Details:

Alternative Title:
BMC Genomics
Personal Author:
Liu, Shiyou ; Roellig, Dawn M. ; Guo, Yaqiong ; Li, Na ; Frace, Michael A. ; ... More +
Liu, Shiyou ; Roellig, Dawn M. ; Guo, Yaqiong ; Li, Na ; Frace, Michael A. ; Tang, Kevin ; Zhang, Longxian ; Feng, Yaoyu ; Xiao, Lihua Less -
Description:
Background

The switch from photosynthetic or predatory to parasitic life strategies by apicomplexans is accompanied with a reductive evolution of genomes and losses of metabolic capabilities. Cryptosporidium is an extreme example of reductive evolution among apicomplexans, with losses of both the mitosome genome and many metabolic pathways. Previous observations on reductive evolution were largely based on comparative studies of various groups of apicomplexans. In this study, we sequenced two divergent Cryptosporidium species and conducted a comparative genomic analysis to infer the reductive evolution of metabolic pathways and differential evolution of invasion-related proteins within the Cryptosporidium lineage.

Results

In energy metabolism, Cryptosporidium species differ from each other mostly in mitosome metabolic pathways. Compared with C. parvum and C. hominis, C. andersoni possesses more aerobic metabolism and a conventional electron transport chain, whereas C. ubiquitum has further reductions in ubiquinone and polyisprenoid biosynthesis and has lost both the conventional and alternative electron transport systems. For invasion-associated proteins, similar to C. hominis, a reduction in the number of genes encoding secreted MEDLE and insulinase-like proteins in the subtelomeric regions of chromosomes 5 and 6 was also observed in C. ubiquitum and C. andersoni, whereas mucin-type glycoproteins are highly divergent between the gastric C. andersoni and intestinal Cryptosporidium species.

Conclusions

Results of the study suggest that rapidly evolving mitosome metabolism and secreted invasion-related proteins could be involved in tissue tropism and host specificity in Cryptosporidium spp. The finding of progressive reduction in mitosome metabolism among Cryptosporidium species improves our knowledge of organelle evolution within apicomplexans.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-016-3343-5) contains supplementary material, which is available to authorized users.


Subjects:
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Apicomplexa Cryptosporidium Genomics Mitosome Metabolism Reductive Evolution Research Article
Source:
BMC Genomics. 17.
Pubmed ID:
27931183
Pubmed Central ID:
PMC5146892
Document Type:
Journal Article
Collection(s):
CDC Public Access
Main Document Checksum:
[+]
urn:sha256:044086037968e3b10ac356924cbac3108b8cd625c55af98f1241277cf77babfd
Download URL:
https://stacks.cdc.gov/view/cdc/43635/cdc_43635_DS1.pdf
File Type:

Supporting Files

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