Estrogen restores cognition and cholinergic phenotype in an animal model of Down syndrome

Estrogen maintains normal function of basal forebrain (BF) cholinergic neurons and estrogen replacement therapy (ERT) has therefore been proposed as a therapy for Alzheimer's disease (AD). We provide evidence to support this hypothesis in an animal model of Down syndrome (DS), a chromosome 16 segmental trisomy (Ts65Dn) mouse. These mice develop cholinergic degeneration similar to young adults with DS and AD patients. ERT has not been tested in women with DS, even though they are more likely than normosomic women to develop early menopause and AD. Female Ts65Dn and normosomic mice (11-15 months) received a subcutaneous estrogen pellet or a sham operation. After 60 days, estrogen treatment improved learning of a T-maze task and normalized behavior in the Ts65Dn mice in reversal learning of the task, a measure of cognitive flexibility. Stereological evaluation of choline acetyltransferase (ChAT) immunopositive BF neurons showed that estrogen increased cell size and total number of cholinergic neurons in the medial septum of Ts65Dn mice. In addition, estrogen increased NGF protein levels in the BF of trisomic mice. These findings support the emerging hypothesis that estrogen may play a protective role during neurodegeneration and cognitive decline, particularly in cholinergic BF neuronal systems underlying cognition. The findings also indicate that estrogen may act, at least partially, via endogenous growth factors. Collectively, the data suggest that ERT may be a viable therapeutic approach for women with DS coupled with dementia.     

Age-related deficits in context discrimination learning in Ts65Dn mice that model Down syndrome and Alzheimer's disease

All individuals with Down syndrome (DS) eventually develop the neuropathology of Alzheimer's disease (AD), which is characterized by a premature loss of basal forebrain cholinergic neurons. Similarly, between 4 and 6 months of age, Ts65Dn mice, which model DS, lose cholinergic markers in their medial septal neurons. It is not known whether Ts65Dn mice have age-related learning deficits as well. Control and Ts65Dn mice were tested at several ages in context discrimination. Controls at all ages showed no deficits in learning this task. Ts65Dn mice younger than 3 months demonstrated impaired learning, suggesting a possible developmental delay in Ts65Dn mice. Four-month-old Ts65Dn mice showed no deficits, whereas Ts65Dn mice older than 5 months were impaired in learning the task. Therefore, Ts65Dn mice have an age-related learning impairment that coincides with their age-related neuroanatomical abnormalities and, consequently, may be a useful model of AD.     

Behavioral and neurobiological markers of Alzheimer's disease in Ts65Dn mice: effects of estrogen

Individuals with Down's syndrome (DS) develop neuropathological features similar to Alzheimer's disease (AD) early in life, including dementia, accumulation of beta-amyloid, and irregular phosphorylation of tau proteins. Ts65Dn mice, an animal model of DS, provide a unique method to investigate the mechanisms related to AD-like symptoms in DS and possible therapeutic interventions. Ts65Dn mice undergo a decline in cholinergic phenotype and cognitive deterioration beginning at 6-8 months of age. In middle-aged female Ts65Dn mice, estrogen supplementation alleviated these cholinergic and cognitive impairments. The current study investigated AD-like markers and the effects of estrogen in male Ts65Dn mice. Estrogen treatment prior to behavioral testing did not improve cognitive deficits in 6-month-old male Ts65Dn mice, but decreased total and phosphorylated (pS199) tau in the entorhinal cortex compared to normosomic animals. Hippocampal beta-amyloid(1-42) levels were increased in Ts65Dn animals, regardless of estrogen treatment. These findings further support Ts65Dn mice as a model for specific AD-like symptoms, and demonstrate that estrogen treatment of this type does not improve the cognitive ability of male Ts65Dn mice.     

Sex Differences in the Cholinergic Basal Forebrain in the Ts65Dn Mouse Model of Down Syndrome and Alzheimer's Disease

In the Down syndrome (DS) population, there is an early incidence of dementia and neuropathology similar to that seen in sporadic Alzheimer's disease (AD), including dysfunction of the basal forebrain cholinergic neuron (BFCN) system. Using Ts65Dn mice, a model of DS and AD, we examined differences in the BFCN system between male and female segmentally trisomic (Ts65Dn) and disomic (2N) mice at ages 5–8 months. Quantitative stereology was applied to BFCN subfields immunolabeled for choline acetyltransferase (ChAT) within the medial septum/vertical limb of the diagonal band (MS/VDB), horizontal limb of the diagonal band (HDB) and nucleus basalis of Meynert/substantia innominata (NBM/SI). We found no sex differences in neuron number or subregion area measurement in the MS/VDB or HDB. However, 2N and Ts65Dn females showed an average 34% decrease in BFCN number and an average 20% smaller NBM/SI region area compared with genotype‐matched males. Further, relative to genotype‐matched males, female mice had smaller BFCNs in all subregions. These findings demonstrate that differences between the sexes in BFCNs of young adult Ts65Dn and 2N mice are region and genotype specific. In addition, changes in post‐processing tissue thickness suggest altered parenchymal characteristics between male and female Ts65Dn mice.     

Whether Alzheimer’s diseases related genes also differently express in the hippocampus of Ts65Dn mice?

Background: Down syndrome is a condition which extra genetic material causes delays in child development, both mentally and physically. Strengthening the study of the neural defects of DS is of great significance. Methods: Ts65Dn mice were used in this study. We removed the brain and isolated their hippocampus. We customized 54 genes in one PCR arrays, included some important genes related to Alzheimer’s disease. The expression of genes were detected by RT-PCR. Results: PCR arrays contained 54 genes related to Alzheimer’s disease. After real-time PCR, three genes (Nae1, APP and Mapt) expressed differently in the hippocampus of Ts65Dn, compared with the normal mice. Nae1 was decreased significantly, while APP and Mapt were increased obviously. The levels of fold-changes of Nae1, APP and Mapt were 86.19, 4.49 and 2.89 respectively. Significantly different levels of expression were found in the Ts65Dn mice compared with the normal control group (P=0.00 for Nae1, P=0.02 for APP, P=0.01 for Mapt respectively). Conclusions: There are differential expressed genes in the hippocampus of Ts65Dn mice that may be closely related to Alzheimer’s disease. PCR array technology was used in the screening and identification of these genes.     

In vivo MRI identifies cholinergic circuitry deficits in a Down syndrome model

In vivo quantitative magnetic resonance imaging (MRI) was employed to detect brain pathology and map its distribution within control, disomic mice (2N) and in Ts65Dn and Ts1Cje trisomy mice with features of human Down syndrome (DS). In Ts65Dn, but not Ts1Cje mice, transverse proton spin–spin (T₂) relaxation time was selectively reduced in the medial septal nucleus (MSN) and in brain regions that receive cholinergic innervation from the MSN, including the hippocampus, cingulate cortex, and retrosplenial cortex. Basal forebrain cholinergic neurons (BFCNs) in the MSN, identified by choline acetyltransferase (ChAT) and nerve growth factor receptors p75^NTR and TrkA immunolabeling were reduced in Ts65Dn brains and in situ acetylcholinesterase (AChE) activity was depleted distally along projecting cholinergic fibers, and selectively on pre- and postsynaptic profiles in these target areas. T₂ effects were negligible in Ts1Cje mice that are diploid for App and lack BFCN neuropathology, consistent with the suspected relationship of this pathology to increased App dosage. These results establish the utility of quantitative MRI in vivo for identifying Alzheimer's disease-relevant cholinergic changes in animal models of DS and characterizing the selective vulnerability of cholinergic neuron subpopulations.     

The functional nature of synaptic circuitry is altered in area CA3 of the hippocampus in a mouse model of Down's syndrome

Down's syndrome (DS) is the most common cause of mental retardation, and memory impairments are more severe in DS than in most if not all other causes of mental retardation. The Ts65Dn mouse, a genetic model of DS, exhibits phenotypes of DS, including memory impairments indicative of hippocampal dysfunction. We examined functional synaptic connectivity in area CA3 of the hippocampus of Ts65Dn mice using organotypic slice cultures as a model. We found reductions in multiple measures of synaptic function in both excitatory and inhibitory inputs to pyramidal neurons in CA3 of the Ts65Dn hippocampus. However, associational synaptic connections between pyramidal neurons were more abundant and more likely to be active rather than silent in the Ts65Dn hippocampus. Synaptic potentiation was normal in these associational connections. Decreased overall functional synaptic input onto pyramidal neurons expressed along with the specific hyperconnectivity of associational connections between pyramidal neurons will result in predictable alterations of CA3 network function, which may contribute to the memory impairments seen in DS.     

Object recognition memory is conserved in Ts1Cje,a mouse model of Down syndrome

Ts1Cje and Ts65Dn are genetic mouse models of Down syndrome (DS). Like individuals with DS, these mice exhibit various hallmarks of hippocampal pathology, and deficits in hippocampal-based, declarative learning and memory tasks. Both spatial navigation and novel object recognition, two prototypical domains of declarative memory function, have been strongly characterized in the Ts65Dn DS model. Indeed, Ts65Dn mice show navigation problems in the Morris water maze, impaired alternation in a T-maze, and deficient working and reference memory in the radial arm maze task. They, likewise, show an inability to detect object novelty over time. In contrast to the Ts65Dn model, hippocampal-dependent cognition has been less well characterized in Ts1Cje. Although Ts1Cje mice have been found to exhibit spatial difficulties in the Morris water maze and reduced spontaneous alternation, their ability to process object-based information has never been examined. Here, we report that Ts1Cje mice perform normally in short-term and long-term novel object recognition tasks. The ability of Ts1Cje mice to detect object novelty, unlike Ts65Dn, may point to differences in the extent of hippocampal pathology in the two DS mouse models.     

Abnormal expression of synaptic proteins and neurotrophin-3 in the Down syndrome mouse model Ts65Dn

Down syndrome (DS) results from triplication of the whole or distal part of human chromosome 21. Persons with DS suffer from deficits in learning and memory and cognitive functions in general, and, starting from early development, their brains show dendritic and spine structural alterations and cell loss. These defects concern many cortical brain regions as well as the hippocampus, which is known to play a critical role in memory and cognition. Most of these abnormalities are reproduced in the mouse model Ts65Dn, which is partially trisomic for the mouse chromosome 16 that is homologous to a portion of human chromosome 21. Thus, Ts65Dn is widely utilized as an animal model of DS. To better understand the molecular defects underlying the cognitive and particularly the memory impairments of DS, we investigated whether the expression of several molecules known to play critical roles in long-term synaptic plasticity and long-term memory in a variety of species is dysregulated in either the neonatal brain or adult hippocampus of Ts65Dn mice. We found abnormal expression of the synaptic proteins synaptophysin, microtubule-associated protein 2 (MAP2) and cyclin-dependent kinase 5 (CDK5) and of the neurotrophin-3 (NT-3). Both the neonatal brain and adult hippocampus revealed significant abnormalities. These results suggest that a dysregulation in the expression of neurotrophins as well as proteins involved in synaptic development and plasticity may play a potential role in the neural pathology of DS in humans.     

Gait dynamics in trisomic mice: quantitative neurological traits of Down syndrome

The segmentally trisomic mouse Ts65Dn is a model of Down syndrome (DS). Gait abnormalities are almost universal in persons with DS. We applied a noninvasive imaging method to quantitatively compare the gait dynamics of Ts65Dn mice (n=10) to their euploid littermates (controls) (n=10). The braking duration of the hind limbs in Ts65Dn mice was prolonged compared to that in control mice (60+/-3 ms vs. 49+/-2 ms, P<.05) at a slow walking speed (18 cm/s). Stride length and stride frequency of forelimbs and hind limbs were comparable between Ts65Dn mice and control mice. Stride dynamics were significantly different in Ts65Dn mice at a faster walking speed (36 cm/s). Stride length was shorter in Ts65Dn mice (5.9+/-0.1 vs. 6.3+/-0.3 cm, P<.05), and stride frequency was higher in Ts65Dn compared to control mice (5.9+/-0.1 vs. 5.3+/-0.1 strides/s, P<.05). Hind limb swing duration was prolonged in Ts65Dn mice compared to control mice (93+/-3 vs. 76+/-3 ms, P<.05). Propulsion of the forelimbs contributed to a significantly larger percentage of stride duration in Ts65Dn mice than in control mice at the faster walking speed. Indices of gait dynamics in Ts65Dn mice correspond to previously reported findings in children with DS. The methods used in the present study provide quantitative markers for genotype and phenotype relationship studies in DS. This technique may provide opportunities for testing the efficacy of therapies for motor dysfunction in persons with DS.     

Alterations of brain circuits in Down syndrome murine models

Trisomy 21, also referred to Down syndrome (DS), is the most common genetic cause of mental retardation, affecting 1 each 800-1000 newborn children all over the world. DS is a complex disease, determined by an extra copy of human chromosome 21 that causes an imbalanced gene dose effect. The syntenies that exist between mouse chromosomes 10, 16, and 17 and human chromosome 21 offer the opportunity for a genotype-phenotype correlation and several mouse models of DS have been developed to improve our knowledge about cognitive disabilities and brain alterations. We present here the different murine models available up to now and we discuss the neural alterations that have been described in these strains. The largest amount of studies involved the so called Ts65Dn mouse showing early alterations of nitrergic, noradrenergic and cholinergic systems at the level of the basal forebrain. Neurogenesis and spine formations are decreased in the hippocampus, as well as the whole size of the cerebellum and the number of granule cells.     

Trisomy for the Down syndrome 'critical region' is necessary but not sufficient for brain phenotypes of trisomic mice

Trisomic Ts65Dn mice show direct parallels with many phenotypes of Down syndrome (DS), including effects on the structure of cerebellum and hippocampus. A small segment of Hsa21 known as the 'DS critical region' (DSCR) has been held to contain a gene or genes sufficient to cause impairment in learning and memory tasks involving the hippocampus. To test this hypothesis, we developed Ts1Rhr and Ms1Rhr mouse models that are, respectively, trisomic and monosomic for this region. Here, we show that trisomy for the DSCR alone is not sufficient to produce the structural and functional features of hippocampal impairment that are seen in the Ts65Dn mouse and DS. However, when the critical region is returned to normal dosage in trisomic Ms1Rhr/Ts65Dn mice, performance in the Morris water maze is identical to euploid, demonstrating that this region is necessary for the phenotype. Thus, although the prediction of the critical region hypothesis was disproved, novel gene dosage effects were identified, which help to define how trisomy for this segment of the chromosome contributes to phenotypes of DS.     

Subicular hypotrophy in fetuses with Down syndrome and in the Ts65Dn model of Down syndrome

Intellectual disability in Down syndrome (DS) has been attributed to neurogenesis impairment during fetal brain development. Consistently with explicit memory alterations observed in children with DS, fetuses with DS exhibit neurogenesis impairment in the hippocampus, a key region involved in memory formation and consolidation. Recent evidence suggests that the subiculum plays a unique role in memory retrieval, a process that is also altered in DS. While much attention has been devoted to the hippocampus, there is a striking lack of information regarding the subiculum of individuals with DS and DS models. In order to fill this gap, in the current study, we examined the subiculum of fetuses with DS and of the Ts65Dn mouse model of DS. We found that in fetuses with DS (gestational week: 17–21), the subiculum had a reduced thickness, a reduced cell density, a reduced density of progenitor cells in the ventricular zone, a reduced percentage of neurons, and an increased percentage of astrocytes and of cells immunopositive for calretinin—a protein expressed by inhibitory interneurons. Similarly to fetuses with DS, the subiculum of neonate Ts65Dn mice was reduced in size, had a reduced number of neurons and a reduced number of proliferating cells. Results suggest that the developmental defects in the subiculum of fetuses with DS may underlie impairment in recall memory and possibly other functions played by the subiculum. The finding that the subiculum of the Ts65Dn mouse exhibits neuroanatomical defects resembling those seen in fetuses with DS further validates the use of this model for preclinical studies.     

Deficits in hippocampal CA1 LTP induced by TBS but not HFS in the Ts65Dn mouse: a model of Down syndrome

Down syndrome (DS) is the most common genetically defined cause of intellectual disabilities. Both hippocampal function and volume seem to be disproportionally reduced in individuals with DS and in at least one aneuploid murine model of DS, the Ts65Dn mouse. Two previous studies by one research group have reported deficits in long-term potentiation (LTP) induced by in vitro high-frequency stimulation (HFS) of hippocampal CA1 synapses of adult Ts65Dn mice. Here, we report on the results of our own investigation on LTP in Ts65Dn mice. This study was designed to confirm the previous findings and possibly shed some light onto potential mechanisms underlying the reported deficit in this important form of long-term synaptic plasticity in a mouse model of DS. LTP was induced in area CA1 with either theta burst stimulation (TBS) or HFS. Contrary to the previous reports, our results showed no significant difference in HFS-induced LTP between Ts65Dn and euploid littermate mice. We have found, however, a significant reduction of the amount of TBS-induced LTP in Ts65Dn mice compared to euploid controls. Because this specific LTP deficit can be rescued by bath application of picrotoxin (10 microM), we hypothesize that an increase in GABA(A)-mediated inhibition or in plasticity of the inhibitory circuitry in Ts65Dn mice may underlie the observed deficits. However, future experiments to examine the state of hippocampus CA1 GABAergic inhibition in Ts65Dn mice will be necessary to further explore these hypotheses.     

Systemic pathology in aged mouse models of Down's syndrome and Alzheimer's disease

Down's syndrome (DS) in humans is caused by trisomy of chromosome 21 (HSA 21). DS patients have a variety of pathologies, including mental retardation and an unusually high incidence of leukemia or lymphoma such as megakaryocytic leukemia. Individuals with DS develop the characteristic neuropathological hallmarks of Alzheimer's disease (AD) in early adulthood, generally by the fourth decade of life. There are several mouse models of DS that have a segmental trisomy of mouse chromosome 16 (MMU 16) with triplicated genes orthologous to HSA 21. These mice display neurodegeneration similar to DS. Although brain pathology in DS models is known, little information is available about other organs. We studied the extraneural pathology in aged DS mice (Ts65Dn, Ts2 and Ts1Cje aged 8 to 24 months) as well as other mouse models of neurodegeneration, including presenilin (PS), amyloid-β precursor protein (APP), and tau (hTau and JNPL) transgenic mice. An increased incidence of peripheral amyloidosis, positive for amyloid A (AA) but not amyloid-β peptide (Aβ), was found in APP over-expressing and tauopathic mice as compared to non-transgenic (ntg) littermates or to DS mouse models. A higher incidence of lymphoma was found in the DS models, including Ts1Cje that is trisomic for a small segment of MMU 16 not including the App gene, but not in the APP over-expressing mice, suggesting that high APP expression is not the cause of lymphoma in DS. The occurrence of lymphomas in mouse DS models is of interest in relation to the increased incidence of malignant conditions in human DS.     

In vivo 1H MRS study in microlitre voxels in the hippocampus of a mouse model of Down syndrome at 11.7 T

In this article, we report in vivo ¹H MRS performed in 1.8‐μL voxels in a mouse model of Down syndrome (DS). To characterise the excitation–inhibition imbalance observed in DS, metabolite concentrations in the hippocampi of adult Ts65Dn mice, which recapitulate features of DS, were compared with those of their euploid littermates at a voxel 42‐fold smaller than in a previously published study. Quantification of the metabolites was performed using a linear combination model. We detected 16 metabolites in the right and left hippocampi. Principal component analysis revealed that the absolute concentrations of the 16 detected metabolites could differentiate between Ts65Dn and euploid hippocampi. Although measurements in the left and right hippocampi were highly correlated, the concentration of individual metabolites was sometimes significantly different in the left and right structures. Thus, bilateral values from Ts65Dn and euploid mice were further compared with Hotelling's test. The level of glutamine was found to be significantly lower, whereas myo‐inositol was significantly higher, in the hippocampi of Ts65Dn relative to euploid mice. However, γ‐aminobutyric acid (GABA) and glutamate levels remained similar between the groups. Thus, the excitation–inhibition imbalance described in DS does not appear to be related to a radical change in the levels of either GABA or glutamate in the hippocampus. In conclusion, microliter MRS appears to be a valuable tool to detect changes associated with DS, which may be useful in investigating whether differences can be rescued after pharmacological treatments or supplementation with glutamine. Copyright © 2014 John Wiley & Sons, Ltd.     

Motor dysfunction in a mouse model for Down syndrome

Motor deficits are among the most frequently occurring features of Down syndrome (DS). Individuals with DS exhibit disturbances in the dynamics of movement production and postural control that are thought to have a significant impact in delaying their acquisition of motor skills. The origin of these deficits has been hypothesized to be cerebellar. The Ts65Dn mouse is the most robust and genetically sound animal model for DS currently available. Ts65Dn mice show many DS-like features, including significant learning deficits in different behavioral tasks and neurodegeneration of cholinergic neurons. In the present study, we investigate the motor function of these animals. We have analyzed hind paw print patterns during walking, running speeds, rotarod performance, grip force production, swim paths, and swimming speeds. Our results indicate that Ts65Dn mice present mild to severe dysfunction according to all of the above assessments. The most evident impairments presented by these mice were related to equilibrium and motor coordination, which agrees with reported clinical observations made on individuals with DS. Because none of these findings were readily apparent by simple inspection of these animals, these findings reiterate the need for a careful evaluation of any mutant mouse strain for which there is reason to suspect motor deficits. The identification of motor dysfunction in Ts65Dn mice may have important consequences for the interpretation of some previous assessments of learning and memory of these animals that assumed intact motor function, and further strengthens the use of this aneuploid mouse strain as a model for DS.     

Speeding of miniature excitatory post-synaptic currents in Ts65Dn cultured hippocampal neurons

Down syndrome (DS) is the leading non-heritable cause of mental retardation and is due to the effects of an extra chromosome 21. Mouse models of DS have been developed which parallel many of the cognitive and behavioral deficits of DS individuals. Of these, Ts65Dn mice show abnormal hippocampal properties including learning and memory deficits, altered synaptic plasticity and irregular dendritic spines. We assessed synaptic function of cultured postnatal Ts65Dn hippocampal neurons through examination of spontaneous miniature excitatory post-synaptic currents (mEPSCs) and compared them to those from diploid neurons. Averaged amplitudes and frequency of mEPSC events were similar to diploid suggesting presynaptic function is not overtly disrupted in Ts65Dn hippocampal neurons. However, both averaged decay and rise times (10-90% of peak) were significantly faster (approximately 20% for both rise and decay) in Ts65Dn neurons compared to diploid. The distribution of both decay and rise times, indicates global scaling of all percentile groups and is independent of amplitude suggesting normal electrotonic filtering in spite of abnormal expression of GIRK2 channel in Ts65Dn mouse. Western blot analysis suggests overexpression of GluR4 subunit of AMPA receptors which may contribute to faster mEPSC in Ts65Dn neurons. Intrinsic synaptic properties influenced by genetics or epigenetics factors in Ts65Dn postnatal cultured neurons are therefore disrupted and may contribute to the cognitive deficits associated with DS.     

Discovery and genetic localization of Down syndrome cerebellar phenotypes using the Ts65Dn mouse

Down syndrome (DS) is the most common genetic cause of mental retardation and affects many aspects of brain development. DS individuals exhibit an overall reduction in brain size with a disproportionately greater reduction in cerebellar volume. The Ts65Dn mouse is segmentally trisomic for the distal 12-15 Mb of mouse chromosome 16, a region that shows perfect conserved linkage with human chromosome 21, and therefore provides a genetic model for DS. In this study, high resolution magnetic resonance imaging and histological analysis demonstrate precise neuro- anatomical parallels between the DS and the Ts65Dn cerebellum. Cerebellar volume is significantly reduced in Ts65Dn mice due to reduction of both the internal granule layer and the molecular layer of the cerebellum. Granule cell number is further reduced by a decrease in cell density in the internal granule layer. Despite these changes in Ts65Dn cerebellar structure, motor deficits have not been detected in several tests. Reduction in granule cell density in Ts65Dn mice correctly predicts an analogous pathology in humans; a significant reduction in granule cell density in the DS cerebellum is reported here for the first time. The candidate region of genes on chromosome 21 affecting cerebellar development in DS is therefore delimited to the subset of genes whose orthologs are at dosage imbalance in Ts65Dn mice, providing the first localization of genes affecting a neuroanatomical phenotype in DS. The application of this model for analysis of developmental perturbations is extended by the accurate prediction of DS cerebellar phenotypes.     

Chronobiometry of Behavioral Activity in the Ts65Dn Model of Down Syndrome

Disruption of the sleep-wake cycle has been reported among individuals with Down syndrome (DS). Here we studied behavioral rhythms in adult male and female Ts65Dn mice, a model of DS. The overall behavioral activity of Ts65Dn and diploid (2N) littermates as defined by total movements (TM), movement time (MT), ambulatory movement time (AMT), time spent in center of arena (CT), jumps (JFP), rotational behavior (TURNS), and wheel-running activity (WRA) was recorded under a 12 h:12 h light–dark photocycle. During the light phase, Ts65Dn mice exhibited higher TM, MT, CT, JFP, and WRA compared to 2N littermates. During the dark phase, Ts65Dn and 2N mice differed only in CT and WRA, with the Ts65Dn group engaging in higher levels of both. There were no gender differences for any of the behavioral variables studied. Non-linear least-squares (Cosinor) analysis of the distribution of total behavioral activity (TM) indicated that Ts65Dn mice exhibited a slightly higher mean oscillation (i.e., mesor), but significantly lower amplitude in comparison to 2N mice, suggesting that levels of TM were elevated in trisomic mice but were relatively constant throughout the photocycle. The peak of the Ts65Dn TM rhythm was significantly phase-advanced, occurring approximately 4 h earlier than 2N mice. Overall, Ts65Dn mice were hyperactive and differed significantly in daily patterns of specific behaviors from those of 2N littermates. To control for the potential confound of retinal degeneration in Ts65Dn and 2N mice, we compared and found no difference between the TM rhythm parameters of 2N and non-retinally degenerate C57/129Sv mice, suggesting that abnormal behavioral rhythmicity in Ts65Dn mice may not due to the absence of rod and cone photoreceptors. These results serve as a starting point for further investigations into the physiological basis of sleep–wake disturbances in DS patients. Edited by Pierre Roubertoux