Effects of Trypanosoma brucei tryptophanyl-tRNA synthetases silencing by RNA interference

The kinetoplast genetic code deviates from the universal code in that 90% of mitochondrial tryptophans are specified by UGA instead of UGG codons. A single nucleus-encoded tRNA Trp(CCA) is used by both nuclear and mitochondria genes, since all kinetoplast tRNAs are imported into the mitochondria from the cytoplasm. To allow decoding of the mitochondrial UGA codons as tryptophan, the tRNA Trp(CCA) anticodon is changed to UCA by an editing event. Two tryptophanyl tRNA synthetases (TrpRSs) have been identified in Trypanosoma brucei: TbTrpRS1 and TbTrpRS2 which localize to the cytoplasm and mitochondria respectively. We used inducible RNA interference (RNAi) to assess the role of TbTrpRSs. Our data validates previous observations of TrpRS as potential drug design targets and investigates the RNAi effect on the mitochondria of the parasite

Structure of an Odorant-Binding Protein from the Mosquito Aedes aegypti Suggests a Binding Pocket Covered by a pH-Sensitive “Lid”

Background: The yellow fever mosquito, Aedes aegypti, is the primary vector for the viruses that cause yellow fever, mostly in tropical regions of Africa and in parts of South America, and human dengue, which infects 100 million people yearly in the tropics and subtropics. A better understanding of the structural biology of olfactory proteins may pave the way for the development of environmentally-friendly mosquito attractants and repellents, which may ultimately contribute to reduction of mosquito biting and disease transmission. Methodology: Previously, we isolated and cloned a major, female-enriched odorant-binding protein (OBP) from the yellow fever mosquito, AaegOBP1, which was later inadvertently renamed AaegOBP39. We prepared recombinant samples of AaegOBP1 by using an expression system that allows proper formation of disulfide bridges and generates functional OBPs, which are indistinguishable from native OBPs. We crystallized AaegOBP1 and determined its three-dimensional structure at 1.85 angstrom resolution by molecular replacement based on the structure of the malaria mosquito OBP, AgamOBP1, the only mosquito OBP structure known to date. Conclusion: The structure of AaegOBP1 (= AaegOBP39) shares the common fold of insect OBPs with six alpha-helices knitted by three disulfide bonds. A long molecule of polyethylene glycol (PEG) was built into the electron-density maps identified in a long tunnel formed by a crystallographic dimer of AaegOBP1. Circular dichroism analysis indicated that delipidated AaegOBP1 undergoes a pH-dependent conformational change, which may lead to release of odorant at low pH (as in the environment in the vicinity of odorant receptors). A C-terminal loop covers the binding cavity and this ""lid"" may be opened by disruption of an array of acid-labile hydrogen bonds thus explaining reduced or no binding affinity at low pH.National Science Foundation (NSF) [0918177]National Institutes of Health (NIH) NIAIDBrazilian National Institutes of Science and Technology: Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq) [573607/2008-7]Brazilian National Institutes of Science and Technology: FAPESP [08/57910-0

Molecular studies of two tryptophanyl tRNA synthetase from Leishmania major and a cysteine protease from Xylella fastidiosa.

As aminoacil tRNA sintetases (AaRSs) são enzimas essenciais na síntese de proteínas assegurando a correta relação entre os aminoácidos e seus tRNA cognatos. O genoma mitocondrial dos tripanossomatídeos perdeu os genes codificantes dos tRNAs, assim os tRNA mitocondriais são codificados no núcleo e importados do citoplasma. O código genético do kinetoplasto desvia do código genético pela utilização do códon de terminação UGA para a decodificação do códon do triptofano. Um único gene codificando o tRNATrp(CCA) observado no genoma de Leismania é responsável pela incorporação do aminoácido triptofano durante a síntese proteíca na mitocôndria. Para decodificar os dois códons do Trp (UGA e UGG) a base na posição 34 do tRNATrp(CCA) passa por um evento de editoração, convertendo o ribunuclotídeo C34 em U34, produzindo o tRNATrp(UCA) capaz de decodificar o códon UGA. Nesse trabalho foram caracterizadas duas triptofanil tRNA sintetases de Leishmania major. De acordo com experimentos de ?western blotting? e análises ?in silico? das seqüências de aminoácidos, uma enzima tem localização citoplasmática (LmTrpRS1) enquanto a outra mitocondrial (LmTrpRS2). Os mRNAs dos dois genes foram definidos por experimentos de 5? e 3? RT-PCR. As duas enzimas foram clonadas em diversos vetores de expressão procariotos e eucariotos. A LmTrpRS1 foi obtida somente na fração insolúvel, já a LmTrpRS2 foi obtida na fração solúvel quando clonada no vetor de expressão pET28a. Esta porém mostrou-se instável precipitando rapidamente após sua purificação. Os ensaios enzimáticos realizados com a mesma mostraram que ela é capaz de reconhecer os tRNAsTrp editado e não editado. Modelagem molecular por homologia com as duas proteínas foi realizada usando a proteína citoplasmática humana como molde, para estudar a interação entre a proteína e o tRNATrp. Xylella fastidiosa é um bactéria gram negativa limitada ao xilema, responsável por um grande número de doenças economicamente importantes, como a doença de Pierces em videiras, Clorose variegata do Citrus (CVC) e a doença da requeima das folhas em outras plantas incluindo, amendoeira, ameixeira, louro, amoreira e café. Em todos os casos a X. fastidiosa afeta o xylema da planta causando redução na produção de frutos. Nesse trabalho nós mostramos a estrutura da Xylellaína, uma cisteíno protease desse patógeno. A estrutura foi resolvida por dispersão anômala a um único comprimento de onda, utilizando cristais de xylellaína selenometionina substituídos. A estrutura da Xylellaína foi refinada até 1,65 Å de resolução, mostrando enovelamento similar às proteínas da família da papaína, porém algumas características interessantes como uma região N-terminal composta por 38 aminoácidos cobrindo o sulco ativo da enzima, um intrigante ribonucleotídeo encontrado fora do sítio ativo da enzima e um ?loop? semelhante ao ?loop? de oclusão presente na catepsina B.The aminoacyl tRNA synthetases (aaRSs) are essential enzymes in protein synthesis that ensure the correct match between amino acids and their cognate tRNAs. The mitochondrial (kinetoplast) genome of trypanossomatids lacks tRNA genes, and therefore nucleus-encoded tRNAs are imported from the cytoplasm, the kinetoplast genetic code deviates from the universal code in that UGA instead of UGG encodes for tryptophan. A single nucleus-encoded tRNATrp(CCA) is responsible for Trp insertion during organellar protein synthesis. To decode both Trp codons (UGA and UGG), tRNATrp(CCA) undergoes a single C to U editing event at position 34 of the anticodon yielding to versions of the tRNA in the mitochondria with anticodon CCA and UCA, permitting UGA decoding. This work have characterized two Leishmania major tryptophanyl-tRNA synthetase, acording western blotting experiments and ?in silico? sequence analisis one of cytoplasmatic localization (LmTrpRS1) and another from mitochondria localization (LmTrpRS2). The mature mRNA transcripts for both genes were defined by 5? and 3? RT-PCR. Both enzymes were cloned into several expressions vectors. LmTrpRs1 was obtained as an insoluble protein and LmTrpRs2 expressed into the soluble fraction in pET28a expression system. LmTrpRS2 protein, however, is unstable precipitating shortly after purification. The enzymatic assay showed that this enzyme is able to recognize both tRNATrp. Molecular modeling for LmTrpRS1 and LmTrpRS2 were constructed using the cytoplasmatic human tryptophanyl tRNA synthetase as a model, to study the interaction between proteins and tRNATrp. Xylella fastidiosa is a xylem-limited, gram-negative bacteria responsible for a large number of economically important plant diseases, such as Pierces disease in grapevines, citrus variegated chlorosis (CVC) in sweet oranges and leaf scorch diseases in other plants, including almond, plum, oleander, mulberry and coffee. In all cases, X. fastidiosa infects the plant xylem and impairs fruit production. Here, we report the crystal structure of xylellain, a cystein protease from X. fastidiosa. The structure was solved by single-wavelength anomalous dispersion (SAD) using seleno-methionine containing xylellain crystals. The final structure of Xylellaína was refined against the best native data set (1.65 Å) showing R/Rfree= 17/21. Xylellain shares fold similar to Papain like Family, but contains some interesting features, like a 38 N-terminal tail covering the active site cleft; one intriguing ribonucleotide found outside the active site and one loop that resemble the ocluding loop from cathepsin B

Effects of Trypanosoma brucei tryptophanyl-tRNA synthetases silencing by RNA interference

The kinetoplast genetic code deviates from the universal code in that 90% of mitochondrial tryptophans are specified by UGA instead of UGG codons. A single nucleus-encoded tRNATrp(CCA) is used by both nuclear and mitochondria genes, since all kinetoplast tRNAs are imported into the mitochondria from the cytoplasm. To allow decoding of the mitochondrial UGA codons as tryptophan, the tRNATrp(CCA) anticodon is changed to UCA by an editing event. Two tryptophanyl tRNA synthetases (TrpRSs) have been identified in Trypanosoma brucei: TbTrpRS1 and TbTrpRS2 which localize to the cytoplasm and mitochondria respectively. We used inducible RNA interference (RNAi) to assess the role of TbTrpRSs. Our data validates previous observations of TrpRS as potential drug design targets and investigates the RNAi effect on the mitochondria of the parasite

The crystal structure of the cysteine protease Xylellain from Xylella fastidiosa reveals an intriguing activation mechanism

Xylella fastidiosa is responsible for a wide range of economically important plant diseases. We report here the crystal structure and kinetic data of Xylellain, the first cysteine protease characterized from the genome of the pathogenic X. fastidiosa strain 9a5c. Xylellain has a papain-family fold, and part of the N-terminal sequence blocks the enzyme active site, thereby mediating protein activity. One novel feature identified in the structure is the presence of a ribonucleotide bound outside the active site. We show that this ribonucleotide plays an important regulatory role in Xylellain enzyme kinetics, possibly functioning as a physiological mediator.FAPESP (98/14138-2

Cartoon representation of AaegOBP1 structure.

<p>α-Helices are shown in green, loops in gray and three disulfide linkages (DS1-3) knitting α-helices are highlighted in yellow. N- and C-terminus residues are denoted with blue and red spheres, respectively.</p

Summary of data-processing and refinement statistics.

<p>Values in parentheses are for the highest resolution bin (1.92–1.85 Å)</p

AaegOBP1 binding pocket with a PEG molecule.

<p>The structure in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0008006#pone-0008006-g006" target="_blank">Fig. 6</a> was rotated by 90°.</p