Temperature-sensitive mutants of the EcoRI endonuclease

The EcoRI endonuclease is an important recombinant DNA tool and a paradigm of sequence-specific DNA-protein interactions. We have isolated temperature-sensitive (TS) EcoRI endonuclease mutants (R56Q, G78D, P90S, V97I, R105K, M157I, C218Y, A235E, M255I, T261I and L263F) and characterized activity in vivo and in vitro. Although the majority were TS for function in vivo, all of the mutant enzymes were stably expressed and largely soluble at both 30°C and 42°C in vivo and none of the mutants was found to be TS in vitro. These findings suggest that these mutations may affect folding of the enzyme at elevated temperature in vivo. Both non-conservative and conservative substitutions occurred but were not correlated with severity of the mutation. Of the 12 residues identified, 11 are conserved between EcoRI and the isoschizomer RsrI (which shares 50% identity), a further indication that these residues are critical for EcoRI structure and function. Inspection of the 2.8 Å resolution X-ray crystal structure of the wild-type EcoRI endonuclease-DNA complex revealed that: (1) the TS mutations cluster in one half of the globular enzyme; (2) several of the substituted residues interact with each other; (3) most mutations would be predicted to disrupt local structures; (4) two mutations may affect the dimer interface (G78D and A235E); (5) one mutation (P90S) occurred in a residue that is part of, or immediately adjacent to, the EcoRI active site and which is conserved in the distantly related EcoRV endonuclease. Finally, one class of mutants restricted phage in vivo and was active in vitro, whereas a second class did not restrict and was inactive in vitro. The two classes of mutants may differ in kinetic properties or cleavage mechanism. In summary, these mutations provide insights into EcoRI structure and function, and complement previous genetic, biochemical, and structural analyses.     

Xylanase XYL1p from Scytalidium acidophilum: Site-directed mutagenesis and acidophilic adaptation

The role of residues Asp60, Tyr35 and Glu141 in the pH-dependent activity of xylanase XYL1p from Scytalidium acidophilum was investigated by site-directed mutagenesis. These amino acids are highly conserved among the acidophilic family 11 xylanases and located near the catalytic site. XYL1p and its single mutants D60N, Y35W and E141A and three combined mutants DN/YW, DN/EA and YW/EA were over-expressed in Pichia pastoris and purified. Xylanase activities at different pH’s and temperatures were determined. All mutations increased the pH optimum by 0.5–1.5 pH units. All mutants have lower specific activities except the E141A mutant that exhibited a 50% increase in specific activity at pH 4.0 and had an overall catalytic efficiency higher than the wild-type enzyme. Thermal unfolding experiments show that both the wild-type and E141A mutant proteins have a T_m maximum at pH 3.5, the E141A mutant being slightly less stable than the wild-type enzyme. These mutations confirm the importance of these amino acids in the pH adaptation. Mutant E141A with its enhanced specific activity at pH 4.0 and improved overall catalytic efficiency is of possible interest for biotechnological applications.     

Nematicidal activity of Trichoderma spp. and isolation of an active compound

Trichoderma spp. play an important role in biotic control, and several are efficacious against nematodes. To study the potential of Trichoderma species in controlling nematodes, fungal filtrates of 329 Trichoderma strains were evaluated for their nematicidal activity against Panagrellus redivivus and Caenorhabditis elegans. Fifteen strains exhibited nematicidal activity against P. redivivus, and 14 strains showed activity against C. elegans. The strain YMF1.02647 showed strong nematicidal activity against both nematodes, and the culture broth could cause more than 90% mortality to the tested nematodes within 48 h. A nematicidal compound was isolated from ethyl acetate extract of Trichoderma YMF1.02647 based on bioassay-guided fractionation. The compound was identified as trichodermin according to the spectroscopic data, which could kill more than 95% both P. redivivus and C. elegans in 72 h at 0.4 g l⁻¹.     

Surface charge engineering of Thermomyces lanuginosus lipase improves enzymatic activity and biodiesel synthesis

Objectives

This study was aimed at engineering charged residues on the surface of Thermomyces lanuginosus lipase (TLL) to obtain TLL variant with elevated performance for industrial applications.

Results

Site-directed mutagenesis of eight charged amino acids on the TLL surface were conducted and substitutions on the negatively charged residues D111, D158, D165, and E239 were identified with elevated specific activities and biodiesel yields. Synergistic effect was not discovered in the double mutants, D111E/D165E and D165E/E239R, when compared with the corresponding single mutants. One TLL mutant, D165E, was identified with increased specific activity (456.60 U/mg), catalytic efficiency (k_cat/K_m: 44.14 s^?1 mM^?1), the highest biodiesel conversion yield (93.56%), and comparable thermostability with that of the TLL.

Conclusions

Our study highlighted the importance of surface charge engineering in improving TLL activity and biodiesel production, and the resulting TLL mutant, D165E, is a promising candidate for biodiesel industry.

     

Structure-activity relationships of trichothecenes against COLO201 cells and Cochliobolus miyabeanus: The role of 12-epoxide and macrocyclic moieties

The novel trichothecene 12-deoxytrichodermin (3) was isolated from the fungus Trichoderma sp. 1212-03, and included with other known natural trichothecenes in a structure-activity relationship investigation against a human colon cancer cell line (COLO201) and filamentous fungus Cochliobolus miyabeanus. This revealed that the 12-epoxide functionality is critical for the cytotoxicity of simple trichothecenes trichodermin (4) and deoxynivalenol (2), while not critical for the cytotoxicity of roridin J (6) and epiisororidin E (8). In contrast, 12-epoxide is essential for the antifungal activity.     

Site-directed mutagenesis of the succinate dehydrogenase subunits B and D from Corynespora cassiicola reveals different fitness costs and sensitivities to succinate dehydrogenase inhibitors

Carboxamide fungicides target succinate dehydrogenase (SDH). Recently published monitoring studies have shown that Corynespora cassiicola isolates are resistant to one or several SDH inhibitors (SDHIs) with amino acid substitutions in the SDH B and D subunits. We confirmed, by site-directed mutagenesis of the sdhB and sdhD genes, that each of the mutations identified in the field strains of C. cassiicola conferred resistance to boscalid and, in some cases, cross-resistance to other SDHIs (fluopyram, carboxin and penthiopyrad). Analyses of the enzyme activity and sdhB and sdhD gene expression show that modifications (SdhB_H278Y and SdhD_H105R) that result in a decline in SDH enzyme activity may be complemented by gene overexpression. The SdhB_H278Y, SdhB_I280V and SdhD_H105R mutants suffered large fitness penalties based on their biological properties, including conidia production and germination, mycelial growth, pathogenicity or survival abilities under environment stress. However, fitness cost was not found in the SdhB_H278R, SdhD_D95E and SdhD_G109V mutants. In the evaluation of resistance to boscalid in 2018 and 2019, the frequency of the SdhD_D95E and SdhD_G109V genotypes in the Liaoning and Shandong provinces changed dramatically compared with 2005–2017, from low resistance frequency (0.53% for D95E and 2.53% for G109V) to dominant resistance frequency (17.28% for D95E and 15.38% for G109V). Considering both the fitness and increased frequency of these genotypes, we may infer that the SdhD_D95E and SdhD_G109V mutants will be the dominant resistance mutants in field.     

Functional changes in a novel uracil-DNA glycosylase determined by mutational analyses

Uracil-DNA glycosylase (UDG) is a ubiquitous enzyme found in bacteria and eukaryotes, which removes uracil residues from DNA strands. Methanococcus jannaschii UDG (MjUDG), a novel monofunctional glycosylase, contains a helix-hairpin-helix (HhH) motif and a Gly/Pro rich loop (GPD region), which is important for catalytic activity; it shares these features with other glycosylases, such as endonuclease III. First, to examine the role of two conserved amino acid residues (Asp150 and Tyr152) in the HhH-GPD region of MjUDG, mutant MjUDG proteins were constructed, in which Asp150 was replaced with either Glu or Trp (D150E and D150W), and Tyr152 was replaced with either Glu or Asn (Y152E and Y152N). Mutant D150W completely lacked DNA glycosylase activity, whereas D150E displayed reduced activity of about 70% of the wild type value. However, the mutants Y152E and Y152N retained unchanged levels of UDG activity. We also replaced Glu132 in the HhH motif with a lysine residue equivalent to Lys120 in endonuclease III. This mutation converted the enzyme into a bifunctional glycosylase/AP lyase capable of both removing uracil at a glycosylic bond and cleaving the phosphodiester backbone at an AP site. Mutant E132K catalyzes a β-elimination reaction at the AP site via uracil excision and forms a Schiff base intermediate in the form of a protein-DNA complex. This text was submitted by the authors in English.     

Molecular analysis of three major wall-associated proteins of Bacillus subtilis 168: evidence for processing of the product of a gene encoding a 258 kDa precursor two-domain ligand-binding protein

Antisera raised to a 109 kDa wall-associated protein (WAP) of Bacillus subtilis 168 cross-reacts with two other WAPs of 220 and 58 kDa. The structural gene for the 109 kDa WAP (designated wapA) was cloned, sequenced, mapped at around 340° on the B. subtilis 168 chromosome and found to encode a precursor of all three wall-bound forms (2334 amino acids and 258 329 Da). The protein has two ligand-binding domains; the N-terminal domain has three direct repeats of 102 residues with 40% identity, which are responsible for wall binding. The C-terminal domain consists of two blocks of residues with a conserved motif repeated a total of 31 times. The motif consensus sequence GXXXX(Y,F)XYDXXG is almost identical to that of the Escherichia coli rearrangement hot spot family and shows similarity to a carbohydrate-binding motif of a number of Gram-positive secreted proteins. A mutant insertionally inactivated in the wapA gene had no distinguishable phenotype apart from lacking the three WAPs. The possible role of WAPA and its two-domain relationship with other ligand-binding proteins is discussed.     

Formation of catalytically active cross-species heterodimers of thymidylate synthase from <Emphasis Type="Italic">Plasmodium falciparum</Emphasis> and <Emphasis Type="Italic">Plasmodium vivax</Emphasis>

Thymidylate synthase (TS) of Plasmodium dihydrofolate reductase-thymidylate synthase (DHFR-TS) functions as a homodimeric enzyme with two active sites located near the subunit interface. The dimerization is essential for catalysis, since the active site of each subunit contains amino acid residues contributed from the other TS domain. In P. falciparum DHFR-TS, it has been shown that the active sites require Cys-490 from one domain and Arg-470 donated from the other domain. Mutants of these two series can complement one another giving rise to active enzyme. Here, the potential to form cross-species heterodimers between P. falciparum and P. vivax TS has been explored. Formation of cross-species heterodimer was tested by co-transformation of TS-inactive Cys-490 mutants of P. falciparum or P. vivax with corresponding TS-inactive Arg-486 mutants of P. vivax or P. falciparum into thymidine-requiring Escherichia coli. Active heterodimers were detected by subunit complementation and 6-[³H]-FdUMP binding assays. All combinations of the mutants tested, except for (Pf)R470A+(Pv)C506Y, were able to form catalytically active cross-species heterodimers. The single active site formed by (Pf)R470D+(Pv)C506Y and (Pv)R486D+(Pf)C490A pairs of cross-species heterodimers has k _cat and K _m values similar to those of intra-species heterodimers of P. falciparum and P. vivax. This is the first report to demonstrate that the TS subunit interface between Plasmodium species is sufficiently conserved to allow formation of fully active cross-species heterodimer.     

Diversity Profile and Dynamics of Peptaibols Produced by Green Mould Trichoderma Species in Interactions with Their Hosts Agaricus bisporus and Pleurotus ostreatus

Certain Trichoderma species are causing serious losses in mushroom production worldwide. Trichoderma aggressivum and Trichoderma pleuroti are among the major causal agents of the green mould diseases affecting Agaricus bisporus and Pleurotus ostreatus, respectively. The genus Trichoderma is well‐known for the production of bioactive secondary metabolites, including peptaibols, which are short, linear peptides containing unusual amino acid residues and being synthesised via non‐ribosomal peptide synthetases (NRPSs). The aim of this study was to get more insight into the peptaibol production of T. aggressivum and T. pleuroti. HPLC/MS‐based methods revealed the production of peptaibols closely related to hypomurocins B by T. aggressivum, while tripleurins representing a new group of 18‐residue peptaibols were identified in T. pleuroti. Putative NRPS genes enabling the biosynthesis of the detected peptaibols could be found in the genomes of both Trichoderma species. In vitro experiments revealed that peptaibols are potential growth inhibitors of mushroom mycelia, and that the host mushrooms may have an influence on the peptaibol profiles of green mould agents.     

Fermentation,Isolation and Characterization of Isonitrile Antibiotics

A number of soil isolates belonging to the genus Trichoderma were found to produce isonitrins A, B, C and D and isonitrinic acids E and F, a new class of antibiotics characterized by the presence of isonitrile groups. Taxonomy of the producing organisms, fermentation, isolation and physicochemical and biological properties of isonitrins and isonitrinic acids are reported. Isonitrin A showed the highest in vitro antimicrobial activities against gram-positive and negative bacteria and fungi.     

Infrared spectroscopic analysis on structural changes around the protonated Schiff base upon retinal isomerization in light-driven sodium pump KR2

Krokinobacter rhodopsin 2 (KR2) was discovered as the first light-driven sodium pumping rhodopsin (NaR) in 2013, which contains unique amino acid residues on C-helix (N112, D116, and Q123), referred to as an NDQ motif. Based on the recent X-ray crystal structures of KR2, the sodium transport pathway has been investigated by various methods. However, due to complicated structural information around the protonated Schiff base (PRSB) region in the dark state and lack of structural information in the intermediates with sodium bound in KR2, detailed sodium pump mechanism is still unclear. Here we applied comprehensive low-temperature light-induced difference FTIR spectroscopy on isotopically labeled KR2 WT and site-directed mutant proteins (N112A, D116E, R109A, and R109K). We assigned the N-D stretching vibration of the PRSB at 2095 cm⁻¹ and elucidate the hydrogen bonding interaction with D116 (a counter ion for the PRSB). We also assigned strongly hydrogen-bonded water (2333 cm⁻¹) near R109 and D251, and found that presence of a positive charge at the position of R109 is prerequisite for the pumping function of KR2.     

Adopting Selected Hydrogen Bonding and Ionic Interactions from Aspergillus fumigatus Phytase Structure Improves the Thermostability of Aspergillus niger PhyA Phytase

Although it has been widely used as a feed supplement to reduce manure phosphorus pollution of swine and poultry, Aspergillus niger PhyA phytase is unable to withstand heat inactivation during feed pelleting. Crystal structure comparisons with its close homolog, the thermostable Aspergillus fumigatus phytase (Afp), suggest associations of thermostability with several key residues (E35, S42, R168, and R248) that form a hydrogen bond network in the E35-to-S42 region and ionic interactions between R168 and D161 and between R248 and D244. In this study, loss-of-function mutations (E35A, R168A, and R248A) were introduced singularly or in combination into seven mutants of Afp. All seven mutants displayed decreases in thermostability, with the highest loss (25% [P < 0.05]) in the triple mutant (E35A R168A R248A). Subsequently, a set of corresponding substitutions were introduced into nine mutants of PhyA to strengthen the hydrogen bonding and ionic interactions. While four mutants showed improved thermostability, the best response came from the quadruple mutant (A58E P65S Q191R T271R), which retained 20% greater (P < 0.05) activity after being heated at 80°C for 10 min and had a 7°C higher melting temperature than that of wild-type PhyA. This study demonstrates the functional importance of the hydrogen bond network and ionic interaction in supporting the high thermostability of Afp and the feasibility of adopting these structural units to improve the thermostability of a homologous PhyA phytase.     

Complementation of one RecA protein point mutation by another. Evidence for trans catalysis of ATP hydrolysis

The RecA residues Lys248 and Glu96 are closely opposed across the RecA subunit-subunit interface in some recent models of the RecA nucleoprotein filament. The K248R and E96D single mutant proteins of the Escherichia coli RecA protein each bind to DNA and form nucleoprotein filaments but do not hydrolyze ATP or dATP. A mixture of K248R and E96D single mutant proteins restores dATP hydrolysis to 25% of the wild type rate, with maximum restoration seen when the proteins are present in a 1:1 ratio. The K248R/E96D double mutant RecA protein also hydrolyzes ATP and dATP at rates up to 10-fold higher than either single mutant, although at a reduced rate compared with the wild type protein. Thus, the K248R mutation partially complements the inactive E96D mutation and vice versa. The complementation is not sufficient to allow DNA strand exchange. The K248R and E96D mutations originate from opposite sides of the subunit-subunit interface. The functional complementation suggests that Lys248 plays a significant role in ATP hydrolysis in trans across the subunit-subunit interface in the RecA nucleoprotein filament. This could be part of a mechanism for the long range coordination of hydrolytic cycles between subunits within the RecA filament.     

The carboxyl terminal of the archaeal nuclease NurA is involved in the interaction with single-stranded DNA-binding protein and dimer formation

The nuclease NurA is present in all known thermophilic archaea and has been implicated to facilitate efficient DNA double-strand break end processing in Mre11/Rad50-mediated homologous recombinational repair. To understand the structural and functional relationship of this enzyme, we constructed five site-directed mutants of NurA from Sulfolobus tokodaii (StoNurA), D56A, E114A, D131A, Y291A, and H299A, at the conserved motifs, and four terminal deletion mutants, StoNurAΔN (19–331), StoNurAΔNΔC (19–303), StoNurAΔC (1–281), and StoNurAΔC (1–303), and characterized the proteins biochemically. We found that mutation at the acidic residue, D56, E114, D131, or at the basic residue, H299, abolishes the nuclease activity, while mutation at the aromatic residue Y291 only impairs the activity. Interestingly, by chemical cross-linking assay, we found that the mutant Y291A is unable to form stable dimer. Additionally, we demonstrated that deletion of the C-terminal amino acid residues 304–331 of StoNurA results in loss of the physical and functional interaction with the single-stranded DNA-binding protein (StoSSB). These results established that the C-terminal conserved aromatic residue Y291 is involved in dimer formation and the C-terminal residues 304–331 of NurA are involved in the interaction with single-stranded DNA-binding protein.     

Characterization of Mutant HIV-1 Integrase Carrying Amino Acid Changes in the Catalytic Domain

To gain insight into the importance of conserved residues in the core domain of HIV-1 IN, we performed site-directed mutagenesis of the full-length enzyme, overexpressed the mutant proteins in E. coli, purified and analyzed their 3-processing, integration and disintegration activities in vitro. Change of E152V in the DD(35)E motif abolished all detectable activities of IN. Alteration of two highly conserved residues, P145 and K156, by isoleucine, resulted in a substantial loss or completely abolished the three activities of the enzyme. Mutant P90D weakly reduced the 3-processing but severely affected the two other IN activities. Results obtained from double and triple mutations, P90D/P145I and P145I/F185K/C280S, clearly suggest a crucial role of P145 in the catalytic function of IN, whereas the mutants V150E, L158F and L172M had no detectable effect on any of the IN activities. Taken together, these results allowed us to conclude that all the conserved amino acids in the core domain of IN are not equally important for catalytic functions: like D64, D116 and E152, our data suggest that P90, P145 and K156 are also essential for all three enzymatic activities of HIV-1 IN in vitro, whereas V150, L158 and L172 appear to be less critical.     

Active site analysis of <Emphasis Type="Italic">cis</Emphasis>-epoxysuccinate hydrolase from <Emphasis Type="Italic">Nocardia tartaricans</Emphasis> using homology modeling and site-directed mutagenesis

Cis-epoxysuccinate hydrolase (CESH, EC 3.3.2.3) from Nocardia tartaricans is known to catalyze the opening of an epoxide ring of cis-epoxysuccinate (CES), thereby converting it to corresponding vicinal diol, l(+)-tartaric acid. An attempt has been made to build a 3D homology model of CESH to investigate the structure–function relationship, and also to understand the mechanism of the enzymatic reaction. Using a combination of molecular-docking simulation and multiple sequence alignment, a set of putative residues that are involved in the CESH catalysis has been identified. Functional roles of these putative active-site residues were further evaluated by site-directed mutagenesis. Interestingly, the mutants D18A, D18E, Q20E, T22A, R55E, N134D, K164A, H190A, H190N, H190Q, D193A, and D193E resulted in complete loss of activity, whereas the mutants Y58F, T133A, S189A, and Y192D retained partial enzyme activity. Furthermore, the active-site residues responsible for the opening of CES were analyzed, and the mechanism underlying the catalytic triad involved in l(+)-tartaric acid biosynthesis was proposed.