Alterations in the accumulation patterns of polyamines in brains of myelin-deficient mice

Epigenetics and autoimmune diseases: the X chromosome-nucleolus nexus

Autoimmune diseases occur more often in females, suggesting a key role for the X chromosome. X chromosome inactivation, a major epigenetic feature in female cells that provides dosage compensation of X-linked genes to avoid overexpression, presents special vulnerabilities that can contribute to the disease process. Disruption of X inactivation can result in loss of dosage compensation with expression from previously sequestered genes, imbalance of gene products, and altered endogenous material out of normal epigenetic context. In addition, the human X has significant differences compared to other species and these differences can contribute to the frequency and intensity of the autoimmune disease in humans as well as the types of autoantigens encountered. Here a link is demonstrated between autoimmune diseases, such as systemic lupus erythematosus, and the X chromosome by discussing cases in which typically non-autoimmune disorders complicated with X chromosome abnormalities also present lupus-like symptoms. The discussion is then extended to the reported spatial and temporal associations of the inactive X chromosome with the nucleolus. When frequent episodes of cellular stress occur, the inactive X chromosome may be disrupted and inadvertently become involved in the nucleolar stress response. Development of autoantigens, many of which are at least transiently components of the nucleolus, is then described. Polyamines, which aid in nucleoprotein complex assembly in the nucleolus, increase further during cell stress, and appear to have an important role in the autoimmune disease process. Autoantigenic endogenous material can potentially be stabilized by polyamines. This presents a new paradigm for autoimmune diseases: that many are antigen-driven and the autoantigens originate from altered endogenous material due to episodes of cellular stress that disrupt epigenetic control. This suggests that epigenetics and the X chromosome are important aspects of autoimmune diseases.

Autoimmune diseases and polyamines

Genetics and environmental factors have important roles in autoimmune diseases but neither has given us sufficient understanding of these mysterious diseases. Therefore, we are now looking closer at epigenetics, an interface between genetics and environmental factors. Epigenetics can be defined as reversible heritable changes to chromatin that can alter gene expression without altering the gene's DNA sequence. Methylation of DNA and histones are primary means of epigenetic control. By adding methyl groups to DNA and histones, it can limit accessibility of the underlying gene thereby altering the amount of gene expression. The methyl group is derived from an essential molecule in the cell, S-adenosylmethionine (SAM). However, a group of small molecules called polyamines also require SAM for their synthesis. Polyamines are essential for many cellular functions and polyamine activity is increased in many autoimmune diseases. Presented here is the "polyamine hypothesis" in which increased polyamine synthesis competes with cellular methylation (epigenetic control) for SAM. It is proposed that increased polyamine activity can cause disruption of cellular methylation, which can lead to abnormal expression of previously sequestered genes and disruption of other methylation-dependent cellular processes.

Autoimmune disorders result from loss of epigenetic control following chromosome damage

Multiple sclerosis, systemic lupus erythematosus, and rheumatoid arthritis share common features in typical cases such as: adult onset, central nervous system problems, female predominance, episodes triggered by a variety of stresses, and an autoimmune reaction. At times, the different disorders are found in the same patient or close relatives. These disorders are quite complex but they may share a common mechanism that results in different, tissue-specific consequences based on the cell types in which the mechanism occurs. Here, it is hypothesized that DNA damage can lead to loss of epigenetic control, particularly when the damaged chromatin is distributed unevenly to daughter cells. Expression of genes and pseudogenes that have lost their epigenetic restraints can lead to autoimmune disorders. Loss of control of genes on the X chromosome and loss of control of polyamine expression are discussed as examples of this mechanism.

Systemic lupus erythematosus and related autoimmune diseases are antigen-driven, epigenetic diseases

Autoimmune diseases result when cellular stresses (ex UV, cell cycle, hormones, viruses, and/or drugs) induce altered expression of polyamines, leading to chromatin disruption, interference with chromatin methylation, exposure of sequestered genes, and interference with tissue-specific processes. Exposure of previously sequestered Alu and LINE-1 sequences can lead to reverse transcription of Alu-RNA (and other transcripts) by the LINE-1 reverse transcriptase, yielding autoantigenic, hypomethylated DNA fragments. Release from the cell of the hypomethylated DNA fragments, along with polyamine-associated nucleoprotein complexes formed with the fragments, would elicit the autoimmune response. Loss of gene control due to hypomethylation and chromatin disruption by polyamines or other factors can include loss of dosage compensation from the inactive X chromosome for spermine synthase and spermidine/spermine N(1)-acetyltransferase at Xp22.1. This leads to ongoing altered polyamine levels. Thus, autoimmune diseases result from epigenetic changes that lead to autoantigen generation.

Axonal transport of putrescine, spermidine and spermine in normal and regenerating goldfish optic nerves

Radopactove putrescine, spermidine or spermine was injected into the right eye of normal goldfish and fish in which both optic nerves had been crushed 18 days earlier. Fish were sacrificed 0.25-21 days after injection. Trichloroacetic acid-soluble and -insoluble material was extracted from the right retina and both tecta and assayed for radioactivity (significant differences between left and right tecta suggesting axonal transport). The nature of the radioactivity in the TCA-soluble fraction was determined on an amino acid analyzer. Results indicate that putrescine is not axonally transported in intact goldfish optic nerves, but that during regeneration of the optic nerve large amounts of putrescine are axonally transported at rates similar to the fast component of protein transport. Spermidine appears to be axonally transported both in intact optic nerves and in regenerating optic nerves, and at an intermediate rate of transport; the amount of spermidine transported is significantly increased during regeneration. Spermine is also axonally transported in intact and regenerating nerves, at a rate similar to the rapid rate of protein transport. The amount of spermine transported appears to be slightly less in regenerating than in intact nerves during early stages of regeneration, but increases during later stages of nerve regeneration. The results suggest that putrescine and spermidine may be preferentially transported during nerve regeneration, while spermine and spermidine are transported extensively in intact nerves.