Proinflammatory effects of M-CSF and A beta in hippocampal organotypic cultures.

Macrophage colony stimulating factor (M-CSF) is a microglial activator expressed at increased levels in the brain in Alzheimer's disease. In monotypic microglial cultures, M-CSF strongly augments amyloid beta (Abeta) induced microglial production of proinflammatory cytokines and nitric oxide. However, this augmentation could be due to strong autocrine and paracrine effects in monotypic cultures. We used hippocampal organotypic cultures to test M-CSF/Abeta augmentation in a system modeling intact brain. Combined M-CSF/Abeta treatment increased interleukin-1 (IL-1) and macrophage inflammatory protein 1-alpha expression by microglia, whereas inducible nitric oxide synthase (iNOS) expression was localized primarily to astroglia. Induction of cytokines and iNOS was also observed after lipopolysaccharide treatment of organotypic hippocampal cultures, but iNOS expression was localized mainly to microglia rather than astrocytes. Treatment with M-CSF/Abeta did not result in neuronal death. These results demonstrate that combined M-CSF/Abeta treatment results in a strong inflammatory response in the organotypic environment without inducing neurotoxicity.

Gene expression profile of the PDAPP mouse model for Alzheimer's disease with and without Apolipoprotein E.

The APOE epsilon 4 allele is a strong risk factor for Alzheimer's disease (AD). However, the molecular basis for this effect remains unclear. We examined expression of approximately 12,000 genes and expressed sequence tags in the hippocampus and cortex of PDAPP (APP(V717)) mice modeling AD that show extensive amyloid beta (A beta) deposition, and in PDAPP mice lacking murine APOE expression, which show marked attenuation of A beta deposition in the brain. Wild type and APOE knockout animals were also examined. Expression levels were determined at the initial stage of A beta deposition, as well as in older animals showing extensive neuropathological changes. Fifty-four transcripts were identified using our statistical analysis as differentially regulated between the PDAPP and PDAPP/APOE ko mice, whereas 31 transcripts were classified as differentially regulated among PDAPP mice and WT animals, and seven transcripts were identified as regulated between the PDAPP/APOE ko animals and the APOE ko animals. Interestingly, many of the differentially regulated genes we detected can be related to biological processes previously shown to be important in AD pathophysiology, including inflammation, calcium homeostasis, cholesterol transport and uptake, kinases and phosphatases involved in tau phosphorylation and dephosphorylation, mitochondrial energy metabolism, protein degradation, neuronal growth, endoplasmic reticulum (ER) stress related proteins, antioxidant activity, cytoskeletal organization, and presenilin binding proteins. Regulated genes also included some not directly associated with AD in the past but likely to be involved in known AD pathophysiologic mechanisms, and others that may represent completely novel factors in the pathogenesis of AD. These results provide a global molecular profile of hippocampal and cortical gene expression during the initial and intermediate stages Abeta deposition, and the effects of APOE deletion on this process.

Cardiac gene expression profile and lipid accumulation in response to starvation.

Starvation induces many biochemical and histological changes in the heart; however, the molecular events underlying these changes have not been fully elucidated. To explore the molecular response of the heart to starvation, microarray analysis was performed together with biochemical and histological investigations. Serum free fatty acids increased twofold in both 16- and 48-h-fasted mice, and cardiac triglyceride content increased threefold and sixfold in 16- and 48-h-fasted mice, respectively. Electron microscopy showed numerous lipid droplets in hearts of 48-h-fasted mice, whereas fewer numbers of droplets were seen in hearts from 16-h-fasted mice. Expression of 11,000 cardiac genes was screened by microarrays. More than 50 and 150 known genes were detected by differential expression analysis after 16- and 48-h-fasts, respectively. Genes for fatty acid oxidation and gluconeogenesis were increased, and genes for glycolysis were decreased. Many other genes for metabolism, signaling/cell cycle, cytoskeleton, and tissue antigens were affected by fasting. These data provide a broad perspective of the molecular events occurring physiologically in the heart in response to starvation.