Proteomics

Dataset Information

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The impact of biomaterial cell contact on the immunopeptidome


ABSTRACT: Biomaterials play an increasing role in clinical applications and regenerative medicine. Modern biomaterials should imitate the function of damaged tissue without triggering an immune response, initiate self-regeneration of the body and gradually degrade after implantation. The immune system is now well recognized to play a major role in influencing the biocompatibility of implanted medical devices. To develop a better understanding of the effects of biomaterials on the immune response, we have developed a highly sensitive novel test system capable of examining changes in the immune system by biomaterial. Here, we evaluate for the first time the immunopeptidome, a highly sensitive system that reflects cancer transformation, virus or drug influences and passes these changes directly to T cells, as a test system to examine the effects of contact with materials. Since monocytes are one of the first immune cells reacting to biomaterials, we have tested the influence of different materials - stainless steel, aluminum, zinc, high-density polyethylene, polyurethane films containing zinc diethyldithiocarbamate, copper, and zinc sulphate - on the monocytic THP-1 cell line. Material-associated peptides were identified after stimulation with all material types examined. The magnitude of induced changes in the immunopeptidome after the stimulation appears comparable to that of bacterial lipopolysaccharides (LPS). The source proteins of many detected peptides are associated with cytotoxicity, fibrosis, autoimmunity, inflammation and cellular stress. Considering all tested materials, it was found that the LPS-induced cytotoxicity-, inflammation- and cellular stress-associated HLA class I peptides were mainly induced by aluminum and HLA class II peptides mainly by stainless steel. These findings provide some of the first insights into the effects on the immunopeptidome by biomaterials. A more thorough understanding of these effects may enable the design of more biocompatible implant materials using in vitro models in future. This may be achieved through developing a deeper understanding of possible immune responses induced by biomaterials such as fibrosis, inflammation, cytotoxicity, and autoimmune reactions.

INSTRUMENT(S): LTQ Orbitrap

ORGANISM(S): Homo Sapiens (human)

TISSUE(S): Monocyte, Blood

SUBMITTER: Michael Ghosh  

LAB HEAD: Stefan Stevanović

PROVIDER: PXD019258 | Pride | 2020-12-01

REPOSITORIES: Pride

Dataset's files

Source:
Action DRS
2Alu_classII_assayIII_1.msf Msf
2Alu_classII_assayIII_1.raw Raw
2Alu_classII_assayIII_2.msf Msf
2Alu_classII_assayIII_2.raw Raw
2Alu_classII_assayIII_3.msf Msf
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Biomaterials play an increasing role in clinical applications and regenerative medicine. A perfectly designed biomaterial should restore the function of damaged tissue without triggering an undesirable immune response, initiate self-regeneration of the surrounding tissue and gradually degrade after implantation. The immune system is well recognized to play a major role in influencing the biocompatibility of implanted medical devices. To obtain a better understanding of the effects of biomaterial  ...[more]

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