Biomarkers and evolution in Alzheimer disease

Rapoport, Stanley I.; Nelson, Peter T.

doi:10.1016/j.pneurobio.2011.07.006

Cited by 35 publications

(26 citation statements)

References 46 publications

(51 reference statements)

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“…These areas include not only the temporal regions, but regions around the medial parietal cortex (the precuneus/posterior cingulate/retrosplenial cortex) – an area that is an important component of the DMN. One speculation is that areas characterized by high degree of life-long plasticity are those most vulnerable to detrimental effects of normal and pathological aging (Neill, 1995, Mesulam, 1999, Bufill and Carbonell, 2004, Rapoport and Nelson, 2011, Neill, 2012, Bufill et al, 2013). The pattern of effects may be explained by the special role of the medial temporal lobes and other parts of DMN in learning and memory, with high demands for life-long plasticity required for these cognitive functions (Aimone et al, 2010, Deng et al, 2010).…”

Section: Neuroplasticity In the Aging Brain – A Critical Vulnerabimentioning

confidence: 99%

What is normal in normal aging? Effects of aging, amyloid and Alzheimer's disease on the cerebral cortex and the hippocampus

Fjell

McEvoy

Holland

et al. 2014

Progress in Neurobiology

708

522

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What can be expected in normal aging, and where does normal aging stop and pathological neurodegeneration begin? With the slow progression of age-related dementias such as Alzheimer’s Disease (AD), it is difficult to distinguish age-related changes from effects of undetected disease. We review recent research on changes of the cerebral cortex and the hippocampus in aging and the borders between normal aging and AD. We argue that prominent cortical reductions are evident in fronto-temporal regions in elderly even with low probability of AD, including regions overlapping the default mode network. Importantly, these regions show high levels of amyloid deposition in AD, and are both structurally and functionally vulnerable early in the disease. This normalcy-pathology homology is critical to understand, since aging itself is the major risk factor for sporadic AD. Thus, rather than necessarily reflecting early signs of disease, these changes may be part of normal aging, and may inform on why the aging brain is so much more susceptible to AD than is the younger brain. We suggest that regions characterized by a high degree of life-long plasticity are vulnerable to detrimental effects of normal aging, and that this age-vulnerability renders them more susceptible to additional, pathological AD-related changes. We conclude that it will be difficult to understand AD without understanding why it preferably affects older brains, and that we need a model that accounts for age-related changes in AD-vulnerable regions independently of AD-pathology.

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Section: Neuroplasticity In the Aging Brain – A Critical Vulnerabimentioning

confidence: 99%

What is normal in normal aging? Effects of aging, amyloid and Alzheimer's disease on the cerebral cortex and the hippocampus

Fjell

McEvoy

Holland

et al. 2014

Progress in Neurobiology

708

522

View full text Add to dashboard Cite

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“…Determining whether tau exon 8 is expressed in different primate species, for example, would help to affirm or refute its hypothesized protective role [87], as would studies of exon 8-bearing tau in cell cultures, organoids [102], and genetically modified animal models. A comparative evaluation of specific types of neurons especially vulnerable to tauopathy in AD [103] could also be informative; brain regions giving rise to long axonal connections have expanded in the evolution of hominids, and it has been proposed that enhanced neuroplasticity of these areas may render cells more susceptible to tangle formation, possibly due to increased remodeling of synaptic membranes, or the cytoskeleton [4]. An in depth analysis of regional vulnerability, tau variants and posttranslational modifications in humans and nonhuman primates is clearly needed.…”

Section: Why Has Ad Not Been Identified In Nonhuman Species?mentioning

confidence: 99%

The Exceptional Vulnerability of Humans to Alzheimer’s Disease

Walker

Jucker

2017

Trends in Molecular Medicine

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Like many humans, nonhuman primates deposit copious misfolded Aβ protein in the brain as they age. Nevertheless, the complete behavioral and pathologic phenotype of Alzheimer’s disease (AD), including Aβ plaques, neurofibrillary (tau) tangles, and dementia, has not yet been identified in a nonhuman species. Recent research suggests that the crucial link between Aβ aggregation and tauopathy is somehow disengaged in aged monkeys. Understanding why AD fails to develop in species that are biologically proximal to humans could disclose new therapeutic targets in the chain of events leading to neurodegeneration and dementia.

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“…In this way, the neocortex can be thought of as the evolutionary foundation for cognitive advances, including the uniquely human “theory of mind” and language. However, with these advances, human-specific ailments such as schizophrenia, autism spectrum disorders, Parkinson’s disease, Alzheimer’s disease, and Amyotrophic Lateral Sclerosis have also developed (Garey, 2010, Wegiel et al, 2010, Morgen et al, 2011, Ozdinler et al, 2011, Rapoport and Nelson, 2011, Yang et al, 2011). Therefore, understanding the molecular and cellular mechanisms underlying neocortical formation, maintenance, and dysfunction is critical not only for furthering basic neuroscience knowledge of brain development and architecture but also for better understanding neuropsychiatric disorders.…”

Section: Introductionmentioning

confidence: 99%

Post-transcriptional regulatory elements and spatiotemporal specification of neocortical stem cells and projection neurons

et al. 2013

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The mature neocortex is a unique six-layered mammalian brain region. It is composed of morphologically and functionally distinct subpopulations of primary projection neurons that form complex circuits across the central nervous system. The precisely-timed generation of projection neurons from neural stem cells governs their differentiation, postmitotic specification, and signaling, and is critical for cognitive and sensorimotor ability. Developmental perturbations to the birthdate, location, and connectivity of neocortical neurons are observed in neurological and psychiatric disorders. These facts are highlighting the importance of the precise spatiotemporal development of the neocortex regulated by intricate transcriptional, but also complex post-transcriptional events. Indeed, mRNA transcripts undergo many post-transcriptional regulatory steps before the production of functional proteins, which specify neocortical neural stem cells and subpopulations of neocortical neurons. Therefore, particular attention is paid to the differential post-transcriptional regulation of key transcripts by RNA-binding proteins, including splicing, localization, stability, and translation. We also present a transcriptome screen of candidate molecules associated with post-transcriptional mRNA processing that are differentially expressed at key developmental time points across neocortical prenatal neurogenesis.

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Biomarkers and evolution in Alzheimer disease

Cited by 35 publications

References 46 publications

What is normal in normal aging? Effects of aging, amyloid and Alzheimer's disease on the cerebral cortex and the hippocampus

What is normal in normal aging? Effects of aging, amyloid and Alzheimer's disease on the cerebral cortex and the hippocampus

The Exceptional Vulnerability of Humans to Alzheimer’s Disease

Post-transcriptional regulatory elements and spatiotemporal specification of neocortical stem cells and projection neurons

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