Bacterial multi-solute transporters

Bacterial membrane proteins of the SbmA/BacA family are multi-solute transporters that mediate the uptake of structurally diverse hydrophilic molecules, including aminoglycoside antibiotics and antimicrobial peptides. Some family members are full-length ATP-binding cassette (ABC) transporters, whereas other members are truncated homologues that lack the nucleotide-binding domains and thus mediate ATP-independent transport. A recent cryo-EM structure of the ABC transporter Rv1819c from Mycobacterium tuberculosis has shed light on the structural basis for multi-solute transport and has provided insight into the mechanism of transport. Here, we discuss how the protein architecture makes SbmA/BacA family transporters prone to inadvertent import of antibiotics and speculate on the question which physiological processes may benefit from multi-solute transport

Chlamydial contribution to anaerobic metabolism during eukaryotic evolution

The origin of eukaryotes is a major open question in evolutionary biology. Multiple hypotheses posit that eukaryotes likely evolved from a syntrophic relationship between an archaeon and an alphaproteobacterium based on H-2 exchange. However, there are no strong indications that modern eukaryotic H-2 metabolism originated from archaea or alphaproteobacteria. Here, we present evidence for the origin of H-2 metabolism genes in eukaryotes from an ancestor of the Anoxychlamydiales-a group of anaerobic chlamydiae, newly described here, from marine sediments. Among Chlamydiae, these bacteria uniquely encode genes for H-2 metabolism and other anaerobiosis-associated pathways. Phylogenetic analyses of several components of H-2 metabolism reveal that Anoxychlamydiales homologs are the closest relatives to eukaryotic sequences. We propose that an ancestor of the Anoxychlamydiales contributed these key genes during the evolution of eukaryotes, supporting a mosaic evolutionary origin of eukaryotic metabolism

A Phylometagenomic Exploration of Oceanic Alphaproteobacteria Reveals Mitochondrial Relatives Unrelated to the SAR11 Clade

BACKGROUND: According to the endosymbiont hypothesis, the mitochondrial system for aerobic respiration was derived from an ancestral Alphaproteobacterium. Phylogenetic studies indicate that the mitochondrial ancestor is most closely related to the Rickettsiales. Recently, it was suggested that Candidatus Pelagibacter ubique, a member of the SAR11 clade that is highly abundant in the oceans, is a sister taxon to the mitochondrial-Rickettsiales clade. The availability of ocean metagenome data substantially increases the sampling of Alphaproteobacteria inhabiting the oxygen-containing waters of the oceans that likely resemble the originating environment of mitochondria. METHODOLOGY/PRINCIPAL FINDINGS: We present a phylogenetic study of the origin of mitochondria that incorporates metagenome data from the Global Ocean Sampling (GOS) expedition. We identify mitochondrially related sequences in the GOS dataset that represent a rare group of Alphaproteobacteria, designated OMAC (Oceanic Mitochondria Affiliated Clade) as the closest free-living relatives to mitochondria in the oceans. In addition, our analyses reject the hypothesis that the mitochondrial system for aerobic respiration is affiliated with that of the SAR11 clade. CONCLUSIONS/SIGNIFICANCE: Our results allude to the existence of an alphaproteobacterial clade in the oxygen-rich surface waters of the oceans that represents the closest free-living relative to mitochondria identified thus far. In addition, our findings underscore the importance of expanding the taxonomic diversity in phylogenetic analyses beyond that represented by cultivated bacteria to study the origin of mitochondria

The Archaeal Roots of the Eukaryotic Dynamic Actin Cytoskeleton

It is generally well accepted that eukaryotes evolved from the symbiosis of an archaeal host cell and an alphaproteobacterium, a union that ultimately gave rise to the complex, eukaryotic cells we see today. However, the catalyst of this merger, the exact nature of the cellular biology of either partner, or how this event spawned the vast majority of complex life on Earth remains enigmatic. In recent years, the discovery of the Asgard archaea, the closest known prokaryotic relatives of eukaryotes, has been monumental for addressing these unanswered questions. These prokaryotes seem to encode an unprecedented number of genes related to features typically descriptive of eukaryotes, including intracellular trafficking, vesicular transport and a dynamic actin-based cytoskeleton. Collectively, these features imply that the Asgard archaea have the potential for cellular complexity previously thought to be unique to eukaryotes. Here, we review the most recent advances in our understanding of the archaeal cytoskeleton and its implications for determining the origin of eukaryotic cellular complexity. The transition from prokaryotic to eukaryotic cells represents a cornerstone event in the evolution of life on Earth. The actin cytoskeleton is one of many key features of eukaryotic cells. Here, Stairs and Ettema review the most recent advances in our understanding of the archaeal cytoskeleton and its implications for the origins of eukaryotes.</p

Archaea and the origin of eukaryotes

Woese and Fox's 1977 paper on the discovery of the Archaea triggered a revolution in the field of evolutionary biology by showing that life was divided into not only prokaryotes and eukaryotes. Rather, they revealed that prokaryotes comprise two distinct types of organisms, the Bacteria and the Archaea. In subsequent years, molecular phylogenetic analyses indicated that eukaryotes and the Archaea represent sister groups in the tree of life. During the genomic era, it became evident that eukaryotic cells possess a mixture of archaeal and bacterial features in addition to eukaryotic-specific features. Although it has been generally accepted for some time that mitochondria descend from endosymbiotic alphaproteobacteria, the precise evolutionary relationship between eukaryotes and archaea has continued to be a subject of debate. In this Review, we outline a brief history of the changing shape of the tree of life and examine how the recent discovery of a myriad of diverse archaeal lineages has changed our understanding of the evolutionary relationships between the three domains of life and the origin of eukaryotes. Furthermore, we revisit central questions regarding the process of eukaryogenesis and discuss what can currently be inferred about the evolutionary transition from the first to the last eukaryotic common ancestor.</p

Differential expression analysis of Spironucleus salmonicida in response to oxygen stress

Background: Spironucleus salmonicida is an anaerobic diplomonad parasite that can cause systemic infections in multiple species of fish including Atlantic salmon. Unlike other anaerobic or microaerophilic gut parasites, such as its close relative Giardia intestinalis, S. salmonicida is able to leave the animal gut via the blood stream eventually colonizing organs, skin and gills, although the precise life cycle and transmissive (i.e., cyst) form of this parasite has not been determined. How this presumed anaerobe can persist and invade oxygenated tissues despite having a strictly anaerobic metabolism remains elusive. Results: To investigate gene expression-level changes specifically related to oxygen stress and tolerance in S. salmoncida, we performed RNAseq transcriptomic analyses of cells grown in presence of oxygen or in media depleted of antioxidants. We found that over 20% of the transcriptome is differentially regulated in both oxygen (1705 genes) and antioxidant-depleted conditions (2280 genes). These differentially regulated transcripts encode proteins related to anaerobic metabolism, cysteine and Fe-S cluster biosynthesis, as well as, a large number of proteins of unknown function. S. salmoncida does not encode genes involved in the classical elements of oxygen-defense (e.g. catalases, superoxide dismutase, glutathione biosynthesis). Instead, we identified a vast repertoire of bacterial-like oxidoreductases likely acquired by lateral gene transfer (LGT) that are upregulated in response to oxygen and anti-oxidant depletion, suggesting that the acquisition of these proteins has been critical for oxygen adaptation of this parasite. Unexpectedly, we observed that many invasion-related genes were upregulated under oxidative stress suggesting that oxygen might be a signal for pathogenesis. Conclusion: These data provide the first molecular evidence for how S. salmonicida is able to and tolerate different oxygen tensions to ultimately colonize different host environments. While oxygen is toxic for other metamonad parasites, such as Giardia, we find that oxygen is actually an gene induction signal for many host invasion and evasion-related pathways

Giardia intestinalis Raw sequence reads

Raw sequence reads generated to benchmark different versions of a protocol for generation of cDNA from single protist cell

An efficient single-cell transcriptomics workflow for microbial eukaryotes benchmarked on Giardia intestinalis cells

Background Most diversity in the eukaryotic tree of life is represented by microbial eukaryotes, which is a polyphyletic group also referred to as protists. Among the protists, currently sequenced genomes and transcriptomes give a biased view of the actual diversity. This biased view is partly caused by the scientific community, which has prioritized certain microbes of biomedical and agricultural importance. Additionally, some protists remain difficult to maintain in cultures, which further influences what has been studied. It is now possible to bypass the time-consuming process of cultivation and directly analyze the gene content of single protist cells. Single-cell genomics was used in the first experiments where individual protists cells were genomically explored. Unfortunately, single-cell genomics for protists is often associated with low genome recovery and the assembly process can be complicated because of repetitive intergenic regions. Sequencing repetitive sequences can be avoided if single-cell transcriptomics is used, which only targets the part of the genome that is transcribed. Results In this study we test different modifications of Smart-seq2, a single-cell RNA sequencing protocol originally developed for mammalian cells, to establish a robust and more cost-efficient workflow for protists. The diplomonad Giardia intestinalis was used in all experiments and the available genome for this species allowed us to benchmark our results. We could observe increased transcript recovery when freeze-thaw cycles were added as an extra step to the Smart-seq2 protocol. Further we reduced the reaction volume and purified the amplified cDNA with alternative beads to test different cost-reducing changes of Smart-seq2. Neither improved the procedure, and reducing the volumes by half led to significantly fewer genes detected. We also added a 5′ biotin modification to our primers and reduced the concentration of oligo-dT, to potentially reduce generation of artifacts. Except adding freeze-thaw cycles and reducing the volume, no other modifications lead to a significant change in gene detection. Therefore, we suggest adding freeze-thaw cycles to Smart-seq2 when working with protists and further consider our other modification described to improve cost and time-efficiency. Conclusions The presented single-cell RNA sequencing workflow represents an efficient method to explore the diversity and cell biology of individual protist cells.Title in thesis list of papers: An efficient single-cell transcriptomics workflow to assess protist diversity and lifestyleDe två första författarna delar förstaförfattarskapetDe två sista författarna delar sistaförfattarskapet</p