Unnatural production of natural products: Heterologous expression and combinatorial biosynthesis of cyanobacterial-derived compounds

Roberts, Alexandra Anne, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

Cyanobacteria produce a myriad of structurally unique secondary metabolites with useful bioactive properties. Heterologous expression of a variety of microbial natural compounds has been used to harness their diversity and facilitate their combinatorial biosynthesis. However, these genetic techniques have not been developed for secondary metabolite-producing cyanobacteria. Therefore the genetically manipulable Escherichia coli and Synechocystis sp. PCC6803 were engineered in order to develop effective heterologous hosts and promoters for the expression of cyanobacterial-derived compounds. The phosphopanthetheinyl transferase (PPT), Sppt, from Synechocystis sp. PCC6803 was characterised to determine its ability to activate carrier proteins from secondary metabolite pathways. Despite in silico evidence which suggested Sppt was able to activate a wide range of carrier proteins, biochemical analysis revealed that it is dedicated for fatty acid synthesis. Consequently, E. coli and Synechocystis sp. PCC6803 were engineered to encode a broad-range PPT, from the filamentous cyanobacteria Nodularia spumigena NSOR10, for the activation of carrier proteins from nonribosomal peptide synthesis. Cyanobacterial natural product engineering was also explored with the characterisation of two relaxed specificity adenylation domains (A-domains) from the biosynthetic pathway of the toxin microcystin. The wide variety of microcystin compounds produced by cyanobacterial species suggests that multiple amino acids can be activated by the same A-domain. This was supported by preliminary ATP-[32P]PPi exchange assays and was subsequently harnessed in the production of a variety of dipeptides using two reconstituted modules in vitro. Transposition was investigated as a potential mechanism for the transfer of nonribosomal peptide synthetase gene clusters to heterologous hosts. This was performed via the characterisation of the putative transposase, Mat, physically linked with the microcystin synthetase gene cluster (mcyS). PCR screening, in silico analysis and nitrocellulose filter binding assays indicated that this transposase may have mediated mcyS gene cluster rearrangements but not entire gene cluster mobilisation between species. The potential role of transposases in the natural combinatorial biosynthesis of microcystin has evolutionary implications for the dynamic nature of cyanobacterial genomes and applications for use in the engineering of novel bioactive compounds. Therefore, the results from this study may provide a biotechnological platform for the transfer, expression and combinatorial biosynthesis of novel cyanobacterial-derived natural products.

Phosphopantetheinyl transferase

Cyanobacteria

Transposase

Unnatural production of natural products: Heterologous expression and combinatorial biosynthesis of cyanobacterial-derived compounds

Roberts, Alexandra Anne, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

Cyanobacteria produce a myriad of structurally unique secondary metabolites with useful bioactive properties. Heterologous expression of a variety of microbial natural compounds has been used to harness their diversity and facilitate their combinatorial biosynthesis. However, these genetic techniques have not been developed for secondary metabolite-producing cyanobacteria. Therefore the genetically manipulable Escherichia coli and Synechocystis sp. PCC6803 were engineered in order to develop effective heterologous hosts and promoters for the expression of cyanobacterial-derived compounds. The phosphopanthetheinyl transferase (PPT), Sppt, from Synechocystis sp. PCC6803 was characterised to determine its ability to activate carrier proteins from secondary metabolite pathways. Despite in silico evidence which suggested Sppt was able to activate a wide range of carrier proteins, biochemical analysis revealed that it is dedicated for fatty acid synthesis. Consequently, E. coli and Synechocystis sp. PCC6803 were engineered to encode a broad-range PPT, from the filamentous cyanobacteria Nodularia spumigena NSOR10, for the activation of carrier proteins from nonribosomal peptide synthesis. Cyanobacterial natural product engineering was also explored with the characterisation of two relaxed specificity adenylation domains (A-domains) from the biosynthetic pathway of the toxin microcystin. The wide variety of microcystin compounds produced by cyanobacterial species suggests that multiple amino acids can be activated by the same A-domain. This was supported by preliminary ATP-[32P]PPi exchange assays and was subsequently harnessed in the production of a variety of dipeptides using two reconstituted modules in vitro. Transposition was investigated as a potential mechanism for the transfer of nonribosomal peptide synthetase gene clusters to heterologous hosts. This was performed via the characterisation of the putative transposase, Mat, physically linked with the microcystin synthetase gene cluster (mcyS). PCR screening, in silico analysis and nitrocellulose filter binding assays indicated that this transposase may have mediated mcyS gene cluster rearrangements but not entire gene cluster mobilisation between species. The potential role of transposases in the natural combinatorial biosynthesis of microcystin has evolutionary implications for the dynamic nature of cyanobacterial genomes and applications for use in the engineering of novel bioactive compounds. Therefore, the results from this study may provide a biotechnological platform for the transfer, expression and combinatorial biosynthesis of novel cyanobacterial-derived natural products.

Phosphopantetheinyl transferase

Cyanobacteria

Transposase

Unnatural production of natural products: Heterologous expression and combinatorial biosynthesis of cyanobacterial-derived compounds

Roberts, Alexandra Anne, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

Cyanobacteria produce a myriad of structurally unique secondary metabolites with useful bioactive properties. Heterologous expression of a variety of microbial natural compounds has been used to harness their diversity and facilitate their combinatorial biosynthesis. However, these genetic techniques have not been developed for secondary metabolite-producing cyanobacteria. Therefore the genetically manipulable Escherichia coli and Synechocystis sp. PCC6803 were engineered in order to develop effective heterologous hosts and promoters for the expression of cyanobacterial-derived compounds. The phosphopanthetheinyl transferase (PPT), Sppt, from Synechocystis sp. PCC6803 was characterised to determine its ability to activate carrier proteins from secondary metabolite pathways. Despite in silico evidence which suggested Sppt was able to activate a wide range of carrier proteins, biochemical analysis revealed that it is dedicated for fatty acid synthesis. Consequently, E. coli and Synechocystis sp. PCC6803 were engineered to encode a broad-range PPT, from the filamentous cyanobacteria Nodularia spumigena NSOR10, for the activation of carrier proteins from nonribosomal peptide synthesis. Cyanobacterial natural product engineering was also explored with the characterisation of two relaxed specificity adenylation domains (A-domains) from the biosynthetic pathway of the toxin microcystin. The wide variety of microcystin compounds produced by cyanobacterial species suggests that multiple amino acids can be activated by the same A-domain. This was supported by preliminary ATP-[32P]PPi exchange assays and was subsequently harnessed in the production of a variety of dipeptides using two reconstituted modules in vitro. Transposition was investigated as a potential mechanism for the transfer of nonribosomal peptide synthetase gene clusters to heterologous hosts. This was performed via the characterisation of the putative transposase, Mat, physically linked with the microcystin synthetase gene cluster (mcyS). PCR screening, in silico analysis and nitrocellulose filter binding assays indicated that this transposase may have mediated mcyS gene cluster rearrangements but not entire gene cluster mobilisation between species. The potential role of transposases in the natural combinatorial biosynthesis of microcystin has evolutionary implications for the dynamic nature of cyanobacterial genomes and applications for use in the engineering of novel bioactive compounds. Therefore, the results from this study may provide a biotechnological platform for the transfer, expression and combinatorial biosynthesis of novel cyanobacterial-derived natural products.

Phosphopantetheinyl transferase

Cyanobacteria

Transposase

Unnatural production of natural products: Heterologous expression and combinatorial biosynthesis of cyanobacterial-derived compounds

Roberts, Alexandra Anne, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

Cyanobacteria produce a myriad of structurally unique secondary metabolites with useful bioactive properties. Heterologous expression of a variety of microbial natural compounds has been used to harness their diversity and facilitate their combinatorial biosynthesis. However, these genetic techniques have not been developed for secondary metabolite-producing cyanobacteria. Therefore the genetically manipulable Escherichia coli and Synechocystis sp. PCC6803 were engineered in order to develop effective heterologous hosts and promoters for the expression of cyanobacterial-derived compounds. The phosphopanthetheinyl transferase (PPT), Sppt, from Synechocystis sp. PCC6803 was characterised to determine its ability to activate carrier proteins from secondary metabolite pathways. Despite in silico evidence which suggested Sppt was able to activate a wide range of carrier proteins, biochemical analysis revealed that it is dedicated for fatty acid synthesis. Consequently, E. coli and Synechocystis sp. PCC6803 were engineered to encode a broad-range PPT, from the filamentous cyanobacteria Nodularia spumigena NSOR10, for the activation of carrier proteins from nonribosomal peptide synthesis. Cyanobacterial natural product engineering was also explored with the characterisation of two relaxed specificity adenylation domains (A-domains) from the biosynthetic pathway of the toxin microcystin. The wide variety of microcystin compounds produced by cyanobacterial species suggests that multiple amino acids can be activated by the same A-domain. This was supported by preliminary ATP-[32P]PPi exchange assays and was subsequently harnessed in the production of a variety of dipeptides using two reconstituted modules in vitro. Transposition was investigated as a potential mechanism for the transfer of nonribosomal peptide synthetase gene clusters to heterologous hosts. This was performed via the characterisation of the putative transposase, Mat, physically linked with the microcystin synthetase gene cluster (mcyS). PCR screening, in silico analysis and nitrocellulose filter binding assays indicated that this transposase may have mediated mcyS gene cluster rearrangements but not entire gene cluster mobilisation between species. The potential role of transposases in the natural combinatorial biosynthesis of microcystin has evolutionary implications for the dynamic nature of cyanobacterial genomes and applications for use in the engineering of novel bioactive compounds. Therefore, the results from this study may provide a biotechnological platform for the transfer, expression and combinatorial biosynthesis of novel cyanobacterial-derived natural products.

Phosphopantetheinyl transferase

Cyanobacteria

Transposase

Crystallographic and functional study on DNA binding proteins: repressor and partitioning protein KorB from RP4 plasmid and the transposase "Sleeping Beauty" of vertebrate origin

Khare, Dheeraj.

January 2004

Berlin, Freie Universiẗat, Diss., 2004. / Dateiformat: zip, Dateien im PDF-Format.

Plasmid RP4 Transposase

Biochemische und funktionelle Untersuchungen der Transposase des Activator-Elements aus Zea mays

Adolphs, Ruth Hedwig.

Unknown Date

Universiẗat, Diss., 2001--München.

DNA repair by the Mu transposase

Choi, Wonyoung

14 December 2010

Phage Mu transposes by two distinct pathways depending on the specific stage of its life cycle. A common θ strand transfer intermediate is resolved differentially in the two pathways. During lytic growth, the θ intermediate is resolved by replication of Mu initiated within the flanking target DNA; during integration of infecting Mu, it is resolved without replication, by removal and repair of DNA from a previous host that is still attached to the ends of the incoming Mu genome. Our studies show that the cryptic endonuclease activity reported for the isolated C-terminal domain of the transposase MuA, which is not observed in the full-length protein or in the assembled transpososome in vitro, is required in vivo for removal of the attached host DNA or “5’flap” after the infecting Mu genome has integrated into the E. coli chromosome. I have identified additional phage and host factors required for flap removal in vivo, which include an early Mu protein called Ner, and the E. coli protein ClpX. Ner regulates bidirectional transcription through the Mu transposition enhancer, while ClpX, a molecular chaperone, is known to interact with the C-terminus of MuA to remodel the transpososome for replication. The transpososome is a multi-subunit MuA complex assembled on the two paired ends of Mu. The enhancer DNA segment serves as an essential scaffold for transpososome assembly, and remains stably associated with θ strand transfer MuA complexes. I hypothesize that Ner-regulated transcription through the enhancer remodels transpososome conformation in the presence of ClpX, promoting activation of the MuA endonuclease, which resects flanking DNA during the repair pathway of Mu transposition. / text

Mu DNA transposition

MuA transposase

ClpX

Mécanismes de transposition et de régulation de la transposase de l'élément mariner Mos1 / Mecanisms of transposition and regulation of the mariner Mos1 element

Bouchet, Nicolas

23 October 2009

L’élément mariner Mos1 est un élément transposable de classe II qui code une transposase, l’enzyme permettant aux transposons de se déplacer dans les génomes. Cette transposase possède un coeur catalytique DDE similaire à celui des intégrases rétrovirales. Mon travail de thèse a consisté en l’étude de la transposase de Mos1, sous différents aspects. Mes résultats complètent le modèle de transposition précédemment établi au laboratoire et apportent une nouvelle vision de la formation du complexe synaptique qui permet l’excision de transposon du site donneur. Mes travaux ont également permis d’identifier le domaine de liaison à l’ADN de la transposase comme un domaine de type CRO. L’étude de la régulation de l’activité de la transposase, qui est phosphorylée, m’a permis d’élargir le modèle de transposition de Mos1 au contexte cellulaire eucaryote, et des études d’ingénierie de la protéine posent la question de l’impact des facteurs d’hôtes lors de la transposition de Mos1. Enfin, des inhibiteurs de la transposase de Mos1 ont été identifiés et leur mode d’action caractérisé. Ces composés présentent également une activité sur l’intégrase du VIH-1 et une autre transposase à cœur catalytique DDE. / The Mos1 mariner element is a Class II transposable element, encoding a transposase, which is the enzyme allowing them to move in the genomes. This transposase has a DDE catalytic core like the retroviral integrases. My work consisted in studying the Mos1 transposase, under different aspects. My results complete the model of transposition previously established in the laboratory and bring a new vision of the formation of synaptic complex, which allows excision of the transposon donor site. The DNA-binding of Mos1 transposase has also been identified as a CRO-like domain. Work on regulation of the activity of Mos1 transposase, which is phosphorylated, allowed me to expand the model of Mos1 transposition in a eukaryotic cell context. The engineering of the protein were also conducted and questions about the impact of host factors on Mos1 transposition. Inhibitors of Mos1 transposase have been identified and characterized. These compounds also inhibit HIV-1 integrase and an other DDE transposase.

Mos1

Enzymes à coeur catalytique DDE

Transposase

Estudo de dois grupos de elementos de cana-de-açúcar homológos à superfamília hAT de transposons / Studies on hAT-like transposases in sugarcane superfamily

Jesus, Erika Maria de

18 June 2007

Os elementos de transposicão (TEs) são sequências genéticas móveis. Sua capacidade mutagênica faz deles uma importante fonte de variabilidade nos genomas. Outro importante papel dos TEs na evolução dos genomas é o de doadores de domínios protéicos na formação de novos genes. 276 clones de cDNA homólogos a TEs foram previamente identificados no banco de dados do SUCEST (projeto de sequenciamento de etiquetas expressas de cana-de-acúcar). Neste trabalho nós realizamos o sequenciamento completo de 156 destes clones e a classificação e caracterização de suas sequências comparando-as com bancos de dados. Foram identificadas 9 diferentes famílias de transposons e 11 diferentes famílias de retrotransposons. As famílias mais representadas entre os transposons foram MuDr e hAT (que engloba os elementos do tipo Ac e Tam3), para os quais foram identificados 43 e 32 clones de cDNA, respectivamente. Entre os retrotransposons, a família mais representada foi Hopscotch, apresentando 25 clones de cDNA. Após esta análise global, o foco das investigações voltou-se para os cDNAs do tipo hAT. Uma análise comparativa destes cDNAs revelou que as sequências homólogas a hAT estão distribuídas em dois grupos. O grupo I, é composto por sequências com alta conservação no nível de nucleotídeos, está presente no genoma de todas as gramíneas analisadas (híbridos e parentais da cana-de-acúcar, milho e arroz) com um baixo número de cópias, teve a sua expressão detectada em folhas, raízes e mais intensamente em calos cana. Além disso, apresenta alta similaridade de sequências com transposases domesticadas descritas na literatura. O grupo II, por sua vez, é composto por sequências mais heterogêneas, que apresentam similaridade com os transposons originais que constituem a superfamília hAT: hobo (de Drosophila melanogaster), Ac (de Zea mays) e Tam3 (de Antirrhinum majus). Sua distribuição é restrita ao genoma de Saccharum, com um número de cópias maior que o grupo I. Um ensaio de PCR-Inversa identificou terminações inversas repetidas (TIRs) para o cDNA TE221 do grupo II. A partir de iniciadores desenhados sobre estas TIRs foi possível recuperar dois elementos, de 3,5kb e 4,2kb, respectivamente, e um MITE de 250 pb, todos homólogos a hAT. Este resultado demonstrou que a estratégia utilizada para recuperar elementos do genoma da cana-de-açúcar a partir do cDNA TE221 mostrou-se eficiente. Homólogos aos grupos I e II de cana-de-acúcar foram identificados em bancos de dados de milho, arroz e arabidopsis. Estes dados sugerem que a separação dos dois grupos ocorreu antes da divergência entre as classes Monocotiledonea e Eudicotiledonea. Com base nos resultados aqui apresentados sugerimos que um transposon ancestral do tipo hAT, presente nas angiospermas anteriormente à separação de Monocotiledonea e Eudicotiledonea, teve sua transposase capturada na formação de um gene com função celular. A partir do evento da domesticação, estas transposases seguiram dois caminhos evolutivos distintos, um como gene funcional e outro como um transposon tradicional. Estas duas formas de transposase do tipo hAT podem ser encontradas no genoma da cana-de-acúcar, representadas pelos elementos dos grupos I e II, respectivamente. / Transposable elements (TEs) are mobile genetic sequences. Their mutagenic capacity makes them important sources of variation in the genomes. These elements have another important evolutionary role as donors of functional protein domains in the formation of new genes. 276 cDNA clones homologous to TEs were previously identified in the Brazilian Sugarcane Expressed Sequence Tag Project (SUCEST) databases. In this work, we have obtained the full sequences of 156 for these clones. These sequences were compared with Genbank database. We have identified 9 families of transposons and 11 families of retrotransposons. The most representative families found amongst the transposons were MuDr and hAT (wich encompass Ac and Tam3), with 43 and 32 cDNAs, respectively. Amongst the retrotransposons, the most representative family was Hopscotch, with 25 cDNAs. After this global analysis, we have focused our investigation in the hAT-like cDNAs. A comparative analysis of these cDNAs has revealed a profile of two distinct groups. Group I is composed of sequences with high conservation at nucleotide level, it is present in the genome of all grasses analysed (hybrids and parentals of sugarcane, maize and rice) with low copy number, it is expressed in leaves and roots of sugarcane, and more intensely in callus. In addition, group I sequences have clustered with domesticated transposases. The group II is composed of more heterogeneous sequences similar with the original elements that constitute the hAT superfamily: hobo (from Drosophilla melanogaster), Ac (from Zea mays) and Tam3 (from Antirrhinum majus). This group was shown to be restricted to the genome of Saccharum, with higher copy number than group one. Inverse-PCR assays has identified terminal inverted repeats (TIRs) to the cDNA TE221 from group II. Primers based on the sequences of the TIRs allowed us to recover three elements hAT-like from sugarcane’s genomic DNA: one of 3,5kb and another of 4,2kb, and a MITE of 250 bp. These results corroborate the strategy applied in order to recover elements from the sugarcane´s genome. Sequences homologous to both sugarcane group I and group II were found also in maize and rice, as well as in arabidopsis databases. These data suggest that the divergence of the two groups occured before the separation between the classes Monocotiledonea and Eudicotiledonea. Based on our results, we suggest the existence of an ancestral transposon hAT-like, present in angiosperms before the separation between Monocotiledonea and Eudicotiledonea, of which the transposase was captured to compose a new gene with some cellular function. Since the domestication event, these transposases followed distinct evolutive pathways, one as a regular gene and another as a bona fide transposon. These two forms of hAT-like transposases could be found in the sugarcane’s genome, represented by the elements from groups I and II, respectively.

hAT superfamily

Cana-de-açúcar

Domesticated transposase

Sugarcane

Superfamília hAT

Transposase domesticada

Transposon

Transposon

Estudo de dois grupos de elementos de cana-de-açúcar homológos à superfamília hAT de transposons / Studies on hAT-like transposases in sugarcane superfamily

Erika Maria de Jesus

18 June 2007

Os elementos de transposicão (TEs) são sequências genéticas móveis. Sua capacidade mutagênica faz deles uma importante fonte de variabilidade nos genomas. Outro importante papel dos TEs na evolução dos genomas é o de doadores de domínios protéicos na formação de novos genes. 276 clones de cDNA homólogos a TEs foram previamente identificados no banco de dados do SUCEST (projeto de sequenciamento de etiquetas expressas de cana-de-acúcar). Neste trabalho nós realizamos o sequenciamento completo de 156 destes clones e a classificação e caracterização de suas sequências comparando-as com bancos de dados. Foram identificadas 9 diferentes famílias de transposons e 11 diferentes famílias de retrotransposons. As famílias mais representadas entre os transposons foram MuDr e hAT (que engloba os elementos do tipo Ac e Tam3), para os quais foram identificados 43 e 32 clones de cDNA, respectivamente. Entre os retrotransposons, a família mais representada foi Hopscotch, apresentando 25 clones de cDNA. Após esta análise global, o foco das investigações voltou-se para os cDNAs do tipo hAT. Uma análise comparativa destes cDNAs revelou que as sequências homólogas a hAT estão distribuídas em dois grupos. O grupo I, é composto por sequências com alta conservação no nível de nucleotídeos, está presente no genoma de todas as gramíneas analisadas (híbridos e parentais da cana-de-acúcar, milho e arroz) com um baixo número de cópias, teve a sua expressão detectada em folhas, raízes e mais intensamente em calos cana. Além disso, apresenta alta similaridade de sequências com transposases domesticadas descritas na literatura. O grupo II, por sua vez, é composto por sequências mais heterogêneas, que apresentam similaridade com os transposons originais que constituem a superfamília hAT: hobo (de Drosophila melanogaster), Ac (de Zea mays) e Tam3 (de Antirrhinum majus). Sua distribuição é restrita ao genoma de Saccharum, com um número de cópias maior que o grupo I. Um ensaio de PCR-Inversa identificou terminações inversas repetidas (TIRs) para o cDNA TE221 do grupo II. A partir de iniciadores desenhados sobre estas TIRs foi possível recuperar dois elementos, de 3,5kb e 4,2kb, respectivamente, e um MITE de 250 pb, todos homólogos a hAT. Este resultado demonstrou que a estratégia utilizada para recuperar elementos do genoma da cana-de-açúcar a partir do cDNA TE221 mostrou-se eficiente. Homólogos aos grupos I e II de cana-de-acúcar foram identificados em bancos de dados de milho, arroz e arabidopsis. Estes dados sugerem que a separação dos dois grupos ocorreu antes da divergência entre as classes Monocotiledonea e Eudicotiledonea. Com base nos resultados aqui apresentados sugerimos que um transposon ancestral do tipo hAT, presente nas angiospermas anteriormente à separação de Monocotiledonea e Eudicotiledonea, teve sua transposase capturada na formação de um gene com função celular. A partir do evento da domesticação, estas transposases seguiram dois caminhos evolutivos distintos, um como gene funcional e outro como um transposon tradicional. Estas duas formas de transposase do tipo hAT podem ser encontradas no genoma da cana-de-acúcar, representadas pelos elementos dos grupos I e II, respectivamente. / Transposable elements (TEs) are mobile genetic sequences. Their mutagenic capacity makes them important sources of variation in the genomes. These elements have another important evolutionary role as donors of functional protein domains in the formation of new genes. 276 cDNA clones homologous to TEs were previously identified in the Brazilian Sugarcane Expressed Sequence Tag Project (SUCEST) databases. In this work, we have obtained the full sequences of 156 for these clones. These sequences were compared with Genbank database. We have identified 9 families of transposons and 11 families of retrotransposons. The most representative families found amongst the transposons were MuDr and hAT (wich encompass Ac and Tam3), with 43 and 32 cDNAs, respectively. Amongst the retrotransposons, the most representative family was Hopscotch, with 25 cDNAs. After this global analysis, we have focused our investigation in the hAT-like cDNAs. A comparative analysis of these cDNAs has revealed a profile of two distinct groups. Group I is composed of sequences with high conservation at nucleotide level, it is present in the genome of all grasses analysed (hybrids and parentals of sugarcane, maize and rice) with low copy number, it is expressed in leaves and roots of sugarcane, and more intensely in callus. In addition, group I sequences have clustered with domesticated transposases. The group II is composed of more heterogeneous sequences similar with the original elements that constitute the hAT superfamily: hobo (from Drosophilla melanogaster), Ac (from Zea mays) and Tam3 (from Antirrhinum majus). This group was shown to be restricted to the genome of Saccharum, with higher copy number than group one. Inverse-PCR assays has identified terminal inverted repeats (TIRs) to the cDNA TE221 from group II. Primers based on the sequences of the TIRs allowed us to recover three elements hAT-like from sugarcane’s genomic DNA: one of 3,5kb and another of 4,2kb, and a MITE of 250 bp. These results corroborate the strategy applied in order to recover elements from the sugarcane´s genome. Sequences homologous to both sugarcane group I and group II were found also in maize and rice, as well as in arabidopsis databases. These data suggest that the divergence of the two groups occured before the separation between the classes Monocotiledonea and Eudicotiledonea. Based on our results, we suggest the existence of an ancestral transposon hAT-like, present in angiosperms before the separation between Monocotiledonea and Eudicotiledonea, of which the transposase was captured to compose a new gene with some cellular function. Since the domestication event, these transposases followed distinct evolutive pathways, one as a regular gene and another as a bona fide transposon. These two forms of hAT-like transposases could be found in the sugarcane’s genome, represented by the elements from groups I and II, respectively.

Cana-de-açúcar

Superfamília hAT

Transposase domesticada

Transposon

hAT superfamily

Domesticated transposase

Sugarcane

Transposon