Truncated Tau Affects Mitochondrial Transport and reduction of ATP production available for the process of movement of these organelles. These observations are novel and represent a set of exciting findings whereby tau pathology could affect mitochondrial distribution in neurons, an event that may contribute to synaptic failure observed in AD.
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Accumulative evidence has shown that mitochondrial dysfunction plays a pivotal role in the pathogenesis of Alzheimer's
disease (AD). Mitochondrial impairment actively contributes to the synaptic and cognitive failure that characterizes AD. The presence
of soluble pathological forms of tau like hyperphosphorylated at Ser396 and Ser404 and cleaved at Asp421 by caspase 3, negatively
impacts mitochondrial bioenergetics, transport, and morphology in neurons. These adverse effects against mitochondria health will
contribute to the synaptic impairment and cognitive decline showed in AD. Current studies suggest that mitochondrial failure induced
by pathological tau forms are likely the result of the opening of the mitochondrial permeability transition pore (mPTP). mPTP is a
mitochondrial mega-channel that is activated by increases in calcium and is associated with mitochondrial stress and apoptosis. This
structure is composed of different proteins, where CypD is considered to be the primary mediator of mPTP activation. Also, new studies suggest that mPTP contributes to A pathology and oxidative stress in AD.
Further, inhibition of mPTP through the reduction of CypD expression prevents cognitive and synaptic impairment in AD mouse
models. More importantly, tau protein contributes to the physiological regulation of mitochondria through the opening/interaction
with mPTP in hippocampal neurons. Therefore, in this paper, we will discuss evidence that suggests an important role of pathological
forms of tau against mitochondrial health. Also, we will discuss the possible role of mPTP in the mitochondrial impairment produced
by the presence of tau pathology and its impact on synaptic function present in AD.
Fragile X Syndrome (FXS) is the most common inherited form of intellectual disability. It is produced by mutation of the
Fmr1
gene that encodes for the Fragile Mental Retardation Protein (FMRP), an important RNA-binding protein that regulates the expression of multiple proteins located in neuronal synapses. Individuals with FXS exhibit abnormal sensory information processing frequently leading to hypersensitivity across sensory modalities and consequently a wide array of behavioral symptoms. Insects and mammals engage primarily their sense of smell to create proper representations of the external world and guide adequate decision-making processes. This feature in combination with the exquisitely organized neuronal circuits found throughout the olfactory system (OS) and the wide expression of FMRP in brain regions that process olfactory information makes it an ideal model to study sensory alterations in FXS models. In the last decade several groups have taken advantage of these features and have used the OS of fruit fly and rodents to understand neuronal alteration giving rise to sensory perception issues. In this review article, we will discuss molecular, morphological and physiological aspects of the olfactory information processing in FXS models. We will highlight the decreased inhibitory/excitatory synaptic balance and the diminished synaptic plasticity found in this system resulting in behavioral alteration of individuals in the presence of odorant stimuli.
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