The Subcellular Proteome of a Planctomycetes Bacterium Shows That Newly Evolved Proteins Have Distinct Fractionation Patterns.

Christian Seeger,Sara Bergström Lind,Anna Odelgard,Siv G. E. Andersson,Karl Dyrhage,Mayank Mahajan

doi:10.3389/fmicb.2021.643045

Christian Seeger, Sara Bergström Lind + Show 4 more

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https://doi.org/10.3389/fmicb.2021.643045

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Abstract

The Planctomycetes bacteria have unique cell architectures with heavily invaginated membranes as confirmed by three-dimensional models reconstructed from FIB-SEM images of Tuwongella immobilis and Gemmata obscuriglobus. The subcellular proteome of T. immobilis was examined by differential solubilization followed by LC-MS/MS analysis, which identified 1569 proteins in total. The Tris-soluble fraction contained mostly cytoplasmic proteins, while inner and outer membrane proteins were found in the Triton X-100 and SDS-soluble fractions, respectively. For comparisons, the subcellular proteome of Escherichia coli was also examined using the same methodology. A notable difference in the overall fractionation pattern of the two species was a fivefold higher number of predicted cytoplasmic proteins in the SDS-soluble fraction in T. immobilis. One category of such proteins is represented by innovations in the Planctomycetes lineage, including unique sets of serine/threonine kinases and extracytoplasmic sigma factors with WD40 repeat domains for which no homologs are present in E. coli. Other such proteins are members of recently expanded protein families in which the newly evolved paralog with a new domain structure is recovered from the SDS-soluble fraction, while other paralogs may have similar domain structures and fractionation patterns as the single homolog in E. coli. The expanded protein families in T. immobilis include enzymes involved in replication-repair processes as well as in rRNA and tRNA modification and degradation. These results show that paralogization and domain shuffling have yielded new proteins with distinct fractionation characteristics. Understanding the molecular intricacies of these adaptive changes might aid in the development of a model for the evolution of cellular complexity.

Highlights

Members of the Planctomycetes have been classified as bacteria by phylogenetic inferences based on both rRNA gene and concatenated protein sequences, as reviewed in Wiegand et al (2018)
For MutS, we identified three paralogous genes in T. immobilis, two of which were only found in the S3 fraction, FIGURE 10 | Functional analysis of T. immobilis and E. coli subcellular proteomes based on Clusters of Orthologous Groups (COGs)
We have examined the membrane network of T. immobilis using FIB-SEM tomography and analyzed its proteome by LC-MS/MS following a series of protein extractions

Summary

Introduction

Members of the Planctomycetes have been classified as bacteria by phylogenetic inferences based on both rRNA gene and concatenated protein sequences, as reviewed in Wiegand et al (2018). Despite their classification as prokaryotes, they carry many fascinating traits that set them apart from other bacteria, most strikingly an elaborate intracellular membrane system, as shown for example in Subcellular Proteomics of Tuwongella immobilis electron tomography studies of Gemmata obscuriglobus (Santarella-Mellwig et al, 2013; Sagulenko et al, 2014) and cryo electron tomography studies of Planctopirus limnophila (Boedeker et al, 2017) and Tuwongella immobilis (Mahajan et al, 2020a). The third layer contained visible pores on the surfaces of the membranes that were interpreted as nuclear pore-like structures, and it was hypothesized that this layer corresponds to a membrane that surrounds the chromosome (Sagulenko et al, 2017)

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