Escherichia coli productora de toxina Shiga: el desafío de adherirse para sobrevivir / Shiga toxin producing Escherichia coli: the challenge of adherence to survive

Resumen Las cepas de Escherichia coli productoras de toxina Shiga (STEC) son reconocidas como responsables de un alto número de casos de enfermedades de transmisión alimentaria a nivel mundial. Su patogenicidad ha sido vinculada directamente con la actividad de las toxinas (Stx); sin embargo, la habilidad de estas bacterias para colonizar al huésped y otras superficies puede ser esencial para desarrollar su poder patogénico. La gran plasticidad genómica de cepas STEC se infiere de la variabilidad de perfiles de virulencia, con la frecuente emergencia de cepas con nuevos genes, codificados en nuevas islas de patogenicidad vinculadas al metabolismo y la adherencia. La formación de biofilm es un mecanismo espontáneo por el cual las cepas STEC resisten en un ambiente hostil, lo que les permite sobrevivir y, de esa forma, llegar al huésped, a través de los alimentos o de las superficies que están en contacto con ellos. Este mecanismo presenta una alta variabilidad intra e interserotipo y su desarrollo no depende solo de los microorganismos que lo conforman. Factores inherentes al ambiente (pH, temperatura) y la superficie (acero inoxidable, poliestireno) a la que pueden adherirse influyen en la expresión de biofilm. El concepto «una salud¼ implica la interrelación entre los actores de salud pública, animal y ambiental para lograr alimentos inocuos y evitar contaminación cruzada y resistencia a sanitizantes, lo cual pone de manifiesto la necesidad de identificar patógenos emergentes a través de nuevos marcadores moleculares, que detecten cepas STEC portadoras del denominado locus for enterocyte effacement (LEE) o del locus de adherencia y autoagregación (LAA).

Abstract Shiga Toxin-producing Escherichia coli (STEC) is recognized as being responsible for a large number of foodborne illnesses around the world. The pathogenicity of STEC has been related to Stx toxins. However, the ability of STEC to colonize the host and other surfaces can be essential for developing its pathogenicity. Different virulence profiles detected in STEC could cause the emergence of strains carrying new genes codified in new pathogenicity islands linked to metabolism and adherence. Biofilm formation is a spontaneous mechanism whereby STEC strains resist in a hostile environment being able to survive and consequently infect the host through contaminated food and food contact surfaces. Biofilm formation shows intra-and inter-serotype variability, and its formation does not depend only on the microorganisms involved. Other factors related to the environment (such as pH, temperature) and the surface (stainless steel and polystyrene) influence biofilm expression. The «One Health¼ concept implies the interrelation between public, animal, and environmental health actors to ensure food safety, prevent cross-contamination and resistance to sanitizers, highlighting the need to identify emerging pathogens through new molecular markers of rapid detection that involve STEC strains carrying the Locus of Enterocyte Effacement or Locus of Adhesion and Autoaggregation.

[Shiga toxin producing Escherichia coli: the challenge of adherence to survive]. / Escherichia coli productora de toxina Shiga: el desafío de adherirse para sobrevivir.

Shiga Toxin-producing Escherichia coli (STEC) is recognized as being responsible for a large number of foodborne illnesses around the world. The pathogenicity of STEC has been related to Stx toxins. However, the ability of STEC to colonize the host and other surfaces can be essential for developing its pathogenicity. Different virulence profiles detected in STEC could cause the emergence of strains carrying new genes codified in new pathogenicity islands linked to metabolism and adherence. Biofilm formation is a spontaneous mechanism whereby STEC strains resist in a hostile environment being able to survive and consequently infect the host through contaminated food and food contact surfaces. Biofilm formation shows intra-and inter-serotype variability, and its formation does not depend only on the microorganisms involved. Other factors related to the environment (such as pH, temperature) and the surface (stainless steel and polystyrene) influence biofilm expression. The «One Health¼ concept implies the interrelation between public, animal, and environmental health actors to ensure food safety, prevent cross-contamination and resistance to sanitizers, highlighting the need to identify emerging pathogens through new molecular markers of rapid detection that involve STEC strains carrying the Locus of Enterocyte Effacement or Locus of Adhesion and Autoaggregation.

Noncoding RNAs as novel biomarkers in prostate cancer.

Prostate cancer (PCa) is the second most common diagnosed malignant disease in men worldwide. Although serum PSA test dramatically improved the early diagnosis of PCa, it also led to an overdiagnosis and as a consequence to an overtreatment of patients with an indolent disease. New biomarkers for diagnosis, prediction, and monitoring of the disease are needed. These biomarkers would enable the selection of patients with aggressive or progressive disease and, hence, would contribute to the implementation of individualized therapy of the cancer patient. Since the FDA approval of the long noncoding PCA3 RNA-based urine test for the diagnosis of PCa patients, many new noncoding RNAs (ncRNAs) associated with PCa have been discovered. According to their size and function, ncRNAs can be divided into small and long ncRNAs. NcRNAs are expressed in (tumor) tissue, but many are also found in circulating tumor cells and in all body fluids as protein-bound or incorporated in extracellular vesicles. In these protected forms they are stable and so they can be easily analyzed, even in archival specimens. In this review, the authors will focus on ncRNAs as novel biomarker candidates for PCa diagnosis, prediction, prognosis, and monitoring of therapeutic response and discuss their potential for an implementation into clinical practice.

[Assessment of nasal mucociliary transport time in seasonal allergic rhinitis]. / Valoración del tiempo de transporte mucociliar nasal en la rinitis alérgica estacional.

The AA. study the mucociliary transport time resorting to the vegetable coal dust method, in 64 individuals suffering seasonal allergic rhinitis, during the pollinosis epoch (1991-1992). This collective was divided in two groups according to the presence of hidrorrhea at examination: those subjects in whom the disease was considered in activity or inactive. The results were compared with those resulting from a group of other 130 healthy people. The conclusion drawn out is that the full high moment of the seasonal allergic rhinitis influences the cessation or the cancellation of the mucociliary function. The halt of the rhinohidrorrhea clearly improves the mucociliary clearance but without attaining its normalization during the pollinosis epoch.