The cell nucleus plays a key role in differentiation processes in eukaryotic cells. It is not the nucleus in particular, but the organization of the genes and their remodeling that provides the data for the adjustments to be made according to the medium. The neutrophil nucleus has a different morphology. It is a multi-lobed nucleus where some researchers argue no longer function. However, studies indicate that it is very probable the occurrence of chromatin remodeling during activation steps. It may be that the human neutrophil nucleus also contributes to the mobility of neutrophils through thin tissue spaces. Questions like these will be discussed in this small review. The topics include morphology of human neutrophil nucleus, maturation process and modifications of the neutrophil nucleus, neutrophil activation and chromatin modifications, causes and consequences of multi-lobulated segmented morphology, and importance of the nucleus in the formation of neutrophil extracellular traps (NETs).
Although titanium (Ti) is known to elicit a foreign body response when implanted into humans, Ti implant healing resembles normal wound healing in terms of inflammatory cell recruitment and inflammation persistence. Rough implant surfaces may present better conditions for protein adsorption and for the adhesion of platelets and inflammatory cells such as neutrophils. Implanted biomedical devices initially interact with coagulating blood; however, direct contact between the oxide layer of the implant and neutrophils has not been completely described. The aim of the present study is to compare the behaviours of neutrophils in direct contact with different Ti surfaces. Isolated human neutrophils were placed into contact with Ti discs, which had been rendered as 'smooth' or 'rough', following different surface treatments. Scanning electron microscopy and flow cytometry were used to measure cell adhesion to the surfaces and exposure of membrane proteins such as CD62L and CD11b. Topographic roughness was demonstrated as higher for SLA treated surfaces, measured by atomic force microscopy and elemental analysis was performed by energy dispersive X-ray, showing a similar composition for both surfaces. The adhesion of neutrophils to the 'rough' Ti surface was initially stronger than adhesion to the 'smooth' surface. The cell morphology and adhesion marker results revealed clear signs of neutrophil activation by either surface, with different neutrophil morphological characteristics being observed between the two surface types. Understanding the cellular mechanisms regulating cell-implant interactions should help researchers to improve the surface topography of biomedical implant devices.
Polymorphonuclear neutrophils are the main cells of the innate immunity inflammatory response. Several factors can activate or stimulate neutrophils, including platelet-activating factor (PAF), a lipid mediator. Some authors consider the activation induced by PAF priming because it triggers limited production of reactive oxygen species (ROS) and it amplifies the response of the cell to a subsequent activator. The stimulation is reversible, which is critical for modulating the inflammatory response. Exacerbated inflammatory responses lead to serious diseases, such as systemic inflammatory response syndrome (SIRS), among others. Characterizing the stimulation of neutrophils during the possible reversion or prevention of an exaggerated inflammatory response is critical for the development of control strategies. In this study, a proteomic approach was used to identify 36 proteins that differ in abundance between quiescent neutrophils and PAFstimulated neutrophils. The identified proteins were associated with increased DNA repair processes, calcium flux, protein transcription, cytoskeleton alterations that facilitate migration and degranulation, and the release of proinflammatory cytokines and proteins that modulate the inflammatory response. Some of the identified proteins have not been previously reported in neutrophils.
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