BackgroundPeripheral inflammation is often associated with major depressive disorder (MDD), and immunological biomarkers of depression remain a focus of investigation.MethodsWe used microarray data on whole blood from two independent case-control studies of MDD: the GlaxoSmithKline–High-Throughput Disease-specific target Identification Program [GSK-HiTDiP] study (113 patients and 57 healthy control subjects) and the Janssen–Brain Resource Company study (94 patients and 100 control subjects). Genome-wide differential gene expression analysis (18,863 probes) resulted in a p value for each gene in each study. A Bayesian method identified the largest p-value threshold (q = .025) associated with twice the number of genes differentially expressed in both studies compared with the number of coincidental case-control differences expected by chance.ResultsA total of 165 genes were differentially expressed in both studies with concordant direction of fold change. The 90 genes overexpressed (or UP genes) in MDD were significantly enriched for immune response to infection, were concentrated in a module of the gene coexpression network associated with innate immunity, and included clusters of genes with correlated expression in monocytes, monocyte-derived dendritic cells, and neutrophils. In contrast, the 75 genes underexpressed (or DOWN genes) in MDD were associated with the adaptive immune response and included clusters of genes with correlated expression in T cells, natural killer cells, and erythroblasts. Consistently, the MDD patients with overexpression of UP genes also had underexpression of DOWN genes (correlation > .70 in both studies).ConclusionsMDD was replicably associated with proinflammatory activation of the peripheral innate immune system, coupled with relative inactivation of the adaptive immune system, indicating the potential of transcriptional biomarkers for immunological stratification of patients with depression.
Mice received intra-hippocampal injections of scrapie-infected brain homogenate. Open field activity increased from around week 12 post-injection. Concomitantly the tendency to displace food from a tube inside the home cage decreased. The food was generally dug out with the feet, rather than carried by mouth, so its displacement was called burrowing. Food restriction was unnecessary for this burrowing to occur. Only later, around 18 weeks, did more general motor impairments develop. As burrowing in scrapie-infected mice decreased when open field activity increased, and preceded later motor impairments, it was not due to motor dysfunction. Burrowing is a simple, sensitive, objective, ethological measure, sensitive to preclinical prion disease. Other potential applications are in transgenic and knockout mice, models of ageing and Alzheimer's disease, and pharmacology, particularly neuroleptics.
Plasma membrane receptors control macrophage activities such as growth, differentiation and activation, migration, recognition, endocytosis and secretion. They are therefore important in a wide range of physiological and pathological processes including host defence, inflammation and repair, involving all systems of the body including the arterial wall and nervous system. The versatile responsiveness of these cells to various stimuli depends on their ability to express a large repertoire of receptors, some restricted to macrophages and closely related cells, others common to many cell types. This volume contains reviews of the macrophage receptors that are best characterized and deals with aspects of signal transduction and function of the actin cytoskeleton. Our introduction is designed to place these topics in perspective. We summarize features of constitutive and induced mononuclear phagocyte distribution within the body and consider receptor expression and macrophage responses in the context of cell heterogeneity associated with its complex life history. We classify receptors discussed in detail in other chapters, list ligand-binding properties that are not as well defined, and briefly review general features of receptor function in macrophages. An understanding of macrophage receptor biology should bring insights into the contribution of these cells to physiology and disease and result in an improved ability to manipulate activities within the mononuclear phagocyte system.
Kinesin and kinesin superfamily proteins are molecular motors involved in important intracellular functions such as organelle transport and cell division. They are microtubule-activated ATPases composed of a motor domain that binds to microtubules and a cargo-binding domain that binds to specific organelles. While searching for the slow Wallerian degeneration mutation (WldS) on distal mouse Chromosome (Chr) 4, we have identified a member of the kinesin superfamily whose predicted gene product has the N-terminal motor domain of Kif1b and a novel C-terminal cargo-binding domain homologous to Kif1a. Kif1b is responsible for the movement of mitochondria along the axon, but the novel isoform containing the alternative C-terminal domain is likely to have a different cargo-binding specificity. cDNA library screening and Northern blot analysis indicate that the alternatively spliced form of Kif1b containing the novel 3'end accounts for the most part of Kif1b expression. We also found more alternatively spliced exons that can give rise to heterogeneous transcripts. Therefore, alternative splicing, as well as multiple genes, may contribute to the selective movement of diverse organelles by anterograde axonal transport. Kif1b maps on distal mouse Chr 4, within the Wld genetic candidate interval, but outside the recently identified triplication. There is, however, no evidence that Kif1b is the Wld gene.
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