Perfil de expressão e organização genômica de micrornas músculo-específicos na tilápia-do-nilo (Oreochromis nicoticus)

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Mapeamento físico de genes ribosomais 18S e 5S nos cromossomos de espécies simpáticas do gênero Gymnotus (Teleostei, Gymnotiformes, Gymnotidae)

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Dinâmica evolutiva de DNAs repetitivos com ênfase em espécies da tribo Phanaeini

Pós-graduação em Ciências Biológicas (Genética) - IBB

Análises moleculares na subfamília hypoptopomatinae (Siluriformes, Loricariidae): isolamento, caracterização e mapeamento cromossômico de sequências repetitivas

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Caracterização molecular de proetínas envolvidas nos mecanismos de homeostase de cobre em Xanthomonas citri subsp. citri

Pós-graduação em Biotecnologia - IQ

Dinâmica evolutiva dos clusters de pequenos RNAs nucleares (RNAsn) nos cariótipos de espécies de gafanhotos com ênfase em Acrididae

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Identificação e caracterização de elementos retrotransponíveis da família Rex do genoma de espécies do genêro Leporinus SPIX, 1829 (Teleostei: Anostomidae)

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Organização genômima e análise da expressão do gene hnRNP Q-like (Heterogeneous nuclear ribonucleoprotein A-like) retroinserido no cromossomo B de Astatotilapia latifasciata

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Chromosome mapping of retrotransposable elements Rex1 and Rex3 in Leporinus Spix, 1829 species (Characiformes: Anostomidae) and its relationships among heterochromatic segments and W sex chromosome

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Diversidade cariotípica e molecular de Leptodactylus (Anura, Leptodactylidae) e obtenção de sondas cromossomo-específicas de anfíbio por citometria de fluxo

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

A novel linkage map of sugarcane with evidence for clustering of retrotransposon-based markers

Background: The development of sugarcane as a sustainable crop has unlimited applications. The crop is one of the most economically viable for renewable energy production, and CO2 balance. Linkage maps are valuable tools for understanding genetic and genomic organization, particularly in sugarcane due to its complex polyploid genome of multispecific origins. The overall objective of our study was to construct a novel sugarcane linkage map, compiling AFLP and EST-SSR markers, and to generate data on the distribution of markers anchored to sequences of scIvana_1, a complete sugarcane transposable element, and member of the Copia superfamily. Results: The mapping population parents ('IAC66-6' and 'TUC71-7') contributed equally to polymorphisms, independent of marker type, and generated markers that were distributed into nearly the same number of co-segregation groups (or CGs). Bi-parentally inherited alleles provided the integration of 19 CGs. The marker number per CG ranged from two to 39. The total map length was 4,843.19 cM, with a marker density of 8.87 cM. Markers were assembled into 92 CGs that ranged in length from 1.14 to 404.72 cM, with an estimated average length of 52.64 cM. The greatest distance between two adjacent markers was 48.25 cM. The scIvana_1-based markers (56) were positioned on 21 CGs, but were not regularly distributed. Interestingly, the distance between adjacent scIvana_1-based markers was less than 5 cM, and was observed on five CGs, suggesting a clustered organization. Conclusions: Results indicated the use of a NBS-profiling technique was efficient to develop retrotransposon-based markers in sugarcane. The simultaneous maximum-likelihood estimates of linkage and linkage phase based strategies confirmed the suitability of its approach to estimate linkage, and construct the linkage map. Interestingly, using our genetic data it was possible to calculate the number of retrotransposonscIvana_1 (similar to 60) copies in the sugarcane genome, confirming previously reported molecular results. In addition, this research possibly will have indirect implications in crop economics e. g., productivity enhancement via QTL studies, as the mapping population parents differ in response to an important fungal disease.

In vitro expression and antiserum production against the movement protein of Citrus leprosis virus C (CiLV-C)

Citrus leprosis, caused by Citrus leprosis virus C (CiLV-C), is currently considered the most important viral disease in the Brazilian citrus industry due to the high costs required for the chemical control of its vector, the mite Brevipalpus phoenicis. The pathogen induces a non-systemic infection and the disease is characterized by the appearance of localized lesions on citrus leaves, stems and fruits, premature fruit and leaf drop and dieback of stems. Attempts were made to promote in vitro expression of the putative cell-to-cell movement protein of CiLV-C in Escherichia coli and to produce a specific polyclonal antibody against this protein as a tool to investigate the virus-plant-vector relationship. The antibody reacted strongly with the homologous protein expressed in vitro by ELISA, but poorly with the native protein present in leaf lesion extracts from sweet orange caused by CiLV-C. Reactions from old lesions were more intense than those from young lesions. Western blot and in situ immunolocalization assays failed to detect the native protein. These results suggest low expression of the movement protein (MP) in host tissues. Moreover, it is possible that the conformation of the protein expressed in vitro and used to produce the antibody differs from that of the native MP, hindering a full recognition of the latter.

Genomische Struktur und Promotorcharakterisierung des humanen ADAM10-Gens

Das ADAM10-Gen kodiert für eine membrangebundene Disintegrin-Metalloproteinase, die das Amyloidvorläuferprotein spaltet. Im Mausmodell konnte bewiesen werden, dass die Überexpression von ADAM10 die Plaquebildung vermindern und das Langzeitgedächtnis verbessert. Aus diesem Grund ist es für einen möglichen Therapieansatz für die Alzheimer’sche Erkrankung erforderlich, die Organisation des humanen ADAM10-Gens und seines Promotors aufzuklären. Beim Vergleich der genomischen Sequenzen von humanem und murinem ADAM10 zeigte sich eine hohe Übereinstimmung. Beide Gene umfassen 160 kbp und bestehen aus 16 Exons. Die ersten 500 bp stromaufwärts vom Translationsstartpunkt zwischen dem Menschen, der Maus und der Ratte sind hoch konserviert. Diese Region beinhaltet spezifische regulatorische Elemente, die die ADAM10-Transkription modulieren. In den ersten 2179 bp stromaufwärts vom humanen ADAM10-Translationsstartpunkt fanden sich einige potentiellen Transkriptionsfaktor-bindungsstellen (Brn-2, SREBP, Oct-1, Creb1/cJun, USF, Maz, MZF-1, NFkB und CDPCR3HD). Es wurde eine charakteristische GC-Box und eine CAAT-Box, aber keine TATA-Box identifiziert. Nach Klonierung dieser 2179 bp großen Region wurde eine starke Promotoraktivität, insbesondere in neuronalen Zelllinien, gefunden. Bei der Analyse von Deletionskonstrukten wurde die Region zwischen -508 und -300 als essentiell für die Transkriptionsaktivierung bestimmt. Die Promotoraktivität wird zudem streng herunterreguliert, wenn in die Region 317 bp stromaufwärts vom Startpunkt der Translation eine Punktmutation eingeführt wird. Diese per Computeranalyse als USF-Bindungsstelle deklarierte Region spielt eine zentrale Rolle bei der ADAM10-Transkription. Im EMSA wurde eine Protein-DNA-Interaktion für diese Region gezeigt. Durch transienten Transfektionen in Schneider Drosophila Insektenzellen konnte nachgewiesen werden, dass die Überexpression von Sp1 und USp3 für die ADAM10-Promotoraktivität entscheidend ist. In EMSA-Studien bestätigte sich eine Protein-DNA-Interaktion für die Region -366 bp stromaufwärts vom Translationsstartpunkt. Die Punktmutation in der CAAT-Box veränderte die die Promotoraktivität nicht. Da weiterhin für diese potentielle Bindungsstelle kein Bindungsfaktor vorausgesagt wurde, scheint die CAAT-Box keine Bedeutung bei der Promotorregulation zu spielen. Schließlich fand sich im EMSA eine Protein-DNA-Interaktion für die Bindungsstelle 203 bp stromaufwärts vom Translationsstartpunkt. Diese in Computeranalysen als RXR-Bindungsstelle identifizierte Region ist ebenfalls von Bedeutung in der Promotorregulation. Auf der Suche nach Substanzen, die die ADAM10-Promotoraktivität beeinflussen, wurde ein negativer Effekt durch die apoptoseauslösende Substanz Camptothecin und ein positiver Effekt durch die zelldifferenzierungsauslösende Substanz all-trans Retinsäure festgestellt. Mit dieser Arbeit wurde die genomische Organisation des ADAM10-Gens zusammen mit dem zugehörigen Promotor aufgeklärt und ein neuer Regulationsmechanismus für die Hochregulation der Expression der alpha-Sekretase ADAM10 gefunden. Im Weiteren sollen nun die genauen Mechanismen bei der Hochregulation der alpha-Sekretase ADAM10 durch Retinsäure untersucht und durch Mikroarray-Analysen an RNA-Proben transgener Mäuse, welche ADAM10 überexpremieren, neue therapeutische Ansätze zur Behandlung der Alzheimer´schen Erkrankung identifiziert werden.

Strukturelle und funktionelle Untersuchungen zur Bedeutung der endogenen retroviralen Insertion HERV-K(C4) im C4-Gen des Menschen

Der Längenpolymorphismus des C4-Gens beruht auf der An- oder Abwesenheit einer 6.4 kb langen Insertion im Intron 9. Es handelt sich dabei um einen eigenständigen bisher noch nicht beschriebenen Virus-Typ, der alle Sequenzmerkmale der Familie der humanen endogenen Retroviren (HERV) trägt und zu den HERV-K Viren gehört. Der Provirus wurde als HERV-K(C4) bezeichnet. Die Orientierung dieses retroviralen Elements ist entgegengesetzt zu der Transkriptionsrichtung des C4-Gens. Mittels RT-PCR, RNase Protection Assays und Northern-Blot Analysen konnte der Nachweis von HERV-K(C4)-Antisense mRNA-Transkripten in verschiedenen humanen Zellinien und Geweben erbracht werden. Die retroviralen Transkripte schlossen am 5'- und 3'-Ende Sequenzen des C4-Exon 9 und Exon 10 ein, so daß diese wahrscheinlich "readthrough" Transkripte darstellen, die durch einen 5' des LTR2 gelegenen Promotor initiiert oder im Zusammenhang mit der C4-Expression transkribiert und reguliert werden. Weiterhin konnten insgesamt 4 HERV-K(C4)-mRNA Spezies, einschließlich einer Vollängen-RNA detektiert werden. Die drei subgenomischen mRNAs werden vermutlich durch einfaches und mehrfaches Spleißen generiert. Die quantitative Analyse in verschiedenen humanen Zellinien ergab, daß HERV-K(C4) durchschnittlich mit einer Kopienanzahl zwischen ca.1 bis 100 Transkripten in einer Zelle vorkommt, so daß es sich um low abundance mRNAs handelt. Mittels eines Reportergen-System konnte eine Aktivität des LTR2-Promotors in der Sense-Orientierung des Retrovirus nachgewiesen werden, die nach Stimulation mit IFN- signifikant abnahm. Ein humanes Modell-Systems wurde etabliert, um die Theorie einer Antisense-Abwehr gegen exogene Retroviren in HepG2-Zellen zu überprüfen. Die Theorie basiert auf dem Nachweis von HERV-K(C4)-Antisense-Transkripten, die über eine Heteroduplexbildung mit der Sense-mRNA von verwandten, infektiösen Retroviren eine mögliche Blockierung deren Translation erwirken könnten. Es konnte eine signifikante Abnahme der retroviralen Expression von bis zu 45% nach steigenden Dosen an IFN- in HepG2-Zellen nachgewiesen werden. Der funktionell aktive 3'-LTR-Sense Promotor sowie der Nachweis von HERV-K(C4)-Antisense Transkripten sprechen für die bedeutende Rolle von HERV-K(C4) bei der Genregulation und Schutz gegen exogene Retroviren, wodurch eine Selektion stattgefunden hat.

Reverse genetic studies of Benyvirus - Polymyxa betae molecular interaction: Role of the RNA4-encoded protein in virus transmission

Beet necrotic yellow vein virus (BNYVV), the leading infectious agent that affects sugar beet, is included within viruses transmitted through the soil from plasmodiophorid as Polymyxa betae. BNYVV is the causal agent of Rhizomania, which induces abnormal rootlet proliferation and is widespread in the sugar beet growing areas in Europe, Asia and America; for review see (Peltier et al., 2008). In this latter continent, Beet soil-borne mosaic virus (BSBMV) has been identified (Lee et al., 2001) and belongs to the benyvirus genus together with BNYVV, both vectored by P. betae. BSBMV is widely distributed only in the United States and it has not been reported yet in others countries. It was first identified in Texas as a sugar beet virus morphologically similar but serologically distinct to BNYVV. Subsequent sequence analysis of BSBMV RNAs evidenced similar genomic organization to that of BNYVV but sufficient molecular differences to distinct BSBMV and BNYVV in two different species (Rush et al., 2003). Benyviruses field isolates usually consist of four RNA species but some BNYVV isolates contain a fifth RNA. RNAs -1 contains a single long ORF encoding polypeptide that shares amino acid homology with known viral RNA-dependent RNA polymerases (RdRp) and helicases. RNAs -2 contains six ORFs: capsid protein (CP), one readthrough protein, triple gene block proteins (TGB) that are required for cell-to-cell virus movement and the sixth 14 kDa ORF is a post-translation gene silencing suppressor. RNAs -3 is involved on disease symptoms and is essential for virus systemic movement. BSBMV RNA-3 can be trans-replicated, trans-encapsidated by the BNYVV helper strain (RNA-1 and -2) (Ratti et al., 2009). BNYVV RNA-4 encoded one 31 kDa protein and is essential for vector interactions and virus transmission by P. betae (Rahim et al., 2007). BNYVV RNA-5 encoded 26 kDa protein that improve virus infections and accumulation in the hosts. We are interest on BSBMV effect on Rhizomania studies using powerful tools as full-length infectious cDNA clones. B-type full-length infectious cDNA clones are available (Quillet et al., 1989) as well as A/P-type RNA-3, -4 and -5 from BNYVV (unpublished). A-type BNYVV full-length clones are also available, but RNA-1 cDNA clone still need to be modified. During the PhD program, we start production of BSBMV full-length cDNA clones and we investigate molecular interactions between plant and Benyviruses exploiting biological, epidemiological and molecular similarities/divergences between BSBMV and BNYVV. During my PhD researchrs we obtained full length infectious cDNA clones of BSBMV RNA-1 and -2 and we demonstrate that they transcripts are replicated and packaged in planta and able to substitute BNYVV RNA-1 or RNA-2 in a chimeric viral progeny (BSBMV RNA-1 + BNYVV RNA-2 or BNYVV RNA-1 + BSBMV RNA-2). During BSBMV full-length cDNA clones production, unexpected 1,730 nts long form of BSBMV RNA-4 has been detected from sugar beet roots grown on BSBMV infected soil. Sequence analysis of the new BSBMV RNA-4 form revealed high identity (~100%) with published version of BSBMV RNA-4 sequence (NC_003508) between nucleotides 1-608 and 1,138-1,730, however the new form shows 528 additionally nucleotides between positions 608-1,138 (FJ424610). Two putative ORFs has been identified, the first one (nucleotides 383 to 1,234), encode a protein with predicted mass of 32 kDa (p32) and the second one (nucleotides 885 to 1,244) express an expected product of 13 kDa (p13). As for BSBMV RNA-3 (Ratti et al., 2009), full-length BSBMV RNA-4 cDNA clone permitted to obtain infectious transcripts that BNYVV viral machinery (Stras12) is able to replicate and to encapsidate in planta. Moreover, we demonstrated that BSBMV RNA-4 can substitute BNYVV RNA-4 for an efficient transmission through the vector P. betae in Beta vulgaris plants, demonstrating a very high correlation between BNYVV and BSBMV. At the same time, using BNYVV helper strain, we studied BSBMV RNA-4’s protein expression in planta. We associated a local necrotic lesions phenotype to the p32 protein expression onto mechanically inoculated C. quinoa. Flag or GFP-tagged sequences of p32 and p13 have been expressed in viral context, using Rep3 replicons, based on BNYVV RNA-3. Western blot analyses of local lesions contents, using FLAG-specific antibody, revealed a high molecular weight protein, which suggest either a strong interaction of BSBMV RNA4’s protein with host protein(s) or post translational modifications. GFP-fusion sequences permitted the subcellular localization of BSBMV RNA4’s proteins. Moreover we demonstrated the absence of self-activation domains on p32 by yeast two hybrid system approaches. We also confirmed that p32 protein is essential for virus transmission by P. betae using BNYVV helper strain and BNYVV RNA-3 and we investigated its role by the use of different deleted forms of p32 protein. Serial mechanical inoculation of wild-type BSBMV on C. quinoa plants were performed every 7 days. Deleted form of BSBMV RNA-4 (1298 bp) appeared after 14 passages and its sequence analysis shows deletion of 433 nucleotides between positions 611 and 1044 of RNA-4 new form. We demonstrated that this deleted form can’t support transmission by P. betae using BNYVV helper strain and BNYVV RNA-3, moreover we confirmed our hypothesis that BSBMV RNA-4 described by Lee et al. (2001) is a deleted form. Interesting after 21 passages we identifed one chimeric form of BSBMV RNA-4 and BSBMV RNA-3 (1146 bp). Two putative ORFs has been identified on its sequence, the first one (nucleotides 383 to 562), encode a protein with predicted mass of 7 kDa (p7), corresponding to the N-terminal of p32 protein encoded by BSBMV RNA-4; the second one (nucleotides 562 to 789) express an expected product of 9 kDa (p9) corresponding to the C-terminal of p29 encoded by BSBMV RNA-3. Results obtained by our research in this topic opened new research lines that our laboratories will develop in a closely future. In particular BSBMV p32 and its mutated forms will be used to identify factors, as host or vector protein(s), involved in the virus transmission through P. betae. The new results could allow selection or production of sugar beet plants able to prevent virus transmission then able to reduce viral inoculum in the soil.