Tnt1 retrotransposon expression and ethylene phytohormone interplay mediates tobacco (Nicotiana tabacum) defense responses / A dinâmica entre a expressão do retrotransposon Tnt1 e o fitormônio etileno envolvida nas respostas de defesa em tabaco (Nicotiana tabacum)

Danielle Maluf Quintanilha

10 October 2014

Tnt1 is a transcriptionally active LTR-retrotransposon, present in over 600 copies in the Nicotiana tabacum genome. Under normal growth conditions, Tnt1 expression is limited to basal levels, but its expression is further induced under biotic and abiotic stresses. Transgenic tobacco plants (HP plants) expressing a Tnt1 reverse transcriptase hairpin were generated. These showed pleiotropic phenotypes such as cell death spots on the leaves and callose deposition and other severe abnormal development in aerial and underground portions. RNA sequencing of leaves with cell death spots revealed a rewiring of transcriptional regulatory networks related to stress responses exclusive to HPs. Among the positively modulated genes were ethylene synthesis and response cascade genes. The objective of the present work was to unravel the relation observed between Tnt1 and ethylene, generating a model. The results obtained suggest that HP seedlings and plants have increased ethylene synthesis when compared to the wildtype. Folding prediction of Tnt1 messenger RNA allowed the identification of ethylene-responsive sequences in putative stem loop locations. Thus it is possible that Tnt1 expression can produce small RNAs targeted to sequences present in the Tnt1 retrotransposon itself as well as at the promoter region of other ethylene responsive genes. Quantification of the expression of Tnt1 and ethylene related genes revealed \"phase opposition\" expression kinetics in the HPs, which led us to hypothesize that there might be an antagonistic relationship between the expression of Tnt1 and the expression of ethylene responsive genes involved in plant defense responses. Our findings suggest that Tnt1 could generate sRNAs that exerts transcriptional control over itself as well as other genes. Our model establishes a completely new biological role for a retrotransposon: Tnt1 would provide feedback control to ethylene-mediated gene regulation in tobacco defense responses, bringing the system back to a homeostatic condition and turning the defense responses down. / Tnt1 é um retrotransposon com LTR transcricionalmente ativo, e está presente em mais de 600 cópias no genoma de Nicotiana tabacum. Em condições normais de crescimento Tnt1 é expresso em níveis basais. No entanto, sua expressão é induzida pelo estímulo de estresses bióticos e abióticos. Plantas de tabaco transgênicas (chamadas de HP) expressando um grampo da transcriptase reversa de Tnt1 foram geradas. Estas apresentaram fenótipos como: pontos de morte celular e deposição de calose nas folhas e severas anomalias de desenvolvimento severas nas porções aérea e radicular das plantas. Sequenciamento de RNA de folhas com os pontos de morte celular revelou uma reorganização de redes de regulação transcricional relacionadas a resposta a estresses. Essas novas redes surgiram exclusivamente nas plantas HP. Entre os genes modulados positivamente estavam genes de síntese e de resposta ao etileno. O presente trabalho teve como objetivo elucidar a relação observada entre Tnt1 e o fitormônio etileno gerando um modelo de atuação. Os resultados obtidos permitiram demonstrar que plântulas e plantas HP adultas tem um aumento na síntese de etileno quando comparadas à selvagem. A predição do dobramento do RNA mensageiro de Tnt1 permitiu a identificação de sequências responsivas ao etileno localizadas em posição potencial para formar grampos. Desta forma, é possível que a expressão de Tnt1 leve à produção de pequenos RNAs que tem como alvo sequências responsivas a etileno presentes tanto no próprio elemento quanto em regiões promotoras de outros genes. A quantificação da expressão de Tnt1 versus genes relacionados ao etileno revelou um padrão em \"oposição de fase\" nas HPs, o que nos levou a hipotetizar que talvez ocorra uma relação antagonista entre a expressão de Tnt1 e a expressão de genes responsivos ao etileno envolvidos em respostas de defesa vegetais. Nossos resultados sugerem que Tnt1 pode gerar pequenos RNAs que exercem controle transcricional sobre Tnt1 e outros genes endógenos. Nosso modelo estabelece um novo papel biológico para um retrotransposon: Tnt1 agiria como um modulador da indução de genes mediada por etileno nas respostas de defesa de tabaco, trazendo o sistema de volta à condição homeostática e encerrando as respostas de defesa.

Nicotiana tabacum

Etileno

Pequenos RNAs

Respostas de defesa

Retrotransposon

Tnt1

Nicotiana tabacum

Defense responses

Ethylene

Retrotransposon

Small RNAs

Tnt1

Identificação e caracterização de elementos de transposição no genoma de Rhynchosciara / Identification e characterization of transposable elements in genome of Rhynchosciara

Teixeira, Paula Rezende

18 April 2007

Os elementos de transposição são seqüências discretas que são capazes de mover- se de um lócus para outro, constituindo uma parte significante do genoma de eucariotos. São agrupados em duas classes principais, os elementos da Classe I, que se transpõem via um intermediário de RNA (retrotransposon), e os elementos da Classe II, que se transpõem via mecanismo de DNA do tipo corta e cola (transposon). A análise das seqüências de um banco de cDNA construído com RNA mensageiro da glândula salivar de Rhynchosciara americana mostrou a presença de representantes das duas classes de elementos. Nesse trabalho caracteriza-se quarto elementos de transposição tipo mariner, onde as seqüências consenso de nucleotídeos foram derivadas de múltiplas cópias defectivas contendo deleções, mudança no quadro de leitura e códons de terminação. Ramar1, um elemento full-length e Ramar2 um elemento defectivo que contém uma deleção na região interna da ORF da transposase, mas mantém e as extremidades intactas. Ramar3 e Ramar4 são elementos defectivos que apresentam muitas deleções no interior da ORF. As seqüências preditas das transposases demostraram que Ramar1 e Ramar2 estão filogeneticamente muito próximos dos elementos mariner da subfamília mauritiana. Enquanto, Ramar3 e Ramar4 pertencem às subfamílias mellifera e irritans, respectivamente. Hibridização in situ mostrou que Ramar1 localiza-se em muitas regiões do cromossomo, principalmente na heterocromatina pericentromérica, enquanto Ramar2 aparece em uma única banda no cromossomo A. Resultado ainda mais curioso foi a caracterização molecular de um elemento de retrotransposição, denominado RaTART, que provavelmente é o responsável pela reconstituição telomérica em R.americana, assim como os elementos TART, HeT-A e TAHRE de Drosophila. Experimentos de Southern Blots do retroelemento RaTART indicam que este está representado por seqüências repetidas no genoma de R.americana, enquanto que Northern Blots mostraram uma expressão em diferentes estágios do desenvolvimento e o transcrito de alto peso molecular detectado representa o retrotransposon non-LTR inteiro. Enquanto a localização cromossômica de RaTART por hibridização in situ mostrou uma marcação predominante nas extremidades dos cromossomos, indicando possivelmente o primeiro elemento de transposição descrito em R.americana com função definida na estrutura do cromossomo. O último retrotransposon, identificado nesse projeto, presente no genoma de R.americana, denominado R2Ra, foi isolado a partir de uma varredura em um banco genômico construído no bacteriófago lambda dash usando como sonda o recombinante pRa1.4 que contém a unidade de repetição do rDNA. A análise da seqüência mostrou a presença de regiões conservadas, como o domínio de transcriptase reversa e o motivo zinc finger na região amino-terminal. O sítio de inserção no gene 28S do rDNA é altamente conservado em R.americana e a análise filogenética mostrou que este elemento pertence ao grupo R2. A localização cromossômica confirma que o elemento móvel R2Ra se insere em um sítio específico no gene rDNA. / Transposable elements are discrete sequences that are able to move from one locus to another within the genome, constituting a significant part of eukaryotic genome. They are grouped into two main types, Class I elements transpose via an RNA intermediate (retrotransposon), and Class II elements transpose via a DNA \"cut-and-paste\" mechanism (transposons). The analysis of sequences of a cDNA bank constructed from mRNA of the salivary glands of Rhynchosciara americana showed the presence of putative types of two classes elements. In the present thesis we describe four mariner elements, where the nucleotides consensus sequences were derived from multiple defective copies containing deletions, frame shifts and stop codons. Ramar1, a full-length element and Ramar2 is a defective mariner element that contains a deletion overlapping most of the internal region of the transposase ORF and the extremities of the element maintain intact. Ramar3 e Ramar4 are defective mariner element that were impossible to predict a complete ORF. Predicted transposase sequences demonstrated that Ramar1 and Ramar2 are phylogenetically very close to mariner-like elements of mauritiana subfamily. However, Ramar3 and Ramar4 belong to mellifera and irritans subfamilies, respectively. In situ hybridisations showed Ramar1 localized in several chromosome regions, mainly in pericentromeric heterochromatin and their boundaries, while Ramar2 appeared as a single band in chromosome A. More interesting data were the molecular characterization of the non-LTR retrotransposon element, called as RaTART, that probably is the responsible by telomeric reconstruction in R.americana, as well as the telomeric retrotransposable elements TART, Het-A and TAHRE of Drosophila. Southern blot analysis indicated that this transposable element is represented by repeat sequences in the genome of R. americana, and Northern blot analysis showed a expression in different developmental stages and the transcript of high molecular mass detected represents the full-length non-LTR retrotransposon. However, the chromosomal localization of the retroelement by in situ hybridisation showed a labelling predominant on chromosome ends, indicating possibly the first transposable element described in R.americana with a defined role in chromosome structure. The last retrotransposon, identified in this project, present in the genome of Rhynchosciara americana, called R2Ra, was isolated from screening of a lambda dash genomic library using as probe the recombinant pRa1.4 of rDNA. The analysis of sequence showed the presence of conserved regions, like transcriptase reverse domain and zinc finger motif in the amino terminal region. The insertion site is high conserved in R.americana and a phylogenetic analysis showed that this element belongs to the R2 clade. The chromosomal localization confirm that the R2Ra mobile element insert into the site specific in rDNA gene.

Rhynchosciara

Rhynchosciara

Diptera

Diptera

Elemento de transposição

Expressão gênica

Gene expression

Genomas

Genome

ITR

ITR

Mariner

Mariner

Retrotransposon

Retrotransposon

Transposable element

Transposon

Transposon

Desvendando as interações entre retrotransposons e genomas vegetais, com ênfase em cana-de-açúcar. / Unraveling the interactions between retrotransposons and plant genomes, with emphasis on sugarcane.

Cruz, Guilherme Marcello Queiroga

09 May 2014

Esta tese é estruturada em dois capítulos. O primeiro capítulo explora os retrotransposons com LTR (LTR-RT) em cana-de-açúcar e grande parte de seus resultados foram publicados no artigo \'\'Analysis of plant LTR-retrotransposons at the fine-scale family level reveals individual molecular patterns\'\'. Nossos resultados mostraram que as diferentes famílias de LTR-RT em cana-de-açúcar possuem estruturas e regulação distintas. O segundo capítulo desta tese visa responder a perguntas que surgiram durante a primeira metade deste trabalho, mas ao invés de focar no genoma de uma planta optamos por trabalhar com linhagem Del de LTR-RT em dez genomas de angiospermas sequenciados. Os resultados desta parte do trabalho foram submetidos para publicação no artigo intitulado \'\'Virus-like attachment sites and plastic CpG islands: landmarks of diversity in plant Del retrotransposons\'\'. Os resultados mostraram que a LTR é uma região dinâmica e importante para a evolução dos LTR-RTs. Nós especulamos que mudanças nas LTR atuem como gatilhos para a diversificação dos LTR-RTs. / This doctoral thesis is structured in two chapters. In the first chapter we explore the LTRretrotransposons (LTR-RT) in sugarcane, these results were published in an article entitled \'\'Analysis of plant LTR-etrotransposons at the fine-scale family level reveals individual molecular patterns\'\'. In this paper we show that different sugarcane LTR-RT families have distinct structure and are differentially regulated. In the second chapter we try to find answers to questions that came up in the first half of this work, but instead of focusing in one plant genome we chose to work with the Del lineage of LTR-RT in tem angiosperm sequenced genomes. These results are submitted to publication as an article entitled \'\'Virus-like attachment sites and plastic CpG islands: landmarks of diversity in plant Del retrotransposons\'\'. Our results indicate that the LTR region is dynamic and important in the evolution of LTR-retrotransposons, we speculate that it is a trigger for retrotransposon diversification.

Attachment site

Cana-de-açúcar

CpG Island

Evolutionary lineage

Genoma

Genome

Ilha CpG

Linhagem evolutiva

Long Terminal Repeat

LTR

Plantas

Plants

Retrotransposon

Retrotransposon

Sítio Att

Sugarcane

Identificação e caracterização de elementos de transposição no genoma de Rhynchosciara / Identification e characterization of transposable elements in genome of Rhynchosciara

Paula Rezende Teixeira

18 April 2007

Os elementos de transposição são seqüências discretas que são capazes de mover- se de um lócus para outro, constituindo uma parte significante do genoma de eucariotos. São agrupados em duas classes principais, os elementos da Classe I, que se transpõem via um intermediário de RNA (retrotransposon), e os elementos da Classe II, que se transpõem via mecanismo de DNA do tipo corta e cola (transposon). A análise das seqüências de um banco de cDNA construído com RNA mensageiro da glândula salivar de Rhynchosciara americana mostrou a presença de representantes das duas classes de elementos. Nesse trabalho caracteriza-se quarto elementos de transposição tipo mariner, onde as seqüências consenso de nucleotídeos foram derivadas de múltiplas cópias defectivas contendo deleções, mudança no quadro de leitura e códons de terminação. Ramar1, um elemento full-length e Ramar2 um elemento defectivo que contém uma deleção na região interna da ORF da transposase, mas mantém e as extremidades intactas. Ramar3 e Ramar4 são elementos defectivos que apresentam muitas deleções no interior da ORF. As seqüências preditas das transposases demostraram que Ramar1 e Ramar2 estão filogeneticamente muito próximos dos elementos mariner da subfamília mauritiana. Enquanto, Ramar3 e Ramar4 pertencem às subfamílias mellifera e irritans, respectivamente. Hibridização in situ mostrou que Ramar1 localiza-se em muitas regiões do cromossomo, principalmente na heterocromatina pericentromérica, enquanto Ramar2 aparece em uma única banda no cromossomo A. Resultado ainda mais curioso foi a caracterização molecular de um elemento de retrotransposição, denominado RaTART, que provavelmente é o responsável pela reconstituição telomérica em R.americana, assim como os elementos TART, HeT-A e TAHRE de Drosophila. Experimentos de Southern Blots do retroelemento RaTART indicam que este está representado por seqüências repetidas no genoma de R.americana, enquanto que Northern Blots mostraram uma expressão em diferentes estágios do desenvolvimento e o transcrito de alto peso molecular detectado representa o retrotransposon non-LTR inteiro. Enquanto a localização cromossômica de RaTART por hibridização in situ mostrou uma marcação predominante nas extremidades dos cromossomos, indicando possivelmente o primeiro elemento de transposição descrito em R.americana com função definida na estrutura do cromossomo. O último retrotransposon, identificado nesse projeto, presente no genoma de R.americana, denominado R2Ra, foi isolado a partir de uma varredura em um banco genômico construído no bacteriófago lambda dash usando como sonda o recombinante pRa1.4 que contém a unidade de repetição do rDNA. A análise da seqüência mostrou a presença de regiões conservadas, como o domínio de transcriptase reversa e o motivo zinc finger na região amino-terminal. O sítio de inserção no gene 28S do rDNA é altamente conservado em R.americana e a análise filogenética mostrou que este elemento pertence ao grupo R2. A localização cromossômica confirma que o elemento móvel R2Ra se insere em um sítio específico no gene rDNA. / Transposable elements are discrete sequences that are able to move from one locus to another within the genome, constituting a significant part of eukaryotic genome. They are grouped into two main types, Class I elements transpose via an RNA intermediate (retrotransposon), and Class II elements transpose via a DNA \"cut-and-paste\" mechanism (transposons). The analysis of sequences of a cDNA bank constructed from mRNA of the salivary glands of Rhynchosciara americana showed the presence of putative types of two classes elements. In the present thesis we describe four mariner elements, where the nucleotides consensus sequences were derived from multiple defective copies containing deletions, frame shifts and stop codons. Ramar1, a full-length element and Ramar2 is a defective mariner element that contains a deletion overlapping most of the internal region of the transposase ORF and the extremities of the element maintain intact. Ramar3 e Ramar4 are defective mariner element that were impossible to predict a complete ORF. Predicted transposase sequences demonstrated that Ramar1 and Ramar2 are phylogenetically very close to mariner-like elements of mauritiana subfamily. However, Ramar3 and Ramar4 belong to mellifera and irritans subfamilies, respectively. In situ hybridisations showed Ramar1 localized in several chromosome regions, mainly in pericentromeric heterochromatin and their boundaries, while Ramar2 appeared as a single band in chromosome A. More interesting data were the molecular characterization of the non-LTR retrotransposon element, called as RaTART, that probably is the responsible by telomeric reconstruction in R.americana, as well as the telomeric retrotransposable elements TART, Het-A and TAHRE of Drosophila. Southern blot analysis indicated that this transposable element is represented by repeat sequences in the genome of R. americana, and Northern blot analysis showed a expression in different developmental stages and the transcript of high molecular mass detected represents the full-length non-LTR retrotransposon. However, the chromosomal localization of the retroelement by in situ hybridisation showed a labelling predominant on chromosome ends, indicating possibly the first transposable element described in R.americana with a defined role in chromosome structure. The last retrotransposon, identified in this project, present in the genome of Rhynchosciara americana, called R2Ra, was isolated from screening of a lambda dash genomic library using as probe the recombinant pRa1.4 of rDNA. The analysis of sequence showed the presence of conserved regions, like transcriptase reverse domain and zinc finger motif in the amino terminal region. The insertion site is high conserved in R.americana and a phylogenetic analysis showed that this element belongs to the R2 clade. The chromosomal localization confirm that the R2Ra mobile element insert into the site specific in rDNA gene.

Rhynchosciara

Diptera

Elemento de transposição

Expressão gênica

Genomas

ITR

Mariner

Retrotransposon

Transposon

Rhynchosciara

Diptera

Gene expression

Genome

ITR

Mariner

Retrotransposon

Transposable element

Transposon

Desvendando as interações entre retrotransposons e genomas vegetais, com ênfase em cana-de-açúcar. / Unraveling the interactions between retrotransposons and plant genomes, with emphasis on sugarcane.

Guilherme Marcello Queiroga Cruz

09 May 2014

Esta tese é estruturada em dois capítulos. O primeiro capítulo explora os retrotransposons com LTR (LTR-RT) em cana-de-açúcar e grande parte de seus resultados foram publicados no artigo \'\'Analysis of plant LTR-retrotransposons at the fine-scale family level reveals individual molecular patterns\'\'. Nossos resultados mostraram que as diferentes famílias de LTR-RT em cana-de-açúcar possuem estruturas e regulação distintas. O segundo capítulo desta tese visa responder a perguntas que surgiram durante a primeira metade deste trabalho, mas ao invés de focar no genoma de uma planta optamos por trabalhar com linhagem Del de LTR-RT em dez genomas de angiospermas sequenciados. Os resultados desta parte do trabalho foram submetidos para publicação no artigo intitulado \'\'Virus-like attachment sites and plastic CpG islands: landmarks of diversity in plant Del retrotransposons\'\'. Os resultados mostraram que a LTR é uma região dinâmica e importante para a evolução dos LTR-RTs. Nós especulamos que mudanças nas LTR atuem como gatilhos para a diversificação dos LTR-RTs. / This doctoral thesis is structured in two chapters. In the first chapter we explore the LTRretrotransposons (LTR-RT) in sugarcane, these results were published in an article entitled \'\'Analysis of plant LTR-etrotransposons at the fine-scale family level reveals individual molecular patterns\'\'. In this paper we show that different sugarcane LTR-RT families have distinct structure and are differentially regulated. In the second chapter we try to find answers to questions that came up in the first half of this work, but instead of focusing in one plant genome we chose to work with the Del lineage of LTR-RT in tem angiosperm sequenced genomes. These results are submitted to publication as an article entitled \'\'Virus-like attachment sites and plastic CpG islands: landmarks of diversity in plant Del retrotransposons\'\'. Our results indicate that the LTR region is dynamic and important in the evolution of LTR-retrotransposons, we speculate that it is a trigger for retrotransposon diversification.

Cana-de-açúcar

Genoma

Ilha CpG

Linhagem evolutiva

LTR

Plantas

Retrotransposon

Sítio Att

Attachment site

CpG Island

Evolutionary lineage

Genome

Long Terminal Repeat

Plants

Retrotransposon

Sugarcane

CHARACTERIZATION AND DISTRIBUTION OF NOVEL NON-LTR RETROELEMENTS DRIVING HIGH TELOMERE RFLP DIVERSITY IN CLONAL LINES OF MAGNAPORTHE ORYZAE

Starnes, John H

01 January 2013

The filamentous ascomycete fungus Magnaporthe oryzae is a pathogen of over 50 genera of grasses. Two important diseases it can cause are gray leaf spot in Lolium perenne (perennial ryegrass) and blast in Oryza sativa (rice). The telomeres of M. oryzae isolates causing gray leaf spot are highly variable, and can spontaneously change during fungal culture. In this dissertation, it is shown that a rice-infecting isolate is much more stable at the telomeres than an isolate from gray leaf spot. To determine the molecular basis of telomere instability several gray leaf spot isolates telomeres were cloned, which revealed two non-LTR retrotransposons inserted into the telomere repeats. The elements have been termed Magnaporthe oryzae Telomeric Retrotransposons (MoTeRs). These elements do not have poly-A tails common to many other non-LTR retrotransposons, but instead have telomere like sequences at their 5’ end that allow them to insert into telomeres. Intact copies of MoTeRs were restricted to the telomeres of isolates causing gray leaf spot. Surveys for the presence of these elements in M. oryzae showed they were present in several host-specialized forms including gray leaf spot isolates, but were largely absent in the rice blast isolates. The absence of MoTeRs in rice blast isolates, which are relatively stable by comparison, suggested that the telomere instability in gray leaf spot isolates could be due to MoTeRs. Analyzing spontaneous alterations in telomere restriction fragment profiles of asexual progeny revealed that MoTeRs were involved. Expansion and contraction of MoTeR arrays were observed and account for some telomere restriction profile changes. New telomere formation in asexual progeny followed by MoTeR addition was also observed. Based on this evidence, MoTeRs are largely responsible for the high variability of telomere restriction profiles observed in GLS isolates.

Non-LTR

retrotransposon

telomere

gray leaf spot

Magnaporthe oryzae

Agriculture

Genetics

Molecular genetics

High-throughput Detection Of Potentially Active L1 Elements In Human Genomes

January 2014

The active human retrotransposon L1 is the most prevalent human retroelement, constituting 17% of the mass of the human genome and contributing significantly to mutagenesis. L1 mutagenizes human genomes in a number of ways including insertional mutagenesis of itself and other retrotransposons, creating of DNA double strand breaks, and induction of non-allelic homologous recombination. Through these processes, the activity of L1 is responsible for approximately 0.5% of all new genetic diseases. All L1-derived mutagenesis stems from the activity of a small number of intact full-length L1 loci that remain capable of mobilization. A smaller subset of these active L1s are called hot L1s and are responsible for the vast majority of all L1 activity. Hot L1s are polymorphic in the population and represent evolutionarily recent L1 insertion events. Here, we show that potentially active full length L1 elements are more prevalent in individual genomes than previously believed. We find that the typical individual likely harbors approximately 60 active and 50 hot L1s. However, we also find that there is significant variation between individuals in numbers of potentially active L1s. As a result, the mutagenic burden associated with L1 likely varies between individuals. / acase@tulane.edu

Retrotransposon

High-throughput Sequencing

Genetics

School of Medicine

Biomedical Sciences Graduate Program

Ph.D

Comparative and functional genomic analysis of human and chimpanzee retrotransposon sequences

Polavarapu, Nalini

25 June 2007

Transposable elements (TEs) are mobile DNA sequences that can move from one location to another in the genome. These elements encode regulatory features including transcriptional promotion and termination signals facilitating the production of new transcripts (or elements). The elements thus produced are inserted back into the genome. Due to their insertional capacity and encoded regulatory features, TEs have, in recent years, been recognized as significant contributors to regulatory variation both within and between species. In comparing the human and chimpanzee genomes it has been hypothesized that the genetic basis of the phenotypic differences that distinguish them may be the result of regulatory differences existing between the two species. Since TEs inserted in proximity to genes can significantly alter gene expression patterns, this research aims at exploring the influence of TE sequences and retrotransposons in particular in the evolution of gene regulation between humans and chimpanzees. A first systematic search of one particular class of retrotransposons - endogenous retroviruses (ERVs) was carried out in the chimpanzee genome. Forty two families of ERVs were identified in the chimpanzee genome including the discovery of 9 previously unknown families in humans. The vast majority of these families were found to have orthologs in the human genome except for two (CERV 1/PTERV1 and CERV 2) families. The two CERV families without orthologs in the human genome display a patchy distribution among primates. Nine families of chimpanzee ERVs have been transpositionally active since the human-chimpanzee divergence, while only two families have been active in the human lineage. The genomic differences [INDEL variation (80-12,000 bp in length)] between humans and chimpanzees are laid out. The INDEL variation located in or near genes is categorized in detail and is correlated with differences in gene expression patterns in a variety of organs and tissues. Results indicate that the majority of the INDEL variation between the two species is associated with retrotransposon sequences and that this variation is significantly correlated with differences in gene expression most notably in brain and testes. These findings are consistent with the hypothesis that retrotransposon mediated regulatory variation may have been a significant factor in human/chimpanzee evolution.

Gene expression

Indel variation

Chimpanzee

Retrotransposon

Human

Transposons

Genomes

Genetic regulation

Physiology, Comparative

Chimpanzees

Human beings

Novel Regulatory Mechanisms of Autophagy in Human Disease: Implications for the Development of Therapeutic Strategies

Chitiprolu, Maneka

19 November 2018

The dysfunction of autophagy pathways has been linked to the development and progression of numerous human diseases, in particular neurological disorders and cancer. Investigating these pathological autophagy mechanisms is essential to gain insights into the underlying disease mechanisms, identify novel biomarkers, and develop targeted therapies. In this thesis, I present three manuscripts that investigate the regulatory mechanisms of autophagy machinery in human diseases. In the first manuscript (Chitiprolu et al., 2018), we investigated the mechanism of p62-mediated selective autophagic clearance of RNA stress granules implicated in Amyotrophic Lateral Sclerosis (ALS). Repeat expansions in C9ORF72, the major cause of ALS, reduce C9ORF72 levels but how this impacts stress granules is uncertain. By employing mass spectrometry, high resolution imaging and biochemical assays, we demonstrated that the autophagy receptor p62 associates with C9ORF72 to eliminate stress granules by autophagy. This requires p62 to associate with proteins that are symmetrically methylated on arginines. Patients with C9ORF72 repeat expansions accumulate symmetric arginine dimethylated proteins which co-localize with p62. This suggests that C9ORF72 initiates a cascade of ALS-linked proteins (C9ORF72, p62, SMN, FUS) to recognize stress granules for degradation by autophagy and hallmarks of a defect in this process are observable in ALS patients. The second manuscript (Guo, Chitiprolu et al., 2014) describes the mechanism by which autophagy degrades retrotransposon RNA from both long and short interspersed elements, thereby preventing new retrotransposon insertions into the genome. By employing quantitative imaging tools, we demonstrated that retrotransposon RNA localizes to RNA granules that are selectively degraded by the autophagy receptors NDP52 and p62. Mice lacking a copy of Atg6/Beclin1, a gene critical for autophagy, also accumulate both retrotransposon RNA and genomic insertions. This suggests a mechanism for the increased tumorigenesis upon autophagy inhibition and therefore a role for autophagy in tempering evolutionary change. Finally, the third manuscript (Guo, Chitiprolu et al., 2017) examines the intersection of autophagy machinery with exosome release and function in cancer metastasis. By employing dynamic light scattering, Nanosight particle tracking, electron microscopy, super-resolution imaging and Western blotting, we robustly quantified exosome identity and purity in multiple cell lines. We demonstrated that exosome production is strongly reduced in cells lacking Atg5 and Atg16L1, but this is independent of Atg7 and canonical autophagy. The effect of Atg5 on exosome production promotes the migration and in vivo metastasis of orthotopic breast cancer cells. These findings delineate autophagy-independent pathways by which autophagy-related genes can contribute to metastasis. Taken together, data presented in the three manuscripts highlight the molecular mechanisms of autophagy core machinery proteins and selective receptors such as Atg5, p62 and NDP52, in the pathogenesis of cancer and neurodegeneration. In these diseases characterized by mutations in autophagy pathways, the mechanisms we uncover provide insights into their causes and serve as potential therapeutic targets.

Autophagy

RNA granules

ALS

Arginine methylation

Retrotransposon RNA

Tudor domain

Cancer

Exosomes

Proposição dos modelos de expansão genômica dos elementos de transposição 412 e Bari no genoma de espécies do grupo melanogaster e em populações naturais de Drosophila melanogaster e de D. simulans

Dias, Elaine Silva [UNESP]

15 February 2011

Made available in DSpace on 2014-06-11T19:26:05Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-02-15Bitstream added on 2014-06-13T19:12:55Z : No. of bitstreams: 1 dias_es_me_sjrp.pdf: 1177689 bytes, checksum: f1f230e591b3ef47a8155f3bc9916e14 (MD5) / Três modelos têm sido propostos para explicar o modo de expansão dos elementos de transposição nos genomas – master gene, transposon e intermediário. O modelo master gene aplica-se à situação em que existe apenas uma única sequência ativa, de uma subfamília particular, que dá origem às demais sequências, as quais não apresentam capacidade de mobilização, enquanto o modelo transposon assume que todas as sequências de uma subfamília são ativas. Por outro lado, o modelo intermediário, considera que algumas cópias apresentam capacidade de mobilização e outras permanecem inativas. Os modelos propostos podem ser relacionados aos mecanismos de transposição, copy-and-paste e cut-and-paste, característicos das classes de elementos transponíveis I e II, respectivamente. Contudo, os estudos de dispersão intragenômica se concentram em elementos da classe I sem LTRs. Com o objetivo de ampliar o entendimento da dinâmica de dispersão genômica dos elementos de transposição e buscando verificar se os modelos propostos para a dispersão dos retroposons ajustam-se aos transposons e aos retrotransposons, foram analisados o transposon Bari e o retrotransposon 412 no genoma das espécies do grupo melanogaster de Drosophila e em populações naturais de D. melanogaster e D. simulans. Assim, buscas por seqüência similares a ambos os elementos selecionados foram realizadas nos genomas seqüenciados de seis espécies do grupo melanogaster; bem como, foram amplificadas, clonadas e sequenciadas cópias presentes nas populações naturais de ambas as espécies. Foram reconstruídas as relações evolutivas entre as sequências dos genomas, como também entre aquelas das populações naturais por meio do programa Network, utilizando o algoritmo Median Joining. Nossos resultados indicam a ausência de um modelo único de dispersão para ambos os elementos... / Three models have been proposed to explain the expansion of transposable elements within genomes - master gene, transposon and intermediate. The master gene model applies to situations in which there is only one active sequence of a particular subfamily, which gives rise to other sequences which have no capacity for mobilization, while the transposon model assumes that all sequences of a subfamily are active. On the other hand, the intermediate model considers that some copies have the capacity for mobilization and others remain inactive. The proposed models can be related to mechanisms of transposition, copy-and-paste and cut-and-paste, characteristic of class I and II of transposable elements, respectively. However, studies of intragenomic dispersion concentrate on elements of the class I without LTRs. Aiming at enhancing the understanding of the transposable elements genomic dynamics of dispersion and trying to verify whether the proposed models for dispersion of retroposons fit to transposons and retrotransposons, we analyzed the retrotransposon 412 and Bari transposon in the genome of the species melanogaster group of Drosophila and in natural populations of D. melanogaster and D. simulans. Thus, searches for sequences similar to both elements were done in the sequenced genomes of six species of the melanogaster group; as well as copies present in natural populations of both species were amplified, cloned and sequenced. We reconstructed the evolutionary relationships between the sequences of the genomes, as well as those amplified from samples of wild populations through the Network program, using the Median Joining algorithm. Our results indicate the absence of a single model of dispersion for both transposable elements, Bari and 412, in the different species analyzed, as well as in the populations of both species... (Complete abstract click electronic access below)

Genetica animal

Genômica

Evolução molecular

Drosofila

Drosophila

Genomic dispersion

Transposon Bari

Retrotransposon 412

Melanogaster

Species group