Detección de Chlamydia pneumoniae en tejido aórtico humano: amplificación del gen kdtA e hibridación in vitro.

Guzmán, Natalia Salas; Espitia, Claudia M.; Delgado, Pilar; Echeverri, Darío; Buitrago, Lorena

doi:10.7705/biomedica.v25i4.1377

biomedica

2005

DOI: 10.7705/biomedica.v25i4.1377

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Detección de Chlamydia pneumoniae en tejido aórtico humano: amplificación del gen kdtA e hibridación in vitro.

Natalia Salas Guzmán¹,

Claudia M. Espitia²,

Pilar Delgado³

et al.

Abstract: Introducción. La ateroesclerosis es la principal causa de enfermedad coronaria y cerebrovascular, las cuales, a su vez, son las causas más comunes de mortalidad y morbilidad en el mundo occidental. Publicaciones recientes sugieren que ciertos microorganismos infecciosos podrían jugar un papel importante en la génesis y progresión de la aterosclerosis. De acuerdo con reportes seroepidemiológicos y de detección directa, Chlamydia pneumoniae podría ser el candidato más plausible. No obstante, no se ha determinado… Show more

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Lipopolysaccharide

Umamaheswari¹,

Pasala²,

Katari³

et al. 2021

Journal of Clinical and Scientific Research

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Gram-negative bacteria show more drug-resistant than Gram-positive bacteria due to unique structural attribute and cause significant morbidity and mortality across the globe. Such characteristic structure is an organelle lipopolysaccharide (LPS) on the outer membrane (OM) of cell wall essential for growth and survival of bacteria. LPS is a major cell wall component formed by dedicated transenvelope multiprotein complexes that shield the underlying peptidoglycan layer and play a key role in host–pathogen interactions with the innate immune system. Moreover, which constitutes the surface-exposed molecules with lipid portion in the outer leaflet of the OM that able to show antibiotic resistance and also responsible for the variety of biological effects associated with bacterial sepsis. LPS synthesis and structure are a conserved subject in infections during bacterial adaptive changes. Such changes ensue immune evasion, prolonged inflammation and augmented antibiotic resistance by working as molecular decoys which titrate the antimicrobials away from its intracellular antibiotic target. Herein, this review summarises the key features of LPS structure, function and biosynthesis. Moreover, it highlights the broad-spectrum conserved targets in the Raetz pathway without an alternative way for LPS biosynthesis vital for the development of novel therapeutic interventions against Gram-negative pathogens.

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Lipopolysaccharide

Umamaheswari¹,

Pasala²,

Katari³

et al. 2021

Journal of Clinical and Scientific Research

View full text Add to dashboard Cite

show abstract

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Detección de Chlamydia pneumoniae en tejido aórtico humano: amplificación del gen kdtA e hibridación in vitro.

Cited by 1 publication

References 35 publications

Lipopolysaccharide

Lipopolysaccharide

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