We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Molecular insights into nanoplastics-peptides binding and their interactions with the lipid membrane
Summary
Using computer simulations, researchers studied how nanoplastics interact with small protein fragments and cell membranes at the molecular level. They found that nanoplastics readily bind to proteins, forming a coating called a protein corona, which changes how the plastics behave when they encounter cell membranes. This research helps explain how nanoplastics might enter human cells, since the protein coating could either help or hinder the particles from crossing biological barriers.
Micro- and nanoplastics have become a significant concern, due to their ubiquitous presence in the environment. These particles can be internalized by the human body through ingestion, inhalation, or dermal contact, and then they can interact with environmental or biological molecules, such as proteins, resulting in the formation of the protein corona. However, information on the role of protein corona in the human body is still missing. Coarse-grain models of the nanoplastics and pentapeptides were created and simulated at the microscale to study the role of protein corona. Additionally, a lipid bilayer coarse-grain model was reproduced to investigate the behavior of the coronated nanoplastics in proximity of a lipid bilayer. Hydrophobic and aromatic amino acids have a high tendency to create stable bonds with all nanoplastics. Moreover, polystyrene and polypropylene establish bonds with polar and charged amino acids. When the coronated nanoplastics are close to a lipid bilayer, different behaviors can be observed. Polyethylene creates a single polymeric chain, while polypropylene tends to break down into its single chains. Polystyrene can both separate into its individual chains and remain aggregated. The protein corona plays an important role when interacting with the nanoplastics and the lipid membrane. More studies are needed to validate the results and to enhance the complexity of the systems.
Sign in to start a discussion.
More Papers Like This
Assessment on interactive prospectives of nanoplastics with plasma proteins and the toxicological impacts of virgin, coronated and environmentally released-nanoplastics
Researchers found that nanoplastics quickly coat themselves in blood proteins, forming a multi-layered "corona" that changes the proteins' shape and makes them biologically harmful; these protein-coated nanoplastics caused more DNA and cell damage in human blood cells than bare nanoplastics. The study highlights the need to regulate nanoplastics in medical products and better understand how they accumulate in the body.
Interaction of polyethylene nanoplastics with the plasma, endoplasmic reticulum, Golgi apparatus, lysosome and endosome membranes: A molecular dynamics study
Researchers used computer simulations to study how polyethylene nanoplastics interact with five types of cell membranes in the human body, finding that the plastic particles spontaneously insert themselves into the fatty inner layer of membranes and disrupt normal membrane flexibility. These atomic-level findings help explain how nanoplastics may cause cell damage from the inside.
Pollution caused by nanoplastics: adverse effects and mechanisms of interaction via molecular simulation
This review used molecular simulation techniques to examine how nanoplastics interact with biological membranes and proteins, finding that NPs alter lipid membrane organization and protein secondary structure, potentially disrupting digestion and nutrient absorption in the gastrointestinal system. The review synthesized evidence that NPs can also adsorb environmental contaminants and potentiate their toxicity through synergistic mechanisms.
Nanoplastics and Protein Corona - Investigating the Corona Structure and their Biological Impacts
This PhD thesis investigated how proteins from biological fluids coat the surface of nanoplastics, forming a 'protein corona' that changes how nanoplastics interact with cells and tissues. The protein corona is important because it alters the biological behavior of nanoplastics once they enter the body, potentially affecting how harmful they are.
Interactions of Micro- and Nanoplastics with Biomolecules: From Public Health to Protein Corona Effect and Beyond
This review summarizes how micro- and nanoplastics interact with biological molecules in the body, including cell membranes and proteins. These particles can cause membranes to thicken and form pores, and they attract a coating of proteins (called a protein corona) that changes how the body responds to them, potentially increasing inflammation, oxidative stress, and disruption of hormone systems.