DNA-guided assembly of biosynthetic pathways promotes improved catalytic efficiency

Synthetic scaffolds that permit spatial and temporal organization of enzymes in living cells are a promising post-translational strategy for controlling the flow of information in both metabolic and signaling pathways. Here, we describe the use of plasmid DNA as a stable, robust and configurable scaffold for arranging biosynthetic enzymes in the cytoplasm of Escherichia coli. This involved conversion of individual enzymes into custom DNA-binding proteins by genetic fusion to zinc-finger domains that specifically bind unique DNA sequences. When expressed in cells that carried a rationally designed DNA scaffold comprising corresponding zinc finger binding sites, the titers of diverse metabolic products, including resveratrol, 1,2-propanediol and mevalonate were increased as a function of the scaffold architecture. These results highlight the utility of DNA scaffolds for assembling biosynthetic enzymes into functional metabolic structures. Beyond metabolism, we anticipate that DNA scaffolds may be useful in sequestering different types of enzymes for specifying the output of biological signaling pathways or for coordinating other assembly-line processes such as protein folding, degradation and post-translational modifications.     

Fatty acid transport across the cell membrane: Regulation by fatty acid transporters

Transport of long-chain fatty acids across the cell membrane has long been thought to occur by passive diffusion. However, in recent years there has been a fundamental shift in understanding, and it is now generally recognized that fatty acids cross the cell membrane via a protein-mediated mechanism. Membrane-associated fatty acid-binding proteins (‘fatty acid transporters’) not only facilitate but also regulate cellular fatty acid uptake, for instance through their inducible rapid (and reversible) translocation from intracellular storage pools to the cell membrane. A number of fatty acid transporters have been identified, including CD36, plasma membrane-associated fatty acid-binding protein (FABP_pm), and a family of fatty acid transport proteins (FATP1–6). Fatty acid transporters are also implicated in metabolic disease, such as insulin resistance and type-2 diabetes. In this report we briefly review current understanding of the mechanism of transmembrane fatty acid transport, and the function of fatty acid transporters in healthy cardiac and skeletal muscle, and in insulin resistance/type-2 diabetes. Fatty acid transporters hold promise as a future target to rectify lipid fluxes in the body and regain metabolic homeostasis.     

Redirection of acyl donor metabolic flux for lipopeptide A40926B0 biosynthesis

The metabolic flux of fatty acyl-CoAs determines lipopeptide biosynthesis efficiency, because acyl donor competition often occurs from polyketide biosynthesis and homologous pathways. We used A40926B0 as a model to investigate this mechanism. The lipopeptide A40926B0 with a fatty acyl group is the active precursor of dalbavancin, which is considered as a new lipoglycopeptide antibiotic. The biosynthetic pathway of fatty acyl-CoAs in the A40926B0 producer Nonomuraea gerenzanensis L70 was efficiently engineered using endogenous replicon CRISPR (erCRISPR). A polyketide pathway and straight-chain fatty acid biosynthesis were identified as major competitors in the malonyl-CoA pool. Therefore, we modified both pathways to concentrate acyl donors for the production of the desired compound. Combined with multiple engineering approaches, including blockage of an acetylation side reaction, overexpression of acetyl-CoA carboxylase, duplication of the dbv gene cluster and optimization of the fermentation parameters, the final strain produced 702.4 mg l^-1 of A40926B0, a 2.66-fold increase, and the ratio was increased from 36.2% to 81.5%. Additionally, an efficient erCRISPR-Cas9 editing system based on an endogenous replicon was specifically developed for L70, which increased conjugation efficiency by 660% and gene-editing efficiency was up to 90%. Our strategy of redirecting acyl donor metabolic flux can be widely adopted for the metabolic engineering of lipopeptide biosynthesis.     

Use of modular,synthetic scaffolds for improved production of glucaric acid in engineered E. coli

The field of metabolic engineering has the potential to produce a wide variety of chemicals in both an inexpensive and ecologically-friendly manner. Heterologous expression of novel combinations of enzymes promises to provide new or improved synthetic routes towards a substantially increased diversity of small molecules. Recently, we constructed a synthetic pathway to produce d-glucaric acid, a molecule that has been deemed a “top-value added chemical” from biomass, starting from glucose. Limiting flux through the pathway is the second recombinant step, catalyzed by myo-inositol oxygenase (MIOX), whose activity is strongly influenced by the concentration of the myo-inositol substrate. To synthetically increase the effective concentration of myo-inositol, polypeptide scaffolds were built from protein–protein interaction domains to co-localize all three pathway enzymes in a designable complex as previously described (Dueber et al., 2009). Glucaric acid titer was found to be strongly affected by the number of scaffold interaction domains targeting upstream Ino1 enzymes, whereas the effect of increased numbers of MIOX-targeted domains was much less significant. We determined that the scaffolds directly increased the specific MIOX activity and that glucaric acid titers were strongly correlated with MIOX activity. Overall, we observed an approximately 5-fold improvement in product titers over the non-scaffolded control, and a 50% improvement over the previously reported highest titers. These results further validate the utility of these synthetic scaffolds as a tool for metabolic engineering.     

Synthetic metabolic channel by functional membrane microdomains for compartmentalized flux control

The anchoring of metabolic pathway enzymes to spatial scaffolds can significantly improve their reaction efficiency. Here, we successfully constructed a multi-enzyme complex assembly system able to enhance bioproduction in bacteria by using the endogenous spatial scaffolds─functional membrane microdomains (FMMs). First, using VA-TIRFM and SPT analysis, we reveal that FMMs possess high temporal and spatial stability at the plasma membrane and can be used as endogenous spatial scaffolds to organize enzyme pathways. Then, taking the synthesis of N-acetylglucosamine (GlcNAc) in Bacillus subtilis as a proof-of-concept demonstration, we found that anchoring of various enzymes required for GlcNAc synthesis onto FMMs to obtain the FMMs-multi-enzyme complex system resulted in a significant increase in GlcNAc titer and an effectively alleviate in cell lysis at the later stage of fermentation compared to that in control strains expressing the related enzymes in the cytoplasm. Combining with metabolic model and kinetics analysis, the existence of a constructed substrate channel that maximizes the reaction efficiency is verified. In summary, we propose a novel metabolic pathway assembly model which allowed improved titers and compartmentalized flux control with high spatial resolution in bacterial metabolism.     

In vivo co-localization of enzymes on RNA scaffolds increases metabolic production in a geometrically dependent manner

Co-localization of biochemical processes plays a key role in the directional control of metabolic fluxes toward specific products in cells. Here, we employ in vivo scaffolds made of RNA that can bind engineered proteins fused to specific RNA binding domains. This allows proteins to be co-localized on RNA scaffolds inside living Escherichia coli. We assembled a library of eight aptamers and corresponding RNA binding domains fused to partial fragments of fluorescent proteins. New scaffold designs could co-localize split green fluorescent protein fragments to produce activity as measured by cell-based fluorescence. The scaffolds consisted of either single bivalent RNAs or RNAs designed to polymerize in one or two dimensions. The new scaffolds were used to increase metabolic output from a two-enzyme pentadecane production pathway that contains a fatty aldehyde intermediate, as well as three and four enzymes in the succinate production pathway. Pentadecane synthesis depended on the geometry of enzymes on the scaffold, as determined through systematic reorientation of the acyl-ACP reductase fusion by rotation via addition of base pairs to its cognate RNA aptamer. Together, these data suggest that intra-cellular scaffolding of enzymatic reactions may enhance the direct channeling of a variety of substrates.     

Changes in emergence phenology,fatty acid composition,and xenobiotic-metabolizing enzyme expression is associated with increased insecticide resistance in the Colorado potato beetle

The Colorado potato beetle (Leptinotarsa decemlineata) is a major agricultural pest of solanaceous crops. An effective management strategy employed by agricultural producers to control this pest species is the use of systemic insecticides. Recent emphasis has been placed on the use of neonicotinoid insecticides. Despite efforts to curb resistance development through integrated pest management approaches, resistance to neonicotinoids in L. decemlineata populations continues to increase. One contributing factor may be alterations in insect fatty acids, which have multiple metabolic functions and are associated with the synthesis of xenobiotic-metabolizing enzymes to mitigate the effects of insecticide exposure. In this study, we analyzed the fatty acid composition of L. decemlineata populations collected from an organic production field and from a commercially managed field to determine if fatty acid composition varied between the two populations. We demonstrate that a population of L. decemlineata that has a history of systemic neonicotinoid exposure (commercially managed) has a different lipid composition and differential expression of known metabolic detoxification mechanisms relative to a population that has not been exposed to neonicotinoids (organically managed). The fatty acid data indicated an upregulation of Δ⁶ desaturase in the commercially managed L. decemlineata population and suggest a role for eicosanoids and associated metabolic enzymes as potential modulators of insecticide resistance. We further observed a pattern of delayed emergence within the commercially managed population compared with the organically managed population. Variations in emergence timing together with specific fatty acid regulation may significantly influence the capacity of L. decemlineata to develop insecticide resistance.     

合成支架在代谢工程中的研究进展

代谢工程作为通过引入外源合成途径或改造优化代谢网络,进行高附加值的天然代谢产物生物合成的技术,已经得到广泛应用。但随着目标合成产物的结构日渐复杂,构建多基因的从头合成途径造成宿主生物代谢失衡与中间产物对宿主细胞产生毒害作用等一系列问题发生的可能性也随之增加。为解决这些问题合成支架策略应运而生,合成支架将途径酶共定位以提高局部酶和代谢物的浓度,来增强代谢通量并限制中间产物与宿主细胞环境间的相互作用,成为生物催化和合成生物学研究的热点之一。尽管由核酸、蛋白质构成的合成支架策略已经应用于多种代谢物的异源合成,并取得了不同程度的成功,但合成支架的精确组装仍然是一项艰巨的任务。文中详细介绍了合成支架技术的研究现状,详细阐述了合成支架技术的原理和实例,并初步探讨了其应用前景。     

Using Protein Dimers to Maximize the Protein Hybridization Efficiency with Multisite DNA Origami Scaffolds

DNA origami provides a versatile platform for conducting ‘architecture-function’ analysis to determine how the nanoscale organization of multiple copies of a protein component within a multi-protein machine affects its overall function. Such analysis requires that the copy number of protein molecules bound to the origami scaffold exactly matches the desired number, and that it is uniform over an entire scaffold population. This requirement is challenging to satisfy for origami scaffolds with many protein hybridization sites, because it requires the successful completion of multiple, independent hybridization reactions. Here, we show that a cleavable dimerization domain on the hybridizing protein can be used to multiplex hybridization reactions on an origami scaffold. This strategy yields nearly 100% hybridization efficiency on a 6-site scaffold even when using low protein concentration and short incubation time. It can also be developed further to enable reliable patterning of a large number of molecules on DNA origami for architecture-function analysis.     

蛋白骨架在随机肽库构建及靶分子筛选中的应用*

自然界有着丰富的蛋白骨架来源。选择适宜的蛋白骨架和展示、筛选方法,可构建基于合理蛋白骨架结构的优化限制性随机肽库。与非限制性随机肽库相比,可望获得针对靶分子具有新功能的蛋白结构或更高亲和力的配体分子。目前,骨架蛋白限制的随机肽库已在高效靶分子筛选、基础研究、临床诊断和医学治疗等方面显示出巨大的潜在应用价值。以S-S限制性骨架、抗体分子、锌指蛋白、Z结构域、FN3结构域等为主要代表,综合介绍了蛋白骨架的结构基础、分类、基于蛋白骨架的限制性随机肽库构建及近年来在靶分子筛选等方面的应用最新进展。     

Integration of molecular dynamics simulation and hotspot residues grafting for de novo scFv design against Salmonella Typhi TolC protein

With the development of de novo binders for protein targets from non‐related scaffolds, many possibilities for therapeutics and diagnostics have been created. In this study, we described the use of de novo design approach to create single‐chain fragment variable (scFv) for Salmonella enterica subspecies enterica serovar Typhi TolC protein. Typhoid fever is a global health concern in developing and underdeveloped countries. Rapid typhoid diagnostics will improve disease management and therapy. In this work, molecular dynamics simulation was first performed on a homology model of TolC protein in POPE membrane bilayer to obtain the central structure that was subsequently used as the target for scFv design. Potential hotspot residues capable of anchoring the binders to the target were identified by docking “disembodied” amino acid residues against TolC surface. Next, scFv scaffolds were selected from Protein Data Bank to harbor the computed hotspot residues. The hotspot residues were then incorporated into the scFv scaffold complementarity determining regions. The designs recapitulated binding energy, shape complementarity, and interface surface area of natural protein‐antibody interfaces. This approach has yielded 5 designs with high binding affinity against TolC that may be beneficial for the future development of antigen‐based detection agents for typhoid diagnostics.     

过氧化物酶体与病原真菌的致病性

过氧化物酶体(Peroxisome)是一类单层膜的细胞器,普遍存在于各种真核细胞中。过氧化物酶体是丰富的酶库,含有至少50种酶类,参与生物体的多种生理代谢过程,如乙醛酸循环、脂肪酸的β-氧化及活性氧的调节等。近年来,日益增多的研究表明过氧化物酶体和病原真菌的乙醛酸循环及脂肪酸的β-氧化功能的发挥密切相关,并影响病原真菌的致病性。总结过氧化物酶体中酶的种类和功能,评述过氧化物酶体与乙醛酸循环、脂肪酸β-氧化和病原真菌致病性的关系。     

A novel unstructured scaffold based on 4EBP1 enables the functional display of a wide range of bioactive peptides

Target validation using protein aptamers enables the characterization of a specific function of a target protein in an environment that resembles native conditions as closely as possible. A major obstacle to the use of this technology has been the generation of bioactive aptamers, which is dependent on the choice of scaffold. Constraining binding peptides within a particular scaffold does not necessarily result in binding aptamers, as suboptimal presentation of peptides can occur. It is therefore understandable that different peptides might require different scaffolds for optimal presentation. In this article, we describe a novel scaffold protein that bypasses the conventional requirement for scaffolds to have known rigid structures and yet successfully presents several peptides that need to adopt a wide range of conformations for binding to their target protein. Using an unstructured protein, 4EBP1, as scaffold, we successfully construct binding aptamers to three different target proteins: Mdm2, proliferating cell nuclear antigen, and cyclin A. The Mdm2-binding aptamer constructed using 4EBP1 as scaffold demonstrates better stability and bioactivity compared to that constructed using thioredoxin as scaffold. This new scaffold protein, which makes it relatively easy to create bioactive aptamers based on known interaction sequences, will greatly facilitate the aptamer approach to target validation.     

SufA/IscA: reactivity studies of a class of scaffold proteins involved in [Fe-S] cluster assembly

IscA/SufA proteins belong to complex protein machineries which are involved in iron-sulfur cluster biosynthesis. They are defined as scaffold proteins from which preassembled clusters are transferred to target apoproteins. The experiments described here demonstrate that the transfer reaction proceeds in two observable steps: a first fast one leading to a protein–protein complex between the cluster donor (SufA/IscA) and the acceptor (biotin synthase), and a slow one consisting of cluster transfer leading to the apoform of the scaffold protein and the holoform of the target protein. Mutation of cysteines in the acceptor protein specifically inhibits the second step of the reaction, showing that these cysteines are involved in the cluster transfer mechanism but not in complex formation. No cluster transfer from IscA to IscU, another scaffold of the isc operon, could be observed, whereas IscU was shown to be an efficient cluster source for cluster assembly in IscA. Implications of these results are discussed.Abbreviations AdoMet S-adenosylmethionine - APS adenosine-5-phosphosulfate - BioB biotin synthase - DAF deazaflavin - DTB dethiobiotin - DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - _hisIscU/A six histidine residues at the N-terminus of IscU/A - PCR polymerase chain reaction - PLP pyridoxal 5-phosphate - SufA_his six histidine residues at the C-terminus of SufA     

以胶原膜为支架的心肌细胞体外三维培养

将从新生乳鼠心室肌组织获取的心肌细胞接种于鼠尾胶原膜三维支架和组织培养板,以细胞形态、细胞搏动、葡萄糖比消耗率(q_glu)、乳酸比产率(q_lac)、乳酸转化率(Y_lac/glu)、肌酸激酶及乳酸脱氢酶的活力为观察指标,比较心肌细胞在鼠尾胶原膜中三维(3D)培养和组织培养板中二维(2D)培养的差异。培养于鼠尾胶原膜的乳鼠心肌细胞在第5天形成闰盘连接,形成面积约为80mm³、肉眼可见自律性同步收缩的心肌细胞3D培养物。3D培养体系中乳鼠心肌细胞的q_glu、q_lac和Y_lac/glu的均值分别为7.37 μmol/10.6cells/d、2.92 μmol/106cells/d和0.38 μmol/μmol;2D培养体系中乳鼠心肌细胞的q_glu、q_lac和Y_lac/glu的均值分别为7.59 μmol/10.6cells/d、3.83 μmol/10.6cells/d和 0.51 μmol/μmol。两种培养体系中乳鼠心肌细胞的肌酸激酶及乳酸脱氢酶的活力无明显差别。实验结果表明：培养于鼠尾胶原膜的心肌细胞保持正常心肌细胞的代谢活力和收缩功能。     

Design of selective PI3Kδ inhibitors using an iterative scaffold-hopping workflow

PI3Kδ mediates key immune cell signaling pathways and is a target of interest for multiple indications in immunology and oncology. Here we report a structure-based scaffold-hopping strategy for the design of chemically diverse PI3Kδ inhibitors. Using this strategy, we identified several scaffolds that can be combined to generate new PI3Kδ inhibitors with high potency and isoform selectivity. In particular, an oxindole-based scaffold was found to impart exquisite selectivity when combined with several hinge binding motifs.     

Enzyme assembly guided by SPFH-induced functional inclusion bodies for enhanced cascade biocatalysis

Enzyme clustering into compact agglomerates could accelerate the processing of intermediates to enhance metabolic pathway flux. However, enzyme clustering is still a challenging task due to the lack of universal assembly strategy applicable to all enzymes. Therefore, we proposed an alternative enzyme assembly strategy based on functional inclusion bodies. First, functional inclusion bodies in cells were formed by the fusion expression of stomatin/prohibitin/flotillin/HflK/C (SPFH) domain and enhanced green fluorescent protein, as observed visually and by transmission electron microscopy. The formation of SPFH-induced functional inclusion bodies enhanced intermolecular polymerization as revealed by further analysis combined with Förster resonance energy transfer and bimolecular fluorescent complimentary. Finally, the functional inclusion bodies significantly improved the enzymatic catalysis in living cells, as proven by the examples with whole-cell biocatalysis of phenyllactic acid by Escherichia coli, and the production of N-acetylglucosamine by Bacillus subtilis. Our findings suggest that SPFH-induced functional inclusion bodies can enhance the cascade reaction of enzymes, to serve as a potential universal strategy for the construction of efficient microbial cell factories.     

Membrane-Mediated Interaction between Strongly Anisotropic Protein Scaffolds

Specialized proteins serve as scaffolds sculpting strongly curved membranes of intracellular organelles. Effective membrane shaping requires segregation of these proteins into domains and is, therefore, critically dependent on the protein-protein interaction. Interactions mediated by membrane elastic deformations have been extensively analyzed within approximations of large inter-protein distances, small extents of the protein-mediated membrane bending and small deviations of the protein shapes from isotropic spherical segments. At the same time, important classes of the realistic membrane-shaping proteins have strongly elongated shapes with large and highly anisotropic curvature. Here we investigated, computationally, the membrane mediated interaction between proteins or protein oligomers representing membrane scaffolds with strongly anisotropic curvature, and addressed, quantitatively, a specific case of the scaffold geometrical parameters characterizing BAR domains, which are crucial for membrane shaping in endocytosis. In addition to the previously analyzed contributions to the interaction, we considered a repulsive force stemming from the entropy of the scaffold orientation. We computed this interaction to be of the same order of magnitude as the well-known attractive force related to the entropy of membrane undulations. We demonstrated the scaffold shape anisotropy to cause a mutual aligning of the scaffolds and to generate a strong attractive interaction bringing the scaffolds close to each other to equilibrium distances much smaller than the scaffold size. We computed the energy of interaction between scaffolds of a realistic geometry to constitute tens of k_BT, which guarantees a robust segregation of the scaffolds into domains.     

The increase in unsaturation of fatty acids of phosphatidylglycerol in thylakoid membrane enhanced salt tolerance in tomato

Overexpression of chloroplastic glycerol-3-phosphate acyltransferase gene (LeGPAT) in tomato increased cis-unsaturated fatty acid content in phosphatidylglycerol (PG) of thylakoid membrane. By contrast, suppressing the expression of LeGPAT decreased the content of cis-unsaturated fatty acid in PG. Under salt stress, sense transgenic plants exhibited higher activities of chloroplastic antioxidant enzymes, lower content of reactive oxygen species (ROS) and less ion leakage compared with the wild type (WT) plants. The net photosynthetic rate (P _N) and the maximal photochemical efficiency (F_v/F_m) of photosystem II (PSII) decreased more slightly in sense lines but more markedly in the antisense ones, compared to WT. D1 protein, located in the reactive center of the PSII, is the primary target of photodamage and has the highest turnover rate in the chloroplast. Under salt stress, compared with WT, the content of D1 protein decreased slightly in sense lines and significantly in the antisense ones. In the presence of streptomycin (SM), the net degradation of the damaged D1 protein was faster in sense lines than in other plants. These results suggested that, under salt-stress conditions, increasing cis-unsaturated fatty acids in PG by overexpression of LeGPAT can alleviate PSII photoinhibition by accelerating the repair of D1 protein and improving the activity of antioxidant enzymes in chloroplasts.