Induction and selective accumulation of mutant ubiquitin in CA1 pyramidal neurons after transient global ischemia

Diminished stress resistance and defective adaptive homeostasis in age-related diseases

Adaptive homeostasis is defined as the transient expansion or contraction of the homeostatic range following exposure to subtoxic, non-damaging, signaling molecules or events, or the removal or cessation of such molecules or events (Mol. Aspects Med. (2016) 49, 1-7). Adaptive homeostasis allows us to transiently adapt (and then de-adapt) to fluctuating levels of internal and external stressors. The ability to cope with transient changes in internal and external environmental stress, however, diminishes with age. Declining adaptive homeostasis may make older people more susceptible to many diseases. Chronic oxidative stress and defective protein homeostasis (proteostasis) are two major factors associated with the etiology of age-related disorders. In the present paper, we review the contribution of impaired responses to oxidative stress and defective adaptive homeostasis in the development of age-associated diseases.

Adaptive preconditioning in neurological diseases - therapeutic insights from proteostatic perturbations

In neurological disorders, both acute and chronic neural stress can disrupt cellular proteostasis, resulting in the generation of pathological protein. However in most cases, neurons adapt to these proteostatic perturbations by activating a range of cellular protective and repair responses, thus maintaining cell function. These interconnected adaptive mechanisms comprise a 'proteostasis network' and include the unfolded protein response, the ubiquitin proteasome system and autophagy. Interestingly, several recent studies have shown that these adaptive responses can be stimulated by preconditioning treatments, which confer resistance to a subsequent toxic challenge - the phenomenon known as hormesis. In this review we discuss the impact of adaptive stress responses stimulated in diverse human neuropathologies including Parkinson׳s disease, Wolfram syndrome, brain ischemia, and brain cancer. Further, we examine how these responses and the molecular pathways they recruit might be exploited for therapeutic gain. This article is part of a Special Issue entitled SI:ER stress.

Role of the ubiquitin-proteasome system in brain ischemia: friend or foe?

The ubiquitin-proteasome system (UPS) is a catalytic machinery that targets numerous cellular proteins for degradation, thus being essential to control a wide range of basic cellular processes and cell survival. Degradation of intracellular proteins via the UPS is a tightly regulated process initiated by tagging a target protein with a specific ubiquitin chain. Neurons are particularly vulnerable to any change in protein composition, and therefore the UPS is a key regulator of neuronal physiology. Alterations in UPS activity may induce pathological responses, ultimately leading to neuronal cell death. Brain ischemia triggers a complex series of biochemical and molecular mechanisms, such as an inflammatory response, an exacerbated production of misfolded and oxidized proteins, due to oxidative stress, and the breakdown of cellular integrity mainly mediated by excitotoxic glutamatergic signaling. Brain ischemia also damages protein degradation pathways which, together with the overproduction of damaged proteins and consequent upregulation of ubiquitin-conjugated proteins, contribute to the accumulation of ubiquitin-containing proteinaceous deposits. Despite recent advances, the factors leading to deposition of such aggregates after cerebral ischemic injury remain poorly understood. This review discusses the current knowledge on the role of the UPS in brain function and the molecular mechanisms contributing to UPS dysfunction in brain ischemia with consequent accumulation of ubiquitin-containing proteins. Chemical inhibitors of the proteasome and small molecule inhibitors of deubiquitinating enzymes, which promote the degradation of proteins by the proteasome, were both shown to provide neuroprotection in brain ischemia, and this apparent contradiction is also discussed in this review.

Hypoxic preconditioning attenuates global cerebral ischemic injury following asphyxial cardiac arrest through regulation of delta opioid receptor system

This study was designed to investigate whether delta opioid receptor (DOR) is involved in the neuroprotective effect induced by hypoxic preconditioning (HPC) in the asphyxial cardiac arrest (CA) rat model. Twenty-four hours after the end of 7-day HPC, the rats were subjected to 8-min asphyxiation and resuscitated with a standardized method. In the asphyxial CA rat model, HPC improved the neurological deficit score (NDS), inhibited neuronal apoptosis, and increased the number of viable hippocampal CA1 neurons at 24 h, 72 h, or 7 days after restoration of spontaneous circulation (ROSC); however, the above-mentioned neuroprotection of HPC was attenuated by naltrindole (a selective DOR antagonist). The expression of hypoxia-inducible factor-1α (HIF-1α) and DOR, and the content of leucine enkephalin (L-ENK) in the brain were also investigated after the end of 7-day HPC. HPC upregulated the neuronal expression of HIF-1α and DOR, and synchronously elevated the content of L-ENK in the rat brain. HIF-1α siRNA was used to further elucidate the relationship between HIF-1α and DOR in the HPC-treated brain. Knockdown of HIF-1α by siRNA markedly abrogated the HPC induced upregulation of HIF-1α and DOR. The present study demonstrates that the expression of DOR in the rat brain is upregulated by HIF-1α following exposure to 7-day HPC, at the same time, HPC also increases the production of endogenous DOR ligand L-ENK in the brain. DOR activation after HPC results in prolonged neuroprotection against subsequent global cerebral ischemic injury, suggesting a new mechanism of HPC-induced neuroprotection on global cerebral ischemia following CA and resuscitation.

Distribution of lysine-specific demethylase 1 in the brain of rat and its response in transient global cerebral ischemia

The lysine-specific histone demethylase 1 (LSD1) is a chromatin modifying enzyme that specifically removes methyl groups from lysine 4 of histone 3 (H3-K4) and induces transcriptional repression. However, limited knowledge exists, regarding the existence and significance of LSD1 in the brain. We identified the distribution of LSD1 and H3-K4 mono-, di-, and tri-methylation in the brain of rats, respectively. The temporal and spatial distribution of LSD1 during ischemic brain injury was also explored. LSD1 immunoreactive cells were nucleus positive and were concentrated in the neurons of the hippocampus, cerebral cortex, striatum and amagdala. The distributions of H3-K4 mono-, di-, and tri-methylation exhibited exactly the same pattern as LSD1. LSD1 expression was induced both region and cell specifically after ischemic/perfusion, and complied with the two-peak mode of expression. These studies revealed a tightly regulated distribution for LSD1 in the brain of rats under ischemic insult, suggesting a critical role in neuron function.

Hippocampal CA1 atrophy and synaptic loss during experimental autoimmune encephalomyelitis, EAE

Over half of multiple sclerosis (MS) patients experience cognitive deficits, including learning and memory dysfunction, and the mechanisms underlying these deficits remain poorly understood. Neuronal injury and synaptic loss have been shown to occur within the hippocampus in other neurodegenerative disease models, and these pathologies have been correlated with cognitive impairment. Whether hippocampal abnormalities occur in MS models is unknown. Using experimental autoimmune encephalomyelitis (EAE), we evaluated hippocampal neurodegeneration and inflammation during disease. Hippocampal pathology began early in EAE disease course, and included decreases in CA1 pyramidal layer volume, loss of inhibitory interneurons and increased cell death of neurons and glia. It is interesting to note that these effects occurred in the presence of chronic microglial activation, with a relative paucity of infiltrating blood-borne immune cells. Widespread diffuse demyelination occurred in the hippocampus, but there was no significant decrease in axonal density. Furthermore, there was a significant reduction in pre-synaptic puncta and synaptic protein expression within the hippocampus, as well as impaired performance on a hippocampal-dependent spatial learning task. Our results demonstrate that neurodegenerative changes occur in the hippocampus during autoimmune-mediated demyelinating disease. This work establishes a preclinical model for assessing treatments targeted toward preventing hippocampal neuropathology and dysfunction in MS.

Hypoxic ischemia and proteasome dysfunction alter tau isoform ratio by inhibiting exon 10 splicing

Alternative splicing of tau exon 10 influences microtubule assembly and stability during development and in pathological processes of the central nervous system. However, the cellular events that underlie this pre-mRNA splicing remain to be delineated. In this study, we examined the possibility that ischemic injury, known to change the cellular distribution and expression of several RNA splicing factors, alters the splicing of tau exon 10. Transient occlusion of the middle cerebral artery reduced tau exon 10 inclusion in the ischemic cortical area within 12 h, resulting in the induction of three-repeat (3R) tau in cortical neurons. Ubiquitinated protein aggregates and reduced proteasome activity were also observed. Administration of proteasome inhibitors such as MG132, proteasome inhibitor I and lactacystin reduced tau exon 10 splicing in cortical cell cultures. Decreased levels of Tra2beta, an RNA splicing factor responsible for tau exon 10 inclusion, were detected both in cortical cell cultures exposed to MG132 and in cerebral cortex after ischemic injury. Taken together, these findings suggest that transient focal cerebral ischemia reduces tau exon 10 splicing through a mechanism involving proteasome-ubiquitin dysfunction and down-regulation of Tra2beta.

Mutant ubiquitin-mediated beta-secretase stability via activation of caspase-3 is related to beta-amyloid accumulation in ischemic striatum in rats

Previous studies have demonstrated that ischemic stroke increases beta-amyloid (Abeta) production by increasing beta-secretase (BACE1) through activation of caspase-3, and stimulates generation of mutant ubiquitin (UBB(+1)) in rat brains. In this study, we examined whether caspase-3 activation participates in the regulation of UBB(+1) generation and UBB(+1)-mediated BACE1 stability in ischemic injured brains. The results showed that UBB(+1) and activated caspase-3-immunopositive-stained cells were time dependently increased in the ipsilateral striatum of rat brains after middle cerebral artery occlusion. UBB(+1)-immunopositive cells could be co-stained with caspase-3, Abeta (UBB(+1)-Abeta), and BACE1 (UBB(+1)-BACE1). BACE1 protein could also be pulled down by immunoprecipitation with UBB(+1) antibody. Z-DEVD-FMK (DEVD), a caspase-3 inhibitor, significantly decreased the level of UBB(+1) protein and the number of UBB(+1)-Abeta and UBB(+1)-BACE1 double-stained cells in the ischemic striatum, as well as the level of UBB(+1)/BACE1 protein complex. We conclude that activation of caspase-3 might be upstream of UBB(+1) formation and that excessive UBB(+1) could bind to BACE1 and increase the stability of BACE1, thereby increasing Abeta in ischemic injured brains. These results suggest new biological and pathological effects of caspases and regulation of the ubiquitin-proteasome system in the brain. Our results provide new therapeutic targets to prevent further neurodegeneration in patients after stroke.

Ischemia-related changes in naive and mutant forms of ubiquitin and neuroprotective effects of ubiquitin in the hippocampus following experimental transient ischemic damage

Ubiquitin binds to short-lived proteins and denatured proteins produced by various forms of injury. The loss of ubiquitin leads to an accumulation of abnormal proteins and may affect cellular structure and function. The aim of the present study is to observe the chronological changes in ubiquitin naive form and its mutant form (ubiquitin(+1)) in the hippocampal CA1 region (CA1) after transient cerebral ischemia in gerbils. Delayed neuronal death in the CA1 was confirmed 4 days after ischemic insult with NeuN immunohistochemistry. Ubiquitin immunoreactivity and protein level in the CA1 were lowest at 12 h after ischemia/reperfusion; thereafter, they were increased with time. Ubiquitin(+1) immunoreactivity and protein levels in the CA1 were slightly decreased at 3 h after ischemia/reperfusion, and they were significantly increased 1 day after ischemia/reperfusion. In addition, ubiquitin and ubiquitin(+1) immunoreaction was expressed in astrocytes after delayed neuronal death in the ischemic CA1. To elucidate the protective effect of ubiquitin on ischemic damage, the animals were treated with ubiquitin (1.5 mg/kg body weight) intravenously via the femoral vein. Ubiquitin treatment significantly reduced ischemia-induced locomotor hyperactivity, neuronal death and reactive gliosis such as astrocytes and microglia. In addition, 5 days after ubiquitin treatment in the ischemic group, ubiquitin immunoreactivity was similar to that in the ubiquitin-treated sham group, however, ubiquitin(+1) immunoreactivity was higher than that in the ubiquitin-treated sham group. These findings indicate that the depletion of ubiquitin and the accumulation of ubiquitin(+1) in CA1 pyramidal neurons after transient cerebral ischemia may inhibit ubiquitin proteolytic pathway and this leads to delayed neuronal death of CA1 pyramidal neurons directly or indirectly after transient cerebral ischemia.