Exploration of a hypothesized independent association of a common 9p21.3 gene variant and ischemic stroke in patients with and without angiographic coronary artery disease.

BACKGROUND: Single-nucleotide polymorphisms (SNPs) at the chromosome 9p21.3 locus are associated with coronary artery disease (CAD). An association of this genomic region with ischemic stroke independent of its effect on CAD could suggest an additional, stroke-specific pathophysiological relationship. METHODS: Medical record review was used to identify 548 patients without a history of cerebrovascular disease and 232 who had a verified ischemic stroke or transient ischemic attack (TIA) from the Duke CATHGEN biorepository of patients who had a cardiac catheterization. ANCOVA and multivariable logistic regression modeling were performed to determine independent genetic associations between the key chromosome 9p21.3 SNP, rs10757278, and ischemic stroke by comparing allele frequencies between 229 patients with stroke or TIA and an equal number of matched nonstroke controls, adjusting for other risk factors. In a secondary analysis, controls were further divided based on the presence (n = 353) or absence (n = 195) of angiographic CAD. RESULTS: Allele frequencies were similar between patients with and without a history of ischemic stroke in both additive (p = 0.83) and dominant (p = 0.92) models of genetic risk. There was no association between rs10757278 allele frequency and stroke status based on the presence or absence of angiographically demonstrated CAD in nonstroke controls (ANCOVA, p = 0.99). CONCLUSION: These results provide no evidence of a stroke-specific association of the 9p21.3 locus regardless of the presence or absence of angiographic CAD and highlight the need for larger studies to further evaluate this hypothesized relationship.

Lymphotoxin beta receptor (Lt betaR): dual roles in demyelination and remyelination and successful therapeutic intervention using Lt betaR-Ig protein.

Inflammation mediated by macrophages is increasingly found to play a central role in diseases and disorders that affect a myriad of organs, prominent among these are diseases of the CNS. The neurotoxicant-induced, cuprizone model of demyelination is ideally suited for the analysis of inflammatory events. Demyelination on exposure to cuprizone is accompanied by predictable microglial activation and astrogliosis, and, after cuprizone withdrawal, this activation reproducibly diminishes during remyelination. This study demonstrates enhanced expression of lymphotoxin beta receptor (Lt betaR) during the demyelination phase of this model, and Lt betaR is found in areas enriched with microglial and astroglial cells. Deletion of the Lt betaR gene (Lt betaR-/-) resulted in a significant delay in demyelination but also a slight delay in remyelination. Inhibition of Lt betaR signaling by an Lt betaR-Ig fusion decoy protein successfully delayed demyelination in wild-type mice. Unexpectedly, this Lt betaR-Ig decoy protein dramatically accelerated the rate of remyelination, even after the maximal pathological disease state had been reached. This strongly indicates the beneficial role of Lt betaR-Ig in the delay of demyelination and the acceleration of remyelination. The discrepancy between remyelination rates in these systems could be attributed to developmental abnormalities in the immune systems of Lt betaR-/- mice. These findings bode well for the use of an inhibitory Lt betaR-Ig as a candidate biological therapy in demyelinating disorders, because it is beneficial during both demyelination and remyelination.

TNF superfamily member TWEAK exacerbates inflammation and demyelination in the cuprizone-induced model.

Inflammatory cytokines have been implicated in the pathology of multiple neurologic diseases, including multiple sclerosis. We examined the role of the TNF family member TWEAK in neuroinflammation. Cuprizone-fed mice undergo neuroinflammation and demyelination in the brain, but upon removal of cuprizone from the diet, inflammation is resolved and remyelination occurs. Using this model, we demonstrate that mice lacking TWEAK exhibit a significant delay in demyelination and microglial infiltration. During remyelination, mice lacking the TWEAK gene demonstrate only a marginal delay in remyelination. Thus, this study identifies a primary role of TWEAK in promoting neuroinflammation and exacerbating demyelination during cuprizone-induced damage.

Upregulation of the stress-associated gene p8 in mouse models of demyelination and in multiple sclerosis tissues.

Cuprizone-induced demyelination is a mouse model of multiple sclerosis (MS) as cuprizone-fed mice exhibit neuroinflammation and demyelination in the brain. Upon removal of cuprizone from the diet, inflammation is resolved and reparative remyelination occurs. In an Affymetrix GeneChip analysis, the stress-associated gene p8 was strongly upregulated (>10x) during cuprizone-induced demyelination but not remyelination. We verified this upregulation (>15x) of p8 in the CNS during demyelination by real-time polymerase chain reaction (PCR). This upregulation is brain-specific, as p8 is not elevated in the liver, lung, kidney, spleen, and heart of cuprizone-treated mice. We also localized the cellular source of p8 during cuprizone treatment, and further found elevated expression during embryogenesis but not in normal adult brain. Compared with wild-type controls, the death of oligodendrocytes in p8-/- mice is delayed, as is microglial recruitment to areas of demyelination. The corpus callosum of p8-/- mice demyelinates at a slower rate than wild-type mice, suggesting that p8 exacerbates CNS inflammation and demyelination. Enhanced expression of p8 is also observed in the spinal cords of mice with acute experimental autoimmune encephalomyelitis (EAE) induced by PLP139-151 peptide (10x). Increased expression is detected during disease onset and expression wanes during the remission phase. Finally, p8 is found upregulated (8x) in post-mortem tissue from MS patients and is higher in the plaque tissue compared with adjacent normal-appearing white and gray matter. Thus, p8 is an excellent candidate as a novel biomarker of demyelination.

Astroglial-derived lymphotoxin-alpha exacerbates inflammation and demyelination, but not remyelination.

Tumor necrosis factoralpha (TNFalpha) and lymphotoxin-alpha (Ltalpha) are upregulated in and around multiple sclerosis plaques and are proposed to play a role during chronic inflammation in demyelinating disease. Despite the perceived detrimental role of these cytokines, human clinical trials inhibiting TNFalpha signaling has led to worsening of symptoms in multiple sclerosis (MS) patients. Our laboratory has verified a role for TNFalpha in the exacerbation of demyelination but, more importantly, has demonstrated a novel role for TNFalpha in reparative remyelination in a cuprizone-induced demyelination model. This may explain the worsening of symptoms experienced by MS patients. In view of the cross-talk in TNF family signaling, the aim of this study is to understand the role of Ltalpha in demyelination and remyelination in hopes of improving therapeutic strategies for MS. Using the same model, we show that mice lacking Ltalpha exhibit a delay in demyelination that is greater than that exhibited by TNFalpha null mice. In this model, Ltalpha is expressed primarily by astroglia. The delay in demyelination is accompanied by a delay in the loss of mature GSTpi-positive oligodendrocytes in Ltalpha-/- mice compared with wild-type mice. Ltalpha-/- mice have decreased numbers of microglia at the site of insult during demyelination, although the number of astrocytes present is similar between strains. In contrast to TNFalpha the lack of Ltalpha did not alter the time course of remyelination, or the number of mature oligodendrocytes during the remyelination phase. Since Ltalpha is detrimental in inflammation and demyelination, but not necessary for remyelination and repair, inhibiting Ltalpha signaling may represent a promising strategy to treat MS.

bHLH transcription factor Olig1 is required to repair demyelinated lesions in the CNS.

Olig1 and Olig2 are closely related basic helix-loop-helix (bHLH) transcription factors that are expressed in myelinating oligodendrocytes and their progenitor cells in the developing central nervous system (CNS). Olig2 is necessary for the specification of oligodendrocytes, but the biological functions of Olig1 during oligodendrocyte lineage development are poorly understood. We show here that Olig1 function in mice is required not to develop the brain but to repair it. Specifically, we demonstrate a genetic requirement for Olig1 in repairing the types of lesions that occur in patients with multiple sclerosis.