Stabilization of FtsH-unfolded protein complex by binding of ATP and blocking of protease

A simple and ultra-low cost homemade seamless ligation cloning extract (SLiCE) as an alternative to a commercially available seamless DNA cloning kit

The seamless ligation cloning extract (SLiCE) method is a novel seamless DNA cloning tool that utilizes homologous recombination activities in Escherichia coli cell lysates to assemble DNA fragments into a vector. Several laboratory E. coli strains can be used as a source for the SLiCE extract; therefore, the SLiCE-method is highly cost-effective.The SLiCE has sufficient cloning ability to support conventional DNA cloning, and can simultaneously incorporate two unpurified DNA fragments into vector. Recently, many seamless DNA cloning kits have become commercially available; these are generally very convenient, but expensive. In this study, we evaluated the cloning efficiencies between a simple and highly cost-effective SLiCE-method and a commercial kit under various molar ratios of insert DNA fragments to vector DNA. This assessment identified that the SLiCE from a laboratory E. coli strain yielded 30−85% of the colony formation rate of a commercially available seamless DNA cloning kit. The cloning efficiencies of both methods were highly effective, exhibiting over 80% success rate under all conditions examined. These results suggest that SLiCE from a laboratory E. coli strain can efficiently function as an effective alternative to commercially available seamless DNA cloning kits.

Evaluation of seamless ligation cloning extract preparation methods from an Escherichia coli laboratory strain

Seamless ligation cloning extract (SLiCE) is a simple and efficient method for DNA cloning without the use of restriction enzymes. Instead, SLiCE uses homologous recombination activities from Escherichia coli cell lysates. To date, SLiCE preparation has been performed using an expensive commercially available lytic reagent. To expand the utility of the SLiCE method, we evaluated different methods for SLiCE preparation that avoid using this reagent. Consequently, cell extracts prepared with buffers containing Triton X-100, which is a common and low-cost nonionic detergent, exhibited sufficient cloning activity for seamless gene incorporation into a vector.

A simple and efficient seamless DNA cloning method using SLiCE from Escherichia coli laboratory strains and its application to SLiP site-directed mutagenesis

Background

Seamless ligation cloning extract (SLiCE) is a simple and efficient method for DNA assembly that uses cell extracts from the Escherichia coli PPY strain, which expresses the components of the λ prophage Red/ET recombination system. This method facilitates restriction endonuclease cleavage site-free DNA cloning by performing recombination between short stretches of homologous DNA (≥15 base pairs).

Results

To extend the versatility of this system, I examined whether, in addition to bacterial extracts from the PPY strain, other E. coli laboratory strains were suitable for the SLiCE protocol. Indeed, carefully prepared cell extracts from several strains exhibited sufficient cloning activity for seamless gene incorporation into vectors with short homology lengths (approximately 15–20 bp). Furthermore, SLiCE was applied to the polymerase chain reaction (PCR)-based site-directed mutagenesis method, in a process termed “SLiCE-mediated PCR-based site-directed mutagenesis (SLiP site-directed mutagenesis)”. SLiP site-directed mutagenesis simplifies the steps of PCR-based site-directed mutagenesis, as it exploits the capability of the SLiCE method to insert multiple fragments.

Conclusions

SLiCE can be performed in the laboratory with no requirement for a special E. coli strain, and the technique is easily established. This method increases the cloning efficiency, shortens the time for DNA manipulation, and greatly reduces the cost of seamless DNA cloning.

Electronic supplementary material

The online version of this article (doi:10.1186/s12896-015-0162-8) contains supplementary material, which is available to authorized users.

The C-terminal α-helix of SPAS-1, a Caenorhabditis elegans spastin homologue, is crucial for microtubule severing

Spastin belongs to the meiotic subfamily, together with Vps4/SKD1, fidgetin and katanin, of AAA (ATPases associated with diverse cellular activities) proteins, and functions in microtubule severing. Interestingly, all members of this subgroup specifically contain an additional α-helix at the very C-terminal end. To understand the function of the C-terminal α-helix, we characterised its deletion mutants of SPAS-1, a Caenorhabditis elegans spastin homologue, in vitro and in vivo. We found that the C-terminal α-helix plays essential roles in ATP binding, ATP hydrolysing and microtubule severing activities. It is likely that the C-terminal α-helix is required for cellular functions of members of meiotic subgroup of AAA proteins, since the C-terminal α-helix of Vps4 is also important for assembly, ATPase activity and in vivo function mediated by ESCRT-III complexes.

Structure of the whole cytosolic region of ATP-dependent protease FtsH

An ATP-dependent protease, FtsH, digests misassembled membrane proteins in order to maintain membrane integrity and digests short-lived soluble proteins in order to control their cellular regulation. This enzyme has an N-terminal transmembrane segment and a C-terminal cytosolic region consisting of an AAA+ ATPase domain and a protease domain. Here we present two crystal structures: the protease domain and the whole cytosolic region. The cytosolic region fully retains an ATP-dependent protease activity and adopts a three-fold-symmetric hexameric structure. The protease domains displayed a six-fold symmetry, while the AAA+ domains, each containing ADP, alternate two orientations relative to the protease domain, making "open" and "closed" interdomain contacts. Apparently, ATPase is active only in the closed form, and protease operates in the open form. The protease catalytic sites are accessible only through a tunnel following from the AAA+ domain of the adjacent subunit, raising a possibility of translocation of polypeptide substrate to the protease sites through this tunnel.

CELLULAR FUNCTIONS, MECHANISM OF ACTION, AND REGULATION OF FTSH PROTEASE

FtsH is a cytoplasmic membrane protein that has N-terminally located transmembrane segments and a main cytosolic region consisting of AAA-ATPase and Zn2+-metalloprotease domains. It forms a homo-hexamer, which is further complexed with an oligomer of the membrane-bound modulating factor HflKC. FtsH degrades a set of short-lived proteins, enabling cellular regulation at the level of protein stability. FtsH also degrades some misassembled membrane proteins, contributing to their quality maintenance. It is an energy-utilizing and processive endopeptidase with a special ability to dislocate membrane protein substrates out of the membrane, for which its own membrane-embedded nature is essential. We discuss structure-function relationships of this intriguing enzyme, including the way it recognizes the soluble and membrane-integrated substrates differentially, on the basis of the solved structure of the ATPase domain as well as extensive biochemical and genetic information accumulated in the past decade on this enzyme.

Conserved pore residues in the AAA protease FtsH are important for proteolysis and its coupling to ATP hydrolysis

Like other AAA proteins, Escherichia coli FtsH, a membrane-bound AAA protease, contains highly conserved aromatic and glycine residues (Phe228 and Gly230) that are predicted to lie in the central pore region of the hexamer. The functions of Phe228 and Gly230 were probed by site-directed mutagenesis. The results of both in vivo and in vitro assays indicate that these conserved pore residues are important for FtsH function and that bulkier, uncharged/apolar residues are essential at position 228. None of the point mutants, F228A, F228E, F228K, or G230A, was able to degrade sigma32, a physiological substrate. The F228A mutant was able to degrade casein, an unfolded substrate, although the other three mutants were not. Mutation of these two pore residues also affected the ATPase activity of FtsH. The F228K and G230A mutations markedly reduced ATPase activity, whereas the F228A mutation caused a more modest decrease in this activity. The F228E mutant was actually more active ATPase. The substrates, sigma32 and casein, stimulated the ATPase activity of wild type FtsH. The ATPase activity of the mutants was no longer stimulated by casein, whereas that of the three Phe228 mutants, but not the G230A mutant, remained sigma32-stimulatable. These results suggest that Phe228 and Gly230 in the predicted pore region of the FtsH hexamer have important roles in proteolysis and its coupling to ATP hydrolysis.