Investigation of laminopathy-like alterations of the nuclear envelope caused by accumulation of Esc 1p

Hattier, Thomas.

January 2006

Thesis (Ph. D.)--Case Western Reserve University, 2006. / [School of Medicine] Department of Pathology. Includes bibliographical references. Available online via OhioLINK's ETD Center.

Nuclear Envelope. Nuclear Lamina.

Régulation de la mitose par la rigidité de la matrice extracellulaire : étude du rôle de la protéine SUN2 / Mitosis regulation by extracellular matrix rigidity : involvement of SUN2

Belaadi, Nejma

20 November 2017

Au sein des tissus, les cellules sont entourées par une matrice extracellulaire (MEC) dont les propriétés mécaniques influencent de nombreux aspects du comportement cellulaire, tels que la migration ou la différenciation. L’objectif de ce travail était d’explorer les effets de la rigidité de la MEC sur la mitose. En utilisant des hydrogels de polyacrylamide, nous avons observe que des cellules murines et humaines cultivées sur des matrices de rigidités croissantes se divisent plus rapidement. Grace a une analyse protéomique, nous avons mis en évidence que SUN2, une protéine de l’enveloppe nucleaire participe a la régulation de la progression mitotique en réponse a la rigidité de la MEC. Sur une matrice rigide, la stabilité et l’expression de SUN2 augmentent, favorisant ainsi le recrutement de l’actine au niveau cortical lors de la mitose et la progression de la métaphase. L’ensemble de ces résultats révèle l’existence d’un nouveau mécanisme régulant la division cellulaire en fonction de la rigidité de la MEC. Ce mécanisme pourrait notamment jouer un role important dans de nombreux contextes physiologiques et pathologiques associes a une rigidification de la MEC tels que le vieillissement ou l’hypertension artérielle. / Within tissues, cells are surrounded by an extracellular matrix (ECM), whose mechanical properties regulate many aspects of cell behavior, including motility and differentiation. Here we examined the effect of ECM rigidity on cell division. We found that cells divide more rapidly when cultured on substrates with increasing stiffness. We next compared the proteomic content of cells dividing on soft and stiff substrates and we found that ECM rigidity regulates the stability of the LINC complex component SUN2, whose level of expression affects mitotic progression. On rigid substrates, high level of SUN2 promotes cortical actin recruitment, force generation and mitotic progression, while low level of SUN2 delays the onset of anaphase when cells are grown on soft ECM. These results revealed a new mechanism that regulates mitotic progression in response to changes in ECM rigidity.

Actine corticale

Lamina

Quantitative aspects of blood vessels and perineurium in diabetic neuropathy

Bradley, Jane Louise

January 1995

No description available.

610

Cyclooxygenase 2 expression in intestinal tumorigenesis

Faluyi, Olusola Olusesan

January 2003

No description available.

616

Lamina propria mononuclear cells

Colour and polarised light vision in stomatopods : a neuroanatomical study

Strain, Eleanor Violet

January 1998

The mantis shrimp Gonodactylus oerstedii is known to possess eyes capable of colour and polarised light vision. The apposition compound eyes of these creatures are highly mobile and their ommatidia are specialised to analyse the spectral and e-vector qualities of light in a central strip of the eye called the midband. The retina of the midband of Rows 1-4 is tiered with each row being sensitive to a narrow region of the colour spectrum. Row 5 and 6 ommatidia possess many structural features designed to allow the e-vector direction of light to be detected. This thesis investigates the neuroanatomy in the neuropile regions below the retina in an attempt to elucidate the mechanisms which allow colour and polarised light vision to take place. In Chapter 2 the retina-lamina projection of the retinal axons is studied in an ommatidium in Row 3 of the midband, and the findings suggest that the stomatopod is similar to all other crustacea so far studied, despite its unusual retina. Chapter 3 investigates the neuroanatomy of the medulla neuropile regions. A novel region of the medulla externa which deals with colour information is discovered. In Chapter 4 the lamina of Rows 1-4 is looked at in more detail, with the number of monopolar cells and the detailed arrangements of the retinular cell terminals being ascertained. The terminals sensitive to different regions of the spectrum are located in different areas of the lamina cartridge. Chapter 5 looks at many of the issues above but this time in relation to rows 5 and 6 of the midband, which are specialised for polarisation vision. The lamina neuropile is very different to that of Rows 1-4 and again a specialised region of the medulla externa is found which processes information from these rows. This thesis provides evidence that the optic lobes of Gonodactylus oerstedii are comparable to other crustacea but nevertheless may possess some intriguing specialisations related to their extraordinary colour and polarised light vision.

590

Die Kernhülle in Keimzellen: Strukturelle Besonderheiten, dynamische Prozesse und die Umgestaltung des Zellkerns während der Spermatogenese der Maus / The nuclear envelope in germ cells: structural peculiarities, dynamic processes und the reorganization of the cell nucleus during murine spermatogenesis

Göb, Eva

January 2011

Die Kernhülle umgibt als geschlossenes Membransystem einen jeden Zellkern und ist damit ein gemeinsames Merkmal aller eukaryotischen Zellen. Sie besteht aus einer inneren und einer äußeren Kernmembran sowie der nukleoplasmatischen Kernlamina, die aufgrund zahlreicher assoziierter Proteine in enger Wechselbeziehung mit der inneren Kernmembran steht. Neben der rein räumlichen Trennung nukleärer und zytoplasmatischer Strukturen hat die Kernhülle bedeutenden regulatorischen Einfluss auf die gesamte Zelle. So ist sie unter anderem an der Steuerung der genomischen Aktivität, an der nukleo- und zytoplasmatischen Signalübertragung und in hohem Maße an der Positionierung und Formerhaltung des Zellkerns beteiligt. Es mehren sich die Hinweise, dass die Kernhülle auch während der Gametogenese, der Differenzierung befruchtungsfähiger Keimzellen, eine zentrale Rolle einnimmt und folglich auch mit bislang ungeklärten Ursachen humaner Infertilität in Kontext stehen könnte. Um die Bedeutung der Kernhülle für die Keimbahn der Säuger generell besser verstehen zu können, wurden in dieser Arbeit ausgewählte Bestandteile der Keimzellkernhülle untersucht. Dadurch sollte der Kenntnisstand erweitert werden, in welcher Weise die Kernhülle dynamische, morphologische und vor allem für die Keimbahn essentielle Prozesse beeinflusst; insbesondere während der meiotischen und der postmeiotischen Differenzierungsphase bei männlichen Mäusen. Im Mittelpunkt stand dabei einerseits Lamin C2, ein meiosespezifisches A-Typ Lamin, dessen Verlust zu einer schwer geschädigten Meiose und infolgedessen zu vollständiger männlicher Infertilität führt. Es zeigte sich, dass Lamin C2-defiziente männliche Mäuse schwerwiegende Defekte bei der Paarung und Synapsis der homologen Chromosomen in der meiotischen Prophase I aufweisen und aufgrund apoptotischer Spermatocyten keine reifen Spermien bilden können. Es wird angenommen, dass die Assoziation homologer Chromosomen bzw. die Abstoßung nicht-homologer durch gerichtete Telomerbewegungen entlang der Kernhüllenperipherie vorangetrieben bzw. verhindert wird. Da Lamin C2 seinerseits diese Wanderung der Telomere durch eine Flexibilisierung der Spermatocytenkernhülle vereinfachen soll, ist es durchaus vorstellbar, dass sein Verlust verlangsamte Telomerbewegungen, eine gestörte Homologenfindung und folglich Fehlpaarungen zur Folge hat. Ein weiteres zentrales Thema war die Erforschung potentieller LINC-Komplexe während der Differenzierungs- und morphologischen Umgestaltungsphase postmeiotischer Keimzellen. LINC-Komplexe sind kernhüllendurchspannende Proteingebilde aus SUN-Proteinen in der inneren und Nesprinen in der äußeren Kernmembran, die nukleäre Strukturen an das Zytoskelett binden. Da sie aufgrund dieser strukturellen Eigenschaft die Kernmorphologie beeinflussen können, erscheinen sie als äußerst geeignet, an der Formierung des Spermienkopfes beteiligt zu sein. Die detaillierte Untersuchung spermiogeneserelevanter LINC-Komplex-Bestandteile ergab, dass während der Spermiogenese tatsächlich zwei neue, strukturell einzigartige LINC-Komplexe gebildet werden, die darüber hinaus auf den entgegengesetzten Seiten differenzierender Spermatiden polarisieren. Da sie den Kern dort an jeweils spezielle Zytoskelettelemente binden könnten, wurde in dieser Arbeit das Modell der LINC-Komplex vermittelten Umformung des Spermienkopfes aufgestellt. Insgesamt trägt diese Arbeit durch die funktionelle Analyse von Lamin C2 und die Identifizierung neuer LINC-Komplexe dazu bei, die Wichtigkeit der Kernhülle für die Spermatogenese zu vertiefen und auszuweiten. / The nuclear envelope is a double membranous structure enclosing the most typical eukaryotic feature, the cell nucleus. It is composed of an inner and an outer nuclear membrane as well as a nucleoplasmic lamina which is closely connected to the inner nuclear membrane by a number of associated proteins. Thus, besides just separating nuclear and cytoplasmic structures the nuclear envelope is functionally involved in many regulatory processes; i.e. controlling of the genomic activity, nucleo- and cytoplasmic signal transduction and, importantly, nuclear positioning and maintenance of nuclear architecture. Evidence emerges that the nuclear envelope also plays a fundamental role in the differentiation process of germ cells, gametogenesis, likely being responsible for yet unexplained human infertility. In order to expand the knowledge concerning impact and functions of the nuclear envelope for the mammalian germ line selected components and special characteristics of the germ cell nuclear envelope have been investigated in this thesis. Thus, this might help to understand germ line specific dynamic, morphological and other essential processes - particularly in course of meiotic and postmeiotic differentiation in male mice. Of great interest was lamin C2, a meiosis-specific A-type lamin essential for accurate meiosis and fertility of male mice. It has been shown that the targeted depletion of lamin C2 results in a severely defective meiosis and consequently in complete male infertility. Lamin C2-deficient male mice exhibit serious defects concerning pairing and synapsis of the homologous chromosomes. Thus, these mice are characterized by apoptotic spermatocytes and the complete absence of postmeiotic stages. It has been proposed that telomere movements along the nuclear periphery during prophase I might promote homologous but prevent heterologous chromosome association. Lamin C2 in turn is suggested to facilitate those meiotic telomere migrations by providing local flexibility to the telomeres attached to the nuclear envelope. Given that loss of lamin C2 causes decelerated telomere movements and defective homologous pairing afterwards, the situation in lamin C2-deficient spermatocytes could be explained. Another central focus was the investigation of potential LINC complexes in differentiating and morphologically reorganizing postmeiotic cells. LINC complexes are proteinaceous structures formed by SUN-proteins at the inner and nesprins at the outer nuclear membrane that tether the cell nucleus to the surrounding cytoskeleton. Since this structural property is suggested to influence nuclear morphology and shaping, LINC complexes appear to be good candidates for participating in mammalian sperm head shaping. Detailed analysis of LINC complex components relevant for spermiogenesis revealed that two novel uniquely assembled LINC complexes are established in the male post meiotic germ line. Moreover, those LINC complexes were shown to polarize to opposite cell poles in differentiating spermatids probably linking to specialized cytoskeletal elements. Therefore, a model for the LINC complex mediated shaping and elongation of the mammalian sperm head has been proposed in this thesis. Together, the functional analysis of lamin C2 as well as the identification of novel LINC complexes described in this thesis substantiates the fundamental role of the nuclear envelope for entire spermatogenesis.

Spermatogenese

Kernhülle

Lamina

Maus

ddc:570

Collision avoidance : a biologically inspired neural network for the detection of approaching objects

Blanchard, Jonathan Mark

January 1998

The frequently studied lobula giant movement detector (LGMD) system of the locust responds most strongly to approaching objects. This thesis describes simulations which were designed with the ultimate aim of constructing a comprehensive model of the neural circuitry showing the effects of individual neurons on the overall responses of the system. The Rind and Bramwell neural network model of the LGMD was studied using new stimuli which revealed that the responses of the model are dependent on the shape of the stimulus. A modification of the model removes this dependence and allows the model to respond to more complex stimuli. Two models of a locust photoreceptor were developed with the aim of producing a detailed model of a light-adapting photoreceptor which could be used to study the responses of the LGMD to natural scenes. The first model, an electrical model of the cell membrane which describes the principal ionic conductances, was found to be overly complex for use in large scale simulations. However, the model was used to calculate from the photoreceptor's impulse response the average conductance change produced by individual photons. The second photoreceptor model, which is suitable for large scale simulations, uses two leaky integrators to mimic the effects of light adaptation on the photoreceptor's response. An electrical model of the lamina region of the optic lobe allowed the proposal that inhibition in the lamina is produced by electrical presynaptic inhibition to be studied, along with the possible effects of this inhibition on the visual input to the LGMD. The responses of the model correspond well with those measured from the LMCs of locusts and other insects, and their implications for the LGMD system are discussed.

590

Spinal cord plasticity in peripheral inflammatory pain

Dickie, Allen Charles

January 2014

Inflammatory pain is a debilitating condition that can occur following tissue injury or inflammation and results in touch evoked pain (allodynia), exaggerated pain (hyperalgesia) and spontaneous pain, yet the neural plasticity underlying these symptoms is not fully understood. However, it is known that lamina I neurokinin 1 receptor expressing (NK1R+) spinal cord output neurons are crucial for the manifestation of inflammatory pain. There is also evidence that the afferent input to and the postsynaptic response of these neurons may be altered in inflammatory pain, which could be relevant for inflammatory pain hypersensitivity. Therefore, the aim of this thesis was to study inflammatory pain spinal plasticity mechanisms by investigating the synaptic input to lamina I NK1R+ neurons. In ex vivo spinal cord and dorsal root preparations from the rat, electrophysiological techniques were used to assess inflammation-induced changes in and pharmacological manipulation of the primary afferent drive to lamina I NK1R+ neurons. The excitatory input to lamina I NK1R+ neurons was examined and it was found that inflammation did not alter the relative distribution of the type of primary afferent input received and did not potentiate monosynaptic A δ or monosynaptic C-fibre input, the predominant input to these neurons. Spontaneous excitatory input was significantly elevated in the subset of neurons that received monosynaptic A δ-fibre input only, regardless of inflammation. It has recently been shown that the chemerin receptor 23 (ChemR23) represents a novel inflammatory pain target, whereby ChemR23 agonists can decrease inflammatory pain hypersensitivity, by a mechanism that involves the attenuation of potentiated spinal cord responses. This study has found that the ChemR23 agonist, chemerin, attenuated capsaicin potentiation of excitatory input to lamina I NK1R+ neurons and significantly reduced monosynaptic C-fibre input to a subset of these neurons in inflammatory pain. However, chemerin was without effect in non-potentiated conditions. In exploring potential inflammatory pain spinal plasticity mechanisms, I have investigated a phenomenon called activity-dependent slowing (ADS), whereby repetitive stimulation of C-fibres at frequencies of 1Hz or above results in a progressive slowing of action potential conduction velocity, which manifests as a progressive increase in response latency. This is proposed to limit nociceptive input to the spinal cord, thus regulating plasticity. Results demonstrate that inflammation significantly attenuated C-fibre ADS in isolated dorsal roots. Furthermore, ADS in monosynaptic C-fibre input to lamina I NK1R+ neurons was significantly reduced in inflammatory pain, which could facilitate nociceptive drive to these key spinal cord output neurons and promote inflammatory pain spinal cord plasticity. In conclusion, the major novel findings of this thesis are firstly, that chemerin can attenuate primary afferent input to lamina I NK1R+ neurons in potentiated conditions, which supports recent studies that suggest ChemR23 is a potential target for the development of new analgesics. Secondly, it was discovered that ADS in monosynaptic C-fibre inputs to lamina I NK1R+ neurons is altered in inflammatory pain, which could be relevant for inflammatory pain spinal plasticity. The findings presented in this thesis could contribute to the development of novel inflammatory pain treatments.

612.8

Genetic dissection of peripheral pathways in the visual system of Drosophila / Genetische Zerlegung peripherer Pfade im visuellen System von Drosophila

Rister, Jens

January 2008

Die visuellen Systeme von Vertebraten und Invertebraten weisen Ähnlichkeiten in den ersten Schritten visueller Informationsverarbeitung auf. Im menschlichen Gehirn werden zum Beispiel die Modalitäten Farbe, Form und Bewegung separat in parallelen neuronalen Pfaden verarbeitet. Dieses grundlegende Merkmal findet sich auch bei der Fliege Drosophila melanogaster, welche eine ähnliche Trennung in farbsensitive und (farbenblinde) bewegungssensitive Pfade aufweist, die durch zwei verschiedene Gruppen von Photorezeptoren (dem R1-6 und dem R7/8 System) determiniert werden. Fliegen haben ein hoch organisiertes visuelles System, welches durch die repetitive, retinotope Organisation von vier Neuropilen charakterisiert ist: Dies sind die Lamina, die Medulla, die Lobula und die Lobulaplatte. Jedes einzelne besteht aus Kolumnen, die denselben Satz von Nervenzellen enthalten. In der Lamina formen Axonbündel von sechs Photorezeptoren R1-6, die auf denselben Bildpunkt blicken, Säulen, die als Cartridges bezeichnet werden. Diese sind die funktionellen visuellen „sampling units“ und sind mit vier Typen von Interneuronen erster Ordnung assoziiert, die von R1-6 den gleichen Input erhalten: L1, L2, L3 und die Amakrinzellen (amc, mit ihrem postsynaptischen Partner T1). Diese stellen parallele Pfade dar, die auf anatomischer Ebene im Detail untersucht wurden; jedoch ist wenig über ihre funktionelle Rolle bei der Verarbeitung für das Verhalten relevanter Information bekannt, z.B. hinsichtlich der Blickstabilisierung, der visuellen Kurskontrolle oder der Fixation von Objekten. Die Verfügbarkeit einer Vielfalt von neurogenetischen Werkzeugen für die Struktur-Funktionsanalyse bei Drosophila ermöglicht es, erste Schritte in Richtung einer genetischen Zerlegung des visuellen Netzwerks zu unternehmen, das Bewegungs- und Positionssehen vermittelt. In diesem Zusammenhang erwies sich die Wahl des Effektors als entscheidend. Überraschenderweise wurde festgestellt, dass das clostridiale Tetanus-Neurotoxin die Photorezeptorsynapsen adulter Drosophila Fliegen nicht blockiert, hingegen irreversible Schäden bei Expression während deren Entwicklung verursacht. Aus diesem Grund wurde das dominant-negative shibire Allel shits1, welches sich als geeigneter erwies, zur Blockierung der Lamina Interneurone verwendet, um die Notwendigkeit der jeweiligen Pfade zu analysieren. Um festzustellen, ob letztere auch hinreichend für das gleiche Verhalten waren, wurde für die umgekehrte Strategie die Tatsache ausgenutzt, daß die Lamina Interneurone Histaminrezeptoren exprimieren, die vom ort Gen kodiert werden. Die spezifische Rettung der ort Funktion in definierten Pfaden im mutanten Hintergrund ermöglichte festzustellen, ob sie für eine bestimmte Funktion hinreichend waren. Diese neurogenetischen Methoden wurden mit der optomotorischen Reaktion und dem objektinduzierten Orientierungsverhalten als Verhaltensmaß kombiniert, um folgende Fragen innerhalb dieser Doktorarbeit zu beantworten: (a) Welche Pfade stellen einen Eingang in elementare Bewegungsdetektoren dar und sind notwendig und/oder hinreichend für die Detektion gerichteter Bewegung? (b) Gibt es Pfade, die spezifisch Reaktionen auf unidirektionale Bewegung vermitteln? (c) Welche Pfade sind notwendig und/oder hinreichend für das objektinduzierte Orientierungsverhalten? Einige grundlegende Eigenschaften des visuellen Netzwerks konnten dabei aufgedeckt werden: Die zwei zentralen Cartridge Pfade, die von den großen Monopolarzellen L1 und L2 repräsentiert werden, haben eine Schlüsselfunktion bei der Bewegungsdetektion. Über ein breites Spektrum von Reizbedingungen hinweg sind die beiden Subsysteme redundant und können Bewegung unabhängig voneinander verarbeiten. Um eine Beeinträchtigung des Systems festzustellen, wenn nur einer der beiden Pfade intakt ist, muß dieses an die Grenzen seiner Leistungsfähigkeit gebracht werden. Bei niedrigem Signal/Rauschverhältnis, d.h. bei geringem Musterkontrast oder geringer Hintergrundbeleuchtung, hat der L2 Pfad eine höhere Sensitivität. Bei mittlerem Musterkontrast sind beide Pfade auf die Verarbeitung unidirektionaler Bewegung in entgegengesetzten Reizrichtungen spezialisiert. Im Gegensatz dazu sind weder der L3, noch der amc/T1 Pfad notwendig oder hinreichend für die Detektion von Bewegungen. Während der erstere Positionsinformation für Orientierungsverhalten zu verarbeiten scheint, nimmt der letztere eine modulatorische Rolle bei mittlerem Kontrast ein. Es stellte sich heraus, daß das Orientierungsverhalten noch robuster als das Bewegungssehen ist und möglicherweise auf einem weniger komplizierten Mechanismus beruht, da dieser keinen nichtlinearen Vergleich der Signale benachbarter visueller „sampling units“ benötigt. Die Fixation von Objekten setzt nicht grundsätzlich das Bewegungssehen voraus, allerdings verbessert die Detektion von Bewegung die Fixation von Landmarken, im besonderen, wenn diese schmal sind oder einen geringen Kontrast aufweisen. / Vertebrate and invertebrate visual systems exhibit similarities in early stages of visual processing. For instance, in the human brain, the modalities of color, form and motion are separately processed in parallel neuronal pathways. This basic property is also found in the fly Drosophila melanogaster which has a similar division in color- sensitive and (color blind) motion-sensitive pathways that are determined by two distinct subsets of photoreceptors (the R1-6 and the R7/8 system, respectively). Flies have a highly organized visual system that is characterized by its repetitive, retinotopic organization of four neuropils: the lamina, the medulla, the lobula and the lobula plate. Each of these consists of columns which contain the same set of neurons. In the lamina, axon bundles of six photoreceptors R1-6 that are directed towards the same point in space form columnar structures called cartridges. These are the visual sampling units and are associated with four types of first-order interneuron that receive common input from R1-6: L1, L2, L3 and the amacrine cells (amc, together with their postsynaptic partner T1). They constitute parallel pathways that have been studied in detail at the anatomical level. Little is known, however, about their functional role in processing behaviorally relevant information, e.g. for gaze stabilization, visual course control or the fixation of objects. The availability of a variety of neurogenetic tools for structure-function analysis in Drosophila allowed first steps into the genetic dissection of the neuronal circuitry mediating motion and position detection. In this respect, the choice of the effector turned out to be crucial. Surprisingly, it was found that the clostridial tetanus neurotoxin failed to block mature Drosophila photoreceptor synapses, but caused irreversible damage when expressed during their development. Therefore, the dominant-negative shibire allele shits1 which turned out to be better suited was used for blocking lamina interneurons and thereby analyzing the necessity of the respective pathways. To determine whether the latter were also sufficient for the same behavioral task, the inverse strategy was developed, based on the fact that lamina interneurons express histamine receptors encoded by the ort gene. The specific rescue of ort function in defined channels in an otherwise mutant background allowed studying their sufficiency in a given task. Combining these neurogenetic methods with the optomotor response and object induced orientation behavior as behavioral measures, the aim of the present thesis was to answer the following questions: (a) Which pathways feed into elementary motion detectors and which ones are necessary and/or sufficient for the detection of directional motion? (b) Do pathways exist which specifically mediate responses to unidirectional motion? (c) Which pathways are necessary and/or sufficient for object induced orientation behavior? Some basic properties of the visual circuitry were revealed: The two central cartridge pathways, represented by the large monopolar cells L1 and L2, are key players in motion detection. Under a broad range of stimulatory conditions, the two subsystems are redundant and are able to process motion independently of each other. To detect an impairment when only one of the pathways is intact, one has to drive the system to its operational limits. At low signal to noise ratios, i.e. at low pattern contrast or low background illumination, the L2 pathway has a higher sensitivity. At intermediate pattern contrast, both pathways are specialized in mediating responses to unidirectional motion of opposite stimulus direction. In contrast, neither the L3, nor the amc/T1 pathway is necessary or sufficient for motion detection. While the former may provide position information for orientation, the latter has a modulatory role at intermediate pattern contrast. Orientation behavior turned out to be even more robust than motion vision and may utilize a less sophisticated mechanism, as it does not require a nonlinear comparison of signals from neighboring visual sampling units. The position of objects is processed in several redundant pathways, involving both receptor subsystems. The fixation of objects does not generally require motion vision. However, motion detection improves the fixation of landmarks, especially when these are narrow or have a reduced contrast.

Genetik

Neurogenetik

Visuelles System

Bewegungssehen

Taufliege

Lamina

ddc:570

Role of emerin and protein kinase C in herpes simplex nuclear egress

Leach, Natalie

01 December 2010

The nuclear lamina consists of a mesh-like network of lamin proteins anchored to the inner nuclear membrane by interactions with integral membrane proteins such as emerin. Emerin binding to lamin A/C is one of the interactions that connect the inner nuclear membrane to the lamina. Infection by herpesviruses results in changes in the organization of the nuclear lamina, perhaps in order to facilitate envelopment of capsids at the inner nuclear membrane. In HSV-1 infected cells, alterations to the lamin proteins have been shown to involve pUL34, pUL31, and pUS3 proteins, which are also required for normal nuclear envelopment. We tested hypotheses about the mechanism and significance of lamina disruption. This thesis presents the following data. Infection of multiple cell types induced emerin hyperphosphorylation that was dependent on the presence of pUL34 and kinase active pUS3 proteins. The pUL34-dependent component was also sensitive to Rottlerin treatment suggesting that cellular kinases sensitive to Rottlerin were involved in emerin modification. LAP2 (another lamin associated protein) was de-modified (perhaps de-phosphorylated) in a pUS3 and pUL34 independent manner. Emerin was not required for growth of HSV-1. Hyperphosphorylation of emerin was required for its disassociation from the lamina. PKC family members have been implicated in the disruption of the nuclear lamina during herpesvirus nuclear egress. To test the hypothesis that PKC activity was required for viral replication, PKC activity was blocked with PKC inhibitors and dominate negative PKC constructs. Chemical inhibition of all PKC isoforms reduced viral growth five-fold and inhibited capsid egress from the nucleus. However, specific inhibition of either conventional PKCs or PKC delta did not inhibit viral growth. In addition to lamin associated proteins, lamin localization is also disrupted during herpesvirus infections. Emerin and lamin A/C are binding partners and the localization of both proteins is disrupted by pUS3 and cellular kinase mediated phosphorylation. To test the hypothesis that HSV-1-induced lamin A/C disruption is mediated via a mechanism similar to emerin's, pUS3 and Rottlerin Sensitive Kinases were inhibited and lamin A/C localization was observed. Unlike emerin, HSV-1-induced disruption of lamin A/C was not altered by Rottlerin Sensitive Kinase inhibition suggesting that HSV has multiple mechanisms for disruption of the lamina. Phosphorylation of lamina components, by Rottlerin Sensitive Kinases, may be a required event prior to primary envelopment. To test this hypothesis, growth of HSV-1 was tested in Rottlerin treated infected cells. Although the inhibitor Rottlerin, did reduce viral growth, it was also was also associated with severe depression of viral late-gene expression. TEM analysis suggested that Rottlerin Sensitive Kinases(s) were required for: (i) nuclear egress and (ii) capsid accumulation or formation supporting the hypothesis that the capsids were made in the presence of Rottlerin were unable to leave the nucleus. pUS3 is a multi-functional protein in alpha-herpesviruses. It has been implicated in lamina disruption, protecting the infected cell from apoptosis, and de-envelopment at the outer nuclear membrane. In BT-549 cells, a breast cancer cell line with low PKC delta expression, the hypothesis was tested that in the absence of cellular lamina disrupting kinases, an US3-null virus would be blocked at the lamina disruption step. In BT-549 cells, the US3-null (vRR1202) virus was 10-fold decreased above the typical 10-fold decrease, compared to WT virus, to produce a 100-fold decrease in infectious PFU yet apoptosis was not increased. Lamin A/C disruption occurred via similar mechanism in both breast cancer cell lines: BT-549 and MCF-7. Interestingly, in the BT-549 cells, emerin was extensively hyperphosphorylated in an US3-null infection, yet was not redistributed along the NE. These data support a model that one or more specific residue(s) must be phosphorylated for emerin disconnection from lamina.

emerin

herpes

LAP2

nuclear lamina

PKC

UL34

Cell Biology