The Role of Smad2 in Adult Neuroplasticity as Seen through Hippocampal-Dependent Spatial Learning/Memory and Neurogenesis.

Adult neural plasticity is an important and intriguing phenomenon in the brain, and adult hippocampal neurogenesis is directly involved in modulating neural plasticity by mechanisms that are only partially understood. We have performed gain-of-function and loss-of-function experiments to study Smad2, a transcription factor selected from genes that are demethylated after exercise through the analysis of an array of physical activity-induced factors, and their corresponding gene expression, and an efficient inducer of plasticity. In these studies, changes in cell number and morphology were analyzed in the hippocampal dentate gyrus (cell proliferation and survival, including regional distribution, and structural maturation/differentiation, including arborization, dendritic spines, and neurotransmitter-specific vesicles) of sedentary male mice, after evaluation in a battery of behavioral tests. As a result, we reveal a role for Smad2 in the balance of proliferation versus maturation of differentiating immature cells (Smad2 silencing increases both the proliferation and survival of cycling cells in the dentate granule cell layer), and in the plasticity of both newborn and mature neurons in mice (by decreasing dendritic arborization and dendritic spine number). Moreover, Smad2 silencing specifically compromises spatial learning in mice (through impairments of spatial tasks acquisition both in long-term learning and working memory). These data suggest that Smad2 participates in adult neural plasticity by influencing the proliferation and maturation of dentate gyrus neurons.SIGNIFICANCE STATEMENT Smad2 is one of the main components of the transforming growth factor-ß (TGF-ß) pathway. The commitment of cell fate in the nervous system is tightly coordinated by SMAD2 signaling, as are further differentiation steps (e.g., dendrite and axon growth, myelination, and synapse formation). However, there are no studies that have directly evaluated the role of Smad2 gene in hippocampus of adult animals. Modulation of these parameters in the adult hippocampus can affect hippocampal-dependent behaviors, which may shed light on the mechanisms that regulate adult neurogenesis and behavior. We demonstrate here a role for Smad2 in the maturation of differentiating immature cells and in the plasticity of mature neurons. Moreover, Smad2 silencing specifically compromises the spatial learning abilities of adult male mice.

Noggin rescues age-related stem cell loss in the brain of senescent mice with neurodegenerative pathology.

Increasing age is the greatest known risk factor for the sporadic late-onset forms of neurodegenerative disorders such as Alzheimer's disease (AD). One of the brain regions most severely affected in AD is the hippocampus, a privileged structure that contains adult neural stem cells (NSCs) with neurogenic capacity. Hippocampal neurogenesis decreases during aging and the decrease is exacerbated in AD, but the mechanistic causes underlying this progressive decline remain largely unexplored. We here investigated the effect of age on NSCs and neurogenesis by analyzing the senescence accelerated mouse prone 8 (SAMP8) strain, a nontransgenic short-lived strain that spontaneously develops a pathological profile similar to that of AD and that has been employed as a model system to study the transition from healthy aging to neurodegeneration. We show that SAMP8 mice display an accelerated loss of the NSC pool that coincides with an aberrant rise in BMP6 protein, enhanced canonical BMP signaling, and increased astroglial differentiation. In vitro assays demonstrate that BMP6 severely impairs NSC expansion and promotes NSC differentiation into postmitotic astrocytes. Blocking the dysregulation of the BMP pathway and its progliogenic effect in vivo by intracranial delivery of the antagonist Noggin restores hippocampal NSC numbers, neurogenesis, and behavior in SAMP8 mice. Thus, manipulating the local microenvironment of the NSC pool counteracts hippocampal dysfunction in pathological aging. Our results shed light on interventions that may allow taking advantage of the brain's natural plastic capacity to enhance cognitive function in late adulthood and in chronic neurodegenerative diseases such as AD.

The relationship between behavior acquisition and persistence abilities: Involvement of adult hippocampal neurogenesis.

The influence of the learning process on the persistence of the newly acquired behavior is relevant both for our knowledge of the learning/memory mechanisms and for the educational policy. However, it is unclear whether during an operant conditioning process with a continuous reinforcement paradigm, individual differences in acquisition are also associated to differences in persistence of the acquired behavior. In parallel, adult neurogenesis has been implicated in spatial learning and memory, but the specific role of the immature neurons born in the adult brain is not well known for this process. We have addressed both questions by analyzing the relationship between water maze task acquisition scores, the persistence of the acquired behavior, and the size of the different subpopulations of immature neurons in the adult murine hippocampus. We have found that task acquisition and persistence rates were negatively correlated: the faster the animals find the water maze platform at the end of acquisition stage, the less they persist in searching for it at the learned position in a subsequent non-reinforced trial; accordingly, the correlation in the number of some new neurons' subpopulations and the acquisition rate is negative while with persistence in acquired behavior is positive. These findings reveal an unexpected relationship between the efficiency to learn a task and the persistence of the new behavior after a non-reinforcement paradigm, and suggest that the immature neurons might be involved in different roles in acquisition and persistence/extinction of a learning task. © 2016 Wiley Periodicals, Inc.

Meta-Analysis Design and Results in Real Life: Problem Solvers or Detour to Maze. A Critical Review of Meta-Analysis of DAPT Randomized Controlled Trials.

BACKGROUND: Therapeutic strategies - such as duration of dual antiplatelet therapy after coronary artery stenting - usually generate a large quantity of meta-analyses. The meta-analyses that include the same randomized clinical trials should produce similar results. Our aim in the study is to analyze the quality and to compare the results of meta-analyses focused on a controversial topic such as dual antiplatelet therapy after percutaneous coronary intervention. METHODS: We searched all published meta-analyses published up to November 2015 (near DAPT trial publication) selecting those that included the same randomized clinical trials comparing patterns of briefer versus longer-term double antiplatelet therapy. RESULTS: Seventeen meta-analyses achieved our selection criteria. Of the seventeen analyzed, we identified seven (41.1%) based on the same ten randomized clinical trials (RCTs), yet their results varied widely. Many of the meta-analyses differed in only some minor aspect of the design (i.e. eligible studies, length of comparators and statistical methods used). Some authors differed in the number of patients participating in RCTs and even, despite reviewing the same underlying trials, only 2 of the 7 meta-analyses included the same number of patients. CONCLUSION: Meta-analyses around cardiovascular, all-cause or non-cardiovascular death differ frequently. In the DAPT duration setting, several meta-analyses have been recently published based on the same data, presenting several issues making it difficult to determine clear recommendations on certain points.

The GSK-3-inhibitor VP2.51 produces antidepressant effects associated with adult hippocampal neurogenesis.

Glycogen synthase kinase 3 (GSK-3) is a constitutively active kinase that has been implicated in the mechanism of action of mood stabilizers. According to the neurogenic hypothesis of depression, newborn neurons in the adult dentate gyrus are required for the antidepressant effects of certain agents. We demonstrate that administration of the GSK-3 inhibitor VP2.51 (2.5 mg/kg ip, for 3.5 weeks) increases cell proliferation (pH3+ cells), as well as the short- and long-term survival of newborn neurons (assessed by the 24 h survival of BrdU+ and DCX+ neurons), while significantly increasing the commitment of cells to the granule neuron lineage (Prox1 immunoreactivity). In parallel, VP2.51 induces a net antidepressant effect, as judged by the decrease in the immobility time in the forced swim test of naïve mice (non-stressed mice), as well as a therapeutic effect on previously stressed mice (Porsolt-induced stress). Interestingly, the morphological changes were found prominently in the ventral region of the hippocampus. We found that these effects are neurogenesis dependent by combining the antimitotic temozolomide (50 mg/kg ip) with the drug. Importantly VP2.51 did not provoke changes in weight or in a battery of behavioral tests (learning/memory and activity tests). As the effects of VP2.51 were concomitant with the increase in ß-catenin expression and a shift towards the inactive form of GSK-3, we suggest that VP2.51 has therapeutic benefits following stress, and it may be a preventive treatment in situations where a potential depressive state and/or loss of memory is associated with diminished neurogenesis, through selective GSK3-beta inhibition.

Can Exercise Make You Smarter, Happier, and Have More Neurons? A Hormetic Perspective.

Exercise can make you smarter, happier and have more neurons depending on the dose (intensity) of the training program. It is well recognized that exercise protocols induce both positive and negative effects depending on the intensity of the exercise, among other key factors, a process described as a hormetic-like biphasic dose-response. However, no evidences have been reported till very recently about the biphasic response of some of the potential mediators of the exercise-induced actions. This hypothesis and theory will focus on the adult hippocampal neurogenesis (AHN) as a putative physical substrate for hormesis responses to exercise in the context of exercise-induced actions on cognition and mood, and on the molecular pathways which might potentially be mediating these actions.

The growth factors cascade and the dendrito-/synapto-genesis versus cell survival in adult hippocampal neurogenesis: the chicken or the egg.

The decision between cellular survival and death is governed by a balance between proapoptotic versus antiapoptotic signaling cascades. Growth factors are key actors, playing two main roles both at developmental and adult stages: a supporting antiapoptotic role through diverse actions converging in the mitochondria, and a promoter role of cell maturation and plasticity through dendritogenesis and synaptogenesis, especially relevant for the adult hippocampal neurogenesis, a case of development during adulthood. Here, both parallel roles mutually feed forward each other (the success in avoiding apoptosis lets the cell to grow and differentiate, which in turn lets the cell to reach new targets and form new synapses accessing new sources of growth factors to support cell survival) in a circular cause and consequence, or a "the chicken or the egg" dilemma. While identifying the first case of this dilemma makes no sense, one possible outcome might have biological relevance: the decision between survival and death in the adult hippocampal neurogenesis is mainly concentrated at a specific time window, and recent data suggest some divergences between the survival and the maturational promoter effect of growth factors. This review summarizes these evidences suggesting how growth factors might contribute to the live-or-die decision of adult-born immature granule neurons through influencing the maturation of the young neuron by means of its connectivity into a mature functional circuit.