On the role and nature of retroactive interference in anterograde amnesia

Dewar, Michaela

January 2007

Recent research has elucidated significantly improved delayed recall in patients with severe anterograde amnesia following an unfilled as opposed to a filled retention interval. Such findings are of great interest as they suggest that some anterograde amnesiacs are able to retain material for much longer than usual when Retroactive Interference is kept minimal. The research thus provides a novel cognitive hypothesis for the severe forgetting in anterograde amnesia, namely a greatly heightened susceptibility to Retroactive Interference. The aim of this thesis was to further examine such phenomenon and hypothesis. More specifically the main aim was to (a) investigate which cognitive conditions are required for a benefit of minimal Retroactive Interference to emerge in anterograde amnesiacs; and thus how specific their susceptibility to Retroactive Interference is, and (b) which cognitive processes underlie the benefit of minimal Retroactive Interference in such patients. A secondary aim was to review and further explore Müller and Pilzecker’s (1900) original research and theory of Retroactive Interference in forgetting in healthy people, to investigate the effects of Retroactive Interference on age related memory decline as well as to examine potential neural correlates of the benefit of minimal Retroactive Interference. Various samples of anterograde amnesia patients (Focal injury and MCI) and healthy participants were tested by means of a range of experimental manipulations in order to explore these questions. The research elucidated that any material or distraction (‘diversion Retroactive Interference’) had to be removed during the delay interval for anterograde amnesiacs to show improved delayed recall. Moreover the results of this thesis strongly suggest that minimal Retroactive Interference allows for improved Long Term Memory formation in at least some anterograde amnesia patients. These two main findings were also made for the healthy participants, albeit to a greatly reduced extent. In conclusion, the present research provides further and novel detailed evidence for a ‘diversion’ Retroactive Interference hypothesis of forgetting in pathological and normal forgetting alike.

616.85

psychology ; Anterograde Amnesia

The role of sec24 in protein export from the plant endoplasmic reticulum

Renna, Luciana

19 March 2008

Plant cells contain multiple mobile Golgi bodies. Golgi bodies receive cargo from specialized subdomains of the endoplasmic reticulum (ER), so-called ER export sites (ERES). How ERES operate in plant cells is largely uncharacterized. <p>In mammals and yeast, the commonly recognized ER-to-Golgi transport model asserts that protein transport between these two organelles is mediated by vesicles. Formation of these vesicles is interceded by COPII and COPI coat complexes. COPII coat proteins assemble at ERES. The minimal components of the COPII coat comprise the following proteins: the GTPase Sar1, and two large heterodimeric complexes, Sec23/24 and Sec13/31. COPII vesicles are responsible for forward (anterograde) protein traffic from the ER to the Golgi apparatus. Proteins are constantly recycled from the Golgi back to the ER through a conserved backward (retrograde) pathway mediated by COPI coat proteins. Fusion of the anterograde and retrograde carriers with target membranes is mediated by a subset of specialized proteins called soluble N-ethyl maleimide sensitive factor attachment protein receptors (SNAREs). Studies conducted in mammalian and yeast systems also concluded that ER-to-Golgi SNARE proteins and membrane cargo proteins are concentrated into COPII vesicles through a direct interaction and binding with the pre-budding complex Sec23/24-Sar1. <p>The COPII component distribution and their biological function in plant cells are largely uncharacterized. Therefore, through the study of the COPII protein Sec24, this work aimed (i) to investigate where and how protein transport between ER and Golgi occurs in plant cells, and (ii) to establish the importance of the anterograde and retrograde transport equilibrium in regulating the ER protein export. To do so, live cell imaging of a fluorescent protein fusion of Sec24 was used and the dynamics of this protein chimaera were followed in tobacco leaf epidermal cells. The imaging investigations were complemented by mutagenesis studies and biochemical analyses. <p>The obtained results indicate that in plant cells Sec24 is localized at specific regions of the ER that represent mobile units continuously joined to the Golgi apparatus. From this study the importance of the balance between the anterograde and retrograde transport in protein ER export has also emerged. I have shown in fact, that blockage of the retrograde pathway using Arf1 mutants and COPI chemical inhibitor determines the collapse of the anterograde protein trafficking from the ER to the Golgi. Moreover, this study has shown that Sec24 is capable of an interaction with the SNAREs Sed5 and Sec22. This is a forward step in our understanding of the role of Sec24 in the mechanism of cargo selection and recruitment.

COPII

endoplasmic reticulum export sites

anterograde transport

The role of sec24 in protein export from the plant endoplasmic reticulum

Renna, Luciana

19 March 2008

Plant cells contain multiple mobile Golgi bodies. Golgi bodies receive cargo from specialized subdomains of the endoplasmic reticulum (ER), so-called ER export sites (ERES). How ERES operate in plant cells is largely uncharacterized. <p>In mammals and yeast, the commonly recognized ER-to-Golgi transport model asserts that protein transport between these two organelles is mediated by vesicles. Formation of these vesicles is interceded by COPII and COPI coat complexes. COPII coat proteins assemble at ERES. The minimal components of the COPII coat comprise the following proteins: the GTPase Sar1, and two large heterodimeric complexes, Sec23/24 and Sec13/31. COPII vesicles are responsible for forward (anterograde) protein traffic from the ER to the Golgi apparatus. Proteins are constantly recycled from the Golgi back to the ER through a conserved backward (retrograde) pathway mediated by COPI coat proteins. Fusion of the anterograde and retrograde carriers with target membranes is mediated by a subset of specialized proteins called soluble N-ethyl maleimide sensitive factor attachment protein receptors (SNAREs). Studies conducted in mammalian and yeast systems also concluded that ER-to-Golgi SNARE proteins and membrane cargo proteins are concentrated into COPII vesicles through a direct interaction and binding with the pre-budding complex Sec23/24-Sar1. <p>The COPII component distribution and their biological function in plant cells are largely uncharacterized. Therefore, through the study of the COPII protein Sec24, this work aimed (i) to investigate where and how protein transport between ER and Golgi occurs in plant cells, and (ii) to establish the importance of the anterograde and retrograde transport equilibrium in regulating the ER protein export. To do so, live cell imaging of a fluorescent protein fusion of Sec24 was used and the dynamics of this protein chimaera were followed in tobacco leaf epidermal cells. The imaging investigations were complemented by mutagenesis studies and biochemical analyses. <p>The obtained results indicate that in plant cells Sec24 is localized at specific regions of the ER that represent mobile units continuously joined to the Golgi apparatus. From this study the importance of the balance between the anterograde and retrograde transport in protein ER export has also emerged. I have shown in fact, that blockage of the retrograde pathway using Arf1 mutants and COPI chemical inhibitor determines the collapse of the anterograde protein trafficking from the ER to the Golgi. Moreover, this study has shown that Sec24 is capable of an interaction with the SNAREs Sed5 and Sec22. This is a forward step in our understanding of the role of Sec24 in the mechanism of cargo selection and recruitment.

COPII

endoplasmic reticulum export sites

anterograde transport

Sortilin is a Negative Regulator of Sonic Hedgehog Processing and Anterograde Trafficking in Neurons

Campbell, Charles

January 2016

Sonic Hedgehog (SHH) is a secreted morphogen that is an essential regulator of patterning and growth. The SHH protein requires cleavage of its full-length precursor (SHHFL) for secretion of biologically active SHH (SHHNp). Mutations in SHH that affect SHH processing are associated with human disease, which highlights the importance of processing for patterning in vivo. We identified Sortilin (SORT1), a member of the VPS10P receptor family, as a novel SHH interacting protein. SORT1 preferentially associates with SHHFL and SORT1 levels correlate inversely with cleavage of SHHFL. Consistent with an antagonistic relationship between SORT1 and SHH processing, loss of SORT1 results in an increase in SHH levels in axons and a partial rescue of Hedgehog-associated patterning defects in a mouse model of deficient SHH processing. Finally, we demonstrate a functional requirement for SORT1-mediated trafficking on SHH-dependent signaling from axons in the developing visual system in vivo. Our findings identify a novel role for SORT1 in the regulation of SHH processing and trafficking.

Sonic Hedgehog

Sortilin1

Anterograde Trafficking

Protein Processing

Neuron

A descending circuit derived from the superior colliculus modulates vibrissal movements / ラットのヒゲ運動における上丘からの下行性神経調節機構

Kaneshige, Miki

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第21706号 / 人健博第72号 / 新制||人健||5(附属図書館) / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 澤本 伸克, 教授 木下 彩栄, 教授 渡邉 大 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM

whisker

premotor neurons

rat

anterograde tracing

kinematic analysis

498

Telencephalic Projections to the Goldfish Hypothalamus: An Anterograde Degeneration Study

Airhart, Mark J., Shirk, James O., Kriebel, Richard M.

01 January 1988

In this study, large areas of goldfish telencephalon were ablated including rostral nucleus preopticus periventriculare (rNPP), and degenerating axons were traced by a modified Fink and Heimer procedure. The lesioning procedure ablated large regions of area dorsalis telencephali pars medialis, centralis, and dorsolateral complex; and completely removed area ventralis telencephali pars dorsalis, ventralis, and lateralis. In addition, the supracommissural nucleus and rNPP were lesioned specifically because both nuclei have been thought to be involved in courtship behavior and endocrine control of reproduction. This investigation demonstrated extensive fiber projections from telencephalic nuclei and/or rNPP to the hypothalamus. Lesioned telencephalon and/or rNPP projected bilaterally to nucleus preopticus and the suprachiasmatic nucleus and unilaterally to the following tuberal nuclei: nucleus anterior tuberis, and the lateral hypothalamic nucleus. A much larger fiber projection to the inferior lobe nuclei was also observed with a large contralateral as well as ipsilateral input.

anterograde degeneration techniques

goldfish

preoptic and hypothalamic afferents

telencephalic projections

An examination of how Rab GTPases and molecular chaperones influence plasma membrane expression of chemokine receptor dimers

Gillies, Kelsie

07 November 2013

Signal termination processes of GPCRs are well established, unlike processes that regulate the assembly and intracellular trafficking of these signaling complexes. Bimolecular fluorescence complementation was used to study GPCR dimer formation in two projects. Firstly, the importance of Rab GTPases on the cell surface expression and signaling of two chemokine receptors expressed on prostate cancer cells was examined. Rab GTPases necessary for CXCR4 and CCR2 cell surface expression and signaling were different from those necessary for the CXCR4/CCR2 heterodimer. Therefore, this project emphasizes the importance of studying heterodimers as unique entities from their constituent receptors. Secondly, interactions between molecular chaperones and two coreceptors necessary for HIV infection – CCR5, a chemokine GPCR, and the main HIV receptor, CD4, a glycoprotein – were investigated. Further emphasizing the unique characteristics of GPCR dimers, this project found that molecular chaperones interact differently with CCR5 homodimers, when compared to CCR5/CD4 heterodimers.

GPCR

CXCR4

CCR2

Rab GTPase

Anterograde trafficking

Prostate cancer

CD4

CCR5

Molecular chaperone

HIV

Organization of Corticostriatal Projections From the Vibrissal Representations in the Primary Motor and Somatosensory Cortical Areas of Rodents

Calupca, Michelle A., Locknar, Sarah A., Zhang, Lili, Harrison, Theresa A., Hoover, Donald B., Parsons, Rodney L.

08 October 2001

To characterize corticostriatal projections from rodent sensorimotor cortex, the anterograde tracers biotinylated dextran amine (BDA) and fluororuby (FR) were injected into the whisker representations of the primary motor (MI) and somatosensory (SI) cortices. Reconstructions of labeled terminals and their beaded varicosities in the neostriatum and thalamus were analyzed quantitatively to determine the degree of labeled overlap in both of these subcortical structures. Corticostriatal projections from the vibrissal representation in MI were more extensive than corresponding projections from SI. Both cortical areas sent dense projections to the dorsolateral neostriatum, but the MI vibrissal representation also projected to regions located more rostrally and medially. Despite these differences, both MI and SI projected to overlapping parts of the dorsolateral neostriatum. Tracer injections in both cortical areas also produced dense anterograde and retrograde labeling in the medial sector of the posterior complex of the thalamus (POm). Because POm is somatotopically organized and has reciprocal connections with both SI and MI cortices, the amount of labeled overlap in POm was used to indicate whether the tracers were injected into corresponding whisker representations of MI and SI. We found that the proportion of labeled overlap in the neostriatum was highly correlated with the amount of labeled overlap in POm. These results indicate that the rodent neostriatum receives convergent projections from corresponding regions in MI and SI cortex. Furthermore, the thalamocortical projections of the POm indicate that it may modulate corticostriatal outputs from corresponding representations in MI and SI.

anterograde tracing

caudate-putamen

convergence

neostriatum

sensorimotor integration

thalamus

Biomedical Sciences

DIFFUSE TRAUMATIC AXONAL INJURY WITHIN THE VISUAL SYSTEM: IMPLICATIONS FOR VISUAL PATHWAY REORGANIZATION

Wang, Jiaqiong

04 December 2012

Traumatic brain injury is a major health problem with much of its morbidity associated with traumatic axonal injury (TAI). To date, significant insight has been gained into the initiating pathogenesis of TAI. However, the specific anterograde and retrograde sequelae of TAI are poorly understood because the diffuse nature of TAI complicates data analysis. To overcome this limitation, we subjected transgenic mice expressing yellow fluorescent protein (YFP) within the visual system to central fluid percussion injury, and consistently generated diffuse TAI within the optic nerve that could easily be followed in the organized YFP positive fibers. We demonstrated progressive axonal swelling, disconnection and proximal and distal axonal dieback, with regression and reorganization of the proximal swellings, and the persistence of the distal disconnected and degenerating swellings. Antibodies targeting the C-terminus of amyloid precursor protein, a marker of TAI, mapped to the proximal axonal segments without distal targeting. Antibodies targeting microglia/macrophages, revealed activated microglia/ macrophages closely encompassing the distal disconnected, degenerating axonal segments at 7 - 28 days post injury, suggesting their role in the delayed axonal degeneration. In contrast, in the proximal reorganizing axonal segments, microglia/macrophages appeared less reactive with their processes paralleling preserved axonal profiles. Concomitant with these events, YFP fluorescence quenching also occurred, complicating data analysis. This quenching mapped to Texas-Red-conjugated-IgG immunoreactive loci, suggesting that blood–brain barrier disruption and its attendant edema participated in fluorescence quenching. This was confirmed through antibodies targeting endogenous YFP, which identified the retention of intact axons despite YFP fluorescent loss. Paralleling these events, TAI was not accompanied by retrograde retinal ganglion cell (RGC) death. Specifically, no TUNEL+ or cleaved caspase-3 immunoreactive RGCs were observed from 2 days to 3 months post-TBI. Further, Brn3a immunoreactive RGC quantification revealed no significant RGC loss. This RGC preservation was accompanied by the persistent phospho-c-Jun expression for up to 3 months post-TBI, a finding linked to neuronal survival and potential axonal repair. Parallel ultrastructural study again failed to identify RGC death. Collectively, this study provides unprecedented insight into the evolving pathobiology associated with TAI, and offers advantages for future studies focusing on its therapeutic management and neuronal reorganization.

traumatic brain injury

traumatic axonal injury

anterograde and retrograde axonal change

YFP mice

visual system

Medical Sciences

Medicine and Health Sciences

Neurosciences

Caracterização neuroquímica das áreas relacionadas ao controle reprodutivo inervadas pela área incerto-hipotalâmica em camundongos fêmeas. / Neurochemical characterization of areas related to reproductive control innervated by incerto-hypothalamic area in female mice.

Barbeiro, Érica Olmos

08 February 2017

A área incerto-hipotalâmica (IHy) está envolvida no controle neuroendócrino de fêmeas, com associação de suas células MCHérgicas (hormônio concentrador de melanina). Em ratos, a área pré-óptica medial (MPA), o núcleo periventricular anteroventral (AVPe) e o núcleo arqueado (Arc) são mais densamente inervadas pela IHy em fêmeas do que em machos, sugerindo um dimorfismo sexual das projeções da IHy relevantes para o controle reprodutivo. Nosso objetivo é caracterizar as áreas relacionadas ao controle reprodutivo inervadas pela IHy em camundongos fêmeas, utilizando traçador neuronal anterógrado, analisar a inervação das células GnRH (hormônio liberador de gonadotrofinas) da MPA pela IHy e analisar a inervação do AVPe e Arc pela IHy, usando camundongos Kiss1-hrGFP. Como resultado, observamos que MPA, AVPe e Arc recebem projeções da IHy, assim como áreas relacionadas ao circuito de defesa. Nos animais Kiss1-hrGFP, não encontramos inervação de células KiSS-1 pela IHy. Problemas metodológicos impossibilitaram a análise das projeções da IHy para os neurônios GnRH. / The incerto-hypothalamic area (IHy) is related to the neuroendocrine control of females, involving their MCHergic cells (melanin-concentrating hormone). In rats, the medial preoptic area (MPA), the anteroventral periventricular nucleus (AVPe) and the arcuate nucleus (Arc) are more densely innervated by IHy in females than in males, suggesting a sexual dimorphism of IHy projections relevant to reproductive control. Our aim is to characterize the areas related to reproductive control innervated by IHy in female mice using anterograde neuronal tracer, analyze the innervation of GnRH cells (gonadotropin-releasing hormone) of MPA by IHy and analyze the innervation of AVPe and Arc by IHy using Kiss1-hrGFP mice. As a result, we observed that MPA, AVPe and Arc are innervated by IHy, as well as areas related to the defensive circuit. In Kiss1-hrGFP animals, KiSS-1 cells were not innervated by IHy cells. Methodological problems made it impossible to analyze the projections of IHy to the GnRH neurons.

Anterograde tracer

Hipotálamo

Hormônio concentrador de melanina

Hypothalamus

Immunohistochemistry

Imuno-histoquímica

Melanin-concentrating hormone

Reproductive system

Sistema reprodutivo

Traçador anterógrado