Designing a highly efficient type III polyketide whole-cell catalyst with minimized byproduct formation.

BACKGROUND: Polyketide synthases (PKSs) are classified into three types based on their enzyme structures. Among them, type III PKSs, catalyzing the iterative condensation of malonyl-coenzyme A (CoA) with a CoA-linked starter molecule, are important synthases of valuable natural products. However, low efficiency and byproducts formation often limit their applications in recombinant overproduction. RESULTS: Herein, a rapid growth selection system is designed based on the accumulation and derepression of toxic acyl-CoA starter molecule intermediate products, which could be potentially applicable to most type III polyketides biosynthesis. This approach is validated by engineering both chalcone synthases (CHS) and host cell genome, to improve naringenin productions in Escherichia coli. From directed evolution of key enzyme CHS, beneficial mutant with ~ threefold improvement in capability of naringenin biosynthesis was selected and characterized. From directed genome evolution, effect of thioesterases on CHS catalysis is first discovered, expanding our understanding of byproduct formation mechanism in type III PKSs. Taken together, a whole-cell catalyst producing 1082 mg L-1 naringenin in flask with E value (evaluating product specificity) improved from 50.1% to 96.7% is obtained. CONCLUSIONS: The growth selection system has greatly contributed to both enhanced activity and discovery of byproduct formation mechanism in CHS. This research provides new insights in the catalytic mechanisms of CHS and sheds light on engineering highly efficient heterologous bio-factories to produce naringenin, and potentially more high-value type III polyketides, with minimized byproducts formation.

Ultrasensitive detection of aggregated α-synuclein using quiescent seed amplification assay for the diagnosis of Parkinson's disease.

BACKGROUND: Seed amplification assays (SAA) enable the amplification of pathological misfolded proteins, including α-synuclein (αSyn), in both tissue homogenates and body fluids of Parkinson's disease (PD) patients. SAA involves repeated cycles of shaking or sonication coupled with incubation periods. However, this amplification scheme has limitations in tracking protein propagation due to repeated fragmentation. METHODS: We introduced a modified form of SAA, known as Quiescent SAA (QSAA), and evaluated biopsy and autopsy samples from individuals clinically diagnosed with PD and those without synucleinopathies (control group). Brain biopsy samples were obtained from 14 PD patients and 6 controls without synucleinopathies. Additionally, skin samples were collected from 214 PD patients and 208 control subjects. Data were analyzed from April 2019 to May 2023. RESULTS: QSAA successfully amplified αSyn aggregates in brain tissue sections from mice inoculated with pre-formed fibrils. In the skin samples from 214 PD cases and 208 non-PD cases, QSAA demonstrated high sensitivity (90.2%) and specificity (91.4%) in differentiating between PD and non-PD cases. Notably, more αSyn aggregates were detected by QSAA compared to immunofluorescence with the pS129-αSyn antibody in consecutive slices of both brain and skin samples. CONCLUSION: We introduced the new QSAA method tailored for in situ amplification of αSyn aggregates in brain and skin samples while maintaining tissue integrity, providing a streamlined approach to diagnosing PD with individual variability. The integration of seeding activities with the location of deposition of αSyn seeds advances our understanding of the mechanism underlying αSyn misfolding in PD.

Engineering and application of LacI mutants with stringent expressions.

Optimal transcriptional regulatory circuits are expected to exhibit stringent control, maintaining silence in the absence of inducers while exhibiting a broad induction dynamic range upon the addition of effectors. In the Plac /LacI pair, the promoter of the lac operon in Escherichia coli is characterized by its leakiness, attributed to the moderate affinity of LacI for its operator target. In response to this limitation, the LacI regulatory protein underwent engineering to enhance its regulatory properties. The M7 mutant, carrying I79T and N246S mutations, resulted in the lac promoter displaying approximately 95% less leaky expression and a broader induction dynamic range compared to the wild-type LacI. An in-depth analysis of each mutation revealed distinct regulatory profiles. In contrast to the wild-type LacI, the M7 mutant exhibited a tighter binding to the operator sequence, as evidenced by surface plasmon resonance studies. Leveraging the capabilities of the M7 mutant, a high-value sugar biosensor was constructed. This biosensor facilitated the selection of mutant galactosidases with approximately a seven-fold improvement in specific activity for transgalactosylation. Consequently, this advancement enabled enhanced biosynthesis of galacto-oligosaccharides (GOS).

Artificial Biosynthetic Pathway for Efficient Synthesis of Vanillin, a Feruloyl-CoA-Derived Natural Product from Eugenol.

Eugenol, the main component of essential oil from the Syzygium aromaticum clove tree, has great potential as an alternative bioresource feedstock for biosynthesis purposes. Although eugenol degradation to ferulic acid was investigated, an efficient method for directly converting eugenol to targeted natural products has not been established. Herein we identified the inherent inhibitions by simply combining the previously reported ferulic acid biosynthetic pathway and vanillin biosynthetic pathway. To overcome this, we developed a novel biosynthetic pathway for converting eugenol into vanillin, by introducing cinnamoyl-CoA reductase (CCR), which catalyzes conversion of coniferyl aldehyde to feruloyl-CoA. This approach bypasses the need for two catalysts, namely coniferyl aldehyde dehydrogenase and feruloyl-CoA synthetase, thereby eliminating inhibition while simplifying the pathway. To further improve efficiency, we enhanced CCR catalytic efficiency via directed evolution and leveraged an artificialvanillin biosensor for high-throughput screening. Switching the cofactor preference of CCR from NADP+ to NAD+ significantly improved pathway efficiency. This newly designed pathway provides an alternative strategy for efficiently biosynthesizing feruloyl-CoA-derived natural products using eugenol.

Engineering an SspB-mediated degron for novel controllable protein degradation.

Elegant controllable protein degradation tools have great applications in metabolic engineering and synthetic biology designs. SspB-mediated ClpXP proteolysis system is well characterized, and SspB acts as an adaptor tethering ssrA-tagged substrates to the ClpXP protease. This degron was applied in metabolism optimization, but the efficiency was barely satisfactory. Limited high-quality tools are available for controllable protein degradation. By coupling structure-guided modeling and directed evolution, we establish state-of-the-art high-throughput screening strategies for engineering both degradation efficiency and SspB-ssrA binding specificity of this degron. The reliability of our approach is confirmed by functional validation of both SspB and ssrA mutants using fluorescence assays and metabolic engineering of itaconic acid or ferulic acid biosynthesis. Isothermal titration calorimetry analysis and molecular modeling revealed that an appropriate instead of excessively strong interaction between SspB and ssrA benefited degradation efficiency. Mutated SspB-ssrA pairs with 7-22-fold higher binding KD than the wild-type pair led to higher degradation efficiency, revealing the advantage of directed evolution over rational design in degradation efficiency optimization. Furthermore, an artificial SspB-ssrA pair exhibiting low crosstalk of interactions with the wild-type SspB-ssrA pair was also developed. Efforts in this study have demonstrated the plasticity of SspB-ssrA binding pocket for designing high-quality controllable protein degradation tools. The obtained mutated degrons enriched the tool box of metabolic engineering designs.

Metabolic Engineering for Improved Curcumin Biosynthesis in Escherichia coli.

The biosynthetic efficiency of curcumin, a highly bioactive compound from the plant Curcuma longa, needs to be improved. In this study, we performed host cell and biosynthetic pathway engineering to improve curcumin biosynthesis. Using in vivo-directed evolution, the expression level of curcuminoid synthase (CUS), the rate-limiting enzyme in the curcumin biosynthetic pathway, was significantly improved. Furthermore, as curcumin is a highly hydrophobic compound, two cell membrane engineering strategies were applied to optimize the biosynthetic efficiency. Curcumin storage was increased by overexpression of monoglucosyldiacylglycerol synthase from Acholeplasma laidlawii, which optimized the cell membrane morphology. Furthermore, unsaturated fatty acid supplementation was used to enhance membrane fluidity, which greatly ameliorated the damaging effect of curcumin on the cell membrane. These two strategies enhanced curcumin biosynthesis and demonstrated an additive effect.

Dynamic control of toxic natural product biosynthesis by an artificial regulatory circuit.

To mimic the delicately regulated metabolism in nature for improved efficiency, artificial and customized regulatory components for dynamically controlling metabolic networks in multiple layers are essential in laboratory engineering. For this purpose, a novel regulatory component for controlling vanillin biosynthetic pathway was developed through directed evolution, which was responsive to both the product vanillin and substrate ferulic acid, with different capacities. This regulatory component facilitated pathway expression via dynamic control of the intracellular substrate and product concentrations. As vanillin is an antimicrobial compound, low pathway expression and vanillin formation levels enabled better cell growth at an early stage, and the product feedback-activated pathway expression at later stages significantly improved biosynthesis efficiency. This novel multiple-layer dynamic control was demonstrated effective in managing the trade-off between cell growth and production, leading to improved cell growth and vanillin production compared to the conventional or quorum-sensing promoter-controlled pathway. The multiple-layer dynamic control enabled by designed regulatory components responsive to multiple signals shows potential for wide applications in addition to the dynamic controls based on biosynthetic intermediate sensing and quorum sensing reported to date.

Towards the construction of high-quality mutagenesis libraries.

OBJECTIVES: To improve the quality of mutagenesis libraries in directed evolution strategy. RESULTS: In the process of library transformation, transformants which have been shown to take up more than one plasmid might constitute more than 20% of the constructed library, thereby extensively impairing the quality of the library. We propose a practical transformation method to prevent the occurrence of multiple-plasmid transformants while maintaining high transformation efficiency. A visual library model containing plasmids expressing different fluorescent proteins was used. Multiple-plasmid transformants can be reduced through optimizing plasmid DNA amount used for transformation based on the positive correlation between the occurrence frequency of multiple-plasmid transformants and the logarithmic ratio of plasmid molecules to competent cells. CONCLUSIONS: This method provides a simple solution for a seemingly common but often neglected problem, and should be valuable for improving the quality of mutagenesis libraries to enhance the efficiency of directed evolution strategies.

Design and application of a lactulose biosensor.

In this study the repressor of Escherichia coli lac operon, LacI, has been engineered for altered effector specificity. A LacI saturation mutagenesis library was subjected to Fluorescence Activated Cell Sorting (FACS) dual screening. Mutant LacI-L5 was selected and it is specifically induced by lactulose but not by other disaccharides tested (lactose, epilactose, maltose, sucrose, cellobiose and melibiose). LacI-L5 has been successfully used to construct a whole-cell lactulose biosensor which was then applied in directed evolution of cellobiose 2-epimerase (C2E) for elevated lactulose production. The mutant C2E enzyme with ~32-fold enhanced expression level was selected, demonstrating the high efficiency of the lactulose biosensor. LacI-L5 can also be used as a novel regulatory tool. This work explores the potential of engineering LacI for customized molecular biosensors which can be applied in practice.

Improving key enzyme activity in phenylpropanoid pathway with a designed biosensor.

Overexpressing key enzymes of biosynthetic pathways for overproduction of value-added products usually imposes metabolic burdens on cells, which can be circumvented by improving the key enzyme activities. p-Coumarate: CoA ligase (4CL) is a critical enzyme in the phenylpropanoid pathway that synthesizes various natural products. To screen for 4CL with improved activity, a biosensor of resveratrol whose biosynthetic pathway involves 4CL was designed by engineering the TtgR regulatory protein. The biosensor exhibited good specificity and robustness, allowing rapid and sensitive selection of resveratrol hyper-producers. A 4CL variant with improved activity was selected from a 4CL mutagenesis library constructed in the resveratrol biosynthetic pathway in Escherichia coli. This mutant led to increased production of not only resveratrol but also the flavonoid naringenin, when introduced in their corresponding biosynthetic pathways. These findings demonstrate the feasibility of improving key enzyme activities in important biosynthetic pathways with the aid of designed biosensors of pathway products.

Conformal Robotic Stereolithography.

Additive manufacturing by layerwise photopolymerization, commonly called stereolithography (SLA), is attractive due to its high resolution and diversity of materials chemistry. However, traditional SLA methods are restricted to planar substrates and planar layers that are perpendicular to a single-axis build direction. Here, we present a robotic system that is capable of maskless layerwise photopolymerization on curved surfaces, enabling production of large-area conformal patterns and the construction of conformal freeform objects. The system comprises an industrial six-axis robot and a custom-built maskless projector end effector. Use of the system involves creating a mesh representation of the freeform substrate, generation of a triangulated toolpath with curved layers that represents the target object to be printed, precision mounting of the substrate in the robot workspace, and robotic photopatterning of the target object by coordinated motion of the robot and substrate. We demonstrate printing of conformal photopatterns on spheres of various sizes, and construction of miniature three-dimensional objects on spheres without requiring support features. Improvement of the motion accuracy and development of freeform toolpaths would enable construction of polymer objects that surpass the size and support structure constraints imparted by traditional SLA systems.

Improving the activity of the subtilisin nattokinase by site-directed mutagenesis and molecular dynamics simulation.

Nattokinase (NK), a bacterial serine protease from Bacillus subtilis var. natto, is a potential cardiovascular drug exhibiting strong fibrinolytic activity. To broaden its commercial and medical applications, we constructed a single-mutant (I31L) and two double-mutants (M222A/I31L and T220S/I31L) by site-directed mutagenesis. Active enzymes were expressed in Escherichia coli with periplasmic secretion and were purified to homogeneity. The kinetic parameters of enzymes were examined by spectroscopy assay and isothermal titration calorimetry (ITC), and their fibrinolytic activities were determined by fibrin plate method. The substitution of Leu(31) for Ile(31) resulted in about 2-fold enhancement of catalytic efficiency (Kcat/KM) compared with wild-type NK. The specific activities of both double-mutants (M222A/I31L and T220S/I31L) were significantly increased when compared with the single-mutants (M222A and T220S) and the oxidative stability of M222A/I31L mutant was enhanced with respect to wild-type NK. This study demonstrates the feasibility of improving activity of NK by site-directed mutagenesis and shows successful protein engineering cases to improve the activity of NK as a potent therapeutic agent.

Probing the cell death signaling pathway of HepG2 cell line induced by copper-1,10-phenanthroline complex.

Copper-1,10-phenanthroline (phen) complex [Cu(phen)2] has been typically known as DNA-cleaving agent. And now it becomes more important for developing multifunctional drugs with its improved cytotoxic properties. In our study, we probed the cytophysiological mechanism of Cu(phen)2. HepG2 cells were more sensitive to Cu(phen)2 with an IC50 of 4.03 µM than other three kinds of cell lines. After treated by Cu(phen)2, HepG2 cells had some typical morphological changes which happened to its nucleus. DNA ladder's occurence and Annexin V-positive increased cells indicated that Cu(phen)2 induced HepG2 cells into apoptosis. Further studies showed that Cu(phen)2 treatment resulted in significant G2/M phase arrest and collapse of mitochondrial membrane potential. Several cell cycle-related factors were down-regulated, including Cyclin A, Cyclin B1 and Cdc2. But p21 and p53 were up-regulated. DNA damage, microtubule disorganization and mitotic arrest through spindle assembly checkpoint activation were observed in Cu(phen)2-treated cells. The activation of caspase-3, 8 & 9 were checked out. The increased-expression ratio of Bax/Bcl-2 was detected. The expression levels of Bcl-xL and Bid were found to decrease. These meant that a mitochondrial-related apoptosis pathway was activated in treated HepG2 cells. Furthermore, some ER stress-associated signaling factors were found to be up-regulated, such as Grp78, XBP-1and CHOP. Ca(2+) was also found to be released from the ER lumen. Collectively, our findings demonstrate that Cu(phen)2 induces apoptosis in HepG2 cells via mitotic arrest and mitochondrial- and ER-stress-related signaling pathways.