The Response of Plasmodium Falciparum to Isoleucine Withdrawal is Dependent on the Stage of Progression Through the Intraerythrocytic Cell Cycle

Overview

Journal Malar J

Publisher Biomed Central

Specialty Tropical Medicine

Date 2020 Apr 10

PMID 32268910

Citations 9

Authors

Kyle Jarrod McLean

Marcelo Jacobs-Lorena

Affiliations

Soon will be listed here.

Abstract

Background: A previous study reported that the malaria parasite Plasmodium falciparum enters an altered growth state upon extracellular withdrawal of the essential amino acid isoleucine. Parasites slowed transit through the cell cycle when deprived of isoleucine prior to the onset of S-phase.

Methods: This project was undertaken to study at higher resolution, how isoleucine withdrawal affects parasite growth. Parasites were followed at regular intervals across an extended isoleucine deprivation time course across the cell cycle using flow cytometry.

Results: These experiments revealed that isoleucine-deprived parasites never exit the cell cycle, but instead continuously grow at a markedly reduced pace. Moreover, slow growth occurs only if isoleucine is removed prior to the onset of schizogony. After S-phase commenced, the parasite is insensitive to isoleucine depletion and transits through the cell cycle at the normal pace.

Conclusions: The markedly different response of the parasite to isoleucine withdrawal before or after the onset of DNA replication is reminiscent of the nutrient-dependent G1 cell cycle checkpoints described in other organisms.

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