effects of intrathecal nocistatin on the flexor reflex and its interaction with orphanin FQ nociceptin

We studied the effects of intrathecal (i.t.) nocistatin, a peptide identified from the precursor of orphanin FQ/nociceptin (OFQ) on the spinal nociceptive flexor reflex in decerebrate, spinalized, unanesthetized rats and its interaction with i.t. OFQ. Nocistatin induced a moderate, non-dose-dependent facilitation of the flexor reflex without producing reflex depression whereas i.t. OFQ induced a biphasic dose-dependent facilitatory and inhibitory effect. The facilitatory effect of low dose (0.55 pmol) OFQ was significantly increased by nocistatin. On the other hand, the duration, but not magnitude, of reflex depression induced by a high (550 pmol) dose of OFQ was significantly shortened by 5.5 nmol nocistatin. Thus, nocistatin interacts with OFQ in a complex fashion, increasing excitation and reducing inhibition. No evidence was obtained for an antinociceptive effect of nocistatin in rat spinal cord.     

Evaluation of etiologic and prognostic factors in neonatal convulsions

This study evaluated etiologic and risk factors affecting long-term prognoses of neurologic outcomes in newborns with neonatal seizures. We enrolled patients at chronologic ages of 23-44 months, referred to the Department of Pediatric Neurology, Istanbul Medical Faculty, from January 1, 2007-December 31, 2009, after manifesting seizures in their first postnatal 28 days. Of 112 newborns, 41 were female, 71 were male, 33 were preterm, and 79 were full-term. Perinatal asphyxia (28.6%) and intracranial hemorrhage (17%) were the most common causes of neonatal seizures. Cerebral palsy developed in 27.6% of patients during follow-up. The incidence of epilepsy was 35.7%. Almost 50% of patients manifested developmental delay in one or more areas. Global developmental delay was the most common (50.8%) neurologic disorder. The correlation between gestational age or birth weight and adverse outcomes was nonsignificant. Etiology, Apgar score, need for resuscitation at birth, background electroencephalogram, neonatal status epilepticus, cranial imaging findings, type/duration of antiepileptic treatment, and response to acute treatment were all strong prognostic factors in neurologic outcomes. Neonatal seizures pose a threat of neurologic sequelae for preterm and full-term infants. Although the number of recognized etiologic factors in neonatal seizures has increased because of improvements in neonatology and diagnostic methods, perinatal asphyxia remains the most common factor.     

Endogenous nociceptin signaling and stress-induced analgesia

Nociceptin/orphanin FQ (NC) and its receptor (OP4) have been implicated in pain transmission. The aim of the present study was to investigate the role of the NC/OP4 system in stress-induced analgesia (SIA). The tail-withdrawal assay was performed in mice stressed by forced swimming in water at 15 degrees C (high severity swims) or 32 degrees C (low severity swims). High severity swims produced a naloxone-insensitive antinociceptive effect which was blocked by supraspinal NC (1 nmol). The selective OP4 receptor antagonist, [Nphe1]NC(-13)NH2 (30 nmol), was inactive by itself, but prevented the effect of NC. Low severity swims produced a milder analgesic effect that was partially antagonized by naloxone, completely blocked by NC and potentiated by [Nphe1]NC(-13)NH2. These findings confirm the anti-analgesic role of supraspinal NC and suggest that endogenous NC signaling counteracts the opioid component of SIA.     

A tolC Mutant of Francisella tularensis Is Hypercytotoxic Compared to the Wild Type and Elicits Increased Proinflammatory Responses from Host Cells

The highly infectious bacterium Francisella tularensis is a facultative intracellular pathogen and the causative agent of tularemia. TolC, which is an outer membrane protein involved in drug efflux and type I protein secretion, is required for the virulence of the F. tularensis live vaccine strain (LVS) in mice. Here, we show that an LVS ΔtolC mutant colonizes livers, spleens, and lungs of mice infected intradermally or intranasally, but it is present at lower numbers in these organs than in those infected with the parental LVS. For both routes of infection, colonization by the ΔtolC mutant is most severely affected in the lungs, suggesting that TolC function is particularly important in this organ. The ΔtolC mutant is hypercytotoxic to murine and human macrophages compared to the wild-type LVS, and it elicits the increased secretion of proinflammatory chemokines from human macrophages and endothelial cells. Taken together, these data suggest that TolC function is required for F. tularensis to inhibit host cell death and dampen host immune responses. We propose that, in the absence of TolC, F. tularensis induces excessive host cell death, causing the bacterium to lose its intracellular replicative niche. This results in lower bacterial numbers, which then are cleared by the increased innate immune response of the host.Francisella tularensis is the etiological agent of tularemia. F. tularensis is classified as a category A agent of bioterrorism by the U.S. Centers for Disease Control and Prevention (http://emergency.cdc.gov/agent/agentlist-category.asp) due to its low infectious dose, ease of aerosol dissemination, and capacity to cause high morbidity and mortality (19). There are two clinically relevant subspecies of F. tularensis: subsp. tularensis, which is extremely pathogenic in humans, and subsp. holarctica, which causes a less severe clinical presentation (48). The most severe form of the disease is pneumonic tularemia caused by the inhalation of aerosolized F. tularensis subsp. tularensis (19). The F. tularensis subsp. holarctica-derived live vaccine strain (LVS) was used for many years as the vaccination against tularemia. However, the basis for its attenuation is unknown, and it is no longer in use as a vaccine (46). The LVS is highly virulent in mice, where it causes a disease closely resembling human tularemia (30). These features make the LVS an important model for the study of tularemia. An additional Francisella species, F. novicida, causes disease only in immunocompromised individuals. F. novicida, like the LVS, is highly virulent in mice and widely used as a model of tularemia (20).F. tularensis is a Gram-negative, facultative intracellular pathogen (50). Although factors important for the virulence of F. tularensis are beginning to be identified, the molecular mechanisms behind the extreme pathogenicity of this organism still are largely unknown. In vivo, F. tularensis is a stealth pathogen, evading host cell defenses and dampening host proinflammatory responses. F. tularensis produces an unusual lipopolysaccharide that has low toxicity and does not activate host cells in a TLR4-dependent manner (4, 22). A critical aspect of the pathogenesis of F. tularensis is its ability to escape the phagosome and replicate within the cytosol of a variety of host cells, including both murine and human macrophages and dendritic cells (2, 3, 16, 25, 49). Although F. tularensis does have an extracellular phase (24), it is thought that cytosolic replication allows the bacteria to grow to large numbers while avoiding detection by the host immune system.Host cells respond to F. tularensis invasion by inducing cell death pathways, including apoptosis and pyroptosis (32, 38). In the intrinsic apoptotic pathway, cytochrome c is released from mitochondria into the cytosol, leading to caspase-9 activation and ultimately to the activation of effector caspases such as caspase-3 and -7 (10). In pyroptosis, caspase-1 is activated through the inflammasome complex, resulting in the release of proinflammatory cytokines such as interleukin-1ß (IL-1ß) (6, 32). Lai and coworkers demonstrated that the infection of murine J774 macrophage-like cells with the LVS activated the intrinsic apoptotic pathway as early as 12 h postinfection. Activated caspase-3, but not caspase-1, was detected in the infected cells (38). In contrast, Mariathasan et al. found that the infection of preactivated murine peritoneal macrophages by either the LVS or strain U112 (F. novicida) triggered pyroptosis and the release of IL-1ß (42). In both studies, the induction of cell death was dependent upon the bacteria escaping the phagosome and initiating cytosolic replication. Weiss and colleagues isolated mutants of strain U112 that were attenuated in vivo and caused increased cell death in tissue culture compared to that caused by wild-type U112 (53). This suggests that although host cells initiate death pathways in response to F. tularensis infection, the bacteria has the ability to actively reduce cell death, and this is important for virulence.In addition to triggering death pathways, host cells respond to invading bacteria by mounting a proinflammatory response to alert neighboring cells of the impending bacterial threat (17). However, F. tularensis has been shown to actively suppress these innate host responses. Telepnev and coworkers showed that the LVS disrupted toll-like receptor signaling and blocked the secretion of the proinflammatory cytokines tumor necrosis factor alpha (TNF-α) and IL-1ß by murine and human macrophages (51, 52). Similarly, Bosio and colleagues showed that the LVS inhibited the innate immune response of murine pulmonary dendritic cells to bacterial ligands, and the infection of mice with the fully virulent Schu4 strain (F. tularensis subsp. tularensis) caused an overall state of immunosuppression in the lungs (8, 9).The genome analysis of F. tularensis identified only a few potential virulence factors, suggesting that the bacterium uses novel factors to achieve its high level of pathogenicity (40). Unique to F. tularensis is a 33.9-kb region of DNA termed the Francisella pathogenicity island (FPI) (29, 40, 45). The FPI encodes genes that are essential for intracellular survival and virulence, including iglABCD and pdpABCD (45). F. tularensis lacks type III and IV secretion systems, which is surprising considering its intracellular nature. These secretion systems commonly are used by intracellular pathogens to deliver effector proteins inside host cells to manipulate host cell responses (14, 26). F. tularensis does contain genes encoding a type IV pilus biogenesis system that also functions in the secretion of soluble proteins by a type II-like mechanism and that are important for virulence (12, 31, 54). Finally, F. tularensis appears to contain a functioning type I secretion system that is critical for pathogenesis (28).Type I secretion systems function in the secretion of a variety of toxins and other virulence factors directly from the cytoplasm to the extracellular milieu in a single energized step (33, 37). The type I system consists of three separate components: an outer membrane channel-forming protein, a periplasmic adaptor or membrane fusion protein, and an inner membrane pump that typically belongs to the ATP-binding cassette family. The TolC protein of Escherichia coli, which functions in hemolysin secretion, is the prototypical outer membrane channel component (37). In addition to protein secretion, TolC functions in the efflux of small noxious molecules, conferring multidrug resistance (37). F. tularensis contains three TolC paralogs, TolC, FtlC, and SilC, with TolC and FtlC exhibiting significant homology to the E. coli TolC protein (28, 35). In a previous study we created tolC and ftlC deletion mutants in the F. tularensis LVS (28). We found that both TolC and FtlC participate in multidrug resistance in F. tularensis, but only the ΔtolC mutant was attenuated for virulence in mice by the intradermal route. Thus, tolC is a critical virulence factor of F. tularensis and likely functions in type I secretion in addition to multidrug efflux.Here, we delineate the molecular mechanisms behind the attenuation of the LVS ΔtolC mutant in mice infected by both the intradermal and intranasal routes. In vivo organ burden assays revealed that the ΔtolC strain is decreased for the bacterial colonization of liver, spleen, and most prominently, lungs. In vitro experiments revealed that the ΔtolC mutant is hypercytotoxic to murine macrophages, causing increased apoptosis via a mechanism involving caspase-3 but not caspase-1. In addition, the LVS ΔtolC mutant was hypercytotoxic toward human macrophages and elicited the significantly increased secretion of the proinflammatory chemokines CXCL8 (also known as IL-8) and CCL2 (also known as monocyte chemoattractant protein [MCP-1]). Taken together, these data demonstrate a critical role for TolC, likely via a TolC-secreted toxin(s), in the successful intracellular lifestyle of F. tularensis, its ability to evade host innate immune responses, and its overall virulence.     

Outbreak of Acute Respiratory Infection among Infants in Lisbon,Portugal, Caused by Human Adenovirus Serotype 3 and a New 7/3 Recombinant Strain

Human adenoviruses (AdVs) typically cause mild illnesses in otherwise healthy hosts. We investigated a pediatric outbreak of acute respiratory infection with fatal outcomes that occurred in Lisbon, Portugal, in 2004. Biological specimens were collected from 83 children attending two nurseries, a kinesiotherapy clinic, and the household of a nanny. Adenovirus infection was confirmed in 48 children by PCR and virus isolation. Most (96%) isolates were classified as being of subspecies B1. Phylogenetic analysis of fiber and hexon gene sequences revealed that most infants were infected with AdV serotype 3 (AdV3) strains. Infants attending one nursery harbored a new recombinant strain containing an AdV serotype 7 hexon and serotype 3 fiber (AdV7/3). Both the AdV3 and the AdV7/3 strains caused fatal infections. Two different serotype 3 strains were circulating in Lisbon in 2004, and the new AdV7/3 recombinant type originated from only one of those strains. These results demonstrate that recombination leads to the emergence of new adenovirus strains with epidemic and lethal potential.Human adenoviruses (HAdVs) have been associated with a wide spectrum of clinical diseases with respiratory and gastrointestinal symptoms (23, 32). Severe illness can occur in newborns, elderly individuals, and patients with underlying medical conditions. In otherwise healthy adults, infections caused by human adenoviruses do not represent a life-threatening clinical condition. Adenoviruses are characterized by a linear double-stranded DNA genome of 2 to 45 kbp that encodes 30 to 40 proteins (6). HAdV comprises 51 serotypes (HAdV-1 to HAdV-51), on the basis of type-specific antiserum-mediated neutralization of infectivity (10). The serotypes can be divided into seven species, named HAdV-A to HAdV-G, on the basis of hemagglutination inhibition and biochemical criteria (13). HAdV-B is further classified into subspecies B1 and B2, which use different cellular receptors for viral entry (29). These variants can be segregated by different geographic areas, time periods, and clinical conditions.Serotype identification is critical for epidemiological surveillance, the detection of new strains, assessment of treatment efficacy, and understanding the pathogenesis of HAdV. For example, acute respiratory disease is primarily caused by HAdV-B1 serotypes 3, 7, 16, and 21; HAdV-B2 serotypes 11 and 14; and HAdV-E serotype 4 (8, 23, 25, 28, 35, 38, 41). Respiratory infections caused by HAdV-B1 serotypes 3 and 7 (16) and HAdV-B2 serotype 14 (17) are potentially fatal. Neutralization tests are the classical reference method used for the typing of adenovirus and require virus isolation from infected organs or tissues (20). The main type-specific neutralizing epitope, the ɛ determinant, consists of loop 1 (L1) and loop 2 (L2) on the hexon protein, the major capsid protein and the most abundant structural protein (26). Cases of the failure of neutralization with the available antisera require extensive cross-neutralization studies to define a new HAdV type. To circumvent the practical problems associated with traditional serum neutralization studies, molecular methods for the typing of adenovirus have been established. Examples are restriction fragment length polymorphism (RFLP) analysis of adenoviral DNA (16), PCR-based assays (1, 36), and microarray-based methods (36). However, these methods cannot discriminate between all serotypes and do not allow detailed studies of molecular epidemiology and viral evolution to be performed.More recently, analysis of the nucleotide and amino acid sequences from different genes has shown that adenovirus species form three distinct phylogenetic clusters: HAdV-C belongs to cluster 1; HAdV-A and HAdV-F belong to cluster 2; and HAdV-B, HAdV-D, and HAdV-E belong to cluster 3 (6, 22). In addition, phylogenetic analysis of selected gene fragments has increasingly been used to classify human adenoviruses at the serotype and species levels (7, 19, 40), to detect cases of coinfection with multiple adenoviral species (36, 38), and to identify new recombinant strains formed between similar species (18, 37, 41) or different species (19). Finally, phylogenetic analysis has become an important tool in the epidemiological investigation of many disease outbreaks caused by adenovirus (11, 17, 27, 40, 41). In the present study, we have used epidemiological, virological, and molecular phylogenetic methods to investigate the causes and origin of a recent outbreak of acute respiratory infection in Lisbon, Portugal, that resulted in the deaths of two children.     

The role of sperm proteasomes during sperm aster formation and early zygote development: implications for fertilization failure in humans

BACKGROUND Sperm aster organization during bovine and human fertilization requires a paternally-derived centriole that must first disengage from the sperm tail connecting-piece. We investigated the participation of the 26S proteasome in this process. METHODS Proteasome localization and enzymatic activity were studied in normal and pathological human spermatozoa by immunocytochemistry and enzyme-substrate assays. The role of proteasomes during bovine zygote development was investigated using a pharmacological proteasome-inhibitor, MG132, and with anti-proteasome antibodies delivered by Streptolysin O-permeabilization or with the Chariot reagent. Human zygotes discarded after ICSI failures (n = 28) were also examined. RESULTS Proteasomes were localized in the sperm acrosome and connecting-piece, as well as in the pronuclei of bovine and human zygotes. Proteasomal enzymatic activities were decreased in defective human spermatozoa. Disrupted sperm aster formation and pronuclear development were found after pharmacological and immunological block of proteasomes in human/bovine spermatozoa and oocytes, as well as in 28 discarded human post-ICSI fertilization failures. CONCLUSIONS Specific proteasome inhibition disrupts sperm aster formation and pronuclear development/apposition in bovine and human zygotes. Human spermatozoa with defective centriolar/pericentriolar structures have decreased proteasomal enzymatic activity. Release of a functional sperm centriole that acts as a zygote microtubule-organizing center probably relies on selective proteasomal proteolysis. These findings suggest an important role of sperm proteasomes in zygotic development.