Moreira-Ramos Sandra, Arias Loreto, Flores Rodrigo, Katz Assaf, Levicán Gloria, Orellana Omar
Programa de Biología Celular y Molecular, Instituto de Ciencias Biomédicas, Facultad de Medicina, Universidad de Chile, Santiago, Chile.
Departamento de Biología, Facultad de Química y Biología, Universidad de Santiago de Chile (USACH), Santiago, Chile.
Front Microbiol. 2023 Jan 11;13:1074741. doi: 10.3389/fmicb.2022.1074741. eCollection 2022.
Proteostasis refers to the processes that regulate the biogenesis, folding, trafficking, and degradation of proteins. Any alteration in these processes can lead to cell malfunction. Protein synthesis, a key proteostatic process, is highly-regulated at multiple levels to ensure adequate adaptation to environmental and physiological challenges such as different stressors, proteotoxic conditions and aging, among other factors. Because alterations in protein translation can lead to protein misfolding, examining how protein translation is regulated may also help to elucidate in part how proteostasis is controlled. Codon usage bias has been implicated in the fine-tuning of translation rate, as more-frequent codons might be read faster than their less-frequent counterparts. Thus, alterations in codon usage due to synonymous mutations may alter translation kinetics and thereby affect the folding of the nascent polypeptide, without altering its primary structure. To date, it has been difficult to predict the effect of synonymous mutations on protein folding and cellular fitness due to a scarcity of relevant data. Thus, the purpose of this work was to assess the effect of synonymous mutations in discrete regions of the gene that encodes the highly-expressed enzyme 3-phosphoglycerate kinase 1 () in the fission yeast .
By means of systematic replacement of synonymous codons along , we found slightly-altered protein folding and activity in a region-specific manner. However, alterations in protein aggregation, heat stress as well as changes in proteasome activity occurred independently of the mutated region. Concomitantly, reduced mRNA levels of the chaperones Hsp9 and Hsp16 were observed.
Taken together, these data suggest that codon usage bias of the gene encoding this highly-expressed protein is an important regulator of protein function and proteostasis.
蛋白质稳态是指调节蛋白质生物合成、折叠、运输和降解的过程。这些过程中的任何改变都可能导致细胞功能异常。蛋白质合成作为蛋白质稳态的关键过程,在多个水平上受到高度调控,以确保充分适应环境和生理挑战,如不同的应激源、蛋白毒性条件和衰老等因素。由于蛋白质翻译的改变可能导致蛋白质错误折叠,研究蛋白质翻译的调控方式也可能有助于部分阐明蛋白质稳态的控制机制。密码子使用偏好与翻译速率的微调有关,因为使用频率较高的密码子可能比使用频率较低的密码子被更快地读取。因此,同义突变导致的密码子使用改变可能会改变翻译动力学,从而影响新生多肽的折叠,而不改变其一级结构。迄今为止,由于缺乏相关数据,很难预测同义突变对蛋白质折叠和细胞适应性的影响。因此,这项工作的目的是评估在裂殖酵母中编码高表达酶3-磷酸甘油酸激酶1(Pgk1)的基因离散区域中的同义突变的影响。
通过系统替换Pgk1上的同义密码子,我们发现蛋白质折叠和活性以区域特异性方式略有改变。然而,蛋白质聚集、热应激的改变以及蛋白酶体活性的变化与突变区域无关。同时,观察到伴侣蛋白Hsp9和Hsp16的mRNA水平降低。
综上所述,这些数据表明,编码这种高表达蛋白质的基因的密码子使用偏好是蛋白质功能和蛋白质稳态的重要调节因子。
