The cytosolic aminotransferase VAS1 coordinates aromatic amino acid biosynthesis and metabolism.

The aromatic amino acids (AAAs) phenylalanine, tyrosine, and tryptophan are basic protein units and precursors of diverse specialized metabolites that are essential for plant growth. Despite their significance, the mechanisms that regulate AAA homeostasis remain elusive. Here, we identified a cytosolic aromatic aminotransferase, REVERSAL OF SAV3 PHENOTYPE 1 (VAS1), as a suppressor of arogenate dehydrogenase 2 (adh2) in Arabidopsis (Arabidopsis thaliana). Genetic and biochemical analyses determined that VAS1 uses AAAs as amino donors, leading to the formation of 3-carboxyphenylalanine and 3-carboxytyrosine. These pathways represent distinct routes for AAA metabolism that are unique to specific plant species. Furthermore, we show that VAS1 is responsible for cytosolic AAA biosynthesis, and its enzymatic activity can be inhibited by 3-carboxyphenylalanine. These findings provide valuable insights into the crucial role of VAS1 in producing 3-carboxy AAAs, notably via recycling of AAAs in the cytosol, which maintains AAA homeostasis and allows plants to effectively coordinate the complex metabolic and biosynthetic pathways of AAAs.

Rational design of GDP­D­mannose mannosyl hydrolase for microbial L­fucose production.

BACKGROUND: L­Fucose is a rare sugar that has beneficial biological activities, and its industrial production is mainly achieved with brown algae through acidic/enzymatic fucoidan hydrolysis and a cumbersome purification process. Fucoidan is synthesized through the condensation of a key substance, guanosine 5'­diphosphate (GDP)­L­fucose. Therefore, a more direct approach for biomanufacturing L­fucose could be the enzymatic degradation of GDP­L­fucose. However, no native enzyme is known to efficiently catalyze this reaction. Therefore, it would be a feasible solution to engineering an enzyme with similar function to hydrolyze GDP­L­fucose. RESULTS: Herein, we constructed a de novo L­fucose synthetic route in Bacillus subtilis by introducing heterologous GDP­L­fucose synthesis pathway and engineering GDP­mannose mannosyl hydrolase (WcaH). WcaH displays a high binding affinity but low catalytic activity for GDP­L­fucose, therefore, a substrate simulation­based structural analysis of the catalytic center was employed for the rational design and mutagenesis of selected positions on WcaH to enhance its GDP­L­fucose­splitting efficiency. Enzyme mutants were evaluated in vivo by inserting them into an artificial metabolic pathway that enabled B. subtilis to yield L­fucose. WcaHR36Y/N38R was found to produce 1.6 g/L L­fucose during shake­flask growth, which was 67.3% higher than that achieved by wild­type WcaH. The accumulated L­fucose concentration in a 5 L bioreactor reached 6.4 g/L. CONCLUSIONS: In this study, we established a novel microbial engineering platform for the fermentation production of L­fucose. Additionally, we found an efficient GDP­mannose mannosyl hydrolase mutant for L­fucose biosynthesis that directly hydrolyzes GDP­L­fucose. The engineered strain system established in this study is expected to provide new solutions for L­fucose or its high value­added derivatives production.

A widespread pathway for substitution of adenine by diaminopurine in phage genomes.

DNA modifications vary in form and function but generally do not alter Watson-Crick base pairing. Diaminopurine (Z) is an exception because it completely replaces adenine and forms three hydrogen bonds with thymine in cyanophage S-2L genomic DNA. However, the biosynthesis, prevalence, and importance of Z genomes remain unexplored. Here, we report a multienzyme system that supports Z-genome synthesis. We identified dozens of globally widespread phages harboring such enzymes, and we further verified the Z genome in one of these phages, Acinetobacter phage SH-Ab 15497, by using liquid chromatography with ultraviolet and mass spectrometry. The Z genome endows phages with evolutionary advantages for evading the attack of host restriction enzymes, and the characterization of its biosynthetic pathway enables Z-DNA production on a large scale for a diverse range of applications.

Programmable adenine deamination in bacteria using a Cas9-adenine-deaminase fusion.

Precise genetic manipulation is vital to studying bacterial physiology, but is difficult to achieve in some bacterial species due to the weak intrinsic homologous recombination (HR) capacity and lack of a compatible exogenous HR system. Here we report the establishment of a rapid and efficient method for directly converting adenine to guanine in bacterial genomes using the fusion of an adenine deaminase and a Cas9 nickase. The method achieves the conversion of adenine to guanine via an enzymatic deamination reaction and a subsequent DNA replication process rather than HR, which is utilized in conventional bacterial genetic manipulation methods, thereby substantially simplifying the genome editing process. A systematic screening targeting the possibly editable adenine sites of cntBC, the importer of the staphylopine/metal complex in Staphylococcus aureus, pinpoints key residues for metal importation, demonstrating that application of the system would greatly facilitate the genomic engineering of bacteria.

A Cost-Effective Method for Preparing Robust and Conductive Superhydrophobic Coatings Based on Asphalt.

The wide application of superhydrophobic materials is mainly hindered by the poor mechanical robustness and complicated preparation method. To overcome these problems, we tried to make a combination of hierarchical and self-similar structure by the means of a simple spraying method. By adding nanofiller (carbon nanotube) and microfiller (graphite powder and expanded graphite), the hierarchical structure was constructed. By further doping the fillers in the commercial asphalt uniformly, the self-similar structure was prepared. Based on the aforementioned work, the as-prepared sample could withstand the sandpaper abrasion for 12.00 m under 4.90 kPa. Moreover, this superhydrophobic coating demonstrated good conductivity, superior self-cleaning property, and excellent corrosion resistance. The integration of conductivity with the superhydrophobicity might open new avenues for ground grid applications.

Purification, characterization, and application of a high activity 3-ketosteroid-Δ1-dehydrogenase from Mycobacterium neoaurum DSM 1381.

Δ1-Dehydrogenation is one of the most important reactions for steroid drug modification. Numerous 3-ketosteroid-Δ1-dehydrogenases (KstDs) catalyzing this reaction were observed in various organisms. However, only a few have been characterized and used for substrate conversion. In this study, a promising enzyme (KstD2) from Mycobacterium neoaurum DSM 1381 was purified and characterized. Interestingly, KstD2 displayed a high activity on a range of substrates, including 17α-hydroxypregn-4-ene-3,20-dione (17α-OH-P); androsta-4,9(11)-diene-3,17-dione (NSC 44826); and 4-androstene-3,17-dione (AD). These reactions were performed under optimal conditions at 40 °C and pH 8.0. Noteworthy, both the activity and stability of the enzyme were sensitive to various metal ions. After optimizing the expression and biocatalyst conditions, up to 1586 U mg-1 intracellular KstD activity on AD could be produced. Furthermore, the associated conversion rate was 99% with 30 g L-1 AD after 8 h. On the other hand, we obtained 99%, 90%, and over 80% of conversion with 20 g L-1 NSC 44826; 10 g L-1 16,17α-epoxyprogesterone; and 20 g L-1 17α-OH-P or canrenone, respectively, after 24 h. Sequence homology and structural analyses indicated that the residue R178 located in a unique short loop among cluster 2 is crucial for substrate recognition which was confirmed by mutagenesis. In summary, this study reports on the first purification and characterization of a KstD from cluster 2. Its remarkable properties deserve more attention to potentially lead to further industrial applications.

Dynamic changes in peripheral blood-targeted miRNA expression profiles in patients with severe traumatic brain injury at high altitude.

BACKGROUND: The aim of this work is to detect and compare the peripheral blood miRNA expression profiles in patients with severe traumatic brain injury (sTBI) 2, 12, 24, 48, and 72 h after injury at high altitude and to predict the target genes of differential expressed miRNAs. METHODS: Twenty sTBI patients from high-altitude areas were randomly selected according to the inclusion and exclusion criteria and were divided into five groups: the 2-h group, 12-h group, 24-h group, 48-h group, and 72-h group. Peripheral blood miRNA expression profiles were detected using real-time quantitative PCR (qRT-PCR). RESULTS: The expression levels of miR-18a, miR-203, miR-146a, miR-149, miR-23b, and miR-let-7b in peripheral blood showed significant differences between the 2-h group and the 12-h group. The expression levels of miR-203, miR-146a, miR-149, miR-23b, and miR-let-7f in peripheral blood were up-regulated in the 24-h group. In the 48-h group, the expression levels of miR-181d, miR-29a, and miR-18b were upregulated. In the 72-h group, the expression levels of miR-203, miR-146a, miR-149, miR-23b, and miR-let-7f changed. The main target genes of the differentiation expressed miRNAs were genes that regulate inflammatory responses, apoptosis, and DNA damage/repair. CONCLUSIONS: miRNAs may be involved in the pathogenesis of sTBI by dynamically regulating the target genes that regulate inflammatory responses, apoptosis, and DNA damage/repair pathways.