The Pharmacological Potential of Novel Melittin Variants from the Honeybee and Solitary Bees against Inflammation and Cancer.
Pelin ErkocBjörn Marcus von ReumontTim LüddeckeMarina HenkeThomas UlshöferAndreas VilcinskasRobert FürstSusanne SchiffmannPublished in: Toxins (2022)
The venom of honeybees is composed of numerous peptides and proteins and has been used for decades as an anti-inflammatory and anti-cancer agent in traditional medicine. However, the bioactivity of specific biomolecular components has been evaluated for the predominant constituent, melittin. So far, only a few melittin-like peptides from solitary bee species have been investigated, and the molecular mechanisms of bee venoms as therapeutic agents remain largely unknown. Here, the preclinical pharmacological activities of known and proteo-transcriptomically discovered new melittin variants from the honeybee and more ancestral variants from phylogenetically older solitary bees were explored in the context of cancer and inflammation. We studied the effects of melittin peptides on cytotoxicity, second messenger release, and inflammatory markers using primary human cells, non-cancer, and cancerous cell lines. Melittin and some of its variants showed cytotoxic effects, induced Ca 2+ signaling and inhibited cAMP production, and prevented LPS-induced NO synthesis but did not affect the IP3 signaling and pro-inflammatory activation of endothelial cells. Compared to the originally-described melittin, some phylogenetically more ancestral variants from solitary bees offer potential therapeutic modalities in modulating the in vitro inflammatory processes, and hindering cancer cell viability/proliferation, including aggressive breast cancers, and are worth further investigation.
Keyphrases
- papillary thyroid
- copy number
- lps induced
- squamous cell
- oxidative stress
- endothelial cells
- lymph node metastasis
- inflammatory response
- squamous cell carcinoma
- signaling pathway
- bone marrow
- gene expression
- mass spectrometry
- amino acid
- genome wide
- dna methylation
- high resolution
- young adults
- single molecule
- protein kinase
- high speed