Epidemiology and outcomes of bone and joint infections in solid organ transplant recipients.

Bone and joint infection (BJI) epidemiology and outcomes in solid organ transplant recipients (SOTr) remain largely unknown. We aim to describe BJI in a multi-center cohort of SOTr (Swiss Transplant Cohort Study). All consecutive SOTr with BJI (01.05.2008-31.12.2019) were included. A nested case-control study to identify risk factors for BJI was performed. Among 4482 patients, 61 SOTr with 82 BJI were included, at an incidence of 1.4% (95% CI 1.1-1.7), higher in heart and kidney-pancreas SOTr (Gray's test p < .01). Although BJI were predominately late events (median of 18.5 months post-SOT), most infections occurred during the first year post-transplant in thoracic SOTr. Diabetic foot osteomyelitis was the most frequent infection (38/82, 46.3%), followed by non-vertebral osteomyelitis (26/82, 31.7%). Pathogens included Gram-positive cocci (70/131, 53.4%), Gram-negative bacilli (34/131, 26.0%), and fungi (9/131, 6.9%). BJI predictors included male gender (OR 2.94, 95% CI 1.26-6.89) and diabetes (OR 2.97, 95% CI 1.34-6.56). Treatment failure was observed in 25.9% (21/81) patients and 1-year mortality post-BJI diagnosis was 14.8% (9/61). BJI remain a rare event in SOTr, associated with subtle clinical presentations, high morbidity and relapses, requiring additional studies in the future.

Abeta-globulomers are formed independently of the fibril pathway.

Soluble A beta-oligomers are currently discussed as the major causative species for the development of Alzheimer's disease (AD). Consequently, the beta-amyloid cascade hypothesis was extended by A beta-oligomers and their central neuropathogenic role in AD. However, the molecular structure of A beta-oligomers and their relation to amyloid fibril formation remains elusive. Previously we demonstrated that incubation of A beta(1-42) with SDS or fatty acids induces the formation of a homogeneous globular A beta-oligomer termed A beta-globulomer. In this study we investigated the role of A beta-globulomers in the aggregation pathway of A beta-peptide. We used in vitro assays such as thioflavin-T binding and aggregation inhibitors like Congo red to reveal that A beta-peptide in its A beta-globulomer conformation is a structural entity which is independent from amyloid fibril formation. In addition, cellular Alzheimer's-like plaque forming assays show the resistance of A beta-globulomers to deposition as amyloid plaques. We hypothesize that a conformational switch of A beta is decisive for either fibril formation or alternatively and independently A beta-globulomer formation.

Alzheimer-like plaque formation by human macrophages is reduced by fibrillation inhibitors and lovastatin.

The cerebral deposition of Abeta-peptide as amyloid fibrils and plaques represents a hallmark characteristic of Alzheimer's disease (AD). AD plaques are defined by their green birefringence after Congo red staining, their spherulite-like superstructure and their association with specific secondary components. Here we show that primary human macrophages promote the formation of amyloid plaques that correspond in all aforementioned characteristics to typical amyloid plaques from diseased tissues: they consist of aggregated Abeta-peptide, they reveal the typical ''Maltese cross" structure and they are associated with the secondary components glycosaminoglycanes, apolipoprotein E (apoE) and the raft lipids cholesterol and sphingomyelin. Plaque formation can be impaired in this cell system by addition of small molecules, such as Congo red, melantonine and lovastatin, suggesting potential applications for the study of cellular amyloid formation and for the identification or validation of drug candidates.

Identification of molecular compounds critical to Alzheimer's-like plaque formation.

Amyloid diseases are characterized by the formation of insoluble amyloid fibrils from previously soluble polypeptides. In Alzheimer's disease (AD), amyloid fibrils, formed from beta-amyloid peptides, are deposited as extracellular amyloid plaques only inside the brain. As previously shown, Alzheimer's-like plaque formation in human monocyte culture recapitulates the features of in vivo amyloid plaque formation. Here we show that this cell model can be used to screen compounds that potentially influence amyloid formation in a throughput manner. We found that cellular amyloid fibril formation can be enhanced by dextran sulfate as well as heparin and can be impaired by stabilization of a micell-like beta-amyloid conformer by using myoinositol or by inhibition of phagocytosis with cytochalasin D. Altogether, our data demonstrate the utility of this cell model for investigating pathways and molecular interactions critical to amyloidogenesis.