Age-matched Wild-type Littermates Research Articles

Daily rhythms in metabolic and locomotor behaviour of prematurely ageing PolgA mice.

Ageing is an inherent and intricate biological process that takes place in living organisms as time progresses. It involves the decline of multiple physiological functions, leading to body structure and overall performance modifications. The ageing process differs among individuals and is influenced by various factors, including lifestyle, environment and genetic makeup. Metabolic changes and reduced locomotor activity are common hallmarks of ageing. Our study focuses on exploring these phenomena in prematurely ageing PolgA(D257A/D257A) mice (also known as PolgA) aged 41-42 weeks, as they closely mimic human ageing. We assess parameters such as oxygen consumption (VO2), carbon dioxide production (VCO2), respiratory exchange ratio (RER) and locomotor activity using a metabolic cage for 4 days and comparing them with age-matched wild-type littermates (WT). Our findings revealed that VO2, VCO2, RER, locomotor activities, water intake and feeding behaviour show a daily rhythm, aligning with roughly a 24-h cycle. We observed that the RER was significantly increased in PolgA mice compared to WT mice during the night-time of the light-dark cycle, suggesting a shift towards a higher reliance on carbohydrate metabolism due to more food intake during the active phase. Additionally, female PolgA mice displayed a distinct phenotype with reduced walking speed, walking distance, body weight and grip strength in comparison to male PolgA and WT mice, indicating an early sign of ageing. Taken together, our research highlights the impact of sex-specific patterns on ageing traits in PolgA mice aged 41-42 weeks, which may be attributable to human ageing phenotypes. The unique genetic composition and accelerated ageing characteristics of PolgA mice make them invaluable in ageing studies, facilitating the investigation of underlying biological mechanisms and the identification of potential therapeutic targets for age-related diseases.

A novel preclinical model of human lung cancer cachexia

Most patients with lung cancer are afflicted with cancer cachexia (CC), a syndrome characterized by wasting of muscle and fat tissues, which leads to poor treatment response and increased mortality. Pre-clinical models used to study CC often do not mimic the human condition, which may explain why there are no approved treatments for CC. To overcome this barrier, we sought to develop a model of lung CC that better recapitulates the pathoetiological characteristics of human lung CC using mice with a tamoxifen-inducible, lung epithelial cell (club cell)-specific KrasG12D allele ( G12D mice). We hypothesized that this model would mimic human CC in tumor location and burden, rate of progression, and tumor-driven tissue wasting. Following induction by tamoxifen injection, adenocarcinomas developed in the terminal bronchioles as early as 3.5 weeks post-induction and were accompanied by loss of 15% of animal body weight over a 12-week period. This weight loss began at 6 weeks and yielded a slow rate of CC progression (-1.9%/week) relative to currently available lung CC models (-5-10%/week). Body weight loss resulted from reductions in hindlimb muscle mass (18-30%) and profound depletion of inguinal and gonadal adipose tissue depots (60-70%) compared to age-matched wild-type (WT) littermates. At 6 weeks post-induction, fat tissue was reduced at the tissue and cellular levels while reductions in hindlimb muscle weight and fiber size were not observed. This fat loss corresponded with increased serum glycerol levels at 6 and 12 weeks, a metabolic characteristic that was also found in patients with lung cancer receiving treatment. Lung organoids were developed from G12D and WT mice. G12D organoids exhibited similarities in gene expression to human lung tumors ( RNAseq) and their conditioned medium (CM) elicited glycerol release from cultured 3T3L1 adipocytes compared to CM from WT organoids, suggesting that tumor-derived factors may contribute to early adipose tissue atrophy. Collectively, these findings suggest that G12D mice may be a valuable model, well-suited to identify mechanisms leading to CC and test preventative therapies. NIH R01 AR065826(MJT), NCI R21 CA283492(MJT), T32- HL076122-18(DBS/MEP), R01 CA273238 (YJ-H) and the University of Vermont Cancer Center. Funding support for RNAseq provided by Zymo Impact Initiative Grant (DBS). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Lung-specific interleukin 6 mediated transglutaminase 2 activation and cardiopulmonary fibrogenesis.

Pulmonary hypertension (PH) pathogenesis is driven by inflammatory and metabolic derangements as well as glycolytic reprogramming. Induction of both interleukin 6 (IL6) and transglutaminase 2 (TG2) expression participates in human and experimental cardiovascular diseases. However, little is known about the role of TG2 in these pathologic processes. The current study aimed to investigate the molecular interactions between TG2 and IL6 in mediation of tissue remodeling in PH. A lung-specific IL6 over-expressing transgenic mouse strain showed elevated right ventricular (RV) systolic pressure as well as increased wet and dry tissue weights and tissue fibrosis in both lungs and RVs compared to age-matched wild-type littermates. In addition, IL6 over-expression induced the glycolytic and fibrogenic markers, hypoxia-inducible factor 1α, pyruvate kinase M2 (PKM2), and TG2. Consistent with these findings, IL6 induced the expression of both glycolytic and pro-fibrogenic markers in cultured lung fibroblasts. IL6 also induced TG2 activation and the accumulation of TG2 in the extracellular matrix. Pharmacologic inhibition of the glycolytic enzyme, PKM2 significantly attenuated IL6-induced TG2 activity and fibrogenesis. Thus, we conclude that IL6-induced TG2 activity and cardiopulmonary remodeling associated with tissue fibrosis are under regulatory control of the glycolytic enzyme, PKM2.

Inferring Parameters of Pyramidal Neuron Excitability in Mouse Models of Alzheimer’s Disease Using Biophysical Modeling and Deep Learning

Alzheimer’s disease (AD) is believed to occur when abnormal amounts of the proteins amyloid beta and tau aggregate in the brain, resulting in a progressive loss of neuronal function. Hippocampal neurons in transgenic mice with amyloidopathy or tauopathy exhibit altered intrinsic excitability properties. We used deep hybrid modeling (DeepHM), a recently developed parameter inference technique that combines deep learning with biophysical modeling, to map experimental data recorded from hippocampal CA1 neurons in transgenic AD mice and age-matched wildtype littermate controls to the parameter space of a conductance-based CA1 model. Although mechanistic modeling and machine learning methods are by themselves powerful tools for approximating biological systems and making accurate predictions from data, when used in isolation these approaches suffer from distinct shortcomings: model and parameter uncertainty limit mechanistic modeling, whereas machine learning methods disregard the underlying biophysical mechanisms. DeepHM addresses these shortcomings by using conditional generative adversarial networks to provide an inverse mapping of data to mechanistic models that identifies the distributions of mechanistic modeling parameters coherent to the data. Here, we demonstrated that DeepHM accurately infers parameter distributions of the conductance-based model on several test cases using synthetic data generated with complex underlying parameter structures. We then used DeepHM to estimate parameter distributions corresponding to the experimental data and infer which ion channels are altered in the Alzheimer’s mouse models compared to their wildtype controls at 12 and 24 months. We found that the conductances most disrupted by tauopathy, amyloidopathy, and aging are delayed rectifier potassium, transient sodium, and hyperpolarization-activated potassium, respectively.

Ovaries of estrogen receptor 1-deficient mice show iron overload and signs of aging.

Estrogens are crucial regulators of ovarian function, mediating their signaling through binding to estrogen receptors. The disruption of the estrogen receptor 1 (Esr1) provokes infertility associated with a hemorrhagic, cystic phenotype similar to that seen in diseased or aged ovaries. Our previous study indicated the possibility of altered iron metabolism in Esr1-deficient ovaries showing massive expression of lipocalin 2, a regulator of iron homeostasis. Therefore, we examined the consequences of depleting Esr1 in mouse ovaries, focusing on iron metabolism. For that reason, we compared ovaries of adult Esr1-deficient animals and age-matched wild type littermates. We found increased iron accumulation in Esr1-deficient animals by using laser ablation inductively coupled plasma mass spectrometry. Western blot analysis and RT-qPCR confirmed that iron overload alters iron transport, storage and regulation. In addition, trivalent iron deposits in form of hemosiderin were detected in Esr1-deficient ovarian stroma. The depletion of Esr1 was further associated with an aberrant immune cell landscape characterized by the appearance of macrophage-derived multinucleated giant cells (MNGCs) and increased quantities of macrophages, particularly M2-like macrophages. Similar to reproductively aged animals, MNGCs in Esr1-deficient ovaries were characterized by iron accumulation and strong autofluorescence. Finally, deletion of Esr1 led to a significant increase in ovarian mast cells, involved in iron-mediated foam cell formation. Given that these findings are characteristics of ovarian aging, our data suggest that Esr1 deficiency triggers mechanisms similar to those associated with aging.

Vulnerability of Spatial Pattern Separation in 5xFAD Alzheimer's Disease Mouse Model.

Alzheimer's disease (AD) is the most common cause of dementia and remains incurable. This age-related neurodegenerative disease is characterized by an early decline in episodic and spatial memory associated with progressive disruption of the hippocampal functioning. Recent clinical evidence suggests that impairment of the spatial pattern separation (SPS) function, which enables the encoding and storage of episodic spatial information, may be an indicator of the early stages of AD. The aim of our study was to characterize SPS performance at a prodromal stage in 5xFAD transgenic mouse model of AD. Behavioral performance of male wild-type (WT) and 5xFAD mice (n = 14 per group) was assessed from the age of 4 months in two validated paradigms of SPS function either based on spontaneous exploration of objects or on the use of a touchscreen system. Compared with age-matched WT littermates, a mild deficit in SPS function was observed in the object recognition task in 5xFAD mice, whereas both groups showed similar performance in the touchscreen-based task. These results were observed in the absence of changes in locomotor activity or anxiety-like behavior that could have interfered with the tasks assessing SPS function. Our results indicate an early vulnerability of the SPS function in 5xFAD mice in the paradigm based on spontaneous exploration of objects. Our work opens up the possibility of examining the early neurobiological processes involved in the decline of episodic memory and may help to propose new therapeutic strategies in the context of AD.

0258 Altered sleep regulation in a mouse model of Parkinson’s disease

Abstract Introduction Parkinson’s disease (PD) is a progressive neurodegenerative disorder characterized by pathognomonic motor abnormalities that lead to significant disability and morbidity in advanced stages. PD is also associated with sleep abnormalities such as increased fragmentation, insomnia, and excessive daytime sleepiness. Little is known of the underlying mechanisms, in part due to the limited ability of existing mouse models to adequately replicate human PD patient sleep phenotypes. Here we characterize sleep-wake behavior in an innovative genetic mouse model of PD (MCI-Park) targeting a mitochondrial complex I gene (Ndufs2), which experiences progressive dopaminergic neuron loss and displays motor phenotypes resembling those seen in human PD. Methods Undisturbed sleep-wake behavior during 12 hr light: 12 hr dark cycles was evaluated in MCI-Park mice during prodromal stages (6-8 weeks of age) and later parkinsonian stages (14-18 weeks of age) as well as in age-matched wildtype littermate controls. Electroencephalographic (EEG) and electromyographic (EMG) recording electrodes were surgically implanted using sterile technique in male and female MCI-Park and wildtype mice. After one week of recovery and acclimation to recording chambers, EEG and EMG were recorded continuously and sleep phenotypes were analyzed. Results In prodromal stages, MCI-Park mice exhibited similar overall sleep state amounts compared to wildtype mice, however there were significantly more state shifts as well as longer bouts of wakefulness and shorter bouts of non-REM (NREM) sleep. As mice progressed to parkinsonian stages, these fragmentation measures worsened. In addition, parkinsonian MCI-Park mice experienced a significant increase in wakefulness, a significant reduction in NREM sleep amount, and alterations in REM sleep, with pronounced reductions in REM sleep amount and number of REM bouts. Power spectral analysis revealed consistent decreases in theta2 (also known as alpha) power across all sleep-wake states in MCI-Park mice. Conclusion These results indicate that mice harboring a genetic defect causing selective disruption of dopaminergic neurons exhibit progressive sleep abnormalities that resemble sleep disturbances in PD patients. This model thus offers an opportunity to evaluate mechanisms underlying and therapeutic strategies targeting altered sleep in PD patients. Support (if any) This work was supported by the Department of Defense award number W81XWH-21-0582 (F.W.T. and D.J.S.).

Involvement of p38 MAPK in Leydig cell aging and age-related decline in testosterone.

Age-related decline in testosterone is associated with Leydig cell aging with impaired testosterone synthesis in aging. Obesity accelerates the age-related decline in testosterone. However, the mechanisms underlying the Leydig cell aging and the effects of obesity on Leydig cell aging remain unclear. Natural aging mice and diet-induced obese mice were used to assess the process of testicular Leydig cell senescence with age or obesity. Bioinformatic analysis of the young and aged human testes was used to explore key genes related Leydig cell aging. Leydig cell-specific p38 MAPK knockout (p38LCKO) mice were used to further analyze the roles of p38 MAPK in Leydig cell aging. The levels of testosterone and steroidogenic enzymes, activity of p38 MAPK, aging status of Leydig cells, and oxidative stress and inflammation of testes or Leydig cells were detected by ELISA, immunoblotting, immunofluorescence, and senescence-associated β-galactosidase (SA-β-Gal) staining analysis, respectively. The serum testosterone level was significantly reduced in aged mice compared with young mice. In the testis of aged mice, the reduced mRNA and protein levels of LHCGR, SRB1, StAR, CYP11A1, and CYP17A1 and the elevated oxidative stress and inflammation were observed. KEGG analysis showed that MAPK pathway was changed in aged Leydig cells, and immunoblotting displayed that p38 MAPK was activated in aged Leydig cells. The intensity of SA-β-Gal staining on Leydig cells and the number of p21-postive Leydig cells in aged mice were more than those of young mice. Similar to aged mice, the testosterone-related indexes decreased, and the age-related indexes increased in the testicular Leydig cells of high fat diet (HFD) mice. Aged p38LCKO mice had higher levels of testosterone and steroidogenic enzymes than those of age-matched wild-type (WT) littermates, with reduced the intensity of SA-β-Gal staining and the expression of p21 protein. Our study suggested that obesity was an important risk factor for Leydig cell aging. p38 MAPK was involved in Leydig cell aging induced by age and obesity. The inhibition of p38 MAPK could delay Leydig cell aging and alleviate decline in testosterone.

The 5XFAD mouse model of Alzheimer's disease displays age-dependent deficits in habituation to a novel environment.

Habituation is a form of learning characterized by a decrement in responsiveness to a stimulus that is repeated or prolonged. In rodents, habituation to a novel environment is characterized by a decrease in locomotion over time spent in a novel environment. Habituation to a novel environment is dependent on hippocampal function, suggesting that habituation behavior may be a relevant readout for hippocampal-dependent memory deficits that are characteristic of Alzheimer's disease (AD). Current assays that measure hippocampal-dependent memory in preclinical animal models of AD have not accurately predicted the cognitive protection of novel interventions in human trials. Here, we tested whether a behavioral habituation paradigm could detect age-associated changes in a common preclinical mouse model of AD-like amyloid pathology, the 5XFAD mouse. We exposed 5XFAD mice and age-matched wild-type (WT) littermates at 3, 6, and 9months of age to a novel environment over two sessions separated by 24h and measured their locomotion. WT mice habituated to the novel environment over time, while 5XFAD mice displayed age-dependent deficits in behavioral habituation. We replicated our results using publicly available open field data from 5XFAD and late-onset AD mouse models with TREM2*R47H and APOE4 mutations. Overall, we present behavioral habituation as a potentially sensitive task to assess age-associated behavioral deficits in 5XFAD mice and other mouse models of AD that could be used to test the preclinical efficacy of novel AD therapeutics.

Focused ultrasound mitigates pathology and improves spatial memory in Alzheimer's mice and patients.

Rationale: Bilateral sonication with focused ultrasound (FUS) in conjunction with microbubbles has been shown to separately reduce amyloid plaques and hyperphosphorylated tau protein in the hippocampal formation and the entorhinal cortex in different mouse models of Alzheimer's disease (AD) without any therapeutic agents. However, the two pathologies are expressed concurrently in human disease. Therefore, the objective of this study is to investigate the effects of repeated bilateral sonications in the presence of both pathologies. Methods: Herein, we investigate its functional and morphological outcomes on brains bearing both pathologies simultaneously. Eleven transgenic mice of the 3xTg-AD line (14 months old) expressing human amyloid beta and human tau and eleven age-matched wild-type littermates received four weekly bilateral sonications covering the hippocampus followed by working memory testing. Afterwards, immunohistochemistry and immunoassays (western blot and ELISA) were employed to assess any changes in amyloid beta and human tau. Furthermore, we present preliminary data from our clinical trial using a neuronavigation-guided FUS system for sonications in AD patients (NCT04118764). Results: Interestingly, both wild-type and transgenic animals that received FUS experienced improved working memory and spent significantly more time in the escape platform-quadrant, with wild-type animals spending 43.2% (sham: 37.7%) and transgenic animals spending 35.3% (sham: 31.0%) of the trial in the target quadrant. Furthermore, this behavioral amelioration in the transgenic animals correlated with a 58.3% decrease in the neuronal length affected by tau and a 27.2% reduction in total tau levels. Amyloid plaque population, volume and overall load were also reduced overall. Consistently, preliminary data from a clinical trial involving AD patients showed a 1.8% decrease of amyloid PET signal 3-weeks after treatment in the treated hemisphere compared to baseline. Conclusion: For the first time, it is shown that bilateral FUS-induced BBB opening significantly and simultaneously ameliorates both coexistent pathologies, which translated to improvements in spatial memory of transgenic animals with complex AD, the human mimicking phenotype. The level of cognitive improvement was significantly correlated with the volume of BBB opening. Non-transgenic animals were also shown to exhibit similar memory amelioration for the first time, indicating that BBB opening results into benefits in the neuronal function regardless of the existence of AD pathology. A potential mechanism of action for the reduction of the both pathologies investigated was the cholesterol metabolism, specifically the LRP1b receptor, which exhibited increased expression levels in transgenic mice following FUS-induced BBB opening. Initial clinical evidence supported that the beta amyloid reduction shown in rodents could be translatable to humans with significant amyloid reduction shown in the treated hemisphere.

Age- and Sex-Dependent Behavioral and Neurochemical Alterations in hLRRK2-G2019S BAC Mice.

The G2019S mutation in the leucine-rich repeat kinase 2 (LRRK2) gene is associated with late-onset Parkinson's disease (PD). Although PD affects men and women differently, longitudinal studies examining sex- and age-dependent alterations in mice carrying the G2019S mutation are limited. We examined if behavioral and neurochemical dysfunctions, as well as neurodegeneration, occur in male and female BAC LRRK2-hG2019S (G2019S) mice, compared to their age-matched wild type littermates, at four age ranges. In the open field test, hyperlocomotion was observed in 10-12 month old male and 2-4.5 months old female G2019S mice. In the pole test, motor coordination was impaired in male G2019S mice from 15 months of age and in 20-21 months old female G2019S mice. In the striatum of G2019S male and female mice, the amounts of tyrosine hydroxylase (TH), measured with Western blotting, were unaltered. However, we found a decreased expression of the dopamine transporter in 20-21 month old male G2019S mice. The number of TH-positive neurons in the substantia nigra compacta was unaltered in 20-21 month old male and female G2019S mice. These results identify sex- and age-dependent differences in the occurrence of motor and neurochemical deficits in BAC LRRK2-hG2019S mice, and no degeneration of DA neurons.

Repeated performance of spatial memory tasks ameliorates cognitive decline in APP/PS1 mice

BackgroundAlzheimer's disease (AD) is a burden on the public health system because it is a neurodegenerative disease that is incurable and for which there is no successful treatment. AD patients suffer from symptoms for many years, with progressive loss of cognitive and functional abilities. In addition to the features of AD, described as amyloid plaques and neurofibrillary tangles, neuroinflammatory processes, genetic factors, and lifestyle also play important roles. Increasing evidence for lifestyle factors includes possible changes due to smoking, social engagement, and physical activity. MethodsMorris water maze behavioral tasks were performed to analyze the formation of spatial memory. APPswe/PS1dE9 mice with a remarkable increase in amyloid-β production associated with certain behavioral abnormalities comparable to AD symptoms and age-matched wild-type littermates were trained several times at 3, 6, 9, and 12 months of age and compared with untrained groups at 9 and 12 months of age. Performance during the acquisition phase, in the reference memory test, and in searching strategies were analyzed. Results9- and 12-month-old APP/PS1 mice showed cognitive impairment, especially in the reference memory test and searching strategies. This cognitive deterioration was reversed in 9- and 12-month-old APP/PS1 mice that had been previously trained several times. Even in the reversal test, in which memory formation must be adapted to the new platform position, several trained APP/PS1 mice performed better. ConclusionRepeated spatial memory training in the water maze showed positive effects on memory formation in APP/PS1 mice. Interestingly, the cohort that had been previously trained several times was able to use increased hippocampus-dependent strategies, similar to the WT mice. This may suggest that cognitively demanding and physically active tasks can improve cognitive function.

The Immature Morphology of the Megakaryocytes Present in the Bone Marrow of Patients with Myelofibrosis Reflects Changes in the Frequency of Functionally Distinctive Subpopulations

We and others have demonstrated that the immature megakaryocytes (MK) observed in the bone marrow (BM) from patients with myelofibrosis (MF) play a causative role in the establishment of this disease [reviewed in 1]. By leveraging scRNA-seq and other methods, recent studies have identified the existence of at least three megakaryocyte subpopulations, each one exerting different functions [2-4]: the most prevalent is that of platelet producing MK, the second is niche MK (defined here as hematopoietic stem cell (HSC)-supporting for clarity) and the third is classified as immune MK. In addition, the human fetus contains a fourth subpopulation, also defined niche MK, characterized by high expression of extracellular matrix genes, such as COL1A1 and COL3A1, and by a TGF-β signature, which is responsible for shaping the extracellular matrix of the organs during development. Platelet producing MK fall into the high ploidy class, express genes related to thrombopoiesis and are characterized by the CD42b/ARNTL markers. HSC-supporting MKs are mostly >=8N with high expression of IGF1and PF4, which regulate the growth of HSCs, and are characterized by the CD42b/MYLK4 markers. Immune MK are low ploidy with signatures of inflammatory response and myeloid leukocyte activation genes and are characterized as CD41/LSP1 cells. Lastly, niche MK, which are absent in adult BM, are characterized as CD42b/Col I and/or Col III cells. We hypothesize that the immature morphology of the MK from the BM of MF patients flags changes in the relative frequencies of the different MK subpopulations and induction of the formation of niche MK, originally identified in the fetus. To test this hypothesis, we performed extensive confocal microscopy studies with MK-specific markers on the BM from three patients with MF (and three patients with essential thrombocythemia, ET, or with other malignancies but no fibrosis, non-MF, as control) and of the BM from Gata1low mice before (young) and after (old) onset of MF, using age matched wild type (WT) littermates as control (three mice/group). First we confirmed that the BM from MF patients contains greater numbers of MK than that from ET and non-MF patients and that these MF MK have an immature morphology and contain lower levels of GATA1 compared to controls (Fig. 1). We then demonstrated that MF MK are engaged in greater numbers in neutrophils emperipolesis associated with Netosis (Fig. 1), two events predicted to be triggered by the high bioavailability of interleukin-8 in the BM microenvironment of MF patients. Third, we observed that platelet MK (CD42b+ARNTL+) are present in the BM from MF, ET and non-MF patients and from that of WT and Gata1low mice of all ages. By contrast, HSC-supporting MK (CD42b+MYLK4+) are observed in the BM from ET but not in that from MF. They are also observed in the BM from WT mice (both young and old) and from young Gata1low mice, but not in that from old Gata1low mice. Immune MK (CD42b+LSP1+) are instead observed in the BM from ET and non-MF patients but not in MF patients and in the BM from young and old WT mice and in that from young Gata1low mice but not in that from old Gata1low mice. Lastly, great numbers of the CD42b MK in the BM from MF patients, but not in that from ET and non-MF, contain Col I and III (Fig. 1). These cells are also present in the BM from old Gata1low mice but not in their age-matched WT littermates (data not shown) and may represent niche MK the differentiation of which is reactivated by the high TGF-β bioavailability in the BM from MF. In conclusion, these results confirm the hypothesis that changes in frequency of MK subpopulations, rather than in MK maturity state per se, plays a causative role in the development of MF.

Modified Kaixin San improves memory and synaptic damage of mice with Alzheimer's disease by modulating αCaMKⅡ-PSD95 protein binding through inhibition of neuroinflammation:a study of mechanism

To investigated the mechanisms underlying the effects of modified Kaixin San(MKXS) on improving memory and synaptic damage of Alzheimer's disease(AD) mouse model with conditional presenilin 1/2 conditional double knockout(PS cDKO). Specifically, 60 PS cDKO mice(3-3.5 months old) and their age-matched wild-type(WT) littermates were randomized into three groups: WT group(n=20), PS cDKO group(n=20), and PS cDKO+MKXS group(n=20). Mice in WT and PS cDKO groups were fed with standard chow and those in PS cDKO+MKXS group were given chow containing MKXS(at 2.55 g·kg~(-1)) for 60 days. Novel object reco-gnition task was employed to detect the recognition memory of mice, and Western blot to detect the protein levels of synapse-associated proteins in the hippocampus(HPC) of mice, such as NR1, NR2 A, NR2 B, p-αCaMKⅡ, tau, and p-tau. Microglial morphology in the HPC CA1 of mice was observed based on immunohistochemistry. Quantitative real time-PCR(qRT-PCR) was employed to detect the mRNA levels of the pro-inflammatory factors and synapse-associated proteins in the HPC of mice, including COX-2, iNOS, IL-1β, IL-6, TNF-α, PSD95, NR1, NR2 A, NR2 B, and MAP2. The protein levels of IL-1β, TNF-α, and IL-6 were tested by enzyme-linked immunosorbent assay(ELISA). The interaction between PSD95 and αCaMKⅡ and between PSD95 and p-αCaMKⅡ was tested by co-immunoprecipitation(Co-IP). The results showed that PS cDKO+MKXS demonstrated significantly higher preference index and recognition index of the new objects, lower protein level of p-tau(ser 396/404) and mRNA levels of COX-2, iNOS, TNF-α, IL-1β, and IL-6 in HPC, higher protein levels of NR1, NR2 A, NR2 B, and p-αCaMKⅡ and mRNA levels of NR1, NR2 A, NR2 B, PSD95, and MAP2, and stronger interaction of αCaMKⅡ with PSD95 and interaction of p-αCaMKⅡ with PSD95 than the PS cDKO group. Immunohistoche-mical staining showed that MKXS inhibited the activation of microglia. In conclusion, MKXS improves memory and synaptic damage in mice with AD by modulating αCaMKⅡ-PSD95 protein binding through inhibition of neuroinflammation.

Longitudinal characterization of retinal vasculature alterations with optical coherence tomography angiography in a mouse model of tauopathy

Tauopathies are a family of neurodegenerative diseases which predominately afflict the rapidly growing aging population suffering from various brain disorders including Alzheimer's disease, frontotemporal dementia with parkinsonism-17 and Pick disease. As the only visually accessible region of the central nervous system, in recent years, the retina has attracted extensive attention for its potential as a target for visualizing and quantifying emerging biomarkers of neurodegenerative diseases. Our previous study has found that retinal vascular inflammation and leakage occur at the very early stage of tauopathic mouse model. Here, we aimed to non-invasively visualize age-dependent alterations of retinal vasculature assessing the potential for using changes in retinal vasculature as the biomarker for the early diagnosis of tauopathy. Optical coherence tomography angiography (OCTA), a non-invasive depth-resolved high-resolution imaging technique was used to visualize and quantify tauopathy-induced alterations of retinal vasculature in P301S transgenic mice overexpressing the P301S mutant form of human tau and age-matched wild type littermate mice at 3, 6 and 10 months of age. We observed significant alterations of vascular features in the intermediate capillary plexus (ICP) and deep capillary plexus (DCP) but not in the superficial vascular complex (SVC) of P301S mice at early stages of tauopathy. With aging, alterations of vascular features in P301S mice became more prominent in all three vascular plexuses. Staining of retinal vasculature in flatmounts and trypsin digests of P301S mice at 10 months of age revealed decreased vessel density and increased acellular capillary formation, indicating that vascular degeneration also occurs during tauopathy. Overall, our results demonstrate that the changes in retinal vascular features accelerate during the progression of tauopathy. Vessels in the ICP and DCP may be more susceptible to tauopathy than vessels in the SVC. Since changes in retinal vasculature often precede tau pathology in the brain, non-invasive identification of retinal vascular alterations with OCTA may be a useful biomarker for the early diagnosis of tauopathy and monitoring its progression.

The Zinc-sensing Receptor (GPR39) Modulates Declarative Memory and Age-related Hippocampal Gene Expression in Male Mice

As a neuromodulator, zinc regulates synaptic plasticity, learning and memory. Synaptic zinc is also a crucial factor in the development of toxic forms of amyloid beta protein and, subsequently, of Alzheimer’s dementia (AD). Therefore, efforts to pinpoint mechanisms underlying zinc-dependent cognitive functions might aid AD research, by providing potential novel targets for drugs. One of the most understudied proteins in this regard is a zinc-sensing metabotropic receptor: GPR39. In this study we investigated the impact of GPR39 knock-out (KO) on age-related memory decline in mice of both sexes, by comparing them to age-matched wild-type (WT) littermates. We also tested the effects of a GPR39 agonist (TC-G 1008) on declarative memory of old animals, and its disruption in adult mice. We observed episodic-like memory (ELM) and spatial memory (SM) deficits in male GPR39 KO mice, as well as intact procedural memory in GPR39 KO mice regardless of age and sex. ELM was also absent in old WT male mice, and all female mice regardless of their genotype. Acute application of TC-G 1008 (10 mg/kg) reversed a deficit in two of three ELM components in old WT male mice, and had no promnesic effect on consolidation interference of ELM in adult WT mice. We discuss the possible neurobiological mechanisms and the translational value of these results for potential add-on pharmacotherapy of AD aimed at the zinc-sensing receptor.

Polg mtDNA mutator mice reveal limited involvement of vertebral bone loss in premature aging-related thoracolumbar hyperkyphosis

BackgroundAge-related hyperkyphosis is multifactorial and involves alterations of vertebral bone, intervertebral discs (IVD) and paraspinal muscles. The relative contribution of these tissues remains unclear. Here, we compared differences in vertebral bone microarchitecture and IVD thickness between prematurely aging mice with spinal hyperkyphosis and wild type littermates. MethodsThoracolumbar vertebral columns were dissected from homozygous PolgD257A and age-matched wild type littermates. Micro-computed tomography was performed to quantify cortical and trabecular bone parameters at anterior and posterior portions of T8-L4 vertebrae. In addition, vertebral shape, transaxial facet joint orientation and IVD thickness were quantified. Differences in anterior/posterior ratios between genotypes were compared by Student's t-test and association between vertebral bone and IVD parameters was investigated using Pearson correlation analysis. ResultsHyperkyphotic homozygous mice displayed generalized osteopenia that was more pronounced at the posterior compared with anterior portion of thoracolumbar vertebrae. An increase in the anterior/posterior ratio of trabecular bone parameters was revealed at the thoracolumbar junction (T13-L1). PolgD257A displayed diffuse loss of cortical bone thickness, yet anterior/posterior ratios were unchanged. Despite generalized and regional bone loss, vertebral shape was unaffected. PolGD257A mice showed a 10–20 % reduction of IVD thickness at both thoracic and lumbar levels, with only minimal histopathological changes. IVD thickness was negatively correlated with anterior/posterior ratios of trabecular bone parameters, as well as with more coronally oriented facet joints, but negatively correlated with the anterior/posterior ratio of cortical bone thickness. ConclusionsAging-induced regional changes of vertebral trabecular and cortical bone did not lead to altered vertebral shape in PolgD257A mice but may indirectly cause hyperkyphosis through reduction of IVD thickness. These findings suggest a limited role for aging-induced bone loss in spinal hyperkyphosis and warrants further research on the involvement of paraspinal muscle degeneration.

Poster 247: Muscle ERRγ Overexpression Mitigates the Muscle Atrophy after ACL injury

Poster 247: Muscle ERRγ Overexpression Mitigates the Muscle Atrophy after ACL injury

Baz1b Dosage Influences Cardiovascular Function, Predisposing to Dilated Cardiomyopathy.

BAZ1B is one of several genes deleted in Williams-Beuren Syndrome (WBS), a complex, multisystem genetic condition that occurs in ~1 in 8000 live births. Also known as Williams Syndrome Transcription Factor (WSTF), BAZ1B is thought to be essential for neural crest migration. To evaluate the impact of Baz1b loss of function, we evaluated the "knockout first" allele of Baz1btm2a(KOMP)Wtsi . Quantitative PCR revealed markedly reduced, but not absent, expression of Baz1b, suggesting that Baz1btm2a(KOMP)Wtsi mutants are knockdowns rather than knockouts. Homozygous Baz1btm2a(KOMP)Wtsi mutant mice die just hours after birth, and both homozygous mutants and heterozygotes are smaller than age-matched wildtype littermates. Survival analyses conducted on 388 Baz1btm2a(KOMP)Wtsi mice revealed that heterozygotes and homozygous mutants are approximately three and sixteen times more likely to die than wildtype mice, respectively [hazard ratio for death in Baz1b+/- : 3.04 (95% CI, 1.83-5.06), p<0.0001; hazard ratio for death in Baz1b-/- : 15.83 (95% CI, 8.54-29.37); p<0.0001]. Furthermore, a linear mixed effects model for the weights of wildtype and heterozygous mice over a 29-day period showed a significant difference in size based on genotype (mean: WT 7.97 g, Baz1b+/- 6.56 g, p<0.0001). Because neural crest lineages contribute to cardiac development, structure, and function, we hypothesized that early sudden death and failure to thrive in mutant mice may be at least partially attributable to cardiac abnormalities. To evaluate any morphologic and functional abnormalities, we performed microCT and echocardiography. MicroCT analysis of the hearts from P0 pups did not reveal congenital heart disease typical of neural crest defects (e.g. tetralogy of Fallot, truncus arteriosus, double outlet right ventricle, or interrupted aortic arch). Echocardiograms, performed at 1-month to align with the growth analysis timeline, revealed mildly decreased ejection fraction (EF, median: WT 64%, Baz1b+/- 56%, p<0.01) and fractional shortening (FS, median: WT 34%, Baz1b+/- 29%, p<0.01), increased left ventricular internal dimension at diastole (LViDd) normalized to animal size (median: WT 0.22 mm/g, Baz1b+/- 0.27 mm/g, p<0.05), and unchanged left ventricular posterior wall dimension at diastole (LVPWd) normalized to body size (median: WT 0.041 mm/g, Baz1b+/- 0.048 mm/g, p=0.19) in Baz1b+/- when compared to wildtype. However, Baz1b+/- LVPWd is significantly smaller than WT when body size is not considered (median: WT 0.63 mm, Baz1b+/- 0.62 mm, p<0.01), suggesting a relationship between cardiac function and mutant animal growth (all tests for genotype in n=14 WT and n=14 Baz1b+/- by Mann-Whitney U Test). Taken together, our data suggest that Baz1b+/- mice exhibit a dilated cardiomyopathy and that dosage for this gene may contribute to early death, decreased somatic growth, and cardiac abnormalities in Baz1b mutant mice. Additional analyses in older mice and with mutants generated using the conditional Baz1btm2a(KOMP)Wtsi allele will allow us to better explore the mechanisms of both the growth failure and cardiomyopathy phenotypes in this model.

Impaired Experience-Dependent Refinement of Place Cells in a Rat Model of Alzheimer's Disease.

Hippocampal place cells play an integral role in generating spatial maps. Impaired spatial memory is a characteristic pathology of Alzheimer's disease (AD), yet it remains unclear how AD influences the properties of hippocampal place cells. To record electrophysiological activity in hippocampal CA1 neurons in freely-moving 18-month-old male TgF344-AD and age-matched wild-type (WT) littermates to examine place cell properties. We implanted 32-channel electrode arrays into the CA1 subfield of 18-month-old male WT and TgF344-AD (n = 6/group) rats. Ten days after implantation, single unit activity in an open field arena was recorded across days. The spatial information content, in-field firing rate, and stability of each place cell was compared across groups. Pathology was assessed by immunohistochemical staining, and a deep neural network approach was used to count cell profiles. Aged TgF344-AD rats exhibited hippocampal amyloid-β deposition, and a significant increase in Iba1 immunoreactivity and microglia cell counts. Place cells from WT and TgF344-AD rat showed equivalent spatial information, in-field firing rates, and place field stability when initially exposed to the arena. However, by day 3, the place cells in aged WT rats showed characteristic spatial tuning as evidenced by higher spatial information content, stability, and in-field firing rates, an effect not seen in TgF344-AD rats. These findings support the notion that altered electrophysiological properties of place cells may contribute to the learning and memory deficits observed in AD.