The biological mechanisms supporting age-dependent changes in learning and memory remain elusive. While a growing body of human literature implicates KIBRA in memory and neurodevelopmental disorders, KIBRA’s molecular function and contribution to maturation of synaptic function and cognition remain poorly understood. Despite being expressed throughout early postnatal development, germline deletion of KIBRA impairs synaptic plasticity selectively in adult rodents. However, it is unclear whether KIBRA facilitates proper brain maturation necessary for adult plasticity or whether it plays a distinct role in plasticity in the adult brain. Here, using an inducible KIBRA knockout mouse, we demonstrate that acutely deleting KIBRA in adult forebrain neurons impairs both spatial memory and long-term potentiation (LTP). The deficits in LTP correlate with an adult-selective decrease in extrasynaptic AMPA receptors under basal conditions. We also identify a novel role for KIBRA in LTP-induced AMPAR upregulation. In contrast, acute deletion of KIBRA in juvenile forebrain neurons did not affect LTP and had minimal effects on basal AMPAR expression. These data suggest that KIBRA serves a unique role in adult hippocampal function through regulation of basal and activity-dependent AMPAR proteostasis that supports synaptic plasticity.Significance StatementSynaptic plasticity supported by trafficking of postsynaptic AMPA receptors is a conserved mechanism underlying learning and memory. The nature and efficacy of learning and memory undergo substantial changes during childhood and adolescent development, but the mechanisms underlying this cognitive maturation remain poorly understood. Here, we demonstrate that the human memory- and neurodevelopmental disorder-associated gene KIBRA facilitates memory and hippocampal synaptic plasticity selectively in the adult hippocampus. Furthermore, we show that selective loss of KIBRA from adult but not juvenile neurons reduces expression of extrasynaptic AMPA receptors and prevents LTP-induced increases in AMPAR expression. Overall, our results suggest that KIBRA participates in cellular and molecular processes that become uniquely necessary for memory and synaptic plasticity in early adulthood.
Adult dentate gyrus (DG) neurogenesis is important for hippocampal-dependent learning and memory, but the role of new neurons in addiction-relevant learning and memory is unclear. To test the hypothesis that neurogenesis is involved in the vulnerability to morphine addiction, we ablated adult DG neurogenesis and examined morphine self-administration (MSA) and locomotor sensitization. Male Sprague-Dawley rats underwent hippocampal-focused, image-guided X-ray irradiation (IRR) to eliminate new DG neurons or sham treatment (Sham). Six weeks later, rats underwent either MSA (Sham = 16, IRR = 15) or locomotor sensitization (Sham = 12, IRR = 12). Over 21 days of MSA, IRR rats self-administered ~70 percent more morphine than Sham rats. After 28 days of withdrawal, IRR rats pressed the active lever 40 percent more than Sham during extinction. This was not a general enhancement of learning or locomotion, as IRR and Sham groups had similar operant learning and inactive lever presses. For locomotor sensitization, both IRR and Sham rats sensitized, but IRR rats sensitized faster and to a greater extent. Furthermore, dose-response revealed that IRR rats were more sensitive at a lower dose. Importantly, these increases in locomotor activity were not apparent after acute morphine administration and were not a byproduct of irradiation or post-irradiation recovery time. Therefore, these data, along with other previously published data, indicate that reduced hippocampal neurogenesis confers vulnerability for multiple classes of drugs. Thus, therapeutics to specifically increase or stabilize hippocampal neurogenesis could aid in preventing initial addiction as well as future relapse.
Purpose of reviewPatients with end-stage heart failure often present with concomitant end-stage renal or end-stage liver disease requiring transplantation. There are limited data regarding the risks, benefits and long-term outcomes of heart-kidney (HKT) and heart-liver transplantation (HLT), and guidelines are mainly limited to expert consensus statements. Recent findingsThe incidence of HKT and HLT has steadily increased in recent years with favourable outcomes. Both single-centre and large database studies have shown benefits of HKT/HLT through improved survival, freedom from dialysis and lower rates of rejection and coronary allograft vasculopathy. Current guidelines are institution dependent and controversial due to the ethical considerations surrounding multiorgan transplantation (MOT). SummaryMOT is an effective and necessary option for patients with end-stage heart and kidney/liver failure. MOT is ethically permissible, and efforts should be made to consider eligible patients as early as possible to limit morbidity and mortality. Further research is needed regarding appropriate listing criteria and long-term outcomes.
Synaptic plasticity is hypothesized to underlie “replay” of salient experience during hippocampal sharp-wave/ripple (SWR)-based ensemble activity and to facilitate systems-level memory consolidation coordinated by SWRs and cortical sleep spindles. However, it remains unclear how molecular changes at synapses contribute to experience-induced modification of network function. The synaptic protein KIBRA regulates plasticity and memory, although its impact on circuit dynamics remains unknown. Here, we recorded in vivo neural activity from WT mice and littermates lacking KIBRA to examine circuit function before, during, and after novel experience. In WT mice, experience altered network dynamics in a manner consistent with incorporation of new information content in replay and enhanced hippocampal-cortical communication. However, while baseline SWR features were normal in KIBRA cKO mice, experience-dependent alterations in SWRs were absent. Furthermore, intra-hippocampal and hippocampal-cortical communication during SWRs was disrupted following KIBRA deletion. These results reveal molecular mechanisms that underlie network-level memory formation and consolidation.
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