PlasmidMaker: a Versatile, Automated, and High Throughput End-to-End Platform for Plasmid Construction

Plasmids are used extensively in basic and applied biology. However, design and construction of plasmids, specifically the ones carrying complex genetic information, remains one of the most time-consuming, labor-intensive, and rate-limiting steps in performing sophisticated biological experiments. Here, we report the development of a versatile, robust, automated end-to-end platform named PlasmidMaker that allows error-free construction of plasmids with virtually any sequences in a high-throughput manner. This platform consists of a most versatile DNA assembly method using Pyrococcus furiosus Argonaute (PfAgo)-based artificial restriction enzymes, a user-friendly frontend for plasmid design, and a backend that streamlines the workflow and integration with a robotic system. As a proof of concept, we used this platform to generate 101 plasmids from six different species ranging from 5 to 18 kb in size from up to 11 DNA fragments within 3 days. PlasmidMaker should greatly expand the potential of synthetic biology.

Membrane adaptation in the hyperthermophilic archaeon Pyrococcus furiosus relies upon a novel strategy involving glycerol monoalkyl glycerol tetraether lipids

Microbes preserve membrane functionality under fluctuating environmental conditions by modulating their membrane lipid composition. Although several studies have documented membrane adaptations in Archaea, the influence of most biotic and abiotic factors on archaeal lipid compositions remains underexplored. Here, we studied the influence of temperature, pH, salinity, the presence/absence of elemental sulfur, the carbon source, and the genetic background on the core lipid composition of the hyperthermophilic neutrophilic marine archaeon Pyrococcus furiosus. Every growth parameter tested affected the core lipid composition to some extent, the carbon source and the genetic background having the greatest influence. Surprisingly, P. furiosus appeared to only marginally rely on the two major responses implemented by Archaea, i.e., the regulation of the ratio of diether to tetraether lipids and that of the number of cyclopentane rings in tetraethers. Instead, this species increased the ratio of glycerol monoalkyl glycerol tetraethers (GMGT, aka. H-shaped tetraethers) to glycerol dialkyl glycerol tetrathers (GDGT) in response to decreasing temperature and pH and increasing salinity, thus providing for the first time evidence of adaptive functions for GMGT. Besides P. furiosus, numerous other species synthesize significant proportions of GMGT, which suggests that this unprecedented adaptive strategy might be common in Archaea.

Recombinant protein expression and purification of codon-optimized Pfu-Sso7d v2

This protocol has been optimized for the recombinant expression of a codon-optizimed Pfu-Sso7d DNA polymerase. This is a fusion protein composed of the Pfu enzyme from Pyrococcus furiosus for DNA amplification by PCR fused to a small 7 kDa protein from Sulfobulus solfataricus that binds to double-stranded DNA without any preference for specific sequences, thus enhancing polymerization processivity without affecting the catalytic activity or thermal stability of the enzyme. The goal of this protocol was to eliminate the use of large volumes for dyalisis and potential issues with the protein crashing out of the solution due to the use of concentrators for buffer exchange of this enzyme into storage conditions. We also eliminated the use of DTT, which is often found in other similar protocols. The sequence plasmid encoding the codon-optimized Pfu-Sso7d enzyme used here can be found at https://benchling.com/s/seq-2TcUPjO2uMbDG5ufTQN4

Identification and Deletion of The Genes Responsible for Hydrogen Production in Thermoanaerobacter Ethanolicus JW200

Background Thermoanaerobacter ethanolicus produces a considerable amount of ethanol from a range of carbohydrates and is an attractive candidate for applications in bioconversion processes. Due to the coupling of hydrogenase activity with fermentation product distribution, understanding hydrogen production of T. ethanolicus, particularly the genes responsible, is valuable for metabolic engineering of the species. Results Utilizing the hydrogenases reported in Thermoanaerobacterium saccharolyticum and Pyrococcus furiosus as templates, BLAST search identified five hydrogenase gene clusters, including two membrane-bound [NiFe] hydrogenases ech and mbh, two cytoplasmic [FeFe] hydrogenases hyd and hydII, and one cytoplasmic [NiFe] hydrogenase shi. The combined deletion of ech, mbh, shi and hydG resulted in a strain that did not produce hydrogen and showed no methyl viologen hydrogenase activity in cell extracts. Strains with deletions of all the hydrogenases except one showed normal hydrogen production. Methyl viologen hydrogenase activity was greatly reduced in all combined deletion strains except the strain with an intact hydG gene. Conclusion High hydrogen production and hydrogenase activities have been observed for T. ethanolicus. Five hydrogenases have been identified. Hydrogen production was eliminated by deleting genes required for all five hydrogenases. Each individual hydrogenase was verified to be capable of producing hydrogen during fermentation, indicating a high degree of redundancy and flexibility in the hydrogenase systems of T. ethanolicus. A large portion of hydrogenase activity is encoded by the [Fe-Fe] hydrogenases.

Distinct regions of the Haloferax volcanii dolichol phosphate-mannose synthase AglD mediate the assembly and subsequent processing of the lipid-linked mannose

Haloferax volcanii AglD is currently the only archaeal dolichol phosphate (DolP)-mannose synthase shown to participate in N-glycosylation. However, the relation between AglD and Pyrococcus furiosus PF0058, the only archaeal DolP-mannose synthase for which structural information is presently available, was unclear. In this report, similarities between the PF0058 and AglD catalytic domains were revealed. At the same time, AglD includes a transmembrane domain far longer than that of PF0058 or other DolP-mannose synthases. To determine whether this extension affords AglD functions in addition to generating mannose-charged DolP, a series of Hfx. volcanii strains expressing truncated versions of AglD was generated. Mass spectrometry revealed that a version of AglD comprising the catalytic domain and only two of the six to nine predicted membrane-spanning domains could mediate mannose addition to DolP. However, in cells expressing this or other truncated versions of AglD, mannose was not transferred from the lipid to the protein-bound tetrasaccharide precursor of the N-linked pentasaccharide normally decorating Hfx. volcanii glycoproteins. These results thus point to AglD as contributing to additional aspects of Hfx. volcanii N-glycosylation beyond charging DolP with mannose. Accordingly, the possibility that AglD, possibly in coordination with AglR, translocates DolP-mannose across the plasma membrane is discussed. Layman summary In the archaea Haloferax volcanii , the dolichol phosphate (DolP)-mannose synthase AglD charges the lipid DolP with mannose, which is delivered to a protein-bound tetrasaccharide to generate the pentasaccharide decorating glycoproteins in this organism. Structural studies demonstrated the similarity of AglD to Pyrococcus furiosus PF0058, the only archaeal DolP-mannose synthase with a solved 3D structure. Truncated AglD containing the catalytic domain and only two of the predicted six to nine membrane-spanning regions catalyzed mannose-charging of DolP. Yet, no mannose was delivered to protein-linked tetrasaccharide in cells expressing AglD mutants including only up to five membrane-spanning regions, pointing to a role for the extended C-terminal region in a subsequent step of Hfx. volcanii N-glycosylation, such as DolP-mannose translocation across the plasma membrane.

pH Homeostasis and Sodium Ion Pumping by Multiple Resistance and pH Antiporters in Pyrococcus furiosus

Multiple Resistance and pH (Mrp) antiporters are seven-subunit complexes that couple transport of ions across the membrane in response to a proton motive force (PMF) and have various physiological roles, including sodium ion sensing and pH homeostasis. The hyperthermophilic archaeon Pyrococcus furiosus contains three copies of Mrp encoding genes in its genome. Two are found as integral components of two respiratory complexes, membrane bound hydrogenase (MBH) and the membrane bound sulfane sulfur reductase (MBS) that couple redox activity to sodium translocation, while the third copy is a stand-alone Mrp. Sequence alignments show that this Mrp does not contain an energy-input (PMF) module but contains all other predicted functional Mrp domains. The P. furiosus Mrp deletion strain exhibits no significant changes in optimal pH or sodium ion concentration for growth but is more sensitive to medium acidification during growth. Cell suspension hydrogen gas production assays using the deletion strain show that this Mrp uses sodium as the coupling ion. Mrp likely maintains cytoplasmic pH by exchanging protons inside the cell for extracellular sodium ions. Deletion of the MBH sodium-translocating module demonstrates that hydrogen gas production is uncoupled from ion pumping and provides insights into the evolution of this Mrp-containing respiratory complex.

Evolution and origin of sliding clamp in bacteria, archaea and eukarya

The replication of DNA is an essential process in all domains of life. A protein often involved in replication is the sliding clamp. The sliding clamp encircles the DNA and helps replicative polymerase stay attached to the replication machinery increasing the processivity of the polymerase. In eukaryotes and archaea, the sliding clamp is called the Proliferating Cell Nuclear Antigen (PCNA) and consists of two domains. This PCNA forms a trimer encircling the DNA as a hexamer. In bacteria, the structure of the sliding clamp is highly conserved, but the protein itself, called beta clamp, contains three domains, which dimerize to form a hexamer. The bulk of literature touts a conservation of the structure of the sliding clamp, but fails to recognize the conservation of protein sequence among sliding clamps. In this paper, we have used PSI blast to the second iteration in NCBI to show a statistically significant sequence homology between Pyrococcus furiosus PCNA and Kallipyga gabonensis beta clamp. The last two domains of beta clamp align with the two domains of PCNA. This homology data demonstrates that PCNA and beta clamp arose from a common ancestor. In this paper, we have further used beta clamp and PCNA sequences from diverse bacteria, archaea and eukarya to build maximum likelihood phylogenetic tree. Most, but not all, species in different domains of life harbor one sliding clamp from vertical inheritance. Some of these species that have two or more sliding clamps have acquired them from gene duplication or horizontal gene transfer events.