Papel do miR-29a na regulação epigenética de células pluripotentes humanas / The role of miR-29a in epigenetic regulation of human pluripotent cells

Leite, Sarah Blima Paulino

31 August 2017

As células-tronco embrionárias (CTEs), extraídas da massa celular interna do blastocisto, tem como características principais a capacidade de auto-renovação e a pluripotência. Durante o desenvolvimento, as células perdem seu potencial de diferenciação e adquirem um perfil de expressão gênica mais restrito, modulado por mecanismos epigenéticos, assim como por microRNAs. Membros da família miR-29 têm como transcritos alvos enzimas responsáveis pela metilação da citosina em 5mC (DNMT3a e 3b) e também da desmetilação (TET1, 2 e 3) do DNA, pela hidroxilação de 5mC em 5hmC. Recentes trabalhos sugerem que a modulação do miR-29 sobre estes alvos teria um papel no início da diferenciação em CTEs de camundongos e no aumento de eficiência da geração de iPS em células humanas. No presente trabalho, buscou-se compreender o papel regulatório do miR-29a em seus alvos epigenéticos no contexto da pluripotência e no início da diferenciação com atRA. Para tanto, duas linhagens celulares pluripotentes humanas (H1 e NTera- 2) foram submetidas a indução de diferenciação com atRA e ao ganho de função do miR-29a durante quatro dias de cultivo para análises de expressão gênica. Ademais, em NT2, realizamos ensaios funcionais por microscopia de imunofluorescência quantitativa para avaliar os efeitos do ganho e perda de função do miR-29a, DNMT3b e TET1, sobre a expressão nuclear de OCT4 e os perfis globais de 5mC e 5hmC após 96 horas de transfecção. Neste ensaio, também avaliamos o papel específico da regulação pós-transcricional de DNMT3b e TET1 pelo miR-29a, utilizando moléculas bloqueadoras dos sítios alvo (TSB) do miR-29a nestes transcritos. Observamos que sob a indução do atRA, os níveis de expressão do miR- 29a e de seus genes alvos (com exceção de DNMT3b), assim como dos marcadores de endoderme e ectoderme, aumentaram, seguido da diminuição dos marcadores de pluripotência em ambas as linhagens. A transfecção de moléculas mímicas do miR-29a, reduziu os níveis de seus transcritos alvos após dois e quatro dias em NT2 e H1, além de reduzir os níveis nucleares de DNMT3b em NT2. Ainda, ocorreu um aumento na expressão de genes da endoderme, mesoderme e ectoderme em H1 e a queda da expressão gênica e nuclear de OCT4 em NT2. Com o uso de siRNA específicos, demonstramos que o knockdown dos níveis nucleares de DNMT3b foi acompanhado de uma queda nos níveis globais de 5mC e um aumento de OCT4 e de 5hmC. Já o knockdown de TET1, elevou os níveis de 5mC, mas também os níveis de 5hmC e OCT4 nuclear. As avaliações com o uso de TSB contra os sítios de ligação do miR-29a em seus transcritos alvo, TET1 e DNMT3b, demonstraram que em células NT2, o bloqueio da ligação do miR endógeno aos seus alvos resultam no aumento dos níveis globais de 5hmC, indicando que a regulação póstranscricional destes alvos pelo miR-29 teria um importante papel na regulação epigenética de células pluripotentes. / Embryonic stem cells (CTEs), extracted from the internal cell mass of the blastocyst, are main characterized by the capacity for self-renewal and pluripotency. During development, the cells lose their differentiation potential and acquire a restricter gene expression profile, modulated by epigenetic mechanisms, as microRNAs. Members of the miR-29 family have as target transcripts enzymes for cytosine methylation in 5mC (DNMT3a and 3b) and for DNA demethylation (TET1, 2 and 3), by hydroxylation of 5mC in 5hmC. Recent studies suggest that the modulation of miR-29 on these targets plays a role in early differentiation of mouse CTEs and in increasing human iPS cell generation efficiency. In the present study, we sought to understand the regulatory role of miR-29a in its epigenetic targets in the context of pluripotency and in early differentiation with atRA. For this, two human pluripotent cell lines (H1 and NTera-2) were submitted to differentiation induction with atRA and function gain of miR-29a during four days of culture for gene expression analysis. Furthermore, in NT2, we performed functional assays by quantitative immunofluorescence microscopy to evaluate the gain- and loss-of-function of miR-29a, DNMT3b and TET1 in the OCT4 nuclear expression and global profiles of 5mC and 5hC, 96 hours posttransfection. In this assay, we also evaluated the specific role of post-transcriptional regulation of DNMT3b and TET1 by miR-29a, using target site blocking molecules (TSB) of miR-29a. We observed that under the induction of atRA, the miR-29a expression levels and its target genes (except of DNMT3b), further the markers of endoderm and ectoderm, increased, followed by decreased pluripotency markers in both cell lines. Transfection of mimic molecules of miR-29a reduced the levels of their target transcripts after two and four days in NT2 and H1, and reduced nuclear levels of DNMT3b in NT2. In addition, the expression of endoderm, mesoderm and ectoderm genes increased in H1 and gene and nuclear expression of OCT4 decreased in NT2. With the use of specific siRNA, we demonstrated that the knockdown of nuclear levels of DNMT3b was accompanied by a drop in global 5mC levels and an increase of OCT4 and 5hmC. While, the knockdown of TET1 increased the levels of 5mC, 5hmC and nuclear OCT4. Evaluations using TSB against the miR- 29a binding sites in their target transcripts, TET1 and DNMT3b, show that in NT2 cells blocking the binding of endogenous miR to their targets results in an increase in global 5hmC levels, indicating that the post-transcriptional regulation of these targets by miR-29 would play an important role in the epigenetic regulation of pluripotent cells.

Active DNA demethylation

Desmetilação ativa do DNA

DNA methylation

Metilação do DNA

microRNA-29

microRNA-29

Pluripotência

Pluripotency

Nanosystems And Small Molecules Attached To Dna For Microrna Detection, Drug Release And Protein Binding

January 2015

1 / Xiaoye Su

NANOSYSTEMS--SMALL MOLECULES--DNA----

Species relationships in the Lotus cormiculatus group (Leguminosae) as determined by karyotype and cytophotometric analyses.

Cheng, Rosa I-Jung

January 1971

No description available.

DNA.

Legumes.

Chromosome numbers.

Identification of putative functional motifs in viral proteins essential for human cytomegalovirus (HCMV) DNA replication

Woon, Heng Giap, Medical Sciences, Faculty of Medicine, UNSW

January 2008

Human cytomegalovirus (HCMV) is a ubiquitous virus that causes significant morbidity and mortality in immunocompromised individuals. Although there are prophylactic treatments available, all current antiviral drugs ultimately target the DNA polymerase, resulting in the increasing emergence of antiviral resistant strains in the clinical setting. There is a fundamental need for understanding the role of other essential genes in DNA replication as a foundation for developing new antiviral treatments that are safe and which utilize a mechanism of action different to existing therapies. In this study we looked at six HCMV replication genes encoding for the DNA polymerase accessory protein (UL44), single stranded DNA binding protein (UL57), primase (UL70), helicase (UL105), primase-helicase associated protein (UL102), and the putative initiator protein (UL84) in order to increase our understanding of their role in DNA replication. The aim of this project was to identify variation within these genes as well as to predict putative domains and motifs in order to ultimately express and study the functional properties of the HCMV primase (UL70) through the use of recombinant mutants. Sequencing of these genes revealed a high degree of conservation between the isolates with amino acid sequence identity of >97% for all genes. Using ScanProsite software from the Expert Protein Analysis System (ExPASy) proteomics server, we have mapped putative motifs throughout these HCMV replication genes. In particular, highly conserved putative Nlinked glycosylation sites were identified in UL105 that were also conserved across 33 homologues as well as several unique motifs including casein kinase II phosphorylation sites (CKII) in UL105 and UL84, a microbodies signal motif in UL57 and an integrin binding site in the UL102 helicase-primase associated protein. Our investigations have also elucidated motif-rich regions of the UL44 DNA polymerase accessory protein, mapped functionally important domains of the UL105 helicase and identified cysteine motifs that have implications for folding of the UL70 primase. Taken together, these findings provide insights to regions of these HCMV replication proteins that are important for post-translation modification, activation and overall function, and this information can be utilized to target further research into these proteins and advance the development of novel antiviral agents that target these processes.

Cytomegalovirus

DNA Replicaiton

The new scientific eyewitness: The role of DNA profiling in shaping criminal justice

Wise, Jenny Alice, Social Sciences & International Studies, Faculty of Arts & Social Sciences, UNSW

January 2008

Since its first use in criminal investigations in 1987, DNA profiling has become the new gold standard for investigations and prosecutions. Academics, politicians and law enforcement officials have presented DNA evidence as a ??scientific hero?? that is capable of solving crimes and preventing miscarriages of justice. However, in spite of this reputation, few studies have explored the impact of this technology on criminal justice practitioners, or on the process of investigating and processing criminal offences. This dissertation provides a comparative study of the use of DNA profiling in two jurisdictions: New South Wales (NSW) in Australia and the Thames Valley in the United Kingdom (UK). Interviews canvassed the perspectives and experiences of police officers, scene of crime officers (SOCOs), forensic scientists, criminal lawyers, and judicial officers from these areas. These interviews were analysed in conjunction with appeal judgments and police statistics to reveal how DNA evidence has been used in the NSW and Thames Valley. The research presented in this dissertation indicates that DNA profiling is having a number of far-reaching effects on both criminal justice systems and is seen as a reliable forensic tool by criminal justice practitioners. Practitioners routinely use DNA evidence throughout the various stages of the criminal justice process and are actively changing their practices to utilise the technology more effectively. One of the main impacts of the introduction of DNA evidence into criminal investigations has been the need to provide substantial resources and infrastructure for the collection, analysis, and storage of samples. Both jurisdictions encountered a number of problems because they provided insufficient resources to effectively use DNA profiling. This study also offers insight into how criminal justice practitioners perceive the dangers of using DNA evidence and how miscarriages of justice can occur. Finally, through an analysis of the combined experiences of criminal justice practitioners, this dissertation challenges the widespread acceptance and routine use of forensic DNA profiling. It further suggests that it is now time to re-consider current practices in relation to how resources are devoted to the technology, and how criminal justice practitioners are using the technology.

DNA evidence

criminal justice

Role of DNA methylation and intron structure in genetic evolution

Tang, Sze-man,

January 2006

Thesis (M. Phil.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.

DNA Introns. Evolutionary genetics.

Studies on the protective and therapeutic efficacy of duck hepatitis B virus vaccines

Triyatni, Miriam.

January 1999

Copies of author's previously published article inserted onto back cover. Bibliography: leaves 164-187. Confirms the value of DHBV infection in ducks as a model to evaluate the protective and therapeutic efficacy of DNA vaccines against hepadnavirus infection. The possibility that this model could be explored further to evaluate various combinations of antigens and cytokines 'cocktail' DNA vaccines that elicit the most effective humoral and effective CMI responses for prevention and treatment of HBV infection is discussed.

Immunotherapy

DNA vaccines

Sequence dependent conformational variations in DNA holliday junctions

Hays, Franklin A.

14 April 2005

Four-stranded DNA junctions (also known as Holliday junctions) are structural intermediates involved in a growing number of biological processes including DNA repair, genetic recombination, and viral integration. Although previous studies have focused on understanding the conformational variability and sequence-dependent formation of Holliday junctions in solution there have been relatively few insights into junction structure at the atomic level. Recent crystallographic studies have demonstrated that the more compact stacked-X junction form has an antiparallel alignment of DNA strands and standard Watson-Crick base pairs across the central crossover region. Junction formation within this crystallographic system was seen to be dependent on a common trinucleotide sequence motif ("ACC-triplet" at the 6th, 7th and 8th positions of the decanucleotide sequence d(CCnnnN₆N₇N₈GG)) containing a series of stabilizing direct and solvent-mediated hydrogen bonding interactions. This thesis addresses questions concerning the nucleotide sequence-dependent formation and conformational variability of DNA Holliday junctions as determined by single crystal x-ray diffraction. We have used the modified bases 2,6-diaminopurine and inosine to demonstrate that minor groove interactions adjacent to the trinucleotide junction core are not major contributors to overall conformation. In addition, incorporation of guanine into the sixth position of this core does not have a significant effect on junction geometry. Meanwhile, incorporation of 5-bromouracil into the eighth position perturbs the geometry in terms of the interduplex angle as well as the defined conformational variables, J[subscript roll] and J[subscript slide]. These novel junction structures demonstrate that the nucleotide sequence within the central core generates a position specific relationship between molecular interactions at the junction crossover and overall structural geometry. A systematic crystallographic screen of the trinucleotide core region is presented here as an unbiased, comprehensive, search for sequences that stabilize junctions. As the result of this screen, we can extend the core sequence motif to 'N₆Y₇C₈' where N₆ is an adenine, guanine, or cytosine nucleotide and Y₇ is either a cytosine or thymine (if N₆ = adenine) nucleotide. Using these novel junction structures, we demonstrate that base sequence within the central core has a significant effect on the overall geometry of the junction. Thus, this central region of the structure may serve as a linchpin for determining the local and global conformation and overall variability of the four-stranded DNA Holliday junction. These observations raise some interesting questions regarding the importance of this core region in biological processes such as genetic recombination. / Graduation date: 2005

Holliday junctions

DNA -- Structure

The asymmetric binding of Actinomycin D to DNA hexamers

Ivancic, Monika

15 June 2001

The solution structure determination of DNA molecules has been an important part of structural biology. NMR solution structures are a complement to structures solved via X-ray crystallography; the two methods are the only ways of obtaining three dimensional coordinates of macromolecules. Because of the nature of the molecule, the solution structure determination of DNA has been a challenging task. Assignments are the first and most important part of NMR structures, and can be simplified for DNA with the use of the rotating frame Overhauser spectroscopy (ROESY) experiment. The ROESY technique can be used for unambiguous assignments of H2' and H2" protons and for distinguishing the three main forms of DNA duplexes: A-form, B-form and Z-form. Many types of DNA have been examined using NMR spectroscopy, including drug-bound DNA complexes. Most previous studies of complexes of the anti-cancer drug Actinomycin D (ActD) and DNA used self- complementary sequences to identify stabilizing features. The studies presented in this thesis use non-self-complementary DNA hexamers to identify the two orientations in the binding of the asymmetric ActD drug. The largest preference of asymmetric binding was found for the d(CCGCCG)•d(CGGCGG) sequence; however, NMR spectral complications prevented the structure elucidation of this complex. Instead the solution structure was determined for the complex with the next largest orientational preference, ActD:d(CTGCGG)•d(CCGCAG), which has 67% of ActD molecules intercalated with the benzenoid side of ActD in the first strand. The solved structure identifies unusual DNA features, which could be due to the bound drug inducing structural changes to the B-DNA duplex or the presence of conformational motion. For seven of the eight sequences, the orientation of ActD intercalation within the DNA duplex was identified. The largest preference occurs when the benzenoid intercalation site is followed by a guanine. When this guanine is replaced by an inosine, a reduction in the asymmetric binding of ActD is observed, indicating that the guanine NH₂ group plays a role in the intermolecular contacts. Thus, the two orientations of ActD binding are not present in equal concentrations although their structures are similar, and the preference of orientation is influenced by the asymmetric DNA sequence flanking the intercalation site. / Graduation date: 2002

Actinomycin

DNA-drug interactions

The mechanism of interaction of the linker histone with DNA and nucleosomes

Ellen, Thomas Patrick

27 June 2003

This dissertation examines the interaction of the linker histone with DNA and with nucleosomes. The first goal of the project was to characterize the interaction of the linker histone with DNA. Three factors previously reported to influence the linker histone's interaction with DNA were examined: ratio of linker histone to DNA sites of binding, monovalent ions in the local environment, and conformation of the DNA molecules. Evidence obtained through gel mobility shift assays demonstrates the strong preference by the linker histone for DNA with superhelical torsion, i.e., supercoiling, and the negative cooperative mode of binding that the linker histone exhibits in association with supercoiled DNA. The second part of the dissertation examines the location of linker histone binding on the nucleosome, and documents the pronounced tendency of the linker histone to bind to two DNA duplex strands. A preparation of homogeneous nucleosome core particles, consisting of a defined 238 base pair DNA fragment and the core histone octamer positioned precisely on this DNA, was used as a substrate for the UV-induced crosslinking of the linker histone to the DNA of this nucleosome. By site-specific labeling of a single site on the DNA of the nucleosome, the linker histone was observed crosslinked at that labeled site, confirming that the linker histone binds at the pseudo-dyad axis of the nucleosome. This evidence was used to support a model of linker histone binding to the nucleosome that invokes the association of the linker histone with no fewer than two duplex strands of DNA of the nucleosome. / Graduation date: 2004

Histones

DNA-protein interactions