Mannitol Does Not Enhance Tobramycin Killing of Pseudomonas aeruginosa in a Cystic Fibrosis Model System of Biofilm Formation

Cystic Fibrosis (CF) is a human genetic disease that results in the accumulation of thick, sticky mucus in the airways, which results in chronic, life-long bacterial biofilm infections that are difficult to clear with antibiotics. Pseudomonas aeruginosa lung infection is correlated with worsening lung disease and P. aeruginosa transitions to an antibiotic tolerant state during chronic infections. Tobramycin is an aminoglycoside currently used to combat lung infections in individuals with CF. While tobramycin is effective at eradicating P. aeruginosa in the airways of young patients, it is unable to completely clear the chronic P. aeruginosa infections in older patients. A recent report showed that co-addition of tobramycin and mannitol enhanced killing of P. aeruginosa grown in vitro as a biofilm on an abiotic surface. Here we employed a model system of bacterial biofilms formed on the surface of CF-derived airway cells to determine if mannitol would enhance the antibacterial activity of tobramycin against P. aeruginosa grown on a more clinically relevant surface. Using this model system, which allows the growth of robust biofilms with high-level antibiotic tolerance analogous to in vivo biofilms, we were unable to find evidence for enhanced antibacterial activity of tobramycin with the addition of mannitol, supporting the observation that this type of co-treatment failed to reduce the P. aeruginosa bacterial load in a clinical setting.     

The Evolution of Resistance to Simian Immunodeficiency Virus (SIV): A Review

Examining how pathogens cross species boundaries, spread within species, and persist within their hosts is an essential part of understanding the factors that underpin the evolution of virulence and host resistance. Here, we review current knowledge about the genetic diversity, molecular epidemiology, prevalence, and pathogenicity of simian immunodeficiency viruses (SIVs). SIVs have crossed species boundaries from simian hosts to humans on at least 12 separate occasions, one of which led to the global HIV–AIDS crisis. Though SIVs infect a wide range of primates, scientists have only recently begun to describe the natural history of SIV infection in their natural hosts. Several new studies reveal how both viral and host factors are responsible for the transmission to, and adaptation in, new hosts. These studies also suggest that the spread of the virus may be affected by host-specific traits, including social structure, mating system and demographic history. These studies challenge the traditional view that SIV is relatively benign in its natural host, and instead suggest that a highly dynamic relationship exists between SIV and its simian hosts.     

Distinct mechanisms of interactions of Opc-expressing meningococci at apical and basolateral surfaces of human endothelial cells; the role of integrins in apical interactions

Interactions of Opc-expressing Neisseria meningitidis with polarized and non-polarized human umbilical vein endothelial cells (Huvecs) were investigated. Metabolic inhibitors and cytochalasin D treatment showed that host cellular and cytoskeletal functions were important for Opc-expressing bacterial association with Huvecs at the apical surface. In addition, this interaction required the presence of serum in the incubation medium whilst association with nonpolarized cells did not require serum. Pre-exposure of Opc-expressing bacteria to serum was sufficient to increase the number of bacterial interactions at the apical surface; B306, a monoclonal antibody (mAb) against Opc, inhibited these interactions, suggesting that Ope binds to serum factor(s) and this in turn increases adherence to Huvecs. The receptors involved in this ‘sandwich’ adherence belong to the integrin family since the interaction was inhibited by peptides containing the amino acid sequence arginine-glycine-aspartic acid (RGD) and the tetrapeptide RGDS (but not the peptide RGES) was inhibitory. Non-polarized cells appeared to expose receptors/sites that bound to Opc-expressing bacteria directly, did not require serum factors and were not inhibited by RGD-containing peptides. Serum-dependent interactions of Opc-expressing bacteria to apical surface was inhibited significantly by severai mAbs against avβ3 integrins. Some mAbs against α5 and β1 caused partial inhibition; antibodies that did not block the function of β1 integrins or the mAbs against α2 integrins were not inhibitory to bacterial interactions with Huvecs. Purified vitronectin supported adherence of Opc-expressing bacteria to Huvecs but not of Opc-bacteria. These interactions were inhibited by mAb B306 against Opc, by RGDS peptides as well as by blocking antibodies directed against αvβ-3 but not antibodies against other integrins. These data suggest that a sequence of molecular events resulting in trimolecular complexes at the endothelial surface may drive neisserial invasion of Huvesc. The expression of Opc appears to enable bacteria to utilize the normal signal-transduction mechanism of host cells via ligands in sera that adhere to endothelial cell integrins.     

Threshold response of Madagascar's littoral forest to sea-level rise

Aim Coastal biodiversity hotspots are globally threatened by sea‐level rise. As such it is important to understand how ecosystems resist, respond and adapt to sea‐level rise. Using pollen, geochemistry, charcoal and diatom records in conjunction with previously published palaeoclimatic records, we investigated the mechanism, interactions and ecosystem response and resilience of Madagascar's littoral forest to late Holocene sea‐level rise. Location Sediment sequences were collected along the south‐east coast of Madagascar in two adjacent habitats in Mandena; the highly diverse littoral forest fragment and species‐poor Erica‐matrix. Methods We used a multi‐proxy approach to investigate the relative influence of environmental changes on the littoral ecosystem. We reconstructed past vegetation and fire dynamics over the past 6500 years at two sites in the littoral forest using fossil pollen and macrofossil charcoal contained in sedimentary sequences. Alongside these records we reconstructed past marine transgressions from the same sedimentary sequences using geochemical analyses, and a salinity and drought index through the analysis of fossil diatoms. Results Our findings indicated that it was the synergistic effect of sea‐level rise coupled with rainfall deficits that triggered a threshold event with a switch from two types of littoral forest (an open Uapaca forest and a closed littoral forest fragment) to an Erica–Myrica heath/grassland occurring in approximately less than 100 years. Resilience to sea‐level rise differed in the two adjacent habitats, suggesting that the littoral forest fragment was more resilient to the impacts of sea‐level change and aridity than the open Uapaca woodland. Conclusions We demonstrated that the littoral ecosystem was influenced by late Holocene sea‐level rise and climatic desiccation. While climate change‐integrated conservation strategies address the effects of climate change on species distribution and dispersal, our work suggests that more attention should be paid to the impacts of interactive climatic variables that affect ecosystem thresholds.     

Genetic Screens Identify Host Factors for SARS-CoV-2 and Common Cold Coronaviruses

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Low-dose Ad26.COV2.S protection against SARS-CoV-2 challenge in rhesus macaques

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Nitric Oxide and Cnidarian-Dinoflagellate Symbioses: Pieces of a Puzzle

The presence of nitric oxide synthase (NOS) activity is demonstratedin the tropical marine cnidarian Aiptasia pallida and in itssymbiotic dinoflagellate algae, Symbiodinium bermudense. Enzymeactivity was assayed by measuring the conversion of arginineto citrulline. Biochemical characterization of NOS from Aiptasiawas characterized with respect to cellular localization, substrateand cofactor requirements, inhibitors, and kinetics. In responseto acute temperature shock, anemones retracted their tentacles.Animals subjected to such stress had lower NOS activities thandid controls. Treatment with NOS inhibitors caused tentacularretraction, while treatment with the NOS substrate L-arginineinhibited this response to stress, as did treatment with NOdonors. These results provide a preliminary biochemical characterizationof, and suggest a functional significance for, NOS activityin anthozoan-algal symbiotic assemblages.