AI Article Synopsis
- Malaria parasites adapt by digesting host hemoglobin to obtain essential amino acids, leading to a connection between nutrient availability and how genes are expressed.
- The study finds that certain tRNAs, which help decode amino acids that are not provided enough by hemoglobin, are underexpressed, creating a mismatch for optimal translation.
- Proliferation-related genes that rely heavily on these tRNAs can have their protein synthesis regulated during times of nutrient stress, showcasing how metabolic adaptation influences protein evolution in these parasites.
Article Abstract
An adaptive feature of malaria-causing parasites is the digestion of host hemoglobin (HB) to acquire amino acids (AAs). Here, we describe a link between nutrient availability and translation dependent regulation of gene expression as an adaptive strategy. We show that tRNA expression in does not match the decoding need expected for optimal translation. A subset of tRNAs decoding AAs that are insufficiently provided by HB are lowly expressed, wherein the abundance of a protein-coding transcript is negatively correlated with the decoding requirement of these tRNAs. Proliferation-related genes have evolved a high requirement of these tRNAs, thereby proliferation can be modulated by repressing protein synthesis of these genes during nutrient stress. We conclude that the parasite modulates translation elongation by maintaining a discordant tRNA profile to exploit variations in AA-composition among genes as an adaptation strategy. This study exemplifies metabolic adaptation as an important driving force for protein evolution.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11544085 | PMC |
| http://dx.doi.org/10.1016/j.isci.2024.111167 | DOI Listing |
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