Carmela Baamonde

A behavioral assessment of Ts65Dn mice : a putative Down syndrome model

Mice which are trisomic for only the human chromosome (Chr) 21-homologous segment of mouse Chr 16 (segmental trisomy), including a portion of the Down syndrome region of human Chr 21, have recently been developed. Since these segmentally trisomic mice, designated Ts(17(16))65Dn, survive to adulthood, they may represent a mouse model for the study of Down syndrome. A partial characterization of their behavioral phenotype was undertaken by evaluating the sensorimotor reflexes, exploration, locomotor activity, emotionality and spatial learning in 16 male Ts65Dn mice (TS) and 16 control (CO) littermates. No sensorimotor deficits appeared in TS compared to CO mice. By contrast, head-dipping behaviour in the hold board was increased in TS mice with respect to the CO group, showing a higher repetition rate of previously explored holes. Crossings in the open field and total arm entries in the plus maze were higher in TS than in the CO group during the dark phase of the light-dark (LD) cycle under red light, but not during the light phase of the LD cycle under white light. Entries into the open arms of the plus maze were increased overall in TS mice when compared to CO mice, but no differences were found in time spent in the open arms. TS mice showed impaired place learning in the Morris water maze, whereas they were able to reach the same performance as CO animals in cued learning. Thus, absence of sensorimotor deficits, increased exploration, hyperactivity under certain experimental conditions and a moderate impairment of spatial learning were the principal characteristics observed in TS mice compared to their CO littermates.

Impaired short- and long-term memory in Ts65Dn mice, a model for Down syndrome

Ts65Dn (TS), control littermates (CO) and Swiss (SW) male mice were tested in the elevated plus-maze and in the Morris water maze (MWM) for memory evaluation. In the plus-maze, each mouse was placed at the end of an open arm and initial freezing and the time to enter into an enclosed arm (transfer latency) were measured. SW mice decreased both measures over repeated trials, whereas no decrease of freezing was observed in CO mice, thus suggesting increased emotionality in this group. Compared to CO mice, TS mice showed less initial freezing, shorter transfer latencies, and spent less time in enclosed arms, suggesting a reduced ability to habituate or to inhibit behaviour. Animals were also submitted to a learning-set paradigm consisting of reaching a new platform position each day in the MWM. Two training phases (separated by a resting period of 6 weeks), each including eight acquisition and four cued sessions, were performed (each session consisting of four pairs of trials). CO and SW mice already reached an asymptotic performance by the second day of the first phase whereas TS mice did not achieve that level until the second training phase. The progression over trials indicated that CO and SW animals learned the new platform position between trials 1 and 2 of each session, whereas TS animals failed to do it and had more difficulties to find the platform when it was placed in the centre of the pool as compared to the other positions (SW, NE, E). The results suggest that TS mice show working memory impairments in addition to long-term memory deficits, although extensive training appeared to facilitate TS mice to achieve a level of performance similar to their control littermates. This represents another aspect of the cognitive deficits shown by TS mice: a mouse model of the human Down syndrome.

Alterations of central noradrenergic transmission in Ts65Dn mouse, a model for Down syndrome

Mice with segmental trisomy 16 (Ts65Dn) which have triplication of a region of mouse chromosome 16 homologous to the Down syndrome critical region in human chromosome 21, are used as a model for Down syndrome. Functioning of the central beta-noradrenergic transmission was studied in Ts65Dn mice. Binding analysis in cerebral cortex revealed no change in the number of beta-adrenoceptors and a slight reduction of affinity. The beta-adrenoceptor transduction was assessed by analyzing cAMP formation in the cerebral cortex, hippocampus and cerebellar cortex under basal conditions and after stimulation with isoprenaline and forskolin. Basal production of cAMP was significantly reduced in hippocampus and cerebellar cortex of Ts65Dn mice compared to control, but not in cerebellum. After phosphodiesterase inhibition, net increments in cAMP accumulation were similar in both groups of mice. Stimulation of cAMP production by isoprenaline (10 microM) and forskolin (10 microM) was much higher in hippocampus than in cerebral cortex of either group. In both areas, but not in cerebellum, the stimulatory responses were consistently and significantly smaller in Ts65Dn than in control mice. Concentration-response curves for isoprenaline and forskolin were generated in the cerebral cortex. Emax responses were lower in trisomic than in control mice; however, in Ts65Dn mice the slope of the response curve to isoprenaline was markedly depressed whereas that to forskolin was similar to control. It is concluded that Ts65Dn mice show severe deficiencies in the synaptic transmission of the central beta-noradrenergic system, which are selective for specific brain areas.

Impaired cyclic AMP production in the hippocampus of a Down syndrome murine model

Behavioral and learning disturbances have been found in mice with partial trisomy 16, a new model for Down syndrome. Basal production of cyclic AMP in the hippocampus of trisomic mice was shown to be impaired. In addition, the responses of adenylyl cyclase to the stimulation of beta-adrenoceptors with isoprenaline and of the catalytic subunit with forskolin were both severely depressed.

Reduced phospholipase C-β activity and isoform expression in the cerebellum of TS65DN mouse: A model of down syndrome

Agonist‐ and guanine‐nucleotide‐stimulated phospholipase C‐β (PLC) activity was characterized in crude plasma membrane preparations from cerebral cortex, hippocampus and cerebellum of Ts65Dn mice, a model for Down syndrome, and their control littermates. The levels of expression of PLC‐β(1–4) isoforms and G‐protein αq/11 subunits were also quantified by Western blot analysis to establish their contribution to the patterns of PLC functioning. PLC activity regulated by G‐proteins and muscarinic and 5‐HT2 receptors presented a regional distribution in both control and Ts65Dn mice. In both groups of mice, the intensity of PLC responses to maximal activation by calcium followed the sequence cerebellum > cortex > hippocampus. Both basal and maximal PLC activities, however, were significantly lower in cerebellar membranes of Ts65Dn than in control mice. This difference was mostly revealed in crude plasma membranes prepared from cerebellum at the level of G‐protein‐dependent‐PLC activity because the concentration‐response curve to GTPγS showed a reduction of the maximal effect in Ts65Dn mice, with no change in sensitivity (EC50). Western blot analysis showed a heterogeneous distribution of PLC‐β(1–4) isoforms in both groups of mice. The levels of PLC‐β4 isoform, however, were significantly lower in the cerebellum of Ts65Dn than in control mice. We conclude that the cerebellum of Ts65Dn mice has severe deficiencies in PLC activity stimulated by guanine nucleotides, which are specifically related to a lower level of expression of the PLC‐β4 isoform, a fact that may account for the neurological phenotype observed in this murine model of Down syndrome. J. Neurosci. Res. 66:540–550, 2001.

Brain G protein-dependent signaling pathways in Down syndrome and Alzheimer's disease

Summary.Premature aging and neuropathological features of Alzheimer’s disease (AD) are commonly observed in Down syndrome (DS). Based on previous findings in a DS mouse model, the function of signaling pathways associated with adenylyl cyclase (AC) and phospholipase C (PLC) was assessed in cerebral cortex and cerebellum of age-matched adults with DS, AD, and controls. Basal production of cAMP was reduced in DS but not in AD cortex, and in both, DS and AD cerebellum. Responses to GTPγS, noradrenaline, SKF 38393 and forskolin were more depressed in DS than in AD cortex and cerebellum. Although no differences in PLC activity among control, DS and AD cortex were observed under basal and GTPγS- or Ca-stimulated conditions, the response of DS cortex to serotonergic and cholinergic stimulation was depressed, and that of AD was only impaired at cholinergic stimulation. No differences were documented in cerebellum. Our results demonstrate that PLC and AC were severely disturbed in the aged DS and AD brains, but the alterations in DS were more severe, and differed to some extent from those observed in AD.

G-Protein-Associated Signal Transduction Processes Are Restored after Postweaning Environmental Enrichment in Ts65Dn, a Down Syndrome Mouse Model

Individuals with Down syndrome (DS) present cognitive deficits that can be improved by early implementation of special care programs. However, they showed limited and temporary cognitive effects. We previously demonstrated that postnatal environmental enrichment (EE) improved clearly, though temporarily, the execution of visuospatial memory tasks in Ts65Dn mice, a DS model bearing a partial trisomy of murine chromosome 16; but in contrast to wild-type littermates, there was a lack of structural plasticity in pyramidal cell structure in the trisomic cerebral cortex. In the present study, we have investigated the impact of EE on the function of adenylyl cyclase and phospholipase C as a possible mechanism underlying the time-limited improvements observed. Basal production of cyclic adenosine monophosphate (cAMP) was not affected, but responses to GTPγS, isoprenaline, noradrenaline, SKF 38393 and forskolin were depressed in the Ts65Dn hippocampus. In EE conditions, cAMP accumulation was not significantly modified in control animals with respect to nonenriched controls. However, EE had a marked effect in Ts65Dn mice, in which cAMP production was significantly increased. Similarly, EE increased phospholipase C activity in Ts65Dn mice, in response to carbachol and calcium. We conclude that EE restores the G-protein-associated signal transduction systems that are altered in Ts65Dn mice.

Short-Term Effects of Postnatal Manipulation on Central β-Adrenoceptor Transmission

Neonatal handling is known to induce long-lasting changes in behavioral and neuroendocrine responses to stress. Since the central noradrenergic system participates in the adaptive responses to stressful conditions we have analyzed the effects of postnatal handling on β-adrenoceptor binding sites and isoprenaline- and forskolin-stimulated cyclic AMP accumulation in cerebral cortex, hippocampus and cerebellum of rats at 1 and 3 months of age. Handled animals showed reduced emotional reactivity and lower ACTH and corticosterone secretion after stress, Binding studies using [3H]CGP12-177 revealed increased β-adrenoceptor binding sites in handled rats in cerebellum and cerebral cortex with no changes in hippocampus, and decreased affinity in all cerebral regions. Handling reduced basal levels of cyclic AMP in hippocampus and cerebellum but not in cerebral cortex. The concentration-response curves of cyclic AMP to isoprenaline were displaced to the right in cerebellum of handled rats without differences in Emax...

Postnatal Handling Induces Long-term Modifications in Central β-noradrenergic Signalling in Rats

Neonatal handling has been shown to induce a short-term reduction in the binding properties of g -adrenoceptors and in their primary biochemical responses in the young rat brain, which may account for the reduced responsiveness to stress observed in the handled rats. We have studied the persistence and duration of these changes in cerebral cortex, cerebellum and hippocampus at successive stages of life in neonatally handled rats. Binding properties of the g -adrenoceptors in handled animals were essentially similar to those of the control rats from 3 to 24 months of age. However, handling disturbed the efficacy of the g -adrenoceptor intracellular signalling since the isoprenaline-induced accumulation of cyclic AMP was reduced in cerebral cortex at 1, 12 and 24 months; in cerebellum at 12 and 18 months; and in hippocampus at 3 and 12 months. This effect might be partially dependent on a regulatory action of handling on the adenylyl cyclase enzyme itself since both basal and forskolin-induced accumulation of cyclic AMP were persistently reduced. Therefore, postnatal handling can be considered as an effective intervention that modifies sensitivity to various hormonal and neurochemical signals; these changes may be involved over a long period of time in protection against an excessive response to stress. These results suggest that the long-lasting adaptation of the adenylyl cyclase transduction system, which affects the primary biochemical response of the g -adrenoceptor, may participate in the effects of this manipulation.