Activity of the Giardia intestinalis proteasome during encystation and its connection with the expression of the cyst wall protein 1 (CWP1).

Giardia is a parasite whose life cycle is composed of two stages: replicative trophozoites, responsible for the symptoms of the disease, and infective cysts, resistant to adverse environments outside of hosts. Proteasomes are multicatalytic peptidase complexes responsible for the specific degradation of proteins in eukaryotic cells. This study assessed the proteasome activity in the trophozoite and during encystation. Strong activation of the proteasome was observed during the differentiation of trophozoites into cysts, reaching its maximum level 24 h after the stimulus. We also found that the Giardia proteasome presents unusual characteristics related to higher eukaryotic proteasomes, making it an eventual therapeutic target. Here we tested the effects on the synthesis of a cyst wall protein by chemical inactivation of the proteasome and by overexpression or partial inhibition of the deubiquitinating protein RPN11 in transfected cells. Moreover, an analysis of the intracellular localization of RPN11 (an integral part of the proteasome regulatory particle) revealed major changes associated with the differentiation of trophozoites into cysts. This evidence further supports the important role of the proteasome in Giardia encystation.

A new gene inventory of the ubiquitin and ubiquitin-like conjugation pathways in Giardia intestinalis.

BACKGROUND: Ubiquitin (Ub) and Ub-like proteins (Ub-L) are critical regulators of complex cellular processes such as the cell cycle, DNA repair, transcription, chromatin remodeling, signal translation, and protein degradation. Giardia intestinalis possesses an experimentally proven Ub-conjugation system; however, a limited number of enzymes involved in this process were identified using basic local alignment search tool (BLAST). This is due to the limitations of BLAST's ability to identify homologous functional regions when similarity between the sequences dips to < 30%. In addition Ub-Ls and their conjugating enzymes have not been fully elucidated in Giardia. OBJETIVE: To identify the enzymes involved in the Ub and Ub-Ls conjugation processes using intelligent systems based on the hidden Markov models (HMMs). METHODS: We performed an HMM search of functional Pfam domains found in the key enzymes of these pathways in Giardia's proteome. Each open reading frame identified was analysed by sequence homology, domain architecture, and transcription levels. FINDINGS: We identified 118 genes, 106 of which corresponded to the ubiquitination process (Ub, E1, E2, E3, and DUB enzymes). The E3 ligase group was the largest group with 82 members; 71 of which harbored a characteristic RING domain. Four Ub-Ls were identified and the conjugation enzymes for NEDD8 and URM1 were described for first time. The 3D model for Ub-Ls displayed the ß-grasp fold typical. Furthermore, our sequence analysis for the corresponding activating enzymes detected the essential motifs required for conjugation. MAIN CONCLUSIONS: Our findings highlight the complexity of Giardia's Ub-conjugation system, which is drastically different from that previously reported, and provides evidence for the presence of NEDDylation and URMylation enzymes in the genome and transcriptome of G. intestinalis.

A new gene inventory of the ubiquitin and ubiquitin-like conjugation pathways in Giardia intestinalis

BACKGROUND Ubiquitin (Ub) and Ub-like proteins (Ub-L) are critical regulators of complex cellular processes such as the cell cycle, DNA repair, transcription, chromatin remodeling, signal translation, and protein degradation. Giardia intestinalis possesses an experimentally proven Ub-conjugation system; however, a limited number of enzymes involved in this process were identified using basic local alignment search tool (BLAST). This is due to the limitations of BLAST's ability to identify homologous functional regions when similarity between the sequences dips to < 30%. In addition Ub-Ls and their conjugating enzymes have not been fully elucidated in Giardia. OBJETIVE To identify the enzymes involved in the Ub and Ub-Ls conjugation processes using intelligent systems based on the hidden Markov models (HMMs). METHODS We performed an HMM search of functional Pfam domains found in the key enzymes of these pathways in Giardia's proteome. Each open reading frame identified was analysed by sequence homology, domain architecture, and transcription levels. FINDINGS We identified 118 genes, 106 of which corresponded to the ubiquitination process (Ub, E1, E2, E3, and DUB enzymes). The E3 ligase group was the largest group with 82 members; 71 of which harbored a characteristic RING domain. Four Ub-Ls were identified and the conjugation enzymes for NEDD8 and URM1 were described for first time. The 3D model for Ub-Ls displayed the β-grasp fold typical. Furthermore, our sequence analysis for the corresponding activating enzymes detected the essential motifs required for conjugation. MAIN CONCLUSIONS Our findings highlight the complexity of Giardia's Ub-conjugation system, which is drastically different from that previously reported, and provides evidence for the presence of NEDDylation and URMylation enzymes in the genome and transcriptome of G. intestinalis.

In vitro interaction between Plasmodium falciparum myosin B (PfMyoB) and myosin A tail interacting protein (MTIP).

Apicomplexan parasites, including Plasmodium falciparum, are obligate intracellular organisms that utilize a strategy termed "gliding" to move and invade host cells, causing disease. Gliding is carried out by a protein complex known as the glideosome, which includes an actin-myosin motor. To date, six myosins have been identified in P. falciparum (PfMyoA, B, C, D, E, and F), but only the role of PfMyoA, the myosin of the glideosome that is involved in the process of red blood cell and mosquito cell invasion, has been established. Based on previous observations, we speculated that PfMyoA and PfMyoB may have similar or redundant functions. To test this hypothesis, we searched for in vitro interactions between PfMyoB and MTIP (myosin A tail interacting protein), the myosin light chain of PfMyoA. A set of differentially tagged PfMyoA, PfMyoB, and MTIP recombinant proteins was employed to specifically and simultaneously detect each myosin in competition assays and inhibition assays using specific peptides. MTIP potentially acts as the light chain of PfMyoB.

Calcium-binding proteins that are type B″ regulatory subunits of phosphatase 2A in Giardia intestinalis.

Giardia intestinalis is a protozoan parasite that colonizes the upper part of the small intestine of its mammalian hosts. The trophozoite, which is the replicative stage, has a complex cytoskeleton that allows it to move and adhere to intestinal cells. It has been proposed that protein phosphatase 2A (PP2A) participates in the regulation of changes to the parasite cytoskeleton during its life cycle. However, how PP2A is involved in this regulation remains unclear since its substrates and regulators have not been characterized. In this work, we report the bioinformatic and experimental analysis of two potential regulatory B″ subunits of PP2A in Giardia, both of which are calcium-binding proteins. In this work, in silico and experimental evidence of the binding of both proteins to calcium is presented; the proteins are shown to interact with the catalytic PP2A subunit in the trophozoite stage, and they exhibit different subcellular localization patterns. Because PP2A is a heterotrimer, homology analysis of the different subunits of PP2A indicates that fewer holoenzyme combinations can be formed in this parasite than in other organisms. Our results suggest that the localization of PP2A may be associated with calcium-dependent signaling through its B″ type regulatory subunits.

In silico analysis of the EF-hand proteins in the genome of Giardia intestinalis assembly A.

Giardia intestinalis is a parasite that inhabits the small intestine of humans and other mammals, causing a disease that can manifest itself with acute diarrhea. This parasite is an early divergent eukaryote with a compact genome and a life cycle composed of two distinct cell types: the trophozoite, the replicative form, and the cyst, the infectious form. Signal transduction pathways implicated in differentiation processes of G. intestinalis are largely unknown. Calcium, considered an essential messenger in cell signaling, has been shown to regulate a myriad of key cell processes including metabolism, motility, and exocytosis, among other important functions, through calcium-binding proteins (CaBPs). The most important and largest family of CaBPs is the EF-hand protein family. To investigate the nature of calcium signaling pathways present in this protozoan, an in silico analysis of the genome to identify genes encoding EF-hand proteins was undertaken. Twenty-eight sequences containing EF-hand domains were found; most of which have only a pair of domains, and half of the sequences were divergent or unique to Giardia. In addition, the transcription pattern for eight genes encoding EF-hand proteins was assessed during encystation. It was found that all the genes were differentially transcribed suggesting a different function in this process. The in silico results suggest that in G. intestinalis, calcium is involved in the regulation of protein phosphorylation through kinases and phosphatases.

Experimental and bioinformatic characterization of CaBP2933 an EF-Hand protein of Giardia intestinalis.

Giardia intestinalis is a parasite that inhabits the small intestine of humans. This parasite is a divergent eukaryote with a compact genome. The calcium ion is an essential messenger in cell signaling. Calcium's role as a messenger is mediated through calcium-binding proteins (CaBPs) that decode the message. The most important family of CaBPs is the EF-Hand protein family. In this study we have explored the role of EF-Hand protein CaBP2933. We analyzed its location, confirmed its ability to bind calcium and identified some of its interacting proteins. Take together our results suggest that CaBP2933 is involved in vesicular trafficking during encystation, via an interaction with kinesin-3 motor protein.

Myosin B of Plasmodium falciparum (PfMyoB): in silico prediction of its three-dimensional structure and its possible interaction with MTIP.

The mobility and invasion strategy of Plasmodium falciparum is governed by a protein complex known as the glideosome, which contains an actin-myosin motor. It has been shown that myosin A of the parasite (PfMyoA) is the myosin of the glideosome, and the interaction of PfMyoA with myosin tail domain interacting protein (MTIP) determines its correct location and its ability to function in the complex. Because PfMyoA and myosin B of P. falciparum (PfMyoB) share high sequence identity, are both small proteins without a tail domain, belong to the class XIV myosins, and are expressed in late schizonts and merozoites, we suspect that these myosins may have similar or redundant functions. Therefore, this work examined the structural similarity between PfMyoA and PfMyoB and performed a molecular docking between PfMyoB and MTIP. Three-dimensional (3D) models obtained for PfMyoA and PfMyoB achieved high scores in the structural validation programs used, and their superimposition revealed high structural similarity, supporting the hypothesis of possible similar functions for these two proteins. The 3D interaction models obtained and energy values found suggested that interaction between PfMyoB and MTIP is possible. Given the apparent abundance of PfMyoA relative to PfMyoB in the parasite, we believe that the interaction between PfMyoB and MTIP would only be detectable in specific cellular environments because under normal circumstances, it would be masked by the interaction between PfMyoA and MTIP.

Interactions between Giardia duodenalis Sm proteins and their association with spliceosomal snRNAs.

Giardia duodenalis is a parasite that colonises the intestines of humans and other vertebrates, causing diarrhoea and poor nutrient absorption. G. duodenalis is sometimes considered an early diverging eukaryote, and its genome exhibits simplified molecular machinery for many cellular processes, which makes it an interesting model to study. The spliceosome, one of the most complex molecular machines in the eukaryotic cell, is responsible for intron excision and exon splicing. Just over a decade ago, it was believed that the G. duodenalis genome did not contain introns or undergo splicing. Research now shows that this speculation was incorrect and that uncommon mechanisms, such as trans-splicing from different genes, occur. In silico studies of the parasite suggest the possibility of a simplified spliceosome and spliceosomal small nuclear RNA (snRNA) candidates; however, none of these components have been identified in vivo. Here, we developed a strategy to study the in vivo expression, interactions and localisation of these spliceosome components in G. duodenalis. Haemagglutinin (HA)-tagged SmB and SmD3 proteins, which form part of the spliceosome core, were overexpressed in the parasite. Immunoprecipitation with anti-HA revealed that the SmD3 protein is associated with the proteins SmB, SmD1, SmD2, SmE and SmF in vivo. In addition, the U1, U2 and U4 snRNA candidates reported previously were found in the protein complex, suggesting that these molecules are spliceosomal snRNAs of G. duodenalis and they contained a 2,2,7-trimethylguanosine modification at their 5' end. Our data indicate that the actively expressed spliceosome in G. duodenalis is similar to that of highly evolved protists and higher animals.

Production of recombinant proteins from Plasmodium falciparum in Escherichia coli / Producción de proteínas recombinantes de Plasmodium falciparum en Escherichia coli

Introduction: The production of recombinant proteins is essential for the characterization and functional study of proteins from Plasmodium falciparum . However, the proteins of P . falciparum are among the most challenging to express, and when expression is achieved, the recombinant proteins usually fold incorrectly and lead to the formation of inclusion bodies. Objective: To obtain and purify four recombinant proteins and to use them as antigens to produce polyclonal antibodies. The production efficiency and solubility were evaluated as the proteins were expressed in two genetically modified strains of Escherichia coli to favor the production of heterologous proteins (BL21-CodonPlus (DE3)-RIL and BL21-pG-KJE8). Materials and methods: The four recombinant P. falciparum proteins corresponding to partial sequences of PfMyoA (Myosin A) and PfGAP50 (gliding associated protein 50), and the complete sequences of PfMTIP (myosin tail interacting protein) and PfGAP45 (gliding associated protein 45), were produced as glutathione S-transferase-fusion proteins, purified and used for immunizing mice. Results: The protein expression was much more efficient in BL21-CodonPlus, the strain that contains tRNAs that are rare in wild-type E. coli , compared to the expression in BL21-pG-KJE8. In spite of the fact that BL21-pG-KJE8 overexpresses chaperones, this strain did not minimize the formation of inclusion bodies. Conclusion: The use of genetically modified strains of E . coli was essential to achieve high expression levels of the four evaluated P . falciparum proteins and lead to improved solubility of two of them. The approach used here allowed us to obtain and purify four P . falciparum proteins in enough quantity to produce polyclonal antibodies in mice, and a fair amount of two pure and soluble recombinant proteins for future assays.

Introducción. La producción de proteínas recombinantes es fundamental para el estudio funcional de las proteínas de Plasmodium falciparum . Sin embargo, las proteínas recombinantes de P . falciparum están entre las más difíciles de expresar y, cuando lo hacen, usualmente se agregan dentro de cuerpos de inclusión insolubles. Objetivo. Evaluar la producción de cuatro proteínas de P. falciparum usando como sistema de expresión dos cepas de Escherichia coli genéticamente modificadas para favorecer la producción de proteínas heterólogas y establecer una reserva de proteínas recombinantes puras y solubles, y producir anticuerpos policlonales a partir de ellas. Materiales y métodos. Las proteínas recombinantes, las cuales correspondían a secuencias parciales de PfMyoA (Miosina-A) y PfGAP50 (proteína-asociada a glideosoma de 50 kDa) y a las secuencias completas de PfMTIP (proteína de interacción con miosina-A) y PfGAP45 (proteína asociada a glideosoma de 45 kDa), fueron expresadas como proteínas de fusión con la glutatión S-transferasa y luego purificadas y usadas para producir anticuerpos policlonales en ratón. Resultados. La expresión de las proteínas recombinantes fue mucho más eficiente en la cepa BL21-CodonPlus (la cual expresa tRNAs escasos en las bacterias silvestres), que en la cepa BL21-pG-KJE8. Por el contrario, aunque la cepa BL21-pG-KJE sobreexpresa chaperonas, no redujo la formación de cuerpos de inclusión. Conclusión. El uso de cepas de E . coli genéticamente modificadas fue fundamental para alcanzar altos niveles de expresión de las cuatro proteínas recombinantes evaluadas y permitió obtener dos de ellas en forma soluble. La estrategia utilizada permitió expresar cuatro proteínas recombinantes de P . falciparum en cantidad suficiente para inmunizar ratones y producir anticuerpos policlonales y, además, conservar proteína pura y soluble de dos de ellas para ensayos futuros.

Inhibición parcial de dos genes que codifican para proteínas del empalmosoma en Giardia intestinalis / Partial inhibition of two genes that encode spliceosomal proteins in Giardia intestinalis

Introducción. Giardia intestinalis es un organismo tempranamente divergente en el que recientemente se demostró la presencia de intrones. La maquinaria responsable de la remoción de intrones en organismos eucariotas superiores es el empalmosoma, el cual está conformado por cinco ribonucleoproteínas, cada una de las cuales tiene un ARN pequeño nuclear, un set de siete proteínas Sm (B, D1, D2, D3, E, F y G) y varias proteínas específicas. En G. intestinalis se han identificado los genes de algunas proteínas del empalmosoma por bioinformática. Aunque se asume que este es el responsable del empalme en el parásito, su caracterización bioquímica no se ha hecho. Objetivo. Inhibir dos genes que codifican para proteínas del empalmosoma de G. intestinalis con el fin de determinar si esta inhibición afecta el crecimiento o el enquistamiento del parásito. Materiales y métodos. En un vector específico para G. intestinalis se clonaron secuencias antisentido de los genes que codifican para las proteínas SmB y SmD3 del empalmosoma del parásito. Posteriormente, se transfectó G. intestinalis con los vectores recombinantes y se seleccionaron aquellos parásitos que lo incorporaron. Se confirmó la disminución del mensajero mediante reacción en cadena de la polimerasa (PCR) en tiempo real, y se evaluaron el crecimiento y el enquistamiento en parásitos silvestres y transfectados. Resultados. Se observó una disminución de 40 y 70 % en el ARNm de SmB y SmD3, respectivamente. El crecimiento y el enquistamiento no se vieron afectados en estos parásitos. Conclusión. La disminución de SmB y SmD3 no afectó al parásito, lo que indica que el empalmosoma sigue siendo funcional, o que el empalme no es una función vital del parásito.

Introduction. Giardia intestinalis is an early divergent organism that was recently shown to have introns. The machinery responsible for the removal of introns in higher eukaryotes is the spliceosome, which consists of five ribonucleoproteins. Each of these ribonucleoproteins has a small nuclear RNA, a set of seven Sm proteins (B, D1, D2, D3, E, F and G) and several specific proteins. Some genes that encode spliceosome proteins have been bioinformatically identified in the parasite genome. Although it is assumed that the spliceosome is responsible for splicing in this parasite, biochemical characterization is lacking. Objective. To inhibit two G. intestinalis spliceosome protein genes in order to determine whether this inhibition affects parasite growth or encystation. Materials and methods. Antisense sequences of the genes encoding the spliceosomal parasite proteins SmB and SmD3 were cloned into a specific G. intestinalis vector. G. intestinalis individuals were subsequently transfected with the recombinant vectors and those parasites that incorporated the vector were selected. A decrease in mRNA levels by real-time PCR was confirmed and the growth and encystation in wild and transfected parasites was assessed. Results. A decrease of 40% and 70% of SmB and SmD3 mRNA levels, respectively, was observed. Growth and encystation in these parasites were not affected. Conclusion. Decrease of SmB and SmD3 mRNA levels does not affect the parasite, indicating that the spliceosome remains functional or that splicing is not essential for parasite viability.

Production of recombinant proteins from Plasmodium falciparum in Escherichia coli.

INTRODUCTION: The production of recombinant proteins is essential for the characterization and functional study of proteins from Plasmodium falciparum. However, the proteins of P. falciparum are among the most challenging to express, and when expression is achieved, the recombinant proteins usually fold incorrectly and lead to the formation of inclusion bodies.  OBJECTIVE: To obtain and purify four recombinant proteins and to use them as antigens to produce polyclonal antibodies. The production efficiency and solubility were evaluated as the proteins were expressed in two genetically modified strains of Escherichia coli to favor the production of heterologous proteins (BL21-CodonPlus (DE3)-RIL and BL21-pG-KJE8).  MATERIALS AND METHODS: The four recombinant P. falciparum proteins corresponding to partial sequences of PfMyoA (Myosin A) and PfGAP50 (gliding associated protein 50), and the complete sequences of PfMTIP (myosin tail interacting protein) and PfGAP45 (gliding associated protein 45), were produced as glutathione S-transferase-fusion proteins, purified and used for immunizing mice.  RESULTS: The protein expression was much more efficient in BL21-CodonPlus, the strain that contains tRNAs that are rare in wild-type E. coli, compared to the expression in BL21-pG-KJE8. In spite of the fact that BL21-pG-KJE8 overexpresses chaperones, this strain did not minimize the formation of inclusion bodies.  CONCLUSION: The use of genetically modified strains of E. coli was essential to achieve high expression levels of the four evaluated P. falciparum proteins and lead to improved solubility of two of them. The approach used here allowed us to obtain and purify four P. falciparum proteins in enough quantity to produce polyclonal antibodies in mice, and a fair amount of two pure and soluble recombinant proteins for future assays.

Partial inhibition of two genes that encode spliceosomal proteins in Giardia intestinalis.

INTRODUCTION: Giardia intestinalis is an early divergent organism that was recently shown to have introns. The machinery responsible for the removal of introns in higher eukaryotes is the spliceosome, which consists of five ribonucleoproteins. Each of these ribonucleoproteins has a small nuclear RNA, a set of seven Sm proteins (B, D1, D2, D3, E, F and G) and several specific proteins. Some genes that encode spliceosome proteins have been bioinformatically identified in the parasite genome. Although it is assumed that the spliceosome is responsible for splicing in this parasite, biochemical characterization is lacking. Objective. To inhibit two G. intestinalis spliceosome protein genes in order to determine whether this inhibition affects parasite growth or encystation. Materials and methods. Antisense sequences of the genes encoding the spliceosomal parasite proteins SmB and SmD3 were cloned into a specific G. intestinalis vector. G. intestinalis individuals were subsequently transfected with the recombinant vectors and those parasites that incorporated the vector were selected. A decrease in mRNA levels by real-time PCR was confirmed and the growth and encystation in wild and transfected parasites was assessed. Results. A decrease of 40% and 70% of SmB and SmD3 mRNA levels, respectively, was observed. Growth and encystation in these parasites were not affected. Conclusion. Decrease of SmB and SmD3 mRNA levels does not affect the parasite, indicating that the spliceosome remains functional or that splicing is not essential for parasite viability.

Preliminary study of the enzyme ubiquitin carboxylterminal hydrolase 14 (UBP6) in Giardia intestinalis: structural bioinformatic analysis and transcriptional profile during encystation / Estudio preliminar de la enzima ubiquitina carboxiterminal hidrolasa 14 (UBP6) en Giardia intestinalis: análisis bioinformático de su estructura y perfil transcripcional durante la enquistación / Estudo preliminar da enzima ubiquitina carboxi-terminal hidrolasa 14 (UBP6) em Giardia intestinalis: análise bioinformática estrutural e perfil transcricional durante encistamento

This paper presents a combined approach with two aims. The first is to analyze the reported sequence of the enzyme ubiquitin carboxyl-terminal hydrolase 14 of Giardia intestinalis (UBP6) through computational methods to find components related with its hypothetical function. The second is to determine if the protein-coding gene is expressed in G. intestinalis and, if such is the case, also determine its transcription pattern along the life cycle of the parasite. It was established that the protein belongs to the family of Cys-dependent deubiquitinases and more specifically to ubiquitin specific proteases (USPs). Moreover, the catalytic center with the complete triad as well as typical features of the USP motif were also identified. Since the computational findings suggest that the enzyme could be functional, reverse transcription coupled to PCR was used as a first approach to establish if in fact the coding gene is expressed in the parasite. Interestingly, it was found not only that the gene is expressed, but also that there is a transcription variation along the life cycle of the parasite. These two findings are the starting point for further studies since they tentatively suggest that this enzyme could be involved in the protein turnover that occurs during parasite encystation. Although preliminary, this study is the first report concerning the study of a specific deubiquitinating enzyme in the parasite G. intestinalis.

En este trabajo se presenta una estrategia combinada que buscaba, primero, analizar por métodos computacionales la secuencia de la enzima ubiquitina carboxilo-terminal hidrolasa 14 de Giardia intestinalis (UBP6) reportada para buscar componentes relacionados con su función hipotética y segundo, determinar si el gen que codifica para la proteína se expresa en G. intestinalis y si lo hace, cómo es su patrón de transcripción a lo largo del ciclo de vida del parásito. Se encontró que la proteína pertenece a la familia de deubiquitinasas dependientes de cisteína y más específicamente a las proteasas específicas para ubiquitina (USPs por ubiquitin specific proteases). También se identificaron el centro catalítico con la triada completa así como características típicas del motivo USP. Teniendo en cuenta que los resultados computacionales sugieren que la enzima puede ser funcional, se usó la técnica de transcripción reversa acoplada a PCR como un primer acercamiento para establecer si el gen codificante se expresa en el parásito. De manera interesante, se determinó no solo que el gen se expresa sino que existe una variación de su transcripción a lo largo del ciclo de vida del parásito. Estos hallazgos son el punto de partida para posteriores estudios ya que sugieren de manera preliminar que esta enzima podría estar involucrada en el recambio de proteínas que ocurre en el parásito durante el proceso de enquistación. Aunque preliminar, este estudio es el primer reporte acerca de una enzima deubiquitinadora específica en el parásito G. intestinalis.

Este artigo apresenta uma abordagem combinada com dois objetivos. A primeira é analisar a sequência informou da enzima ubiquitina carboxil-terminal hidrolase 14 de Giardia intestinalis (UBP6) através de métodos computacionais para encontrar os componentes relacionados com a sua função hipotética. A segunda é para determinar se o gene de codificação da proteína é expressa em G. intestinalis e, se for o caso, também determinar o seu padrão de transcrição ao longo do ciclo de vida do parasita. Foi estabelecido que a proteína pertence à família de deubiquitinases Cys-dependentes e mais especificamente para proteases específicas de ubiquitina (USPs por ubiquitin specific proteases). Além disso, o centro catalítico com a tríade completo, bem como as características típicas do motivo USP também foram identificados. Uma vez que os resultados computacionais sugerem que a enzima poderia ser funcional, a transcrição reversa acoplada a PCR foi utilizado como uma primeira abordagem para determinar se, de facto, o gene codificante é expressa no parasita. Curiosamente, verificou-se não só que o gene é expresso, mas também que há uma variação de transcrição ao longo do ciclo de vida do parasita. Estes dois elementos são o ponto de partida para estudos posteriores, uma vez que tentativas sugerem que esta enzima pode estar envolvida no refill de proteínas que ocorre durante o parasita encistamento. Embora preliminares, este estudo é o primeiro relatório relativo ao estudo de uma enzima deubiquitinadora específica no parasita intestinalis.

Ubiquitination dynamics in the early-branching eukaryote Giardia intestinalis.

Ubiquitination is a highly dynamic and versatile posttranslational modification that regulates protein function, stability, and interactions. To investigate the roles of ubiquitination in a primitive eukaryotic lineage, we utilized the early-branching eukaryote Giardia intestinalis. Using a combination of biochemical, immunofluorescence-based, and proteomics approaches, we assessed the ubiquitination status during the process of differentiation in Giardia. We observed that different types of ubiquitin modifications present specific cellular and temporal distribution throughout the Giardia life cycle from trophozoites to cyst maturation. Ubiquitin signal was detected in the wall of mature cysts, and enzymes implicated in cyst wall biogenesis were identified as substrates for ubiquitination. Interestingly, inhibition of proteasome activity did not affect trophozoite replication and differentiation, while it caused a decrease in cyst viability, arguing for proteasome involvement in cyst wall maturation. Using a proteomics approach, we identified around 200 high-confidence ubiquitinated candidates that vary their ubiquitination status during differentiation. Our results indicate that ubiquitination is critical for several cellular processes in this primitive eukaryote.

Evaluation of drugs and stationary growth on the cell cycle of Giardia intestinalis.

We examined the effect of aphidicolin, colchicine, demecolcine, fluorouracil, hydroxyurea, and nocodazole, as well as nutrient deprivation on the Giardia intestinalis cell cycle. Aphidicolin was the only drug that was able to block the cell cycle at a specific stage (G1/S), and permit cells to resume growth at a high rate upon its removal. Nutrient deprivation resulted in a portion of G2/M cells completing mitosis and cytokinesis in synchrony during the recovery period, but this synchrony was shortly lost and a sample containing a predominance of G1 cells could not be obtained. Flow cytometry analysis of normal and untreated Giardia cultures showed the occasional appearance of a small percentage of cells with a DNA content of 16C, which is twice the DNA content of G2 cells. However, this 16C peak is larger and more frequently observed in drug-treated Giardia. These 16C are likely produced from endoreplication of 8C/G2 cells, and we propose that they represent a pre-encystation stage that is induced by drug treatments and other stressors.

The ubiquitin-activating enzyme (E1) of the early-branching eukaryote Giardia intestinalis shows unusual proteolytic modifications and play important roles during encystation.

Giardia intestinalis is considered an early-branching eukaryote and is therefore a valuable model for studying primordial cellular processes. This work reports the characterization of the ubiquitin-activating enzyme (E1) during growth and different stages of trophozoite differentiation into cysts. We found that in Giardia E1 expression (both at mRNA and protein levels) is regulated during encystation. The enzyme is proteolytically processed mainly into two fragments of 68kDa (N-terminal) and 47kDa (C-terminal). This phenomenon has not been described for any other E1. In trophozoites, this enzyme localized at spots within the cytoplasm as detected by using polyclonal antibodies against either E1 N- or C-terminal fragments. This pattern changed during encystation into a diffuse localization throughout the cytoplasm of encysting cells. E1 localizes in mature cysts at cytoplasmic spots and in the cyst wall. Our antisense silencing experiments suggested that E1 is an essential gene for parasite viability. On the other hand, E1 over-expression greatly increased the encystation rate, indicating a relationship between E1 and Giardia differentiation.

Calmodulin expression during Giardia intestinalis differentiation and identification of calmodulin-binding proteins during the trophozoite stage.

Calmodulin (CaM) is the primary sensor for calcium in the cell. It modulates various functions by activating CaM-binding proteins (CaMBPs). This study examined the calcium/CaM-dependent system in the ancient eukaryote Giardia intestinalis. A specific antibody against the parasite's CaM was developed; this protein's expression and location during different stages of the parasite's life cycle were analyzed. The results showed that it is a housekeeping protein which is possibly involved in the parasite's motility. No CaMBP has been identified in G. intestinalis to date. Pull-down assays were used for isolating proteins which specifically bind to CaM in a calcium-dependent way. Three of them were identified through mass spectrometry; they were GASP180, α-tubulin, and pyruvate phosphate dikinase (PPDK).The first two are cytoskeleton proteins, and the last one is an essential enzyme for glycolysis. The presence of binding sites was analyzed through bioinformatics in each protein sequence. This is the first report of a CaMBP in this organism; it is considered to be a very interesting differentiation model, indicating that CaM is involved at least in two vital processes: G. intestinalis motility and energetic metabolism.

HSP90 is a target protein for ubiquitination in Giardia intestinalis / HSP90 es una proteina blanco de ubiquitinación en Giardia intestinalis / HSP90 é uma proteína alvo de ubiquitinação em Giardia intestinalis

Previous studies have demonstrated the existence and expression of genes essential to the process of protein ubiquitination in Giardia intestinalis, indicating that the ubiquitin-proteasome system may be involved in the degradation of proteins during its life cycle of the parasite. In this study, purification of ubiquitin was conducted from protein extracts of G. intestinalis trophozoites. Then, an anti-ubiquitin specific antibody was obtained to standardize an assay for the detection and evaluation of ubiquitination patterns. Finally, HSP90 was identified as an ubiquitinated protein in this protozoan. This post-translational modification could have regulatory effects associated with the functionality of the protein or its turnover to regulate key molecular events during the parasite’s life cycle.

Estudios previos han demostrado la existencia y expresión de genes esenciales para el proceso de ubiquitinación de proteínas en Giardia intestinalis, indicando que el sistema ubiquitina-proteosoma puede estar involucrado en el proceso de degradación de proteínas de este parásito durante su ciclo de vida. En el presente trabajo se realizó la purificación de ubiquitina a partir de extractos proteicos de trofozoítos de G. intestinalis, se produjo un anticuerpo anti-ubiquitina específico que permitió la estandarización de un ensayo para la detección y evaluación de los patrones de ubiquitinación, y se identificó la HSP90 como una proteína ubiquitinada en este protozoario. Esta modificación post-transduccional puede tener efectos regulatorios asociados con la funcionalidad de la proteína o con el recambio para regular eventos moleculares claves durante el ciclo de vida del parásito.

Estudos anteriores demonstraram a existência e expressão de genes essenciais para o processo de ubiquitinação de proteínas em Giardia intestinalis, indicando que o sistema ubiquitina-proteassoma podem estar envolvidos na degradação de proteínas do parasita durante seu ciclo de vida. Neste trabalho, foi realizada a purificação da proteína ubiquitina de extratos de trofozoítos de G. intestinalis, foi produzido um antiicorpo anti-ubiquitina específico que permitiu a padronização de um ensaio para a detecção e avaliação de padrões de ubiquitinação e foi identificado a HSP90 como uma proteína ubiquitinada no protozoário. Esta modificação pós-transducional pode ter efeitos regulamentares associados com a funcionalidade das proteínas ou com o a substituição para regular eventos moleculares importantes durante o ciclo de vida do parasita.

Synthesis of pyruvate: ferredoxin oxidoreductase and alcohol dehydrogenase E enzymes during Giardia intestinalis excystation.

INTRODUCTION: Giardia intestinalis is a unicellular parasite of worldwide distribution. It causes an intestinal illness known as giardiasis, and it is probably the earliest diverging eukaryotic microorganism. Previously, changes have been reported in the expression of mRNAs at several stages of the life cycle; however specific enzymatic activity changes have not been explored. OBJECTIVE: The expression of pyruvate ferredoxin oxidoreductase (PFOR) and alcohol dehydrogenase E (ADHE) enzymes was measured in cyst and trophozoite stages, and during the excystation process. MATERIALS AND METHODS: Recombinant proteins were generated for PFOR and ADHE to be used as antigens in the production of polyclonal antibodies for the detection of native proteins by Western Blot. The enzymatic activity of ADHE and glutamate dehydrogenase (GDH) was evaluated by spectrophotometric assays. RESULTS: PFOR (139 kDa) and ADHE (97 kDa) proteins were detected in trophozoites, but not in cysts. During excystation, ADHE protein was detected after the first phase of induction, but the PFOR protein appeared only after the second phase. This indicated that both proteins were synthesized during excystation, although at different times. ADHE enzymatic activity was present only in trophozoites and not in cysts whereas GDH activity was detected in both stages. CONCLUSION: These results conclusively showed that PFOR and ADHE enzymes were translated during the excystation process and is strong evidence that active protein synthesis was occurring during excystation.