Synergy of Plant Essential Oils in Antibiotic Therapy to Combat Klebsiella pneumoniae Infections.

Increased antibiotic resistance presents a health problem worldwide. The World Health Organization published a list of pathogens considered a priority for designing new treatments. Klebsiella pneumoniae (Kp) is a top-priority microorganism, highlighting the strains that produce carbapenemases. Developing new efficient therapies or complementing existing treatments is a priority, and essential oils (EOs) provide an alternative. EOs could act as antibiotic adjuvants and enhance antibiotic activity. Employing standard methodologies, the antibacterial activity of the EOs and their synergic effect with antibiotics were detected. A string test was used to identify the impact of the EOs over the hypermucoviscosity phenotype presented by Kp strains, and Gas Chromatography-Mass Spectrometry analysis identified EOs and the composition of EOs. The potential of EOs for designing synergistic therapies with antibiotics to combat the infection of KPC diseases was demonstrated. In addition, the alteration of the hypermucoviscosity phenotype was shown as the principal mechanism of a synergic action between EOs and antibiotics. The differential composition of the EOs lets us identify some molecules that will be analyzed. Synergic activity of EOs and antibiotics can provide a solid platform for combating multiresistant pathogens that represent a severe health sector problem, such as Kp infections.

Seroprevalence of IgG and Subclasses against the Nucleocapsid of SARS-CoV-2 in Health Workers.

BACKGROUND: The nucleocapsid protein of SARS-CoV-2 participates in viral replication, transcription, and assembly. Antibodies against this protein have been proposed for the epidemiological analysis of the seroprevalence of COVID-19 associated with natural infection by SARS-CoV-2. Health workers were one of the most exposed populations, and some had an asymptomatic form of the disease, so detecting IgG antibodies and subclasses against the N protein can help to reclassify their epidemiological status and obtain information about the effector mechanisms associated with viral elimination. METHODS: In this study, we analyzed 253 serum samples collected in 2021 and derived from health workers, and evaluated the presence of total IgG and subclasses against the N protein of SARS-CoV-2 by indirect ELISA. RESULTS: From the analyzed samples, 42.69% were positive to anti-N IgG antibodies. A correlation between COVID-19 asymptomatic infection and IgG antibodies was observed (p = 0.006). The detected subclasses were: IgG1 (82.4%), IgG2 (75.9%), IgG3 (42.6%), and IgG4 (72.6%). CONCLUSIONS: This work provides evidence about the high seroprevalence of total IgG and subclasses of anti-N and their relations with the asymptomatic infection of SARS-CoV-2 and related symptoms.

Detection of IgA and IgG Antibodies against the Structural Proteins of SARS-CoV-2 in Breast Milk and Serum Samples Derived from Breastfeeding Mothers.

Background: COVID-19 vaccination or natural infection is associated with the development of immunity. The search of IgA and IgG antibodies against all the structural proteins (spike, nucleocapsid, membrane, and envelope) of SARS-CoV-2 in breastfeeding mothers is associated with immunity that can help the newborn avoid development of the infection. Methods: In this study, we analyzed 30 breastfeeding women that provided samples of breast milk and serum and evaluated the presence of IgA, total IgG, and subclasses against the structural proteins of SARS-CoV-2. Results: We reported a high seroprevalence to IgA (76.67-100%) and negativity to IgG against all analyzed proteins in breast milk. Seroprevalence in serum samples was around 10-36.67% to IgA and 23.3-60% to IgG. Finally, we detected the presence of the subclasses IgG1, IgG2, and IgG4 against all the structural proteins of SARS-CoV-2. Conclusions: This work provides evidence of the presence of IgA and IgG antibodies against the four structural proteins of SARS-CoV-2 in breast milk and serum samples derived from breastfeeding women, which can confer immunity to the newborn.

Utility of in silico-identified-peptides in spike-S1 domain and nucleocapsid of SARS-CoV-2 for antibody detection in COVID-19 patients and antibody production.

SARS-CoV-2 contains four structural proteins, two of which, the spike and nucleocapsid, are commonly used for the standardization of novel methods for antibody detection; however, some limitations in their use have been observed due to the homology of this virus with other phylogenetically-related viruses. We performed in silico analysis to search for novel immunogenic and antigenic peptides. A total of twenty-five peptides were preliminarily selected, located in the 3D structure of both proteins. Finally, eight peptides were selected: one located in the N protein and seven in the S1 domain of the spike protein. Additionally, the localization of selected peptides in 2D structures and possible changes in the sequences of these peptides in SARS-CoV-2 variants of concern were analyzed. All peptides were synthetized in MAP8 format, and recombinant S (trimer and RBD) and N proteins were used as antigens to search for antibodies in serum samples derived from COVID-19 patients, and for antibody response in New Zealand rabbits. Results showed high recognition of the serum derived from COVID-19 patients to all selected peptides; however, only the RBD3 peptide induced antibody production. In conclusion, this work provides evidence for a new strategy in peptide selection and its use for antibody detection or antibody production in animals.

Role of Epstein-Barr Virus in Glioblastoma.

Gliomas are the most common and most lethal primary malignant adult brain tumors, and glioblastomas are the most frequent. Several risk factors are involved in their pathogenesis; these include environmental factors as well as host factors. The etiology of most gliomas remains unknown. Epstein-Barr Virus (EBV), a member of the Herpesviridae family, was the first tumoral virus to be described, and several viruses in connection with cancer were discovered thereafter. During the complex interaction between host and EBV, several events take place. In the context of survival, EBV can drive its host cells with subsequent disruption of the cellular machinery, leading to tumorigenesis as the final outcome. Thus, the EBV infection has been associated with different tumors. In this review, we discuss EBV and cancer. We have analyzed previously published papers and have conducted a critical analysis on the role of the viral infection in glioblastoma. Several works have described the presence of the virus, but none have shown a conclusive association. Thus, there is need to continue analyzing the interaction between host and virus to determine whether the viral presence is incidental or has some association with glioblastoma.

Urinary tract infections, immunity, and vaccination. / Infecciones del tracto urinario, inmunidad y vacunación

Urinary tract infections (UTI) are considered one of the main causes of morbidity worldwide, and uropathogenic Escherichia coli (UPEC) is the etiological agent associated with these infections. The high morbidity produced by the UTI and the limitation of antibiotic treatments promotes the search for new alternatives against these infections. The knowledge that has been generated regarding the immune response in the urinary tract is important for the development of effective strategies in the UTI prevention, treatment, and control. Molecular biology and bioinformatic tools have allowed the construction of fusion proteins as biomolecules for the development of a viable vaccine against UTI. The fimbrial adhesins (FimH, CsgA, and PapG) of UPEC are virulence factors that contribute to the adhesion, invasion, and formation of intracellular bacterial communities. The generation of recombinant proteins from fimbrial adhesins as a single molecule is obtained by fusion technology. A few in vivo and in vitro studies have shown that fusion proteins provide an efficient immune response and protection against UTI produced by UPEC. Intranasal immunization of immunogenic molecules has generated a response in the urinary tract mucosa compared with other routes of immunization. The objective of this review was to propose a vaccine designed against UTI caused by UPEC, describing the general scenario of the infection, the mechanism of pathogenicity of bacteria, and the immune response of the host.

Las infecciones del tracto urinario (ITU) se consideran como una de las principales causas de morbilidad en el mundo, y Escherichia coli uropatogénica (UPEC, por sus siglas en inglés) es el agente causal asociado a estas infecciones. La alta morbilidad generada por las ITU y la limitación de tratamientos debido al aumento de la resistencia bacteriana a los diversos antibióticos inducen la búsqueda de nuevas alternativas contra estas infecciones. El conocimiento que se ha generado acerca de la respuesta inmunitaria en el tracto urinario (TU) es importante para el desarrollo de estrategias efectivas en la prevención, el tratamiento y el control de las ITU. Los avances en las herramientas de biología molecular y bioinformática han permitido generar proteínas de fusión consideradas como biomoléculas potenciales para el desarrollo de una vacuna viable contra las ITU. Las adhesinas fimbriales (FimH, CsgA y PapG) de UPEC son factores de virulencia que contribuyen a la adherencia, la invasión y la formación de comunidades bacterianas intracelulares. Pocos estudios in vivo e in vitro han mostrado que las proteínas de fusión promueven una respuesta inmunitaria eficiente y de protección contra las ITU causadas por UPEC. Adicionalmente, la vía de inmunización intranasal con moléculas inmunogénicas ha generado una respuesta en la mucosa del TU en comparación contra otras vías de inmunización. El objetivo de esta revisión fue proponer un diseño de vacuna contra las ITU causadas por UPEC, describiendo el panorama general de la infección, el mecanismo de patogenicidad de la bacteria y la respuesta inmunitaria del huésped.

Infecciones del tracto urinario, inmunidad y vacunación / Urinary tract infections, immunity, and vaccination

Resumen Las infecciones del tracto urinario (ITU) se consideran como una de las principales causas de morbilidad en el mundo, y Escherichia coli uropatogénica (UPEC, por sus siglas en inglés) es el agente causal asociado a estas infecciones. La alta morbilidad generada por las ITU y la limitación de tratamientos debido al aumento de la resistencia bacteriana a los diversos antibióticos inducen la búsqueda de nuevas alternativas contra estas infecciones. El conocimiento que se ha generado acerca de la respuesta inmunitaria en el tracto urinario (TU) es importante para el desarrollo de estrategias efectivas en la prevención, el tratamiento y el control de las ITU. Los avances en las herramientas de biología molecular y bioinformática han permitido generar proteínas de fusión consideradas como biomoléculas potenciales para el desarrollo de una vacuna viable contra las ITU. Las adhesinas fimbriales (FimH, CsgA y PapG) de UPEC son factores de virulencia que contribuyen a la adherencia, la invasión y la formación de comunidades bacterianas intracelulares. Pocos estudios in vivo e in vitro han mostrado que las proteínas de fusión promueven una respuesta inmunitaria eficiente y de protección contra las ITU causadas por UPEC. Adicionalmente, la vía de inmunización intranasal con moléculas inmunogénicas ha generado una respuesta en la mucosa del TU en comparación contra otras vías de inmunización. El objetivo de esta revisión fue proponer un diseño de vacuna contra las ITU causadas por UPEC, describiendo el panorama general de la infección, el mecanismo de patogenicidad de la bacteria y la respuesta inmunitaria del huésped.

Abstract Urinary tract infections (UTI) are considered one of the main causes of morbidity worldwide, and uropathogenic Escherichia coli (UPEC) is the etiological agent associated with these infections. The high morbidity produced by the UTI and the limitation of antibiotic treatments promotes the search for new alternatives against these infections. The knowledge that has been generated regarding the immune response in the urinary tract is important for the development of effective strategies in the UTI prevention, treatment, and control. Molecular biology and bioinformatic tools have allowed the construction of fusion proteins as biomolecules for the development of a viable vaccine against UTI. The fimbrial adhesins (FimH, CsgA, and PapG) of UPEC are virulence factors that contribute to the adhesion, invasion, and formation of intracellular bacterial communities. The generation of recombinant proteins from fimbrial adhesins as a single molecule is obtained by fusion technology. A few in vivo and in vitro studies have shown that fusion proteins provide an efficient immune response and protection against UTI produced by UPEC. Intranasal immunization of immunogenic molecules has generated a response in the urinary tract mucosa compared with other routes of immunization. The objective of this review was to propose a vaccine designed against UTI caused by UPEC, describing the general scenario of the infection, the mechanism of pathogenicity of bacteria, and the immune response of the host.