Clustered regularly interspaced short palindromic repeats (CRISPR)-Cas adaptive immune defense systems, which are widely distributed in bacteria and Archaea, can provide sequence-specific protection against foreign DNA or RNA in some cases. However, the evolution of defense systems in bacterial hosts did not lead to the elimination of phages, and some phages carry anti-CRISPR genes that encode products that bind to the components mediating the defense mechanism and thus antagonize CRISPR-Cas immune systems of bacteria. Given the extensive application of CRISPR-Cas9 technologies in gene editing, in this review, we focus on the anti-CRISPR proteins (Acrs) that inhibit CRISPR-Cas systems for gene editing. We describe the discovery of Acrs in immune systems involving type I, II, and V CRISPR-Cas immunity, discuss the potential function of Acrs in inactivating type II and V CRISPR-Cas systems for gene editing and gene modulation, and provide an outlook on the development of important biotechnology tools for genetic engineering using Acrs.

Rationale Cell-free transcription-translation (TXTL) is becoming a popular technology to prototype and engineer biological systems outside living organisms. TXTL relies commonly to a cytoplasmic extract that provides the molecular components necessary to recapitulate gene expression in vitro, where most of the available systems are derived from E. coli. The proteinic and enzymatic composition of lysates, however, is typically unknown. In this work, we analyzed by mass spectrometry the molecular constituents of the all-E. coli TXTL platform myTXTL prepared from the E. coli strain BL21 Rosetta2. Methods Standard TXTL reactions were assembled and executed for 10-12 hours at 29°C. In addition to a no-DNA control, four DNA programs were executed in separate reactions to synthesize the reporter protein deGFP as well as the phages MS2, phix174 and T7. The reactions were treated according to standard procedures (trypsin treatment, cleaning) before performing liquid chromatography-mass spectrometry (LC-MS). Data analysis was performed using Sequest and protein identification using Scaffold. Results 500-800 proteins were identified by LC-MS in the blank reactions. We organized the most abundant protein sets into several categories pertaining, in particular, to transcription, translation and ATP regeneration. The synthesis of deGFP was easily measured. The major structural proteins that compose the three phages MS2, phix174 and T7 were also identified. Conclusions Mass spectrometry is a practical tool to characterize biochemical solutions as complex as a cell-free TXTL reaction and to determine the presence of synthesized proteins. The data presented demonstrate that the composition of TXTL based on lysates can be used to validate some underlying molecular mechanisms implicated in cell-free protein synthesis. The composition of the lysate shows significant differences with respect to similar studies on other E. coli strains.

Cell-free transcription-translation (TXTL) has recently emerged as a versatile technology to engineer biological systems. In this chapter, we show how an all E. coli TXTL system can be used to build synthetic cell prototypes. We describe methods to encapsulate TXTL reactions in cell-sized liposomes, with an emphasis on the composition of the external solution and lipid bilayer. Cell-free expression is quantitatively described in bulk reactions and liposomes for three proteins: the soluble reporter protein eGFP, the membrane proteins alpha-hemolysin (AH) from Staphylococcus aureus, and the mechanosensitive channel of large conductance (MscL) from E. coli.