Influence of charge and metal coordination of meso-substituted porphyrins on bacterial photoinactivation.

The photodynamic effect of meso-substituted porphyrins with different charges and metal ions: meso-tetraphenylporphyrin tetrasulfonate 1, its nickel 2 and zinc complexes 3; meso-tetranaphthylporphyrin tetrasulfonate 4, and its zinc complex Zn 5; and tetra piridyl ethylacetate porphirins 6 and their nickel 7 and zinc 8 complexes, were synthesized and studied their antimicrobial activity against Escherichia coli. Fluorescence quantum yields (ΦF) were measured in water using reference TPPS4, obtaining higher values for complexes 3 and 4. The singlet oxygen ΦΔ were measured using histidine as trapping singlet oxygen and Rose Bengal as a reference standard. Complexes 1, 2 and 6 have the highest quantum yields of singlet oxygen formation, showing no relation with the peripheral charges and efficiency as Type II photosensitizers. Meanwhile complexes 3, 8 and 4 were the most efficient in producing radical species, determined with their reaction with NADH. The photoinduced antibacterial activity of complex was investigated at different concentrations of the photosensitizers with an irradiation time of 30 min. The higher antibacterial activities were obtained for the complexes 1-3 that are those with greater production of ROS and minor structural deformations. Complexes 7 and 8 had moderate activity, while 4-6 a low activity. Thus, in this work demonstrates that the production of ROS and structural deformations due to peripheral substituents and metal coordination, influence the activity of the complexes studied. Therefore, is important to perform comprehensive study physics and structurally when predicting or explain such activity.

The subsidiary GntII system for gluconate metabolism in Escherichia coli: alternative induction of the gntV gene.

Two systems are involved in the transport and phosphorylation of gluconate in Escherichia coli. GntI, the main system, consists of high and low-affinity gluconate transporters and a thermoresistant gluconokinase for its phosphorylation. The corresponding genes, gntT, gntU and gntK at 76.5 min, are induced by gluconate. GntII, the subsidiary system, includes IdnT and GntV, which duplicate activities of transport and phosphorylation of gluconate, respectively. Gene gntV at 96.8 min is divergently transcribed from the idnDOTR operon involved in L-idonate metabolism. These genetic elements are induced by the substrate or 5-keto-D-gluconate. Because gntV is also induced in cells grown in gluconate, it was of interest to investigate its expression in this condition. E. coli gntK, idnOokan mutants were constructed to study this question. These idnO kan-cassete inserted mutants, unable to convert gluconate to 5-keto-D-gluconate, permitted examining gntV expression in the absence of this inducer and demonstrating that it is not required when the cells grow in gluconate. The results suggest that E. coli gntV gene is alternatively induced by 5-keto-D-gluconate or gluconate in cells cultivated either in idonate or gluconate. In this way, the control of gntV expression would seem to be involved in the efficient utilization of these substrates.

The subsidiary GntII system for gluconate metabolism in Escherichia coli: Alternative induction of the gntV gene

Two systems are involved in the transport and phosphorylation of gluconate in Escherichia coli. GntI, the main system, consists of high and low-affinity gluconate transporters and a thermoresistant gluconokinase for its phosphorylation. The corresponding genes, gntT, gntU and gntK at 76.5 min, are induced by gluconate. GntII, the subsidiary system, includes IdnT and GntV, which duplicate activities of transport and phosphorylation of gluconate, respectively. Gene gntV at 96.8 min is divergently transcribed from the idnDOTR operon involved in L-idonate metabolism. These genetic elements are induced by the substrate or 5-keto-D-gluconate. Because gntV is also induced in cells grown in gluconate, it was of interest to investigate its expression in this condition. E. coli gntK, idnOokan mutants were constructed to study this question. These idnO kan-cassete inserted mutants, unable to convert gluconate to 5-keto-D-gluconate, permitted examining gntV expression in the absence of this inducer and demonstrating that it is not required when the cells grow in gluconate. The results suggest that E. coli gntV gene is alternatively induced by 5-keto-D-gluconate or gluconate in cells cultivated either in idonate or gluconate. In this way, the control of gntV expression would seem to be involved in the efficient utilization of these substrates.

Evaluation of dengue NS1 antigen detection tests with acute sera from patients infected with dengue virus in Venezuela.

The performances of 2 commercial enzyme-linked immunosorbent assay (ELISA) kits (PLATELIA Dengue NS1 AG and Dengue Early ELISA) and a rapid immunochromatography test (Dengue NS1 AG Strip) for detection of dengue NS1 protein were compared using a panel of 87 sera from viremic dengue patients, as well as 36 sera from patients with other acute febrile illnesses. PLATELIA was more sensitive and slightly less specific than Dengue Early ELISA (sensitivity, 71.3% versus 60.9%; specificity, 86.1% versus 94.3%, respectively). The strip test showed an overall sensitivity of 67.8% with a specificity of 94.4%. A lower sensitivity was observed with Dengue Early ELISA for dengue virus (DENV) type 4 (30%) and by the 3 tests for DENV type 2 (56.5%). The use of these kits allows for rapid and specific early diagnosis of dengue infection; however, their sensitivity for each serotype must be further evaluated to guarantee an accurate diagnosis, particularly in those regions where the 4 dengue serotypes are cocirculating.

The metabolism of gluconate in Escherichia coli: Physiological evidences of a regulatory effect of idnR on the expression of the gntR regulon operons

Uptake and phosphorylation initiate the catabolism of gluconate in E. coli. Such activities conform two systems,GntI and GntII, encoded by two sets of genes differently located on the E. coli chromosome and under different regulation. gntT, gntU and gntK (minute 76) encode for high and low affinity gluconate transports and for a thermoresistant gluconokinase respectively, that conform GntI; the mentioned genes and those of the edd-eda operon (minute 41) are negatively regulated by the gntR gene product conforming the gntR regulon. idnT and gntV (minute 96), encode for another gluconate transport and a thermosensitive gluconokinase, conforming GntII. These genes are presumably positively controlled by IdnR. IdnT also functions as a permease for idonate; the corresponding gene is included in the idnDOTR operon, responsible for idonate metabolism, in which gluconate is an intermediary. Here we report a regulatory action of IdnR on the operons of the gntR regulon; i.e., gntT, gntKU and edd-eda. The expression of these operons, was diminished in a gntR mutant complemented with a clone of idnR and also in E. coli mutants in which the idnDOTR operon is expressed in a gluconate dependent inducibility. This is the first report of a regulatory effect of IdnR on edd-eda operon expression.

El transporte y la fosforilación inician el catabolismo del gluconato en E. coli. Estas actividades conforman dossistemas, GntI y GntII, codificados por dos grupos de genes, diferentemente regulados y ubicados en distintos sitios del cromosoma. Los genes gntT, gntU y gntK (minuto 76), codifican distintas proteínas para transportes de alta y baja afinidad para gluconato y una gluconoquinasa termoresistente respectivamente, que forman el sistema GntI; los genes respectivos junto con los del operón edd-eda (minuto 41), son regulados negativamente por el producto de gntR (minuto76) constituyendo el regulón gntR. Los genes IdnT y gntV (minuto 96), codifican otra permeasa para gluconato y una gluconoquinasa termosensible que forman GntII. IdnT funciona también como permeasa para idonato; el gen correspondiente es parte del operón idnDOTR, regulado positivamente por IdnR y responsable del metabolismo del idonato en el que gluconato es un intermediario. Se reporta un efecto regulatorio de IdnR sobre los operones del regulón gntR; i.e., gntT, gntKU and edd-eda. La expresión de estos operones resultó disminuida en una mutante gntR complementada con un clon de idnR y también en mutantes de E. coli en la que la expresión del operón idnDOTR se induce en presencia de gluconato. Este es el primer reporte de la acción regulatoria de IdnR sobre la expresión del operón eddeda.

Localización molecular mediante PCR inverso del sitio de inserción de un transposon TN 10 ligado a gntS en mutantes de Escherichia coli / Molecular location by inverse PCR of the insertion site of a Tn10 transposón ligated to gntS in Escherichia coli mutants

La vecindad del sitio de inserción del transposón Tn10, portado por la mutante de Escherichia coli DF601, contiene el gene gntS, un presunto regulador positivo involucrado en el metabolismo del gluconato en E. coli. Aunque el análisis molecular de la región del minuto 95.3, señalado originalmente como el sitio de inserción del transposón, reveló el ORF f251 con características de regulador, transformaciones con éste y otros ORFs de la región, una vez clonados, no complementaron la función perdida en mutantes gntS. El presente trabajo racionaliza la causa de tales resultados. Con base a la secuencia nucleotídica suministrada por GenBank y la aplicación de la técnica de PCR inverso, se encontró que el sitio exacto de inserción del transposón Tn10, portado por la mencionada mutante y sus derivadas TetR, es la posición 4442377, la cual interrumpe el ORF ytfN en la región del minuto 95.8 del mapa genético y no en la del minuto 95.3, como fue originalmente establecido. Los resultados, además de señalar sin ambigüedad la región cromosómica a investigar para lograr los fines propuestos, indican la conveniencia de aplicar la técnica sencilla de PCR inverso, para ubicar elementos genéticos antes de emplearlos en estudios moleculares.

The vicinity of the Tn10 transposon insertion site, carried by the Escherichia. coli mutant DF601, contains the genegntS, a putative positive regulator involved in the metabolism of the gluconate in E. coli. Although the molecular analysis of the 95.3 minute region, originally reported as the transposon insertion site, revealed the ORF f251 as one with regulator characteristics, transformations with this and other ORFs associated with the region, once cloned, did not complement the lost function in gntS mutants. The present work rationalizes on the cause of such results. Based on the nucleotide sequence provided by GenBank and application of the inverse PCR technique, it was found that the exact site of the Tn10 transposon insertion is in the position 4442377, interrupting the ytfN ORF at the minute 95.8 of the E. coli genetic map and not at minute 95.3, as it was originally established. The results indicate the precise chromosomal region to investigate in order to obtain the initially proposed aims and the convenience of applying the simple technique of inverse PCR to locate genetic elements as well.