TY  - THES
A1  - Hovhanyan, Anna
T1  - Functional analyses of Mushroom body miniature (Mbm) in growth and proliferation of neural progenitor cells in the central brain of Drosophila melanogaster
T1  - Funktionelle Analyse des Mushroom body minature (Mbm) in das Wachstum und die Proliferation von neuronalen Vorläuferzellen im zentralen Gehirn von Drosophila melanogaster
N2  - Zellwachstum und Zellteilung stellen zwei miteinander verknüpfte Prozesse dar, die dennoch grundsätzlich voneinander zu unterscheiden sind. Die Wiederaufnahme der Proliferation von neuralen Vorläuferzellen (Neuroblasten) im Zentralhirn von Drosophila nach der spät-embryonalen Ruhephase erfordert zunächst Zellwachstum. Der Erhalt der regulären Zellgröße ist eine wichtige Voraussetzung für die kontinuierliche Proliferation der Neuroblasten über die gesamte larvale Entwicklungsphase. Neben extrinsischen Ernährungssignalen ist für das Zellwachstum eine kontinuierliche Versorgung mit funktionellen Ribosomen notwendig, damit die Proteinsynthese aufrechterhalten werden kann.
Mutationen  im  mushroom  body  miniature  (mbm)  Gen  wurden  über  einen genetischen  Screen  nach  strukturellen  Gehirnmutanten  identifiziert.  Der  Schwerpunkt dieser Arbeit  lag in  der funktionellen  Charakterisierung des  Mbm  Proteins  als  neues nukleoläres Protein und damit seiner möglichen Beteiligung in der Ribosomenbiogenese. Der Vergleich der relativen Expressionslevel von Mbm und anderen nuklearen		Proteinen in verschiedenen Zelltypen zeigte eine verstärkte Expression von Mbm in der fibrillären Komponente des Nukleolus von Neuroblasten. Diese Beobachtung legte die Vermutung nahe, dass in Neuroblasten neben generell benötigten Faktoren der Ribosomenbiogenese auch	Zelltyp-spezifische	Faktoren	existieren.	Mutationen	in	mbm	verursachen Proliferationsdefekte von Neuroblasten, wirken sich jedoch nicht auf deren Zellpolarität, die  Orientierung  der  mitotischen  Spindel  oder  die  Asymmetrie  der  Zellteilung  aus. Stattdessen wurde eine Reduktion der Zellgröße beobachtet, was im Einklang mit einer Beeinträchtigung der Ribosomenbiogenese steht. Insbesondere führt der Verlust der Mbm Funktion zu einer Retention der kleinen ribosomalen Untereinheit im Nukleolus, was eine verminderte  Proteinsynthese  zur  Folge  hat.  Interessanterweise  wurden  Störungen  der Ribosomenbiogenese nur in den Neuroblasten beobachtet. Zudem ist Mbm offensichtlich nicht	erforderlich,	um	Wachstum		oder	die	Proliferation	von	Zellen	der Flügelimginalscheibe und S2-Zellen zu steuern, was wiederum dafür spricht, dass Mbm eine Neuroblasten-spezifische Funktion erfüllt.
Darüber hinaus wurden die transkriptionelle Regulation des mbm-Gens und die funktionelle Bedeutung von posttranslationalen Modifikationen analysiert. Mbm Transkription wird von dMyc reguliert. Ein gemeinsames Merkmal von dMyc Zielgenen ist das Vorhandensein einer konservierten „E-Box“-Sequenz in deren Promotorregionen. In
 
der Umgebung der mbm-Transkriptionsstartstelle befinden sich zwei „E-Box“-Motive. Mit Hilfe von Genreporteranalysen konnte nachgewiesen werden, dass nur eine von ihnen die dMyc-abhängige Transkription vermittelt. Die dMyc-abhängige Expression von Mbm konnte auch in Neuroblasten verifiziert werden.
Auf posttranslationaler Ebene wird Mbm durch die Proteinkinase CK2 phosphoryliert. In der C-terminalen Hälfte des Mbm Proteins wurden in zwei Clustern mit einer Abfolge von sauren Aminosäuren sechs Serin- und Threoninreste als CK2- Phosphorylierungsstellen identifiziert. Eine Mutationsanalyse dieser Stellen bestätigte deren Bedeutung für die Mbm Funktion in vivo. Weiterhin ergaben sich Evidenzen, dass die Mbm-Lokalisierung durch die CK2-vermittelte Phosphorylierung gesteuert wird.
Obwohl die genaue molekulare Funktion von Mbm in der Ribosomenbiogenese noch im Unklaren ist, unterstreichen die Ergebnisse dieser Studie die besondere Rolle von Mbm in der Ribosomenbiogenese von Neuroblasten um Zellwachstum und Proliferation zu regulieren.
N2  - Cell growth and cell division are two interconnected yet distinct processes. Initiation of  proliferation of  central brain progenitor  cells (neuroblasts)  after  the  late embryonic quiescence stage requires cell growth, and maintenance of proper cell size is an important prerequisite for continuous larval neuroblast proliferation. Beside extrinsic nutrition signals, cell growth requires constant supply with functional ribosomes to maintain protein synthesis.
Mutations in the mushroom body miniature (mbm) gene were previously identified in a screen for structural brain mutants. This study focused on the function of the Mbm protein as a new nucleolar protein, which is the site of ribosome biogenesis. The comparison of the relative expression levels of Mbm and other nucleolar proteins in different cell types showed a pronounced expression of Mbm in neuroblasts, particularly in the fibrillar component of the nucleolus, suggesting that in addition to nucleolar components generally required for ribosome biogenesis, more neuroblast specific nucleolar factors exist. Mutations in mbm cause neuroblast proliferation defects but do not interfere with cell polarity, spindle orientation or asymmetry of cell division of neuroblasts.  Instead a reduction in cell size was observed, which correlates with an impairment of ribosome biogenesis. In particular, loss of Mbm leads to the retention of the small ribosomal subunit in the nucleolus resulting in decreased protein synthesis. Interestingly, the defect in ribosome biogenesis was only observed in neuroblasts. Moreover, Mbm is apparently not required for cell size and proliferation control in wing imaginal disc and S2 cells supporting the idea of a neuroblast-specific function of Mbm.
Furthermore, the transcriptional regulation of the mbm gene and the functional relevance of posttranslational modifications were analyzed. Mbm is a transcriptional target of dMyc. A common feature of dMyc target genes is the presence of a conserved E-box sequence in their promoter regions. Two E-box motifs are found in the vicinity of the transcriptional start site of mbm. Gene reporter assays verified that only one of them mediates dMyc-dependent transcription. Complementary studies in flies showed that removal of dMyc function in neuroblasts resulted in reduced Mbm expression levels.
At the posttranslational level, Mbm becomes phosphorylated by protein kinase CK2. Six serine and threonine residues located in two acidic amino acid rich clusters in the C-terminal  half  of  the  Mbm  protein  were  identified  as  CK2  phosphorylation  sites.
 
Mutational analysis of these sites verified their importance for Mbm function in vivo and indicated that Mbm localization is controlled by CK2-mediated phosphorylation.
Although the molecular function of Mbm in ribosome biogenesis remains to be determined, the results of this study emphasize the specific role of Mbm in neuroblast ribosome biogenesis to control cell growth and proliferation.
KW  - Taufliege
KW  - Mbm
KW  - Neuroblast
KW  - cell growth
KW  - proliferation
KW  - ribosome biogenesis
KW  - CK2
KW  - Myc
KW  - Vorläuferzellen
KW  - Drosophila melanogaster
Y1  - 2014
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-91303
ER  - 
TY  - JOUR
A1  - Beck, Katherina
A1  - Hovhanyan, Anna
A1  - Menegazzi, Pamela
A1  - Helfrich-Förster, Charlotte
A1  - Raabe, Thomas
T1  - Drosophila RSK Influences the Pace of the Circadian Clock by Negative Regulation of Protein Kinase Shaggy Activity
JF  - Frontiers in Molecular Neuroscience
N2  - Endogenous molecular circadian clocks drive daily rhythmic changes at the cellular, physiological, and behavioral level for adaptation to and anticipation of environmental signals. The core molecular system consists of autoregulatory feedback loops, where clock proteins inhibit their own transcription. A complex and not fully understood interplay of regulatory proteins influences activity, localization and stability of clock proteins to set the pace of the clock. This study focuses on the molecular function of Ribosomal S6 Kinase (RSK) in the Drosophila melanogaster circadian clock. Mutations in the human rsk2 gene cause Coffin–Lowry syndrome, which is associated with severe mental disabilities. Knock-out studies with Drosophila ortholog rsk uncovered functions in synaptic processes, axonal transport and adult behavior including associative learning and circadian activity. However, the molecular targets of RSK remain elusive. Our experiments provide evidence that RSK acts in the key pace maker neurons as a negative regulator of Shaggy (SGG) kinase activity, which in turn determines timely nuclear entry of the clock proteins Period and Timeless to close the negative feedback loop. Phosphorylation of serine 9 in SGG is mediated by the C-terminal kinase domain of RSK, which is in agreement with previous genetic studies of RSK in the circadian clock but argues against the prevailing view that only the N-terminal kinase domain of RSK proteins carries the effector function. Our data provide a mechanistic explanation how RSK influences the molecular clock and imply SGG S9 phosphorylation by RSK and other kinases as a convergence point for diverse cellular and external stimuli.
KW  - circadian clock
KW  - Period
KW  - Timeless
KW  - Shaggy kinase
KW  - RSK
KW  - Coffin–Lowry syndrome
Y1  - 2018
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-196034
SN  - 1662-5099
VL  - 11
IS  - 122
ER  - 
TY  - JOUR
A1  - Dapergola, Eleni
A1  - Menegazzi, Pamela
A1  - Raabe, Thomas
A1  - Hovhanyan, Anna
T1  - Light Stimuli and Circadian Clock Affect Neural Development in Drosophila melanogaster
JF  - Frontiers in Cell and Developmental Biology
N2  - Endogenous clocks enable organisms to adapt cellular processes, physiology, and behavior to daily variation in environmental conditions. Metabolic processes in cyanobacteria to humans are under the influence of the circadian clock, and dysregulation of the circadian clock causes metabolic disorders. In mouse and Drosophila, the circadian clock influences translation of factors involved in ribosome biogenesis and synchronizes protein synthesis. Notably, nutrition signals are mediated by the insulin receptor/target of rapamycin (InR/TOR) pathways to regulate cellular metabolism and growth. However, the role of the circadian clock in Drosophila brain development and the potential impact of clock impairment on neural circuit formation and function is less understood. Here we demonstrate that changes in light stimuli or disruption of the molecular circadian clock cause a defect in neural stem cell growth and proliferation. Moreover, we show that disturbed cell growth and proliferation are accompanied by reduced nucleolar size indicative of impaired ribosomal biogenesis. Further, we define that light and clock independently affect the InR/TOR growth regulatory pathway due to the effect on regulators of protein biosynthesis. Altogether, these data suggest that alterations in InR/TOR signaling induced by changes in light conditions or disruption of the molecular clock have an impact on growth and proliferation properties of neural stem cells in the developing Drosophila brain.
KW  - neuroblast growth
KW  - proliferation
KW  - circadian clock
KW  - light stimuli
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-231049
SN  - 2296-634X
VL  - 9
ER  -