Besnoitia besnoiti infection alters both endogenous cholesterol de novo synthesis and exogenous LDL uptake in host endothelial cells

Besnoitia besnoiti, an apicomplexan parasite of cattle being considered as emergent in Europe, replicates fast in host endothelial cells during acute infection and is in considerable need for energy, lipids and other building blocks for offspring formation. Apicomplexa are generally considered as defective in cholesterol synthesis and have to scavenge cholesterol from their host cells for successful replication. Therefore, we here analysed the influence of B. besnoiti on host cellular endogenous cholesterol synthesis and on sterol uptake from exogenous sources. GC-MS-based profiling of cholesterol-related sterols revealed enhanced cholesterol synthesis rates in B. besnoiti-infected cells. Accordingly, lovastatin and zaragozic acid treatments diminished tachyzoite production. Moreover, increased lipid droplet contents and enhanced cholesterol esterification was detected and inhibition of the latter significantly blocked parasite proliferation. Furthermore, artificial increase of host cellular lipid droplet disposability boosted parasite proliferation. Interestingly, lectin-like oxidized low density lipoprotein receptor 1 expression was upregulated in infected endothelial hostcells, whilst low density lipoproteins (LDL) receptor was not affected by parasite infection. However, exogenous supplementations with non-modified and acetylated LDL both boosted B. besnoiti proliferation. Overall, current data show that B. besnoiti simultaneously exploits both, endogenous cholesterol biosynthesis and cholesterol uptake from exogenous sources, during asexual replication

Morphometric analysis of aerobic Eimeria bovis sporogony using live cell 3D holotomographic microscopy imaging

M onoxenous Eimeria species are widespread enteropathogenic apicomplexan protozoa with a high economic impact on livestock. In cattle, tenacious oocysts shed by E. bovis-infected animals are ubiquitously found and making infection of calves almost inevitable. To become infectious oocysts, exogenous oxygen-dependent E. bovis sporogony must occur leading to the formation of sporulated oocysts containing four sporocysts each harboring two sporozoites. Investigations on sporogony by live cell imaging techniques of ruminant Eimeria species are still absent in literature as commonly used fluorescent dyes do not penetrate resistant oocyst bi-layered wall. Sporogonial oocysts were daily analyzed by a 3D Cell Explorer Nanolive microscope to explore ongoing aerobic-dependent sporogony as close as possible to an in vivo situation. Subsequently, 3D holotomographic images of sporulating E. bovis oocysts were digitally stained based on refractive indices (RI) of oocyst bi-layered wall and sub-compartments of circumplasm using STEVE software (Nanolive), and the cellular morphometric parameters were obtained. Overall, three different E. bovis sporogony phases, each of them divided into two sub-phases, were documented: (i) sporoblast/sporont transformation into sporogonial stages, (ii) cytokinesis followed by nuclear division, and finally (iii) formation of four sporocysts with two fully developed sporozoites. Approximately 60% of sporulating E. bovis oocysts accomplished aerobic sporogony in a synchronized manner. E. bovis sporogony was delayed (i.e., 6 days) when compared to an in vivo situation where 2–3 days are required but under optimal environmental conditions. Live cell 3D holotomography analysis might facilitate the evaluation of either novel disinfectants- or anti-coccidial drug-derived effects on ruminant/avian Eimeria sporogony in vitro as discrimination of sporogony degrees based on compactness, and dry mass was here successfully achieved. Main changes were observed in the oocyst area, perimeter, compactness, extent, and granularity suggesting those parameters as an efficient tool for a fast evaluation of the sporulation degree

Ultrastructural localization of fructose-1,6-bisphosphatase in mouse brain

Fructose-1,6-bisphosphatase has been studied in adult mouse brain of different ages using an antibody directed against the liver isoform. The presence of liver fructose-1,6-bisphosphatase in cerebellum, cerebral cortex, and hippocampus was assayed using Western blot and different immunocytochemical techniques. Immunocytochemistry with peroxidase reaction product was used to locate fructose-1,6-bisphosphatase in both neurons and astrocytes in the same areas, as well as in the rest of the brain, at light and electron microscope levels. Double immunofluorescence with neuronal or astrocytic markers confirmed the neuronal and astrocytic location of fructose-1,6-bisphosphatase in confocal microscope images. At the subcellular level, fructose-1,6-bisphosphatase was located in the nuclear and cytoplasmic compartments of both neurons and astrocytes, at all ages studied. Ultrastructurally, immunostaining appeared as small patches in the nucleus and the cytosol. In addition, immunostaining was present over the outer mitochondrial membrane, the plasma membrane, and the membranes of the rough endoplasmic reticulum and nuclear envelope, but not over Golgi membranes. In the neuropil fructose-1,6-bisphosphatase was located in dendritic spines, as well as in abundant astrocytic processes that, in some cases, surrounded immunopositive synapses. The possible role of fructose-1,6-bisphosphatase in neurons and astrocytes is discussed.Zahady Velásquez is a recipient of a Doctoral Fellowship granted by MECESUP-Chile, Proyecto AUS 0006 and Fundación Marcelino Botín-España.Peer reviewe

Epigenetic Control of Somatostatin and Cortistatin Expression by Beta Amyloid Peptide

Beta Amyloid, present in senile plaques, has been related largely to neuronal loss in the brain of patients with Alzheimer’s disease. However, how neurons respond to b amyloid insults is still poorly understood. Here we show that b amyloid increases somatostatin and cortistatin gene expression mainly through an increase in histone 3 lysine 4 methylation (H3K4me3), a modification associated with transcriptional activation. Somatostatin and cortistatin partially decreased b amyloid toxicity in primary cortical neurons in culture. Thus we suggest that neurons respond to b amyloid insults by releasing somatostatin and cortistatin, which will act as a protective agent against b amyloid toxicity. Our results suggest a relevant function for both neuropeptides against b amyloid toxicity, providing new insights into Alzheimer’s diseaseb Amyloid, present in senile plaques, has been related largely to neuronal loss in the brain of patients with Alzheimer’s disease. However, how neurons respond to b amyloid insults is still poorly understood. Here we show that b amyloid increases somatostatin and cortistatin gene expression mainly through an increase in histone 3 lysine 4 methylation (H3K4me3), a modification associated with transcriptional activation. Somatostatin and cortistatin partially decreased b amyloid toxicity in primary cortical neurons in culture. Thus we suggest that neurons respond to b amyloid insults by releasing somatostatin and cortistatin, which will act as a protective agent against b amyloid toxicity. Our results suggest a relevant function for both neuropeptides against b amyloid toxicity, providing new insights into Alzheimer’s diseasePeer reviewe