Alzheimer's Disease Mutant Mice Exhibit Reduced Brain Tissue Stiffness Compared to Wild-type Mice in both Normoxia and following Intermittent Hypoxia Mimicking Sleep Apnea.

BACKGROUND: Evidence from patients and animal models suggests that obstructive sleep apnea (OSA) may increase the risk of Alzheimer's disease (AD) and that AD is associated with reduced brain tissue stiffness. AIM: To investigate whether intermittent hypoxia (IH) alters brain cortex tissue stiffness in AD mutant mice exposed to IH mimicking OSA. METHODS: Six-eight month old (B6C3-Tg(APPswe,PSEN1dE9)85Dbo/J) AD mutant mice and wild-type (WT) littermates were subjected to IH (21% O2 40 s to 5% O2 20 s; 6 h/day) or normoxia for 8 weeks. After euthanasia, the stiffness (E) of 200-µm brain cortex slices was measured by atomic force microscopy. RESULTS: Two-way ANOVA indicated significant cortical softening and weight increase in AD mice compared to WT littermates, but no significant effects of IH on cortical stiffness and weight were detected. In addition, reduced myelin was apparent in AD (vs. WT), but no significant differences emerged in the cortex extracellular matrix components laminin and glycosaminoglycans when comparing baseline AD and WT mice. CONCLUSION: AD mutant mice exhibit reduced brain tissue stiffness following both normoxia and IH mimicking sleep apnea, and such differences are commensurate with increased edema and demyelination in AD.

Ageing and chronic intermittent hypoxia mimicking sleep apnea do not modify local brain tissue stiffness in healthy mice.

Recent evidence suggests that obstructive sleep apnea (OSA) may increase the risk of Alzheimer´s disease (AD), with the latter promoting alterations in brain tissue stiffness, a feature of ageing. Here, we assessed the effects of age and intermittent hypoxia (IH) on brain tissue stiffness in a mouse model of OSA. Two-month-old and 18-month-old mice (N=10 each) were subjected to IH (20% O2 40s - 6% O2 20s) for 8 weeks (6h/day). Corresponding control groups for each age were kept under normoxic conditions in room air (RA). After sacrifice, the brain was excised and 200-micron coronal slices were cut with a vibratome. Local stiffness of the cortex and hippocampus were assessed in brain slices placed in an Atomic Force Microscope. For both brain regions, the Young's modulus (E) in each animal was computed as the average values from 9 force-indentation curves. Cortex E mean (±SE) values were 442±122Pa (RA) and 455±120 (IH) for young mice and 433±44 (RA) and 405±101 (IH) for old mice. Hippocampal E values were 376±62 (RA) and 474±94 (IH) for young mice and 486±93 (RA) and 521±210 (IH) for old mice. For both cortex and hippocampus, 2-way ANOVA indicated no statistically significant effects of age or challenge (IH vs. RA) on E values. Thus, neither chronic IH mimicking OSA nor ageing up to late middle age appear to modify local brain tissue stiffness in otherwise healthy mice.

Oxidative stress and neurodegenerative diseases: a neurotrophic approach.

Neurotrophins are important neurotrophic factors involved in the survival, differentiation and function of a wide variety of neuron populations. A common feature for most neurotrophins is that they are synthesized as precursor proteins (pro-neurotrophins) that upon being processed by proteolysis render the mature active form responsible for most of their trophic functions. However, some of the pro-neurotrophin form of these proteins, such as the precursor form of NGF (pro-NGF), have been shown to induce opposite effects and trigger apoptosis on neurons through the p75NTR receptor. This suggests that the balance between the levels of proneurotrophin and neurotrophin must be tightly controlled. In this context, it has been shown that in conditions of oxidative stress due for instance to aging or the development of some neurodegenerative disease, neurotrophins are oxidatively modified at least by advanced glycation/lipoxidation end products (AGE/ALEs) which makes pro-NGF refractary to be processed. The lack of maturation and the imbalance in favor of the precursor form may change the pattern of active signaling pathways towards cell death, thus exacerbating the deleterious alterations, for instance during the development of neurodegenerative diseases. Besides that, AGE/ALEs also induce the processing of the pro-NGF receptor p75NTR by α- secretase which is followed by the processing by γ -secretase and the release of the intracellular domain of p75NTR (p75NTRICD). Once cleaved, p75NTRICD recruits two intracellular interactors, NRIF and TRAF6, which allows NRIF phosphorylation by JNK. The phosphorylated form of NRIF then translocates to the nucleus and induces the expression of pro-apoptotic proteins. In this chapter we will summarize the mechanisms by which ROS- induce protein modifications, which proteins are susceptible to be modified, how these modifications affect function and signaling and, finally, how they can be related to neurodegenerative diseases.

FLRT3 is a Robo1-interacting protein that determines Netrin-1 attraction in developing axons.

BACKGROUND: Guidance molecules are normally presented to cells in an overlapping fashion; however, little is known about how their signals are integrated to control the formation of neural circuits. In the thalamocortical system, the topographical sorting of distinct axonal subpopulations relies on the emergent cooperation between Slit1 and Netrin-1 guidance cues presented by intermediate cellular targets. However, the mechanism by which both cues interact to drive distinct axonal responses remains unknown. RESULTS: Here, we show that the attractive response to the guidance cue Netrin-1 is controlled by Slit/Robo1 signaling and by FLRT3, a novel coreceptor for Robo1. While thalamic axons lacking FLRT3 are insensitive to Netrin-1, thalamic axons containing FLRT3 can modulate their Netrin-1 responsiveness in a context-dependent manner. In the presence of Slit1, both Robo1 and FLRT3 receptors are required to induce Netrin-1 attraction by the upregulation of surface DCC through the activation of protein kinase A. Finally, the absence of FLRT3 produces defects in axon guidance in vivo. CONCLUSIONS: These results highlight a novel mechanism by which interactions between limited numbers of axon guidance cues can multiply the responses in developing axons, as required for proper axonal tract formation in the mammalian brain.