Simplified adenine base editors improve adenine base editing efficiency in rice

Adenine base editors (ABEs) have been exploited to introduce targeted adenine (A) to guanine (G) base conversions in various plant genomes, including rice, wheat and Arabidopsis. However, the ABEs reported thus far are all quite inefficient at many target sites in rice, which hampers their applications in plant genome engineering and crop breeding. Here, we show that unlike in the mammalian system, a simplified base editor ABE‐P1S (Adenine Base Editor‐Plant version 1 Simplified) containing the ecTadA*7.10‐nSpCas9 (D10A) fusion has much higher editing efficiency in rice compared to the widely used ABE‐P1 consisting of the ecTadA‐ecTadA*7.10‐nSpCas9 (D10A) fusion. We found that the protein expression level of ABE‐P1S is higher than that of ABE‐P1 in rice calli and protoplasts, which may explain the higher editing efficiency of ABE‐P1S in different rice varieties. Moreover, we demonstrate that the ecTadA*7.10‐nCas9 fusion can be used to improve the editing efficiency of other ABEs containing SaCas9 or the engineered SaKKH‐Cas9 variant. These more efficient ABEs will help advance trait improvements in rice and other crops.     

Unusual sensitivity of Escherichia coli to adenine or adenine plus histidine.

The W3110 strain of Escherichia coli K-12 is unusually sensitive to adenine. Inhibition of growth is relieved by a combination of thiamine and uridine (or cytidine). In the presence of histidine, inhibition is more severe and is relieved by a combination of thiamine, glycine, uridine (or cytidine), and inosine (or guanosine).     

Hydrolytic cleavage of N6-substituted adenine derivatives by eukaryotic adenine and adenosine deaminases

Homogeneous adenine deaminases (EC 3.5.4.2) from the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe and a putative ADA (adenosine deaminase; EC 3.5.4.4) from Arabidopsis thaliana were obtained for the first time as purified recombinant proteins by molecular cloning of the corresponding genes and their overexpression in Escherichia coli. The enzymes showed comparable molecular properties with well-known mammalian ADAs, but exhibited much lower k(cat) values. Adenine was the most favoured substrate for the yeast enzymes, whereas the plant enzyme showed only very low activities with either adenine, adenosine, AMP or ATP. Interestingly, the yeast enzymes also hydrolysed N6-substituted adenines from cytokinins, a group of plant hormones, cleaving them to inosine and the corresponding side chain amine. The hydrolytic cleavage of synthetic cytokinin 2,6-di-substituted analogues that are used in cancer therapy, such as olomoucine, roscovitine and bohemine, was subsequently shown for a reference sample of human ADA1. ADA1, however, showed a different reaction mechanism to that of the yeast enzymes, hydrolysing the compounds to an adenine derivative and a side chain alcohol. The reaction products were identified using reference compounds on HPLC coupled to UV and Q-TOF (quadrupole-time-of-flight) detectors.The ADA1 activity may constitute the debenzylation metabolic route already described for bohemine and, as a consequence, it may compromise the physiological or therapeutic effects of exogenously applied cytokinin derivatives.     

Novel non-specific DNA adenine methyltransferases

The mom gene of bacteriophage Mu encodes an enzyme that converts adenine to N(6)-(1-acetamido)-adenine in the phage DNA and thereby protects the viral genome from cleavage by a wide variety of restriction endonucleases. Mu-like prophage sequences present in Haemophilus influenzae Rd (FluMu), Neisseria meningitidis type A strain Z2491 (Pnme1) and H. influenzae biotype aegyptius ATCC 11116 do not possess a Mom-encoding gene. Instead, at the position occupied by mom in Mu they carry an unrelated gene that encodes a protein with homology to DNA adenine N(6)-methyltransferases (hin1523, nma1821, hia5, respectively). Products of the hin1523, hia5 and nma1821 genes modify adenine residues to N(6)-methyladenine, both in vitro and in vivo. All of these enzymes catalyzed extensive DNA methylation; most notably the Hia5 protein caused the methylation of 61% of the adenines in λ DNA. Kinetic analysis of oligonucleotide methylation suggests that all adenine residues in DNA, with the possible exception of poly(A)-tracts, constitute substrates for the Hia5 and Hin1523 enzymes. Their potential 'sequence specificity' could be summarized as AB or BA (where B = C, G or T). Plasmid DNA isolated from Escherichia coli cells overexpressing these novel DNA methyltransferases was resistant to cleavage by many restriction enzymes sensitive to adenine methylation.     

Spectral characterization of a fluorescent nicotinamide adenine dinucleotide analog: 3-Aminopyridine adenine dinucleotide

Both absorption and fluorescence properties of 3-amino pyridine adenine dinucleotide (AAD) were examined. The shape of the AAD fluorescence emission spectrum, maximal at 425 nm, remains unchanged over the pH range 2 to 11, indicating that there is only one detectable emitting species. AAD fluorescence increases as the pH decreases, with an apparent pK_a of about 3.5. The absorption-pH profile indicates a pK_a of about 3.3 for the ground state of AAD. Effects of organic solvents on AAD fluorescence are somewhat diverse. The low fluorescence quantum yield of 0.022 corresponds well with the short lifetime of 1.15 ns at 23 °C in neutral aqueous solution. The steady-state polarization of AAD in water and that at infinite viscosity were determined at 23 °C to be 0.037 and 0.083, respectively. Since a smaller value of polarization for either donor or acceptor leads to a better estimate of the orientation factor for dipole-dipole interaction, AAD appears to be particularly suitable for energy transfer studies. Similar to NADH, AAD also assumes a folded conformation in aqueous solution. This is evident from effects of temperature and hydrolysis by phosphodiesterase on absorption and/or fluorescence properties of AAD. Energy transfer from the adenine group to the 3-aminopyridine ring has been detected to occur in aqueous solution at 23 °C with an efficiency of about 0.12, corresponding to a distance of 7.5 Å between these two ring moieties.