Site-Directed Mutations of the Gatekeeping Loop Region Affect the Activity of Escherichia coli Spermidine Synthase

Spermidine synthase catalyzes the production of spermidine from putrescine and decarboxylated S-adenosylmethionine (dcSAM), and plays a crucial role in cell proliferation and differentiation. The gatekeeping loop identified in the structure of spermidine synthase was predicted to contain residues important for substrate binding, but its correlation with enzyme catalysis has not been fully understood. In this study, recombinant Escherichia coli spermidine synthase (EcSPDS) was produced and its enzyme kinetics was characterized. Site-directed mutants of EcSPDS were obtained to demonstrate the importance of the amino acid residues in the gatekeeping loop. Substitution of Asp158 and Asp161 with alanine completely abolished EcSPDS activity, suggesting that these residues are absolutely required for substrate interaction. Reduction in enzyme activity was observed in the C159A, T160A, and P165Q variants, indicating that hydrophobic interactions contributed by Cys159, Thr160, and Pro165 are important for enzyme catalysis as well. On the other hand, replacement of Pro162 and Ile163 had no influence on EcSDPS activity. These results indicate that residues in the gatekeeping loop of spermidine synthase are indispensable for the catalytic reaction of EcSPDS. To the best of our knowledge, this is the first functional study on the gatekeeping loop of EcSPDS by site-directed mutagenesis.     

High-Level Expression of Cold-Tolerant Pyruvate, Orthophosphate Dikinase from a Genomic Clone with Site-Directed Mutations in Transgenic Maize

Pyruvate, orthophosphate dikinase (PPDK) is a key enzyme in the C₄ photosynthetic pathway of maize. To improve the cold tolerance of the enzyme in maize, we designed two genomic sequence-based constructs in which the carboxy-terminal region of the enzyme was modified to mimic the amino acid sequence of the cold-tolerant PPDK of Flaveria brownii (Asteraceae). A large amount of PPDK was found to have accumulated in the leaves of many of the maize plants transformed with one of these constructs – that which introduced 17 amino acid substitutions without any alteration of the exon-intron structure – although there was a wide range of variation in the amount of PPDK among the separate plants. In contrast, the production was much less in maize transformed with the second construct in which a cDNA fragment for the same carboxy-terminal region was inserted. The specific activity of PPDK in the plants transformed with the gene with the amino acid substitutions was inversely correlated with the amount of enzyme in the leaves. In addition, the activity of the cold-tolerant recombinant enzyme was judged to be regulated by the PPDK regulatory protein, similar to that of the native PPDK. The cold tolerance of PPDK in crude leaf extracts was greatly improved in plants that produced a large amount of the engineered PPDK. The photosynthetic rate at 8°C increased significantly (by 23%, p<0.05), but there was no obvious effect at higher temperatures. These results support the hypothesis that PPDK is one of the limiting factors in the C₄ photosynthesis of maize under cold conditions.     

Site-Directed Mutagenesis in Epitope Mapping

Site-directed mutagenesis is a very useful tool for mapping and defining epitopes on protein antigens. This review discusses the methods used in, and the results of, studies on four different protein antigen systems. In addition, computer analyses and molecular modeling were used in an attempt to better understand the structural and energetic mechanisms underlying the effects observed following mutagenesis. The advantages and limitations of site-directed mutagenesis as an experimental tool are also discussed.     

The Group I Strain of Streptococcus mutans, UA140, Produces Both the Lantibiotic Mutacin I and a Nonlantibiotic Bacteriocin, Mutacin IV

Strains of Streptococcus mutans produce at least three mutacins, I, II, and III. Mutacin II is a member of subgroup AII in the lantibiotic family of bacteriocins, and mutacins I and III belong to subgroup AI in the lantibiotic family. In this report, we characterize two mutacins produced by UA140, a group I strain of S. mutans. One is identical to the lantibiotic mutacin I produced by strain CH43 (F. Qi et al., Appl. Environ. Microbiol. 66:3221–3229, 2000); the other is a nonlantibiotic bacteriocin, which we named mutacin IV. Mutacin IV belongs to the two-peptide, nonlantibiotic family of bacteriocins produced by gram-positive bacteria. Peptide A, encoded by gene nlmA, is 44 amino acids (aa) in size and has a molecular mass of 4,169 Da; peptide B, encoded by nlmB, is 49 aa in size and has a molecular mass of 4,826 Da. Both peptides derive from prepeptides with glycines at positions −2 and −1 relative to the processing site. Production of mutacins I and IV by UA140 appears to be regulated by different mechanisms under different physiological conditions. The significance of producing two mutacins by one strain under different conditions and the implication of this property in terms of the ecology of S. mutans in the oral cavity are discussed.     

Elucidation of the antimicrobial mechanism of mutacin 1140

Mutacin 1140 and nisin A are peptide antibiotics that belong to the lantibiotic family. N-Terminal rings A and B of nisin A and mutacin 1140 (lipid II-binding domain) share many structural and sequence similarities. Nisin A binds lipid II and thus disrupts cell wall synthesis and also forms transmembrane pores. Very little is known about mutacin 1140 in this regard. We performed fluorescence-based studies using a bacteria-mimetic membrane system. The results indicated that lipid II monomers are arranged differently in the mutacin 1140 complex than in the nisin A complex. These differences in complex formation may be attributed to the fact that nisin A uses lipid II to form a distinct pore complex, while mutacin 1140 does not form pores in this membrane system. Further experiments demonstrated that the mutacin 1140-lipid II and nisin A-lipid II complexes are very stable and capable of withstanding competition from each other. Transmembrane electrical potential experiments using a Streptococcus rattus strain, which is sensitive to mutacin 1140, demonstrated that mutacin 1140 does not form pores in this strain even at a concentration 8 times higher than the minimum inhibitory concentration (MIC). Circular complexes of mutacin 1140 and nisin A were observed by electron microscopy, providing direct evidence for a lateral assembly mechanism for these antibiotics. Mutacin 1140 did exhibit a membrane disruptive function in another commonly used artificial bacterial membrane system, and its disruptive activity was enhanced by increasing amounts of anionic phospholipids.     

Structure and dynamics of the lantibiotic mutacin 1140

Mutacin 1140 is a member of a family of ribosomally synthesized peptide bacteriocins called lantibiotics (lanthionine-containing antibiotics) and is produced by the Gram-positive bacterium Streptococcus mutans. Mutacin 1140 has been shown to be effective against a broad array of Gram-positive bacteria. Chromatography and mass spectroscopy data suggested that mutacin 1140 forms a small compact structure. Nuclear magnetic resonance (NMR) data and restrained molecular dynamics simulations showed that mutacin 1140 interconverts between multiple structures. Calculations of scalar (J) coupling constants showed the best agreement with experimental values when the entire population-weighted ensemble of structures was used, providing independent support for the ensemble. Representative structures from each major group in the ensemble had a common feature in which they are all kinked around the hinge region forming a horseshoe-like shape, and the regions of flexibility of the molecule were limited and well-defined. The structures determined in this study provide a starting point for modeling the mutacin 1140-membrane interactions and pore formation.     

Site-Directed Spin-Labeling Study of the Light-Harvesting Complex CP29

The topology of the long N-terminal domain (∼100 amino-acid residues) of the photosynthetic Lhc CP29 was studied using electron spin resonance. Wild-type protein containing a single cysteine at position 108 and nine single-cysteine mutants were produced, allowing to label different parts of the domain with a nitroxide spin label. In all cases, the apoproteins were either solubilized in detergent or they were reconstituted with their native pigments (holoproteins) in vitro. The spin-label electron spin resonance spectra were analyzed in terms of a multicomponent spectral simulation approach, based on hybrid evolutionary optimization and solution condensation. These results permit to trace the structural organization of the long N-terminal domain of CP29. Amino-acid residues 97 and 108 are located in the transmembrane pigment-containing protein body of the protein. Positions 65, 81, and 90 are located in a flexible loop that is proposed to extend out of the protein from the stromal surface. This loop also contains a phosphorylation site at Thr81, suggesting that the flexibility of this loop might play a role in the regulatory mechanisms of the light-harvesting process. Positions 4, 33, 40, and 56 are found to be located in a relatively rigid environment, close to the transmembrane protein body. On the other hand, position 15 is located in a flexible region, relatively far away from the transmembrane domain.     

Phosphorothioate-Based Site-Directed Mutagenesis: Extending the Basic Methodology

Abstract

The versatility of the phosphorothioate-based site-directed mutagenesis method has been extended by employing 5′-3′ exonucleases in the gapping reaction. Mutational frequencies of 70–95% were routinely achieved.     

Purification and Biochemical Characterization of Mutacin I from the Group I Strain of Streptococcus mutans, CH43, and Genetic Analysis of Mutacin I Biosynthesis Genes

Previously, we reported isolation and characterization of mutacin III and genetic analysis of mutacin III biosynthesis genes from the group III strain of Streptococcus mutans, UA787 (F. Qi, P. Chen, and P. W. Caufield, Appl. Environ. Microbiol. 65:3880–3887, 1999). During the same process of isolating the mutacin III structural gene, we also cloned the structural gene for mutacin I. In this report, we present purification and biochemical characterization of mutacin I from the group I strain CH43 and compare mutacin I and mutacin III biosynthesis genes. The mutacin I biosynthesis gene locus consists of 14 genes in the order mutR, -A, -A′, -B, -C, -D, -P, -T, -F, -E, -G, orfX, orfY, orfZ. mutA is the structural gene for mutacin I, while mutA′ is not required for mutacin I activity. DNA and protein sequence analysis revealed that mutacins I and III are homologous to each other, possibly arising from a common ancestor. The mature mutacin I is 24 amino acids in size and has a molecular mass of 2,364 Da. Ethanethiol modification and peptide sequencing of mutacin I revealed that it contains six dehydrated serines, four of which are probably involved with thioether bridge formation. Comparison of the primary sequence of mutacin I with that of mutacin III and epidermin suggests that mutacin I likely has the same bridging pattern as epidermin.     

Optimization of the production of the lantibiotic mutacin 1140 in minimal media

Mutacin 1140 is produced by Streptococcus mutans and belongs to the type A lantibiotic family. Experiments were done to optimize production of mutacin 1140 in minimal media enabling a more cost efficient downstream purification method. The development of a small volume fermentation method enabled a rapid screen of several variables in a standard shaking incubator. This method provided a fast approach for determining components that promote mutacin 1140 production in minimal media broth. Lactose was determined to be the optimal carbon source for mutacin 1140 production. High concentrations of CaCl₂ (0.3%, w/v) and MgSO₄ (0.77%, w/v) promoted an increase in mutacin 1140 production, while ZnCl₂ and FeCl₃ appeared to impair production. Optimization of mutacin 1140 production in minimal media resulted in more than a 100-fold increase in production compared to the base medium used to begin our optimizations. The yield has been estimated by RP-HPLC to be ∼10 mg/L.     

Mutations in the galactose-operator

Summary Constitutive mutations in the galactose operator in E. coli arise with a frequency ten times smaller than in the regulator gene. The operator constitutive mutations do not arise as a consequence of mutagen treatment.Operator constitutive mutations do not revert to wildtype spontaneously or after mutagen treatment.It is concluded that operator constitutive mutations are multisite mutations, and that the operator region is considerably smaller than the regulator gene in the gal operon.     

Functional Analysis of Conserved Histidines in Choline Acetyltransferase by Site-Directed Mutagenesis

Abstract: The choline acetyltransferase (ChAT) reaction involves the transfer of the acetyl group of acetyl-CoA to choline, in which an active site histidine is believed to act as a general acid/base catalyst. A comparison of the deduced amino acid sequences of the enzyme from Drosophila , pig, rat, and Caernohabditis elegans revealed three conserved histidines: Drosophila His²⁶⁸, His³⁹³, and His⁴²⁶. Each of these histidines was replaced by a leucine and a glutamine, and the kinetic properties of each of the recombinant mutant enzymes were determined. The mutations yielded active His²⁶⁸Leu-ChAT, His^Z68Gln-ChAT, and His³⁹³Gln-ChAT and inactive His³⁹³Leu-ChAT, His⁴²⁶Leu- ChAT, and His⁴²⁶Gln-ChAT. The kinetic constants K_m(CoA), K_{m(acetyloholine)}. and V_max were essentially the same for all of the active mutants. When the integrity of the CoASAc binding site was investigated in the inactive mutants, the data suggested that the binding site in His³⁹³Leu-ChAT is disrupted but conserved in His⁴²⁶Leu-ChAT and His⁴²⁶Gln- ChAT. These results suggest that His⁴²⁶ is an essential catalytic residue and could serve as an acid/base catalyst.     

PCR技术对人IL-3 cDNA进行定点突变的研究

本文利用PCR技术对人IL-3cDNA体外进行定点突变,将人IL-3cDNA第3位Met,第116位Lys密码子突变为Val密码子GTT。PCR扩增片段核苷酸序列与引物设计相应的cDNA突变体序列完全一致。结果证实此方法比经典寡聚核苷酸方法简单、迅速、成本低、效率高,也为基因的修饰,蛋白质工程研究提供了简便、稳定的方法。     

Mixed Exciton-Charge-Transfer States in Photosystem II: Stark Spectroscopy on Site-Directed Mutants

Sickle erythrocytes exhibit abnormal morphology and membrane mechanics under deoxygenated conditions due to the polymerization of hemoglobin S. We employed dissipative particle dynamics to extend a validated multiscale model of red blood cells (RBCs) to represent different sickle cell morphologies based on a simulated annealing procedure and experimental observations. We quantified cell distortion using asphericity and elliptical shape factors, and the results were consistent with a medical image analysis. We then studied the rheology and dynamics of sickle RBC suspensions under constant shear and in a tube. In shear flow, the transition from shear-thinning to shear-independent flow revealed a profound effect of cell membrane stiffening during deoxygenation, with granular RBC shapes leading to the greatest viscosity. In tube flow, the increase of flow resistance by granular RBCs was also greater than the resistance of blood flow with sickle-shape RBCs. However, no occlusion was observed in a straight tube under any conditions unless an adhesive dynamics model was explicitly incorporated into simulations that partially trapped sickle RBCs, which led to full occlusion in some cases.