Physiological characteristics of Magnetospirillum gryphiswaldense MSR-1 that control cell growth under high-iron and low-oxygen conditions

Qing Wang,Lei Wang,Xu Wang,Xianyu Li,Weijia Zhang,Yinjia Wang,Jilun Li,Wei Jiang,Dan Li,Jiesheng Tian,Ziding Zhang,Ying Li,Yuan Zhou,Youliang Peng

doi:10.1038/s41598-017-03012-4

Abstract

Magnetosome formation by Magnetospirillum gryphiswaldense MSR-1 is dependent on iron and oxygen levels. We used transcriptome to evaluate transcriptional profiles of magnetic and non-magnetic MSR-1 cells cultured under high-iron and low-iron conditions. A total of 80 differentially expressed genes (DEGs) were identified, including 53 upregulated and 27 downregulated under high-iron condition. These DEGs belonged to the functional categories of biological regulation, oxidation-reduction process, and ion binding and transport, and were involved in sulfur metabolism and cysteine/methionine metabolism. Comparison with our previous results from transcriptome data under oxygen-controlled conditions indicated that transcription of mam or mms was not regulated by oxygen or iron signals. 17 common DEGs in iron- and oxygen-transcriptomes were involved in energy production, iron transport, and iron metabolism. Some unknown-function DEGs participate in iron transport and metabolism, and some are potential biomarkers for identification of Magnetospirillum strains. IrrA and IrrB regulate iron transport in response to low-oxygen and high-iron signals, respectively. Six transcription factors were predicted to regulate DEGs. Fur and Crp particularly co-regulate DEGs in response to changes in iron or oxygen levels, in a proposed joint regulatory network of DEGs. Our findings provide new insights into biomineralization processes under high- vs. low-iron conditions in magnetotactic bacteria.

Highlights

Termed the magnetosome island (MAI), and belong to four conserved clusters: the mamAB, mamXY, mamGFDC, and mms[6] operons[1, 5, 10]
Ferric uptake regulator (Fur) protein is a global regulator of iron and oxygen metabolism
Several proteins that participate in general iron metabolism are involved in magnetosome formation, including FeoB1 and FeoB216, 17, and FeR5 and FeR6, two bifunctional enzymes that have ferric reduction function and play complementary roles in the process[18]

Summary

OPEN Physiological characteristics of Magnetospirillum gryphiswaldense

Received: 18 October 2016 Accepted: 21 April 2017 Published: xx xx xxxx under high-iron and low-oxygen conditions. Six transcription factors were predicted to regulate DEGs. Fur and Crp co-regulate DEGs in response to changes in iron or oxygen levels, in a proposed joint regulatory network of DEGs. Our findings provide new insights into biomineralization processes under high- vs low-iron conditions in magnetotactic bacteria. We evaluated the effects of iron concentration on metabolism and magnetosome formation of MSR-1 cells, in comparison with transcriptome data under high-iron and low-iron conditions. Analysis of the transcriptome data indicated that certain genes in multi-metabolic pathways are involved in magnetosome formation, and led to generation of a proposed regulatory network of DEGs. In comparison with transcriptome data under oxygen-controlled conditions, there were both similarities and differences in results from formation of mature magnetosomes. Our findings provide new insights into physiological differences in biomineralization processes under high- vs. low-iron condition

Results and Discussion

Cyclic nucleotidebinding domain

Methods

Author Contributions

Additional Information