Superwettable surfaces and factors impacting microbial adherence in microbiologically-influenced corrosion: a review.

Microbiologically-influenced corrosion (MIC) is a common operational hazard to many industrial processes. The focus of this review lies on microbial corrosion in the maritime industry. Microbial metal attachment and colonization are the critical steps in MIC initiation. We have outlined the crucial factors influencing corrosion caused by microorganism sulfate-reducing bacteria (SRB), where its adherence on the metal surface leads to Direct Electron Transfer (DET)-MIC. This review thus aims to summarize the recent progress and the lacunae in mitigation of MIC. We further highlight the susceptibility of stainless steel grades to SRB pitting corrosion and have included recent developments in understanding the quorum sensing mechanisms in SRB, which governs the proliferation process of the microbial community. There is a paucity of literature on the utilization of anti-quorum sensing molecules against SRB, indicating that the area of study is in its nascent stage of development. Furthermore, microbial adherence to metal is significantly impacted by surface chemistry and topography. Thus, we have reviewed the application of super wettable surfaces such as superhydrophobic, superhydrophilic, and slippery liquid-infused porous surfaces as "anti-corrosion coatings" in preventing adhesion of SRB, providing a potential avenue for the development of practical and feasible solutions in the prevention of MIC. The emerging field of super wettable surfaces holds significant potential for advancing efficient and practical MIC prevention techniques.

Type-1 interferons prolong the lifespan of neutrophils by interfering with members of the apoptotic cascade.

Polymorphonuclear Neutrophils (PMNs) are metabolically highly active phagocytes, present in abundant numbers in the circulation. These active cells take the onus of clearing invading pathogens by crowding at inflammatory sites in huge numbers. Though PMNs are extremely short living and die upon spontaneous apoptosis, extended lifespan has been observed among those cells arrive at the inflammation sites or tackle intracellular infections or face any microbial challenges. The delay/inhibition of spontaneous apoptosis of these short-living cells at the inflammatory core rather helps in combating pathogens. Like many candidates, type-1 interferons (type-1 IFNs) is a group of cytokines predominant at the inflammation site. Although there are some isolated reports, a systematic study is still lacking which addresses the impact of the predominant type of interferon on the spontaneous apoptosis of neutrophils. Here in, we have observed that exposure of these IFNs (IFN-ß, IFN-α & IFN-ω etc) on human neutrophils prevents the degradation of the Bfl1, an important anti-apoptotic partner in the apoptotic cascade. Treatment showed a significant reduction in the release of cytochrome-C in the cytosol, a critical regulator in the intrinsic apoptotic pathway. We also noticed a reduction in the conversion of procaspase -3 to active caspase-3, a crucial executioner caspase towards initiation of apoptosis. Taken together our results show that exposure to interferon interferes with apoptotic pathways of neutrophils and thereby delay its spontaneous apoptosis. These findings would help us further deciphering specific roles if these inflammatory agents are causing any immune-metabolomic changes on PMNs at the inflammatory and infection core.

Pro-inflammatory cytokine Interleukin-1ß (IL-1ß) controls Leishmania infection.

Leishmania is an obligate intracellular parasite uses low pH phagolysosomal compartments of host macrophages as their final abode. IL-1ß is a pro inflammatory cytokine, which is secreted by immune cells to trigger inflammation and this has been found profoundly in the lesions caused by Leishmania pathogens. But the specific role of this cytokine on host cell macrophages during infection has not been fully explored. Here in, we have showed that prolonged exposure of IL-1ß on macrophages increases the parasite burden. Pre-treatment of bone marrow derived macrophages (BMDM) with IL-1ß also generates significantly higher amount of anti-inflammatory cytokine IL-10. As IL-10 plays crucial role in the establishment of infection, enhanced production of IL-10 observed upon IL-1ß treatment could contribute to the progression of the disease. By quantifying the production of Nitric oxide (NO), we further report that the pretreatment of IL-1ß fails to produce the nitric oxide. By measuring the footpad thickness in two different mice strains of differential susceptibility we showed IL-1ß treatment increases parasitic burden. As our results shows that the exposure of IL-1ß helps in disease progression, IL-1ß signalling may be an attractive target for future therapeutic intervention.

Neutrophils: Interplay between host defense, cellular metabolism and intracellular infection.

Neutrophils are short-living innate immune cells present in abundance in the circulation and they provide the first line of defense against infection. Microbicidal effector functions of the immune cells are tightly linked with their metabolic state. Overall knowledge of the association of neutrophil defense with cellular metabolism is still elusive. Recent studies have reported that neutrophil metabolism during granulopoiesis is impacted by the homeostatic process of autophagy. Autophagy is a complex process of which the subtype xenophagy, an antimicrobial autophagic process, clears invading pathogens. Neutrophils, being sentinels of innate immunity, encounter microbes and digest them. Studies on neutrophil antimicrobial autophagy process is still in its primeval state and has not been much explored as in other professional phagocytes. However, several obligate-intracellular pathogens are able to subvert the toxic antimicrobial machineries and utilize neutrophils as their final abodes or "Trojan Horses" for further propagation. In this review, we would provide an insight into the relationship between neutrophil microbicidal effector functions emphasizing on selective antimicrobial autophagy and metabolism, highlighting on some successful pathogens which have evolved ways to subvert or exploit this defense.