Infant Pneumococcal Carriage in Belgium Not Affected by COVID-19 Containment Measures

Streptococcus pneumoniae is an important and frequently carried respiratory pathogen that has the potential to cause serious invasive diseases, such as pneumonia, meningitis, and sepsis. Young children and older adults are among the most vulnerable to developing serious disease. With the arrival of the COVID-19 pandemic and the concomitant restrictive measures, invasive disease cases caused by respiratory bacterial species, including pneumococci, decreased substantially. Notably, the stringency of the containment measures as well as the visible reduction in the movement of people appeared to coincide with the drop in invasive disease cases. One could argue that wearing protective masks and adhering to social distancing guidelines to halt the spread of the SARS-CoV-2 virus, also led to a reduction in the person-to-person transmission of respiratory bacterial species. Although plausible, this conjecture is challenged by novel data obtained from our nasopharyngeal carriage study which is performed yearly in healthy daycare center attending children. A sustained and high pneumococcal carriage rate was observed amid periods of stringent restrictive measures. This finding prompts us to revisit the connection between nasopharyngeal colonization and invasion and invites us to look closer at the nasopharyngeal microbiome as a whole.

Look Who’s Talking: Host and Pathogen Drivers of Staphylococcus epidermidis Virulence in Neonatal Sepsis

Preterm infants are at increased risk for invasive neonatal bacterial infections. S. epidermidis, a ubiquitous skin commensal, is a major cause of late-onset neonatal sepsis, particularly in high-resource settings. The vulnerability of preterm infants to serious bacterial infections is commonly attributed to their distinct and developing immune system. While developmentally immature immune defences play a large role in facilitating bacterial invasion, this fails to explain why only a subset of infants develop infections with low-virulence organisms when exposed to similar risk factors in the neonatal ICU. Experimental research has explored potential virulence mechanisms contributing to the pathogenic shift of commensal S. epidermidis strains. Furthermore, comparative genomics studies have yielded insights into the emergence and spread of nosocomial S. epidermidis strains, and their genetic and functional characteristics implicated in invasive disease in neonates. These studies have highlighted the multifactorial nature of S. epidermidis traits relating to pathogenicity and commensalism. In this review, we discuss the known host and pathogen drivers of S. epidermidis virulence in neonatal sepsis and provide future perspectives to close the gap in our understanding of S. epidermidis as a cause of neonatal morbidity and mortality.

The quorum sensing com system regulates pneumococcal colonisation and invasive disease in a pseudo-stratified airway tissue model

Streptococcus pneumoniae (Spn) colonises respiratory epithelia but can also invade lung cells causing pneumonia. We developed an ex vivo model with human airway epithelial (HAE) cells harvested from lung biopsies to study Spn colonisation and translocation. Flow-cytometry, confocal imaging and electron microscopy studies identified the epithelial lineage with signs of differentiation (beating cilia, mucus, and tight junctions). HAE cells were challenged with Spn wild-type TIGR4 (wtSpn) or its isogenic ΔcomC quorum sensing-deficient mutant. ΔcomC mutant colonised significantly less than wtSpn at 6 h post-inoculation but at significantly higher levels at 19 h and 30 h. Translocation correlated inversely with colonisation density. Transepithelial electric resistance (TEER) decreased after pneumococcal infection and correlated with increased translocation for both strains. Confocal imaging illustrated colocalisation of intracellular Spn with both cilia and zonulin-1 and prominent microcolony formation with wtSpn but disintegration of microcolony structures over time with ΔcomC mutant. ΔcomC caused a more pronounced release of both zonulin-1 and lactate dehydrogenase into the supernatant at later time points than wtSpn, suggesting that cytotoxicity is likely not the mechanism leading to translocation. There was a density- and time-dependent increase of inflammatory cytokines from human HAE cells infected with ΔcomC compared with wtSpn, including increased levels of the NLRP3 inflammasome-related IL-18. In conclusion, our experiments indicate that ComC system allows a higher organisational level of population structure resulting in microcolony formation, increased early colonisation and subsequent translocation. We propose that ComC inactivation unleashes a very different and possibly more virulent phenotype that merits further investigation.

The Significance of Short Latency in Mesothelioma for Attribution of Causation: Report of a Case with Predisposing Germline Mutations and Review of the Literature

Malignant mesothelioma is a tumour of the serosal membranes, related to asbestos exposure. Median latency is in the order of 40 years in various registries, but small numbers of cases with shorter latencies have long been reported and often dismissed as unrelated to asbestos exposure. However, emerging data regarding the significance of inherited mutations leading to a predisposition to mesothelioma suggest that the causative effect of asbestos may be associated with shorter latencies in a subset of patients. Here, we describe a male patient with germline mutations in RAD51 and p53 who developed peritoneal mesothelioma 8.5 years after well-documented asbestos exposure and discuss the current literature on the subject. Mesothelioma in situ is now a WHO-accepted diagnosis, but preliminary data reveal a potential lead time of 5 or more years to invasive disease, and this is also a factor which may affect the recording of latency (and potentially survival) in the future.

Autopsy dissection techniques and investigations in deaths due to COVID-19 triggered fungal infections - A diagnostic review

The COVID-19 pandemic, which originated from Wuhan, China, has rapidly spread worldwide, including India. As India grappled with the second wave, COVID-triggered fungal infection has suddenly risen tremendously, raising a sense of panic in the country. The fungal infection in COVID-19 includes Mucormycosis and Aspergillosis, as common fungal infections primarily affecting rhino-orbital structures. Many research papers have published postmortem findings in autopsies conducted on COVID-19 decedents, thereby helping to understand this contagious disease's pathogenesis. But, with the arrival of COVID-triggered fungal infection, which is a crucial invasive disease responsible for fatality, very few research papers have commented on the postmortem findings of invasive fungal infections affecting the rhino-orbital and craniocerebral structures in COVID-19 deaths. Therefore, the role of invasive fungal infection due to COVID-19 illness must be established in the causation of deaths in COVID-19 patients. This review research deals with autopsy dissection techniques and possible postmortem findings of invasive fungal infections involving the nasal and paranasal sinuses and orbital structures in COVID-19 deaths. The findings of fungal infection affecting nasal and paranasal systems may not differ in live patients and in a deceased; however, it is essential that correct interpretation of the postmortem findings aided by pre-or post-autopsy investigations is necessary to establish the role of covid triggered fungal infection in such deaths.

Interactions of Both Pathogenic and Nonpathogenic CUG Clade Candida Species with Macrophages Share a Conserved Transcriptional Landscape

Candidiasis is a major fungal infection by Candida species, causing life-threatening invasive disease in immunocompromised patients. C. albicans , which is adapted to commensalism of human mucosae, is the most common cause. While several other species cause infection, most are less prevalent or less virulent.

Epidemiology and population structure of Haemophilus influenzae causing invasive disease

This study provides an update on invasive Haemophilus influenzae disease in Bellvitge University Hospital (2014–2019), reporting its evolution from a previous period (2008–2013) and analysing the non-typeable H. influenzae (NTHi) population structure using a clade-related classification. Clinical data, antimicrobial susceptibility and serotyping were studied and compared with those of the previous period. Population structure was assessed by multilocus sequence typing (MLST), SNP-based phylogenetic analysis and clade-related classification. The incidence of invasive H. influenzae disease remained constant between the two periods (average 2.07 cases per 100 000 population), while the 30 day mortality rate decreased (20.7–14.7 %, respectively). Immunosuppressive therapy (40 %) and malignancy (36 %) were the most frequent comorbidities. Ampicillin and fluoroquinolone resistance rates had increased between the two periods (10–17.6 % and 0–4.4 %, respectively). NTHi was the main cause of invasive disease in both periods (84.3 and 85.3 %), followed by serotype f (12.9 and 8.8 %). NTHi displayed high genetic diversity. However, two clusters of 13 (n=20) and 5 sequence types (STs) (n=10) associated with clade V included NTHi strains of the most prevalent STs (ST3 and ST103), many of which showed increased frequency over time. Moreover, ST103 and ST160 from clade V were associated with β-lactam resistance. Invasive H. influenzae disease is uncommon, but can be severe, especially in the elderly with comorbidities. NTHi remains the main cause of invasive disease, with ST103 and ST160 (clade V) responsible for increasing β-lactam resistance over time.

Cervical Cancer, Papillomavirus, and miRNA Dysfunction

Cervical cancer is the leading cause of death by cancer in women from developing countries. Persistent infection with high-risk human papillomavirus (HPV) types 16 and 18 is a major risk factor for cervical carcinogenesis. Nevertheless, only a few women with morphologic expression of HPV infection progress into invasive disease suggesting the involvement of other factors in cervical carcinogenesis. MicroRNAs (miRNAs) are conserved small non-coding RNAs that negatively regulate gene expression including genes involved in fundamental biological processes and human cancer. Dysregulation of miRNAs has been widely reported in cervical cancer. This work focuses on reviewing the miRNAs affected during the HPV infection process, as well relevant miRNAs that contribute to the development and maintenance of malignant cervical tumor cells. Finally, we recapitulate on miRNAs that may be used to distinguish between healthy individuals from patients with precancerous lesions or cervical tumors.