Hypertension, cerebrovascular impairment, and cognitive decline in aged AβPP/PS1 mice

Introduction

Dementia has become a public health problem in the aging world population ^{1, 2}. Alzheimer's disease (AD) is responsible for most dementia cases followed by vascular dementia (VaD) ^{3, 4}. AD is characterized by brain atrophy and a gradual cognitive decline caused by neuronal death and loss of synapses in brain regions involved in learning and memory processes (e.g. temporal and frontal lobes) ^{5, 6}.

Already the early stages of AD are characterized by the accumulation of Aβ affecting specific brain regions like the forebrain and medial temporal lobe structures like hippocampus, amygdala and entorhinal cortex ^7-9. Almost all insoluble Aβ is accumulated within the neuritic plaques and cerebral vessel walls ⁵.

Epidemiological and clinical studies revealed that AD and VaD share common vascular related risk factors such as hypertension, diabetes, hyperlipidemia, cerebrovascular disease, and arrhythmia ^10-16. Furthermore, it has been shown that vascular risk factors can influence the development of AD pathology (the vascular hypothesis) ¹⁷. A recent study showed that hypertension affects the expression of tau as well as that of Aβ in an AD mouse model ¹⁸. Further evidence supporting this link between hypertension and AD comes from clinical studies indicating that antihypertensives may reduce the development of AD ^{19, 20}. Other clinical studies suggested that resting cerebral blood flow (CBF) is decreased among hypertensive patients as opposed to that of normotensive subjects ^21-25. In elderly patients a decreased CBF has been shown to increase hippocampal and amygdalar atrophy ^{26, 27}. Therefore, an impaired or diminished cerebral perfusion may play a role in the development of AD via decreased delivery of oxygen in ischemia-sensitive brain regions like the hippocampus, inducing neurodegeneration and subsequent cognitive decline ²⁸. Notably, maladapted cerebral hemodynamics could lead to alteration in structural and functional connectivity in the brain represented by white matter lesions/hyperintensities. Impaired functional connectivity is also found in AD patients ^29-31 and additionally, a link between the incidence of white matter lesions and the severity of the underlying AD pathology has been reported ^32-34. Many studies have shown the relationship between increased blood pressure in mid-life and cognitive decline or AD in late-life ^{35, 36} indicating the relevance of proper blood pressure maintenance.

Therefore, to elucidate the underlying vascular origin of neurodegenerative processes in AD, we investigate the relation between vascular parameters (systolic blood pressure (SBP), cerebrovascular density, cerebral perfusion and vasoreactivity), functional and structural connectivity, and postmortem markers for neuroinflammation, neurogenesis, postsynaptic density, and levels of fatty acids and sterols and, in relation to cognition in the AβPP_swe/PS1_dE9 (AβPP/PS1) mouse model for AD.

To develop and evaluate potential therapeutic targets for early stages in AD it is necessary to understand underlying (neurovascular) pathological processes in AD by studying well characterized early stage AD animal models.

Materials and methods

Results

Discussion

Hypertension is the most common cardiovascular risk factor ^{36, 59-65}, and associated with all (other) key markers of AD such as presence of amyloid-β (Aβ) plaques, neurofibrillary tangles, and brain atrophy ⁶⁴. The increasing prevalence of hypertension due to the aging world population and growing prevalence of obesity could also increase the number of AD patients, since midlife hypertension almost doubles the risk of developing AD in later life ^{36, 66}. In agreement with this, the AβPP/PS1 AD-like model mice used in the present study, demonstrated an increased systolic blood pressure (SBP) and concomitant decreased regional CBF in the cortical and thalamic areas, decreased vasoreactivity of the circulation of the hippocampus, and impaired cognition. The WT and AβPP/PS1 mice showed a decrease in SBP over time, while the AβPP/PS1 mice always demonstrated a higher SBP than their WT littermates. This is in line with the AGES-Reykjavik study which has shown that midlife hypertension combined with a lower late-life BP is associated with a lowered total brain and gray matter volume ⁶⁷. Long-standing hypertension stimulates atherosclerosis and vascular remodeling leading to increases in wall thickness. Arterial stiffness and severe atherosclerosis can lead to an increase in pulse pressure ⁶⁸. An increased pulse pressure is correlated with a higher risk of AD in older adults ⁶⁸. In the Rotterdam study the presence of atherosclerotic plaques or wall thickening has been associated with dementia and its two major subtypes AD and vascular dementia ⁶⁶. In accordance to previous research, this AD-like mouse model suffers from early-impaired cerebrovascular autoregulation and CBF, but also shows abnormalities in the cortical microvasculature ^69-72. These results support the significant reduction in regional and global CBF as identified in studies on MCI and AD patients ⁷³. A lowered CBF is a common feature in the early phase of AD, which may possibly be caused by an accumulation of Aβ in the vessel walls or in close vicinity of the blood vessels ^{27, 74, 75}. Furthermore, the impaired vasoreactivity in our transgenic mice is also a clinical hallmark of AD ⁷⁶. Aβ has shown to directly enhance the vasoconstriction of the cerebral arteries and to stimulate selected constrictor responses, resulting in a reduced CBF ⁷⁴. In addition, deposition of Aβ in the cerebral microvessels promotes vascular pathology and dysfunction ^77-79, as embodied by the impaired hippocampal vasoreactivity in the brains of the AβPP/PS1 mice. Hypertension may contribute to this remodeling through increase in smooth muscle tone and damage of endothelial cell function resulting in arterial wall thickening and microvascular rarefaction ⁸⁰. In line with our research, Toth et al. demonstrated that in aging mice hypertension could induce an impaired cerebrovascular autoregulation ⁸¹, cerebromicrovascular injury and neuroinflammation. In the present study we investigated brain diffusivity with DTI as an imaging biomarker for white and gray matter integrity. FA is a marker of the degree of myelination and fiber density of white matter, while MD characterizes an inverse measure of the membrane density and is sensitive to cellularity, edema, and necrosis in grey matter (GM) ^82-84. In addition to an impaired cerebrovascular function, a reduced FA value of the visual cortex was found in our AD model mice indicating a subtle change in microstructural integrity. This impaired microstructural integrity could imply axonal degeneration or demyelination ⁸⁴ in the visual cortex. Nevertheless, no genotype effects were found for MD, being considered to be more informative for grey matter regions like the visual cortex. In our previous research using DTI in 12-month-old WT and AβPP/PS1 mice as well, fiber tract volume reduction, loss of axonal neurofilaments, and myelin breakdown in axonal bundles of several white matter regions (i.e. body of the corpus callosum) were detected in AβPP/PS1 mice compared to WT ⁸⁵. In this recent study minor genotype effect on FA and no genotype effects on MD were found. One reason for these missing genotype effects could be that already in normal aging significant white matter deterioration occurs due to myelin degeneration ⁸⁶. Therefore, myelin degeneration in our 18 months WT mice may mask partly the significant changes regarding structural connectivity in APP/PS1 mice. Nevertheless, in line with the loss of structural connectivity, a disturbed FC pattern in cortical and hippocampal brain regions was revealed in the 18-month-old AβPP/PS1 mice. In support, a mouse model for cerebral amyloidosis demonstrated a compromised FC affecting the sensory motor cortex already in pre-plaque stage ⁸⁷. Our latter results are in accordance with clinical studies, in which a decreased FC was also demonstrated in AD patients ^29-31.

A limiting factor of the acquired FC results is that the rsfMRI measurements are acquired in isoflurane anesthetized mice. Fortunately, using rsfMRI a general structure of the functional networks transcending levels of consciousness was detected in both preclinical and clinical studies ^88-90. Notably, under isoflurane anaesthesia a bilateral cortical connectivity in several cortical regions was measured ^{91, 92}. Nevertheless, also contradictory results were detected in isoflurane anesthetized mice showing not the same level of bilateral connectivity ^{55, 93}. However, in our previous and recent studies using isoflurane as anaesthesia, we confirmed the presence of networks in several well defined cortical and subcortical brain regions in two different murine models for vascular risk factors for AD ^{94, 95}. In our previous work we confirmed that both FC and CBF are dependent on isoflurane concentrations, and both FC and CBF decline with concentrations of isoflurane >2.2%, but do not further decline below a concentration of 2.2% ⁹⁵. Therefore, using the low- dose isoflurane (~1.7%) in this recent experiment will preserve the resting-state networks and will not interfere with the outcome of this study, as all animals were kept under the same low isoflurane concentration.

The combination of impaired cerebral hemodynamics, disturbed structural and functional connectivity, may underlie the impaired spatial learning capability found in the MWM. Here, the AβPP/PS1 mice needed more time to learn the position of the hidden platform. Moreover, these transgenic mice demonstrated a larger swim distance and higher swim velocity indicating an increased usage of non-spatial search strategies instead of hippocampus-dependent search strategies to find the hidden platform in the MWM ^{96, 97}. The behavior of the APP/PS1 mouse has been well-characterized. Mirroring the cognitive impairment being present in early AD patients, this cognitive deficit is a well-known feature of this AD mouse model. While at 4 and 7 months of age no learning deficit could be determined in AβPP/PS1 mice ^{98, 99}, these AD model mice tend to exhibit an impaired memory capacity at 8 months of age in our earlier studies ⁴⁸ and a significantly impaired spatial memory at 12 months of age, as demonstrated in studies from Lalonde et al. ¹⁰⁰. In fear-conditioning tests Kilgore et al. showed at already six months of age an impaired contextual memory in the APP/PS1 mouse model ¹⁰¹. However, Webster et al. performed recently a comprehensive behavioral analysis of a knock-in AβPP/PS1 mouse model ¹⁰² using four different age groups (7, 11, 15, and 24 months) in which cognitive deficits in spatial reference memory (radial arm water maze) appeared from 11 months of age and becoming apparent as the disease progressed and recognition memory (novel object recognition) was demonstrated just from 15 months of age ¹⁰². In line with previous results from our lab on younger (8-/12-/15-month-old) AβPP/PS1 mice ^{40, 48}, also our 18-month-old AβPP/PS1 mice exhibited an increased locomotor activity and anxiety-related behavior in the open field. Being linked to elevated anxiety levels, this heightened activity has been observed in many transgenic AD model mice ^103-105. This hyperactivity and anxiety-related behavior resembles restlessness and anxiety-related symptoms found in up to 71% of AD patients ^{106, 107}. The increased anxiety of our mice could reveal a possible pathological mechanism for the elevation in SBP. This phenotype of anxiety is an expression of a stressful chronic condition. Therefore, it is well known that mental stress is able per se to provoke an increase in blood pressure in mice ^{108, 109}. The influence of the overexpression of AβPP and PS1 on cognition is well-characterized in several AD mouse models, while the non-cognitive behavior has not been considered as systematically ¹¹⁰. Pugh et al. demonstrated reduced spontaneous motor activity, disinhibition, heightened frequency and duration of feeding bouts, decreased body weight and, by 10 months, increased activity over a 24h period in both female and male AβPP/PS1 mice ¹¹⁰. In addition, male mice also expressed a heightened aggression relative to WT controls ¹¹⁰. In the postmortem part of the study we revealed a decreased postsynaptic density and less DCX+ cells in the hippocampus of AβPP/PS1 mice indicating respectively a lowered synaptogenesis and neurogenesis, which may be the cause of the profound cognitive impairment found in the MWM in this AD-like transgenic mouse model. Notably, in our earlier studies, AβPP/PS1 mice showed decreased neurogenesis combined with a lowered hippocampal CBF already at 12-month of age ^{40, 49}. Moreover, in these younger 12-month-old AβPP/PS1 mice Zerbi et al. also detected impaired structural connectivity in the corpus callosum, fimbria, and cortex measured also via DTI ⁴⁹. This decrease in hippocampal CBF was no longer observed in the 18-month-old AβPP/PS1 mice granting a possible pathological timeframe starting with an impaired hippocampal CBF provoking a decreased synapto- and neurogenesis resulting in an impaired cognition. In another study, Ermini et al. showed as well a decreased neurogenesis in younger (8 months of age) AβPP/PS1 and (5 months of age) AβPP23 mice ¹¹¹. In many transgenic mouse models of AD an increased neuroinflammation has been observed reporting modulation of cytokine levels, activation of microglia and in some cases an activation of the complement system ¹¹². In the early pre-plaque stages of transgenic AD mice and, to a much lesser extent, in old WT mice highly activated microglia have been found ^113-117. In addition, Aβ-plaques in AD are engulfed by activated microglia ¹¹⁷. To measure neuroinflammation, we immunohistochemically stained the mouse brains with ionized calcium-binding adapter molecule 1 (IBA-1) being a marker for activated microglia ^118-120. Here, in our AD model mice more IBA+ cells were detected in cortical regions compared to their WT littermates. In accordance to the results of Minogue et al., in this mouse model after 14 months of age an age-associated dysregulation of microglial activation is coupled with an enhanced blood-brain barrier permeability ¹¹⁴. Furthermore, Meadowcroft et al. demonstrated activated microglial cells surrounding Aβ plaques in the brain of AβPP/PS1 mice. In accordance to our previous study, 18-month-old AβPP/PS1 mice did not show any differences in hippocampal capillary density measured via immunohistochemical staining for GLUT-1 ¹²¹. Notably, these mice exhibited the highest level of Aβ in combination with hippocampal atrophy ¹²¹. While 8-month-old AβPP/PS1 mice demonstrated also an increased amount of Aβ deposition in the dentate gyrus, but did not show any differences in hippocampal atrophy ¹²¹. Besides all other AD-like pathological changes in this AD mouse model, we also detected an increase in cerebral omega-6 fatty (n6) acid content (especially arachidonic acid, ARA) combined with a decrease in cerebral omega-3 (n3) fatty acid content (in particular docosahexaenoic acid, DHA) resulting in a pronounced decreased n3/n6-ratio, which is thought to elevate the risk for AD ^{122, 123}. In accordance to our results, Dutch drug-naïve patients with mild AD (Mini-Mental State Examination (MMSE) = 25.0) showed a decreased relative content of n3 fatty acids (including DHA) and an increased relative content of ARA in erythrocyte membranes compared to a group of Dutch healthy controls (MMSE = 29.0) ¹²⁴. In accordance, ARA is a mediator of inflammatory pathways, and its metabolites are involved in the production of Aβ and in the pathogenesis of AD ¹²⁵. In our previous research using the same transgenic mouse model, a multi-nutrient diet was able to induce a pronounced shift in n3/n6 ratio in favor of the n3 fatty acids as compared to the control diet ⁴⁰. Here, the reduction of the relative n6 content was mainly caused by a decrease in ARA, while the higher n3 content was mainly caused by an increase in DHA. Fabelo et al. revealed that AβPP/PS1 mice show a more rapid lipid raft aging compared to WT, which is related to an increased saturation of phospholipids (higher saturated fatty acids content and decreased content of the long chain unsaturated fatty acids ARA and DHA) and increased sphingomyelin levels rather than to alterations in cholesterol ¹²⁶. Moreover, Fabelo et al. demonstrated that both levels of ARA and DHA were gradually lowered with age in AβPP/PS1 mice, with its maximal reduction of approximately 50% at 14 months of age ¹²⁶. In our recent study the aged 18-month-old AβPP/PS1 mice demonstrated a pronounced decreased n3/n6-ratio in the frontal cortices due to a decrease in DHA and increased ARA. This contradictory data on ARA levels may be explained by age and the brain area measured, as Fabelo et al. analyzed homogenized cortex of a total hemisphere. Notably, Perez et al. revealed that both male and female 6-month-old AβPP/PS1 mice show neither a change in ARA nor a decrease in DHA brain fatty acid content ¹²⁷ indicating the pathological role of aging in disturbing cerebral membrane composition. Notably, a novel finding is the increased level of dihydro-lanosterol in our AD-model mice, being an intermediate in the cholesterol synthesis. Nevertheless, no genotype effects on cholesterol levels in blood and brain tissue were found. Decreased brain cholesterol levels were measured in our previous research using 15-month-old AβPP/PS1 mice compared to their WT littermates ⁴⁸. In addition, mice fed a high cholesterol-containing typical western diet showed a significant decreased regional cerebral blood volume compared to mice fed a standard control chow diet ⁴⁸. Notably, Park et al. showed an increased Aβ synthesis and senile Aβ plaque deposition only in female AD model (Tg2576) mice when using lovastatin (a blood-brain barrier crossing inhibitor of the cholesterol biosynthesis pathway) ¹²⁸. Dysregulation of the cerebral cholesterol homeostasis has been increasingly associated with chronic neurodegenerative disorders, including AD, Huntington's disease, and Parkinson's disease ¹²⁹. Furthermore, the E4 isoform of apolipoprotein E, being a cholesterol-carrying protein, is linked to an increased risk of developing AD ¹²⁹.

In conclusion, in this study we detected an increased SBP, impairments in cerebral hemodynamics resulting in an impaired cognition and structural and functional connectivity, increased locomotor activity, and anxiety-related behavior in an AD-like mouse model. In accordance, already in 4.5 months old AβPP/PS1 mice Cifuentes et al. indicated that hypertension is able to accelerate the development of Alzheimer disease-related structural and functional alterations, partially through cerebral vasculature impairment and reduced nitric oxide production ¹³⁰. Future research should also consider gender differences in these AβPP/PS1 mice. In detail, male mice develop Aβ plaques more rapidly than female mice, being saturated at nine months of age, while in female mice plaque accumulation does not reach its maximum in female mice until around 12 months of age ¹³¹. Notably, using both male and female 4-, 12-, and 17-month-old AβPP/PS1 mice Wang et al. demonstrated that female AβPP/PS1 mice have a higher hippocampal Aβ40 and Aβ42 levels than male AβPP/PS1 mice at 4 months of age Aβ and female AβPP/PS1 mice had a heavier Aβ burden and higher plaque number compared to male mice of the same age, both at 12 and at 17 months of age ¹³². Our results indicate that vascular impairment plays an important role in the very early stage of AD but whether it is a causative factor or just a contributor aggravating the disease progress, remains to be elucidated. Thus, future therapeutic approaches should focus on (cerebro)vascular impairment as a promising strategy for the prevention of AD. The present AD mouse model showing hypertension and cerebral circulation impairment could serve as translational tool for the development of treatments to inhibit neurodegenerative diseases like AD already in the prodromal phase of the disease.

Supplementary Material