The Role of Pumilio 2 in Axonal Outgrowth

Sarkis, Dani

26 November 2012

Pumilio 2 (PUM2) is a member of the Puf family of mRNA binding proteins and translational regulators which are involved in various processes including embryonic patterning and memory formation. Nevertheless, its functions in the outgrowth of neuronal axons have not been studied. This study shows endogenous expression of PUM2 in neurites of dorsal root ganglia (DRG) neurons and transport of PUM2 along retinal ganglion cell (RGC) axons and their growth cones. Overexpression of PUM2 in DRG neurons resulted in shorter axons when compared to control neurons. Expression of either dominant negative mutation (dnPUM2) or PUM2W349G displayed a reduction in axonal length. PUM2 downregulation with microRNA (miRNA) also caused a reduction in neurite length compared to control neurons. Finally, PUM2 silencing did not alter eye size at E4, which allows investigation of axonal outgrowth in RGC in vivo. These results suggest a novel role for PUM2 in axonal outgrowth.

Pumilio 2

Axonal outgrowth

Translational regulation

0719

0307

0317

Study of Assembly and Function of the DrrAB Complex

Pradhan, Prajakta A

30 November 2008

The DrrAB proteins of Streptomyces peucetius belong to the ABC family of ubiquitous membrane transporters. The DrrA and DrrB proteins together form a drug efflux pump that carries out the transport of the anticancer drug doxorubicin by carrying out ATP hydrolysis. The present study is the first where the intrinsic factors involved in the assembly of the DrrAB functional complex have been elucidated. The drrA and drrB genes in the wild type operon have overlapping stop and start codons (ATGA) which indicates translational coupling between the two genes. On insertion of a fortuitous stop codon in DrrA it was shown that the expression of DrrB is coupled to that of the upstream gene drrA. Furthermore, it was observed that a functional complex could be achieved only when the genes were maintained in cis in a translationally coupled manner. Translational regulation in DrrA was found to be involved in the control of optimal levels of DrrB. Inhibitory interactions within drrA sequence were speculated to cause translational arrest at the C terminus of DrrA. A novel assembly domain that forms the interface between DrrA containing the Nucleotide Binding Domain (NBD) and DrrB comprising the TransMembrane Domain (TMD) was found. Based on the data presented in this study a model is proposed for the biogenesis of the DrrAB drug pump. The model suggests that translational coupling between DrrA and DrrB is crucial for functional complex formation. Further, there is evidence of regulation of translation by attenuation in the intergenic region of drrA and drrB. The regulation seems to involve the last 30 nucleotides of the mRNA of drrA and some upstream sequences within drrA that cause translational arrest within the C terminus of DrrA. Since DrrB is translationally coupled to drrA, this translational arrest in conjunction with coupling causes lowering in the levels of DrrB. Finally, since the DrrA-DrrB interaction domain lies in the C terminus of DrrA, only the fully translated DrrA product will be competent to form a complex with DrrB. This interaction between the C terminus of DrrA and the N terminus of DrrB may be crucial for initial targeting of the complex to the membrane. The model is expected to serve as primer and open up an interesting yet insufficiently understood subject of membrane protein biogenesis.

membrane protein biogenesis

Trans

Cis

Translational coupling

Biology, general

Association of YY1 with maternal mRNAs in oocyte mRNPs

Belak, Zachery Roderick

01 March 2011

Early embryonic development in vertebrates is directed in part by maternal mRNAs expressed in oocytes and stored in cytoplasmic messenger ribonucleoprotein particles (mRNPs). Abundant evidence demonstrates the importance of mRNPs in embryonic development and in post-embryonic cellular function; however their characterization has been hampered by lack of suitable methodologies. The Xenopus oocyte has been the primary model system for studies of mRNPs. YY1 is a well-studied transcriptional regulatory factor that is sequestered in the oocyte cytoplasm and present entirely in cytoplasmic oocyte mRNPs. The objective of this thesis was to examine the biochemistry of YY1 association with maternal mRNA molecules in order to shed light on the role of YY1 in development and the poorly understood biology of oocyte mRNPs. The initial working hypotheses were that association of YY1 with mRNPs is dependent on sequence-specific RNA-binding activity and, therefore, that YY1 associates with a definite subset of maternal mRNA. A number of unique methods were developed in this study to address these hypotheses. RNA immunoprecipitation-DNA microarray (RIP-CHIP) analysis establishes that YY1 associates with a subset of mRNAs in the oocyte pool. A novel sequence-specific RNA-binding activity of the YY1 protein is demonstrated, and the RNA-binding activity of YY1 is shown to be required for its association with oocyte mRNPs in vivo. The functional roles of YY1 mRNA substrates are discussed in the context of embryological development and the biological function of YY1 in oocyte mRNPs. Extension of the experimental approaches developed in this thesis to the entire set of mRNP proteins would significantly advance our understanding of mRNP composition and heterogeneity, as well as the biological function of maternal mRNAs and mRNPs in development.

RNA storage

translational regulation

oocyte

mRNA

Xenopus

mRNP

YY1

Mathematical Analysis of a Biological Clock Model

Ohlsson, Henrik

January 2006

Have you thought of why you get tired or why you get hungry? Something in your body keeps track of time. It is almost like you have a clock that tells you all those things. And indeed, in the suparachiasmatic region of our hypothalamus reside cells which each act like an oscillator, and together form a coherent circadian rhythm to help our body keep track of time. In fact, such circadian clocks are not limited to mammals but can be found in many organisms including single-cell, reptiles and birds. The study of such rhythms constitutes a field of biology, chronobiology, and forms the background for my research and this thesis. Pioneers of chronobiology, Pittendrigh and Aschoff, studied biological clocks from an input-output view, across a range of organisms by observing and analyzing their overt activity in response to stimulus such as light. Their study was made without recourse to knowledge of the biological underpinnings of the circadian pacemaker. The advent of the new biology has now made it possible to "break open the box" and identify biological feedback systems comprised of gene transcription and protein translation as the core mechanism of a biological clock. My research has focused on a simple transcription-translation clock model which nevertheless possesses many of the features of a circadian pacemaker including its entrainability by light. This model consists of two nonlinear coupled and delayed differential equations. Light pulses can reset the phase of this clock, whereas constant light of different intensity can speed it up or slow it down. This latter property is a signature property of circadian clocks and is referred to in chronobiology as "Aschoff's rule". The discussion in this thesis focus on develop a connection and also a understanding of how constant light effect this clock model.

Circadian

Methods of Multiple Scales

Transcriptional Translational Process

Automatic control

Reglerteknik

Association of YY1 with maternal mRNAs in oocyte mRNPs

Belak, Zachery Roderick

01 March 2011

Early embryonic development in vertebrates is directed in part by maternal mRNAs expressed in oocytes and stored in cytoplasmic messenger ribonucleoprotein particles (mRNPs). Abundant evidence demonstrates the importance of mRNPs in embryonic development and in post-embryonic cellular function; however their characterization has been hampered by lack of suitable methodologies. The Xenopus oocyte has been the primary model system for studies of mRNPs. YY1 is a well-studied transcriptional regulatory factor that is sequestered in the oocyte cytoplasm and present entirely in cytoplasmic oocyte mRNPs. The objective of this thesis was to examine the biochemistry of YY1 association with maternal mRNA molecules in order to shed light on the role of YY1 in development and the poorly understood biology of oocyte mRNPs. The initial working hypotheses were that association of YY1 with mRNPs is dependent on sequence-specific RNA-binding activity and, therefore, that YY1 associates with a definite subset of maternal mRNA. A number of unique methods were developed in this study to address these hypotheses. RNA immunoprecipitation-DNA microarray (RIP-CHIP) analysis establishes that YY1 associates with a subset of mRNAs in the oocyte pool. A novel sequence-specific RNA-binding activity of the YY1 protein is demonstrated, and the RNA-binding activity of YY1 is shown to be required for its association with oocyte mRNPs in vivo. The functional roles of YY1 mRNA substrates are discussed in the context of embryological development and the biological function of YY1 in oocyte mRNPs. Extension of the experimental approaches developed in this thesis to the entire set of mRNP proteins would significantly advance our understanding of mRNP composition and heterogeneity, as well as the biological function of maternal mRNAs and mRNPs in development.

RNA storage

translational regulation

oocyte

mRNA

Xenopus

mRNP

YY1

Functions of human post-translationally modified SUMO proteins under stresses

Chen, Yi-Ling

06 July 2003

Abstract Human ubiquitin-like SUMO-1/2/3 proteins have been identified. The 3-D structure of the SUMO-1 has been shown to be very similar to that of ubiquitin, although their sequences share only 18 % identity. Unlike ubiquitination targets proteins for degradation, sumoylation appears to regulate a number of cellular processes such as protein-protein interaction, subcellular localization, protein stability, apoptosis, cell cycle and so on . Our laboratory has cloned cDNAs encoding human SUMO-2, mouse SUMO-2 and SUMO-3, as well as a single SUMO gene from nematode and Drosophila. Recently (Su & Li, Gene 296:65-73,2002), Su & Li have performed data-mining on current human genomic sequence and found the presence of only three SUMO-1/2/3 functional genes located at chromosome no. 2q33, 17q25.1 and 21q22.3, respectively, as well as eight SUMO-1 pseudogenes and 23 SUMO-2 pseudogenes. The protein-coding sequence of SUMO-1 gene is interrupted by four introns , while those of SUMO-2/3 genes are interrupted by only three introns. In this study , most of SUMO-1/2/3 proteins were show to be localized on nuclear membrane, nuclear bodies and cytoplasm, respectively. The N-terminus-deleted SUMO-1 proteins was further shown to be localized on nuclear membrane and in cytosol, while the mutant SUMO-2/3 proteins were localized only in the cytosol. The inactive precursor form of SUMO-3 was exclusively localized in the cytosol. The activation of SUMO-3 in HeLa cells was triggered by actinomycin D and its location was shifted from cytosol to nucleus. Further, the inactive precursor of SUMO-3 was reduced in HeLa cells treated with nocodazole and arsenic trioxide.

human

ubiquitin

SUMO-1/2/3

stresses

post-translational modification

Post-translational regulation of myocyte enhancer factor 2 (MEF2) /

Du, Min.

January 2008

Thesis (Ph.D.)--York University, 2008. Graduate Programme in Biology. / Typescript. Includes bibliographical references (leaves 182-202). Also available on the Internet. MODE OF ACCESS via web browser by entering the following URL: http://gateway.proquest.com/openurl?url_ver=Z39.88-2004&res_dat=xri:pqdiss&rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation&rft_dat=xri:pqdiss:NR39002

The role of collaborative reflection in a faculty community

Cestone, Christina Marie

16 March 2015

A faculty community is a type of learning community where faculty learning and development is the focus. Previous research suggests that formally structured faculty communities promoted faculty engagement, improved teaching, thwarted career burnout, increased retention of experienced faculty, and fostered organizational change. Researchers have not examined faculty communities embedded in the workplace and the longitudinal effects these communities have on mid-career and senior faculty learning. In this study, I examined how an experienced interprofessional faculty community of medical and biomedical professionals managed the implementation of a novel graduate curriculum in translational sciences. Translational sciences education aims to enhance the collaborations between scientists and clinicians for the advancement of patient treatment and care. I focused on how faculty advanced their individual and collective understanding of the curriculum implementation using collaborative reflection during weekly community interactions. The study began at the start of the curriculum implementation and lasted fifteen months. It was a qualitative, ethnographic case study including three sources of data: naturalistic observation of teaching and faculty meetings, faculty interviews, and community artifacts. Two theoretical frameworks undergirded the design of the study: community of practice and distributed cognition. The results of the study suggest that collaborative reflection in the faculty community promoted faculty learning over time in several areas: teaching and instruction, assessment and evaluation, individual knowledge, student learning, and organizational and leadership skills. Collaborative reflection occurred in response to multiple episodes that occurred during curriculum implementation, but was focused primarily on facets of instruction, which was the dominant work of the community. Collaborative reflection enabled decision-making on instructional content and process, pedagogical content and process, and curricular content. A cyclical process of instructional development emerged in the community including: session planning, implementation, collective teaching observation, and collective instructional evaluation. Attributes of the community that emerged to support collaborative reflection included: shared goals, domain knowledge, and mutual trust. The community provided a shared social context for systematic collaborative reflection and scaffolding in instructional development. The study findings represent a specific set of experiences that may inform a model of instructional development for use with interprofessional faculty communities in academic health centers. / text

Collaborative reflection

Translational sciences

Faculty development

Learning communities

Investigation of Post-Translational Modification and Function of the Yeast Plasmid Partitioning Proteins Rep1 and Rep2

Pinder, Jordan Benjamin

04 October 2011

The 2-micron circle of Saccharomyces cerevisiae is one of a small number of similar DNA plasmids found only in budding yeast. To understand how this cryptic parasite persists, despite conferring no advantage to the host, I investigated the plasmid-encoded Rep1 and Rep2 proteins. Interaction of Rep1 and Rep2 with each other and with the plasmid STB locus is required for equal partitioning of plasmid copies at mitosis. The Rep proteins also repress expression of Flp, the recombinase that mediates plasmid copy-number amplification. In this study, absence of Rep1 and Rep2, or over-expression of the plasmid-encoded Raf antirepressor, increased expression of a longer, novel FLP transcript. Translation of this mRNA may explain elevated Flp activity at low plasmid copy number. Raf competed for Rep2 selfassociation and interaction with Rep1, suggesting the mechanism of Raf anti-repression. Deletion analysis identified a target site for Rep protein repression of FLP that is also repeated in the STB locus, suggesting this as the sequence required for Rep protein association with both regions of the plasmid. Distinct roles for Rep1 and Rep2 were identified; Rep1 was found to depend on Rep2 for post-translational stability, with Rep2 dependent on Rep1 for stable association with STB. Lysine-to-arginine substitutions in Rep1 and Rep2 impaired their association with the host covalent-modifier protein SUMO, suggesting these were sites of sumoylation. The substitutions did not affect interaction of the Rep proteins with each other or their stability but did perturb plasmid inheritance, suggesting that Rep protein sumoylation contributes to their plasmid partitioning function. When Rep1 was mutant, both Rep proteins lost their normal localization to the nuclear foci where 2-micron plasmids cluster, and were impaired for association with STB, supporting this as the cause of defective plasmid inheritance. The potential sumoylation-dependent association of the Rep proteins with the 2-micron plasmid partitioning locus suggests the plasmid has acquired a strategy common to eukaryotic viral and host genomes that depend on sumoylation of their segregation proteins for faithful inheritance. Collectively, my results shed light on how the 2-micron plasmid maintains the delicate balance of persisting without harming its host.

SUMO

chromosome segregation

post-translational modification

protein phosphorylation

gene expression

Dynamic interactions during ribosome targeting to the membrane

Lee, Sejeong

19 May 2014

No description available.

570

Biologie (PPN619462639)