Oncolytic Rodent Protoparvoviruses Evade a TLR- and RLR-Independent Antiviral Response in Transformed Cells.

The oncolytic rodent protoparvoviruses (PVs) minute virus of mice (MVMp) and H-1 parvovirus (H-1PV) are promising cancer viro-immunotherapy candidates capable of both exhibiting direct oncolytic activities and inducing anticancer immune responses (AIRs). Type-I interferon (IFN) production is instrumental for the activation of an efficient AIR. The present study aims at characterizing the molecular mechanisms underlying PV modulation of IFN induction in host cells. MVMp and H-1PV triggered IFN production in semi-permissive normal mouse embryonic fibroblasts (MEFs) and human peripheral blood mononuclear cells (PBMCs), but not in permissive transformed/tumor cells. IFN production triggered by MVMp in primary MEFs required PV replication and was independent of the pattern recognition receptors (PRRs) Toll-like (TLR) and RIG-like (RLR) receptors. PV infection of (semi-)permissive cells, whether transformed or not, led to nuclear translocation of the transcription factors NFĸB and IRF3, hallmarks of PRR signaling activation. Further evidence showed that PV replication in (semi-)permissive cells resulted in nuclear accumulation of dsRNAs capable of activating mitochondrial antiviral signaling (MAVS)-dependent cytosolic RLR signaling upon transfection into naïve cells. This PRR signaling was aborted in PV-infected neoplastic cells, in which no IFN production was detected. Furthermore, MEF immortalization was sufficient to strongly reduce PV-induced IFN production. Pre-infection of transformed/tumor but not of normal cells with MVMp or H-1PV prevented IFN production by classical RLR ligands. Altogether, our data indicate that natural rodent PVs regulate the antiviral innate immune machinery in infected host cells through a complex mechanism. In particular, while rodent PV replication in (semi-)permissive cells engages a TLR-/RLR-independent PRR pathway, in transformed/tumor cells this process is arrested prior to IFN production. This virus-triggered evasion mechanism involves a viral factor(s), which exert(s) an inhibitory action on IFN production, particularly in transformed/tumor cells. These findings pave the way for the development of second-generation PVs that are defective in this evasion mechanism and therefore endowed with increased immunostimulatory potential through their ability to induce IFN production in infected tumor cells.

Alteration of the IFN-Pathway by Human Papillomavirus Proteins: Antiviral Immune Response Evasion Mechanism.

A persistent infection with the so-called high-risk Human Papillomaviruses (hr-HPVs) plays a fundamental role in the development of different neoplasms. The expression of the HPV proteins throughout the different steps of the viral life cycle produce a disruption of several cellular processes, including immune response, which can lead to cell transformation. The interferon-mediated response plays an important role in eliminating HPV-infected and -transformed cells. The ability of HPV to disrupt the proper function of the interferon response is based on a series of molecular mechanisms coordinated by HPV proteins intended to prevent clearance of infection, ultimately producing an immunotolerant environment that facilitates the establishment of persistence and cancer. In this review, we focus on the molecular actions performed by HPV E1, E2, E5, E6 and E7 proteins on IFN signaling elements and their contribution to the establishment of infection, viral persistence and the progression to cancer.

Experimental Evidence of Intrinsic Disorder and Amyloid Formation by the Henipavirus W Proteins.

Henipaviruses are severe human pathogens within the Paramyxoviridae family. Beyond the P protein, the Henipavirus P gene also encodes the V and W proteins which share with P their N-terminal, intrinsically disordered domain (NTD) and possess a unique C-terminal domain. Henipavirus W proteins antagonize interferon (IFN) signaling through NTD-mediated binding to STAT1 and STAT4, and prevent type I IFN expression and production of chemokines. Structural and molecular information on Henipavirus W proteins is lacking. By combining various bioinformatic approaches, we herein show that the Henipaviruses W proteins are predicted to be prevalently disordered and yet to contain short order-prone segments. Using limited proteolysis, differential scanning fluorimetry, analytical size exclusion chromatography, far-UV circular dichroism and small-angle X-ray scattering, we experimentally confirmed their overall disordered nature. In addition, using Congo red and Thioflavin T binding assays and negative-staining transmission electron microscopy, we show that the W proteins phase separate to form amyloid-like fibrils. The present study provides an additional example, among the few reported so far, of a viral protein forming amyloid-like fibrils, therefore significantly contributing to enlarge our currently limited knowledge of viral amyloids. In light of the critical role of the Henipavirus W proteins in evading the host innate immune response and of the functional role of phase separation in biology, these studies provide a conceptual asset to further investigate the functional impact of the phase separation abilities of the W proteins.

NAD+-targeting by bacteria: an emerging weapon in pathogenesis.

Nicotinamide adenine dinucleotide (NAD+) is a major cofactor in redox reactions in all life-forms. A stable level of NAD+ is vital to ensure cellular homeostasis. Some pathogens can modulate NAD+ metabolism to their advantage and even utilize or cleave NAD+ from the host using specialized effectors known as ADP-ribosyltransferase toxins and NADases, leading to energy store depletion, immune evasion or even cell death. This review explores recent advances in the field of bacterial NAD+-targeting toxins, highlighting the relevance of NAD+ modulation as an emerging pathogenesis strategy. In addition, we discuss the role of specific NAD+-targeting toxins in niche colonization and bacterial lifestyle as components of toxin/antitoxin systems and key players in interbacterial competition. Understanding the mechanisms of toxicity, regulation and secretion of these toxins will provide interesting leads in the search for new antimicrobial treatments in the fight against infectious diseases.

The Trojan Horse Model in Paracoccidioides: A Fantastic Pathway to Survive Infecting Human Cells.

Paracoccidioidomycosis (PCM) is the most relevant systemic endemic mycosis limited to Latin American countries. The etiological agents are thermally dimorphic species of the genus Paracoccidioides. Infection occurs via respiratory tract by inhalation of propagules from the environmental (saprophytic) phase. In the lung alveoli the fungus converts to the characteristic yeast phase (parasitic) where interact with extracellular matrix proteins, epithelial cells, and the host cellular immunity. The response involves phagocytic cells recognition but intracellular Paracoccidioides have demonstrated the ability to survive and also multiply inside the neutrophils, macrophages, giant cells, and dendritic cells. Persistence of Paracoccidioides as facultative intracellular pathogen is important in terms of the fungal load but also regarding to the possibility to disseminate penetrating other tissues even protected by the phagocytes. This strategy to invade other organs via transmigration of infected phagocytes is called Trojan horse mechanism and it was also described for other fungi and considered a factor of pathogenicity. This mini review comprises a literature revision of the spectrum of tools and mechanisms displayed by Paracoccidioides to overcame phagocytosis, discusses the Trojan horse model and the immunological context in proven models or the possibility that Paracoccidioides apply this tool for dissemination to other tissues.

Significance of Expression of Complement C4d in Esophageal Squamous Cell Carcinoma.

BACKGROUND/AIM: Esophageal squamous cell carcinoma (ESCC) is one of the most difficult malignancies to cure. C4d is a degradation product of the classical complement pathway and is suggested as an early diagnostic marker for other SCCs. The purpose of this study was to clarify the association of complement C4d with ESCC. PATIENTS AND METHODS: Immunohistochemical staining for C4d was performed on surgical specimens obtained from 114 patients with ESCC. RESULTS: Positive C4d expression was observed in 70 (61.4%) cases and negative expression in 44 (38.6%) cases. There was a significant inverse correlation between C4d expression and depth of tumor invasion (p=0.0001), lymph node metastasis (p=0.011), lymphatic invasion (p=0.033), and TNM stage (p=0.0021). Kaplan-Meier analysis showed that negative C4d expression tended to lead to shorter overall survival (p=0.232). CONCLUSION: C4d expression in ESCC might be useful in developing treatment strategies or suppression of ESCC.

Ébolavirus: biología molecular y evasión de la respuesta inmune / Ebolavirus: molecular biology and immune response evasion

La actual epidemia de enfermedad por virus Ébola que azota al África Occidental ha cobrado la vida de alrededor de 9 000 personas con más de 22 000 infectados en seis países, y algunos casos aislados han llegado a ciudades de Europa y Estados Unidos. Aunque el curso clínico de la enfermedad es bien conocido, los mecanismos específicos que explican su patogenicidad no han sido completamente delineados. Los casos fatales de infección por Ébolavirus están marcados por un fallo catastrófico de las respuestas inmune innata y adaptativa, mediado por proteínas codificadas por el virus, así como por propiedades asociadas a su estructura. El genoma del Ébolavirus está constituido solamente por siete genes que codifican unas 10 proteínas, suficientes para desencadenar una enfermedad cuya letalidad varía del 40 al 90 por ciento. En el centro de la desregulación inducida por el Ébola se encuentra una temprana y coordinada actuación de las proteínas VP24, VP30 y VP35, que conduce a niveles elevados de replicación viral, a una inapropiada temporización de la cascada de liberación de linfocinas y a la muerte, tanto de células presentadoras de antígenos, como de células efectoras. Los complejos mecanismos del Ébola para regular selectivamente la respuesta inmune y su patogenicidad variable en diferentes especies hospederas, convierten a este virus en un adversario formidable, así como de un notable interés científico(AU)

The current Ebolavirus disease outbreak that strikes West Africa has claimed the life of around 9 000 people and has infected more than 22 000 in six countries, and some isolated cases have reached cities of Europe and the United States. Though the clinical course of the disease is well known, the specific mechanisms of its pathogenicity have not been fully delineated yet. Fatal cases of Ebolavirus disease are marked by a catastrophic failure of both innate and adaptive immune responses, mediated by virus-encoded proteins as well as properties associated with its structure. Ebolavirus genome comprises only seven genes encoding about 10 proteins, enough to cause a disease which fatality fluctuates from 40 to 90 percent. At the heart of Ebola-induced immune dysregulation is an early and coordinated disruption by VP24, VP30, and VP35 that leads to elevated levels of virus replication, a cascade of inappropriately timed cytokine release, and death of both antigen-presenting and responding immune cells. The complex mechanisms of Ebola to selectively regulate immune responses and its variable pathogenicity in different host species makes this virus both, a challenging foe and scientifically interesting(AU)

Ébolavirus: biología molecular y evasión de la respuesta inmune / Ebolavirus: molecular biology and immune response evasion

La actual epidemia de enfermedad por virus Ébola que azota al África Occidental ha cobrado la vida de alrededor de 9 000 personas con más de 22 000 infectados en seis países, y algunos casos aislados han llegado a ciudades de Europa y Estados Unidos. Aunque el curso clínico de la enfermedad es bien conocido, los mecanismos específicos que explican su patogenicidad no han sido completamente delineados. Los casos fatales de infección por Ébolavirus están marcados por un fallo catastrófico de las respuestas inmune innata y adaptativa, mediado por proteínas codificadas por el virus, así como por propiedades asociadas a su estructura. El genoma del Ébolavirus está constituido solamente por siete genes que codifican unas 10 proteínas, suficientes para desencadenar una enfermedad cuya letalidad varía del 40 al 90 por ciento. En el centro de la desregulación inducida por el Ébola se encuentra una temprana y coordinada actuación de las proteínas VP24, VP30 y VP35, que conduce a niveles elevados de replicación viral, a una inapropiada temporización de la cascada de liberación de linfocinas y a la muerte, tanto de células presentadoras de antígenos, como de células efectoras. Los complejos mecanismos del Ébola para regular selectivamente la respuesta inmune y su patogenicidad variable en diferentes especies hospederas, convierten a este virus en un adversario formidable, así como de un notable interés científico(AU)

The current Ebolavirus disease outbreak that strikes West Africa has claimed the life of around 9 000 people and has infected more than 22 000 in six countries, and some isolated cases have reached cities of Europe and the United States. Though the clinical course of the disease is well known, the specific mechanisms of its pathogenicity have not been fully delineated yet. Fatal cases of Ebolavirus disease are marked by a catastrophic failure of both innate and adaptive immune responses, mediated by virus-encoded proteins as well as properties associated with its structure. Ebolavirus genome comprises only seven genes encoding about 10 proteins, enough to cause a disease which fatality fluctuates from 40 to 90 percent. At the heart of Ebola-induced immune dysregulation is an early and coordinated disruption by VP24, VP30, and VP35 that leads to elevated levels of virus replication, a cascade of inappropriately timed cytokine release, and death of both antigen-presenting and responding immune cells. The complex mechanisms of Ebola to selectively regulate immune responses and its variable pathogenicity in different host species makes this virus both, a challenging foe and scientifically interesting(AU)