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WHY ARE THERE PARALLEL HIPPOCAMPAL - DIENCEPHALIC PATHWAYS FOR EVENT MEMORY?

WHY ARE THERE PARALLEL HIPPOCAMPAL - DIENCEPHALIC PATHWAYS FOR EVENT MEMORY?. Wellcome Trust Project JOHN AGGLETON SHANE O’MARA JONATHAN ERICHSEN SERALYNNE VANN. Presentation format. Introduction to synaptic plasticity and memory Hippocampal-diencephalic system (HDS)

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WHY ARE THERE PARALLEL HIPPOCAMPAL - DIENCEPHALIC PATHWAYS FOR EVENT MEMORY?

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  1. WHY ARE THERE PARALLEL HIPPOCAMPAL - DIENCEPHALIC PATHWAYS FOR EVENT MEMORY? Wellcome Trust Project JOHNAGGLETON SHANEO’MARA JONATHANERICHSEN SERALYNNE VANN

  2. Presentation format • Introduction to synaptic plasticity and memory • Hippocampal-diencephalic system (HDS) • Mammillary bodies (MB) • Anterior thalamic nuclei (ATN) • Lesion studies • Subiculum • Overview

  3. Synaptic plasticity >> Memory Different types of: Plasticity Sjöström and Nelson, Curr Op Neurobiol 2002 Sjöström and Nelson,Curr Op Neurobiol,2002 Introduction memory memory circuits synaptic plasticity plasticity induction plasticity involved cells plasticity cellular targets intracellular mechanisms

  4. Introduction Long term synaptic plasticity in hippocampal related circuits >> Episodic memory

  5. Introduction Hippocampus related circuits

  6. Introduction Hippocampus related circuits

  7. Introduction Hippocampus related circuits

  8. HDS Hippocampal - diencephalic system Lesion studies : the hippocampal - diencephalic system is required for the encoding of episodic information. Still the functional significance of this system for the memory formation is under construction.

  9. HDS Significance of the parallel thalamic projections (direct and via MB) Hippocampal –diencephalic circuit (Papez’s circuit): hippocampal formation → MB → anterior thalamus → cingulate cortex → parahippocampal gyrus → hippocampal formation MB are part of the extended hippocampal - diencephalic system

  10. HDS Medial & lateral diencephalic systems Rec Rec/Stim Stim

  11. Retrograde markers tracing Lesion application + Behavioural examination (learning tasks) IEG activity immunohistochemistry Field EPSP recording under anaesthesia Field EPSP + Lesion application under anaesthesia EEG under anaesthesia and in freely moving rats Unit recording under anaesthesia and in freely moving rats Others (fMRI, microdialysis) PPF LTP LTD STDP Methodology Methods and approaches • Theta

  12. HDS Medial & lateral diencephalic systems

  13. MB Significance of the parallel thalamic projections (direct and via MB) MMB involvement in spatial working memory tasks: - lesion techniques - c-fos protein expression - cytochrome oxidase (CO) aczivity (Conejo et al., 2004).

  14. MB MB lesions – the mildest outcome Spatial deficits after MB damage are not as severe as those found after hippocampectomy and are typically less severe than those associated with ATN damage. Anatomical or functional bypassing possibility?

  15. MB MMB coordinates - AP: 4.5 - 5.2 mm

  16. MB MB function: relayers of hippocampal theta rhythm - to the ATN and beyond • theta-related cells in the MB seem to be driven by descending projections from the hippocampus • and are especially correlated with the CA1 theta generators.

  17. MB MB function: relayers of hippocampal theta rhythm - to the ATN and beyond • Propolsals about the significance of this relay: • 1. relaying of theta by the mammillary bodies might reduce interference by helping to separate encoding and retrieval (Hasselmo et al., 2002) • 2. theta activity im parallel with head direction processing facilitates the transmission and plasticity of LMN – AD thalamus - retrosplenial information (Vertes et al., 2004). • 3. theta oscillations of MMB facilitate the information current in Papez’s circuit

  18. MB Synaptic plasticity and hippocampo-diencephalic system ATN convergence has a gating effect on theta and its potential to act upon the retrosplenial cortices and back upon the hippocampus.

  19. ATN Anterior thalamus and theta • Approximately 75% of ventral ANT cells fire synchrony with hippocampal theta rhythm. • Active locomotion increases peak firing rates of anterodorsal thalamic head direction cells. The level of locomotor activity provides a statedependent modulation of the response magnitude of AD HD cells (Zugaro et al., 2001).

  20. ATN Anterior thalamus nuclei (ATN)

  21. ATN ATN coordinates

  22. ATN ATN coordinates - AP: 1.4 mm

  23. Lesion studies Hippocamal – diencephalic plasticity lesion studies

  24. Lesion studies Postcommissural fornixlesions Pilot studies postcommissural fornix lesions.

  25. Lesion studies Mammillothalamic tract lesions Vann and Aggleton, 2003; Vann et al., 2003: mammillothalamic tract lesions (MTTx) coordinates of the lesion relative to ear-bar zero were AP +4.2 and L +0.9, and the depth from top of cortex was +6.9 mm.

  26. Subiculum Subiculum – the major challange of the project

  27. Subiculum Ventral vs. dorsal subiculum Naber and Witter, 1998

  28. Subiculum Subicular coordinates Transverse sections perpendicular to the long axis of the hippocampal formation (Ishizuka 2001).

  29. Subiculum Subicular AP coordinates: 5.2 - 5.6 mm

  30. Overview AP spatial configuration of all electrodes MM: 4.5 – 5.2 ATN: 1.4 – 2.1 Sub: 5.2 – 5.6

  31. Overview PLASTICITY IN THE PROJECTION FROM THE ATN TO THE ANTERIOR CINGULATE CORTEX (Gemmell and O‘Mara, 2002) Hippocampal - diencephalic plasticity, system approach

  32. Overview Regional specific long-term synaptic plasticity Physiological substrate of hippocampal diencephalic plasticity – possible key to the encoding of temporal sequences (episodes).

  33. Overview Hippocampal - diencephalic system: basic approach to the episodic memory

  34. Thank you for your attention

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