微生物学

The target of rapamycin complex 1 (TORC1) is a highly conserved protein complex whose primary function is to link nutrient availability to cell growth in eukaryotes, particularly nitrogen sources. It was originally identified during the screening of Saccharomyces cerevisiae strains resistant to rapamycin treatment. For its part, S. cerevisiae is well known for being a key model organism in biological research and an essential microorganism for the fermentation of food and beverages. This yeast is widely distributed in nature, with domesticated and wild strains existing. However, little is known about what effects domestication has had on its different phenotypes; for example, how nitrogen sources are sensed for TORC1 activation and what impact domestication has had on TORC1 activation are questions that still have no complete answer. To study the genetic basis of TORC1 activation associated with domestication through approaches such as quantitative trait loci (QTL) mapping or genome-wide association studies (GWAS), and more generally for any study requiring TORC1 activity as a readout for a large number of individuals, it is necessary to have a high-throughput methodology that allows monitoring the activation of this pathway in numerous yeast strains. In this context, the present protocol was designed to assess phenotypical differences in TORC1 activation using a new reporter plasmid, the pTOMAN-G plasmid, specifically designed to monitor TORC1 activation. As a proof of concept, this methodology allowed phenotyping a large population of yeast strains derived from the 1002 Yeast Genomes Project, the most complete catalog of genetic variation in yeasts. This protocol proved to be an efficient alternative to assess TORC1 pathway activation compared to techniques based on immunoblot detection, which, although effective, are considerably more laborious. Briefly, the protocol involves the design and construction of the pTOMAN-G plasmid, which carries a construct containing the firefly luciferase gene (Luc) under the control of the TORC1-regulated RPL26A gene promoter (P_RPL26A). The protocol then details the process for selecting subgroups of yeasts based on their ability to grow under nutrient-limited conditions, using proline as the sole nitrogen source. These yeasts are then transformed with the TOMAN-G plasmid, using two alternative transformation methods. Finally, those yeasts that emit luminescence are selected, whose phenotype for TORC1 activation is measured by a nitrogen-upshift experiment in microculture. This approach, using the pTOMAN-G plasmid, offers a rapid and consistent method for assessing TORC1 signaling pathway activation in a large number of yeast strains, highlighting its usefulness to study the activation of the TORC1 pathway and the domestication process associated with it. In the future, a redesign of the plasmid could extend its use as a reporter tool to monitor the activation of the TORC1 pathway, or other pathways, in other yeast species.

The Auxin-inducible degron (AID) system is a genetic tool that induces rapid target protein depletion in an auxin-dependent manner. Recently, two advanced AID systems—the super-sensitive AID and AID 2—were developed using an improved pair of synthetic auxins and mutated TIR1 proteins. In these AID systems, a nanomolar concentration of synthetic auxins is sufficient as a degradation inducer for target proteins. However, despite these advancements, AID systems still require the fusion of an AID tag to the target protein for degradation, potentially affecting its function and stability. To address this limitation, we developed an affinity linker–based super-sensitive AID (AlissAID) system using a single peptide antibody known as a nanobody. In this system, the degradation of GFP- or mCherry-tagged target proteins is induced in a synthetic auxin (5-Ad-IAA)–dependent manner. Here, we introduce a simple method for generating AlissAID strains targeting GFP or mCherry fusion proteins in budding yeasts.

The fission yeast Schizosaccharomyces pombe is an excellent genetically tractable model organism used in the study of conserved eukaryotic cellular biology. One genetic tool in the assessment of gene function is the in vivo overexpression of proteins. Existing overexpression tools have limitations of induction kinetics, dynamic range, and/or system-wide changes due to the induction conditions or inducer. Here, I describe the methodology for the use of a plasmid-based long non-coding RNA (lncRNA)-regulated overexpression system that is induced by the addition of thiamine. This system, termed the pTIN-system (thiamine inducible), utilizes the fast repression kinetics of the thiamine-regulated nmt1⁺ promoter integrated with the lncRNA regulated tgp1⁺ promoter. The advantages of the pTIN-system are rapid induction kinetics of gene expression, broad dynamic range, and tunable expression.

Roseburia and Eubacterium species of the human gut microbiota play an important role in the maintaince of human health, partly by producing butyrate, the main energy source of our colonic epithelial cells. However, our knowledge of the biochemistry and physiology of these bacteria has been limited by a lack of genetic manipulation techniques. Conjugative transposons previously introduced into Roseburia species could not be easily modified, greatly limiting their applicability as genetic modification platforms. Modular plasmid shuttle vectors have previously been developed for Clostridium species, which share a taxonomic order with Roseburia and Eubacterium, raising the possibility that these vectors could be used in these organisms. Here, we describe an optimized conjugation protocol enabling the transfer of autonomously replicating plasmids from an E. coli donor strain into Roseburia inulinivorans and Eubacterium rectale. The modular nature of the plasmids and their ability to be maintained in the recipient bacterium by autonomous replication makes them ideal for investigating heterologous gene expression, and as a platform for other genetic tools including antisense RNA silencing or mobile group II interon gene disruption strategies.

Plasmid stability can be measured using antibiotic-resistance plasmid derivatives by positive selection. However, highly stable plasmids are below the sensitivity range of these assays. To solve this problem we describe a novel, highly sensitive method to measure plasmid stability based on the selection of plasmid-free cells following elimination of plasmid-containing cells. The assay proposed here is based on an aph-parE cassette. When synthesized in the cell, the ParE toxin induces cell death. ParE synthesis is controlled by a rhamnose-inducible promoter. When bacteria carrying the aph-parE module are grown in media containing rhamnose as the only carbon source, ParE is synthesized and plasmid-containing cells are eliminated. Kanamycin resistance (aph) is further used to confirm the absence of the plasmid in rhamnose grown bacteria.