@phdthesis{Scholl2015,
  author    = {Scholl, Christina},
  title     = {Cellular and molecular mechanisms contributing to behavioral transitions and learning in the honeybee},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-115527},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {The honeybee Apis mellifera is a social insect well known for its complex behavior and the ability to learn tasks associated with central place foraging, such as visual navigation or to learn and remember odor-reward associations. Although its brain is smaller than 1mm² with only 8.2 x 105 neurons compared to ~ 20 x 109 in humans, bees still show amazing social, cognitive and learning skills. They express an age - related division of labor with nurse bees staying inside the hive and performing tasks like caring for the brood or cleaning, and foragers who collect food and water outside the hive. This challenges foragers with new responsibilities like sophisticated navigation skills to find and remember food sources, drastic changes in the sensory environment and to communicate new information to other bees. Associated with this plasticity of the behavior, the brain and especially the mushroom bodies (MBs) - sensory integration and association centers involved in learning and memory formation - undergo massive structural and functional neuronal alterations. Related to this background my thesis on one hand focuses on neuronal plasticity and underlying molecular mechanisms in the MBs that accompany the nurse - forager transition. In the first part I investigated an endogenous and an internal factor that may contribute to the nurse - forager phenotype plasticity and the correlating changes in neuronal network in the MBs: sensory exposure (light) and juvenile hormone (JH). Young bees were precociously exposed to light and subsequently synaptic complexes (microglomeruli, MG) in the MBs or respectively hemolymph juvenile hormone (JH) levels were quantified. The results show that light input indeed triggered a significant decrease in MG density, and mass spectrometry JH detection revealed an increase in JH titer. Interestingly light stimulation in young bees (presumably nurse bees) triggered changes in MG density and JH levels comparable to natural foragers. This indicates that both sensory stimuli as well as the endocrine system may play a part in preparing bees for the behavioral transition to foraging. Considering a connection between the JH levels and synaptic remodeling I used gene knockdown to disturb JH pathways and artificially increase the JH level. Even though the knockdown was successful, the results show that MG densities remained unchanged, showing no direct effect of JH on synaptic restructuring. To find a potential mediator of structural synaptic plasticity I focused on the calcium-calmodulin-dependent protein kinase II (CaMKII) in the second part of my thesis. CaMKII is a protein known to be involved in neuronal and behavioral plasticity and also plays an important part in structural plasticity reorganizing synapses. Therefore it is an interesting candidate for molecular mechanisms underlying MG reorganization in the MBs in the honeybee. Corresponding to the high abundance of CaMKII in the learning center in vertebrates (hippocampus), CaMKII was shown to be enriched in the MBs of the honeybee. Here I first investigated the function of CaMKII in learning and memory formation as from vertebrate work CaMKII is known to be associated with the strengthening of synaptic connections inducing long term potentiation and memory formation. The experimental approach included manipulating CaMKII function using 2 different inhibitors and a specific siRNA to create a CaMKII knockdown phenotype. Afterwards bees were subjected to classical olfactory conditioning which is known to induce stable long-term memory. All bees showed normal learning curves and an intact memory acquisition, short-term and mid-term memory (1 hour retention). However, in all cases long-term memory formation was significantly disrupted (24 and 72 hour retention). These results suggests the necessity of functional CaMKII in the MBs for the induction of both early and late phases of long-term memory in honeybees. The neuronal and molecular bases underlying long-term memory and the resulting plasticity in behavior is key to understanding higher brain function and phenotype plasticity. In this context CaMKII may be an important mediator inducing structural synaptic and neuronal changes in the MB synaptic network.},
  subject      = {Biene},
  language  = {en}
}
@phdthesis{Boehm2015,
  author    = {B{\"o}hm, Jennifer},
  title     = {Die N{\"a}hrstoffresorption in den Fallen von Dionaea muscipula weist Parallelen zur N{\"a}hrsalzaufnahme in Wurzeln auf},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-123958},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {Die Venusfliegenfalle, Dionaea muscipula, weckte aufgrund ihrer karnivoren Lebensweise schon sehr fr{\"u}h das Interesse vieler Wissenschaftler. F{\"u}r karnivore Pflanzen, die auf N{\"a}hrstoff-armen B{\"o}den wachsen, spielen Insekten als Beute und somit als N{\"a}hrstofflieferant eine entscheidende Rolle. So k{\"o}nnen die Pflanzen durch die Verdauung der Beute mit wichtigen Makro- und Mikron{\"a}hrstoffen, wie Stickstoff, Phosphat, Kalium oder Natrium versorgt werden. Aus diesem Grund sollte im Rahmen meiner Arbeit ein besonderes Augenmerk auf die molekularen Mechanismen der Kationenaufnahme w{\"a}hrend der N{\"a}hrstoffresorption gerichtet werden. Insbesondere die aus dem Insekt stammenden N{\"a}hrstoffe Kalium und Natrium waren dabei von großem Interesse. Im Allgemeinen sind Kaliumionen f{\"u}r Pflanzen eine essentielle anorganische Substanz und von großer physiologischer Bedeutung f{\"u}r die Entwicklung, den Metabolismus, die Osmoregulation, das Membranpotential und viele zellul{\"a}re Prozesse. Analysen der Kaliumaufnahme an Wurzeln von Modellpflanzen wie Arabidopsis thaliana und Reis zeigten, dass die Aufnahme von K+ ein Zusammenspiel von hoch-affinen K+-Transportern der HAK5-Familie und nieder-affinen Kaliumkan{\"a}len (AKT1/AtKC1) erfordert, die in ein komplexes (De-)Phosphorylierungsnetzwerk eingebunden sind. In der vorliegenden Arbeit war es mir m{\"o}glich das Netzwerk zur Kaliumaufnahme in den Dr{\"u}sen der Venusfliegenfalle zu entschl{\"u}sseln. Es konnten Orthologe zum Kaliumtransporter HAK5 aus Arabidopsis (DmHAK5) und zum Kaliumkanal AKT1 (DmKT1) identifiziert und im heterologen Expressionssystem der Xenopus laevis Oozyten elektrophysiologisch charakterisiert werden. Dabei zeigte sich, das DmKT1 durch einen Ca2+-Sensor/Kinase-Komplex aus der CBL/CIPK-Familie phosphoryliert und somit aktiviert wird. Phylogenetische Analysen von DmKT1 best{\"a}tigten die Eingruppierung dieses Kaliumkanals in die Gruppe der pflanzlichen Shaker-Kaliumkan{\"a}le des AKT1-Typs. Die Transporteigenschaften zeigten zudem, dass DmKT1 bei hyperpolarisierenden Membranpotentialen aktiviert wird und einen K+-selektiven Einw{\"a}rtsstrom vermittelt. In Oozyten konnte eine Kaliumaufnahme bis zu einer externen Konzentration von ≥1 mM beobachtet werden. DmKT1 repr{\"a}sentiert also einen Kaliumkanal mit einer hohen Transportkapazit{\"a}t, der die nieder-affine Kaliumaufnahme in die Dr{\"u}senzellen der Venusfliegenfalle vermitteln kann. Unterhalb einer externen Kaliumkonzentration von 1 mM w{\"u}rde der anliegende elektrochemische Kaliumgradient einen Kaliumausstrom und somit einen Verlust von Kalium favorisieren. Hoch-affine K+/H+-Symporter k{\"o}nnen durch die Ausnutzung des Protonengradienten eine Kaliumaufnahme im mikromolaren Bereich gew{\"a}hrleisten. In Wurzelhaaren von Arabidopsis vermittelt der Transporter AtHAK5 die Kaliumaufnahme unter Kaliummangelbedingungen. DmHAK5, ein Ortholog zu AtHAK5, ist in Dionaea Dr{\"u}sen exprimiert und konnte zum ersten Mal im heterologen Expressionssystem der Xenopus Oozyten im Detail charakterisiert werden. Interessanterweise zeigte sich, dass DmHAK5 wie der K+-Kanal DmKT1 durch denselben CBL/CIPK-Komplex posttranslational reguliert und aktiviert wird. Die Transporteigenschaften von DmHAK5 wiesen auf einen Transporter mit einer breiten Substratspezifit{\"a}t hin, sodass sich DmHAK5 neben Kalium auch f{\"u}r Ammonium permeabel zeigte. Affinit{\"a}tsuntersuchungen von DmHAK5 zu seinem Substrat Kalium klassifizierten das Protein als einen hoch-affinen Kaliumtransporter, der im Symport mit Protonen die Kaliumaufnahme im mikromolaren Konzentrationsbereich vermitteln kann. Das Kaliumtransportmodul besteht also aus dem K+-selektiven Kanal DmKT1 und dem K+/H+-Symporter DmHAK5, die die hoch- und nieder-affine Kaliumaufnahme in den Dr{\"u}senzellen w{\"a}hrend der Beuteverdauung in Dionaea muscipula Fallen erm{\"o}glichen. Beide Transportmodule werden Kalzium-abh{\"a}ngig durch die Kinase CIPK23 und den Ca2+-Sensor CBL9 auf posttranslationaler Ebene reguliert. Zusammenfassend gelang es in dieser Arbeit Einblicke in die Kationenaufnahme w{\"a}hrend der N{\"a}hrstoffresorptionsphase der Venusfliegenfalle, Dionaea muscipula, zu gewinnen. Dabei wurde klar, dass Dionaea muscipula im Laufe ihrer Evolution zu einer karnivoren Pflanze, nicht neue Transportmodule zur N{\"a}hrstoffresorption aus der Beute entwickelte, sondern bekannte aus Wurzeln stammende Transportmodule umfunktionierte. Auf molekularer Ebene konnten die biophysikalischen Charakteristika der K+- und Na+-Transportproteine, sowie ihre Regulation entschl{\"u}sselt werden. Diese Erkenntnisse wurden schließlich in den Kontext des Beutefangs der Venusfliegenfalle gebracht und diskutiert.},
  subject      = {Venusfliegenfalle},
  language  = {de}
}
@phdthesis{AnjanaVaman2015,
  author    = {Anjana Vaman, Vamadevan Sujatha},
  title     = {LASP1, a newly identified melanocytic protein with a possible role in melanin release, but not in melanoma progression},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-116316},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {LIM and SH3 protein 1 (LASP1) is a nucleocytoplasmic scaffolding protein. LASP1 interacts with various cytoskeletal proteins via its domain structure and is known to participate in physiological processes of cells. In the present study, a detailed investigation of the expression pattern of LASP1 protein in normal skin, melanocytic nevi and melanoma was carried out and the melanocyte-specific function of LASP1 was analyzed. LASP1 protein was identified in stratum basale of skin epidermis and a very high level was detected in nevi, the benign tumor of melanocyte. In the highly proliferative basal cells, an additional distinct nuclear localization of the protein was noted. In different tumor entities, an elevated LASP1 expression and nuclear localization, correlated positively with malignancy and tumor grade. However, LASP1 level was determined to be very low in melanoma and even reduced in metastases. Melanoma is distinguished as the first tumor tested to date - that displayed an absence of elevated LASP1 expression. In addition no significant relation was observed between LASP1 protein expression and clinicopathological parameters in melanoma. The epidermal melanin unit of skin comprises of melanocytes and keratinocytes. Melanocytes are specialized cells that synthesize the photo protective coloring pigment, melanin inside unique organelles called melanosomes. The presence of LASP1 in melanocytes is reported for the first time through this study and the existence was confirmed by immunoblotting analysis in cultured normal human epidermal melanocyte (NHEM) and in melanoma cell lines, along with the immunohistostaining imaging in normal skin and in melanocytic nevi. LASP1 depletion in MaMel2 cells revealed a moderate increase in the intracellular melanin level independently of de novo melanogenesis, pointing to a partial hindrance in melanin release. Immunofluorescence images of NHEM and MaMel2 cells visualized co-localization of LASP1 with dynamin and tyrosinase concomitant with melanosomes at the dendrite tips of the cells. Melanosome isolation experiments by sucrose density gradient centrifugation clearly demonstrated the presence of LASP1 and the melanosome specific markers tyrosinase and TRP1 in late stage melanosomes. The study identified LASP1 and dynamin as novel binding partners in melanocytes and provides first evidence for the existence of LASP1 and dynamin (a protein well-known for its involvement in vesicle formation and budding) in melanosomes. Co-localization of LASP1 and dynamin along the dendrites and at the tips of the melanocytes indicates a potential participation of the two proteins in the membrane vesicle fission at the plasma membrane. In summary, a possible involvement of LASP1 in the actin-dynamin mediated membrane fission and exocytosis of melanin laden melanosome vesicles into the extracellular matrix is suggested.},
  subject      = {Melanom},
  language  = {en}
}