Genome assembly of Genji firefly (Nipponoluciola cruciata) reveals novel luciferase-like luminescent proteins without peroxisome targeting signal.

The Genji firefly, Nipponoluciola cruciata, is an aquatic firefly endemic to Japan, inhabiting a wide area of the Japanese archipelago. The luminescence of fireflies is a scientifically interesting phenomenon, and many studies have evaluated this species in Japan. In this study, we sequenced the whole genome of male N. cruciata and constructed a high-quality genome assembly of 662 Mb with a BUSCO completeness of 99.1% in the genome mode. Using the detected set of 15,169 protein-coding genes, the genomic structures and genetic background of luminescence-related genes were also investigated. We found four new firefly luciferase-like genes in the genome. The highest bioluminescent activity was observed for LLa2, which originated from ancestral PDGY, a mitochondrial acyl-CoA synthetase. A thioesterase candidate, NcruACOT1, which is involved in d-luciferin biosynthesis, was expressed in the lantern. Two opsins were also detected and the absorption wavelength of the UV-type opsin candidate shifted from UV to blue. These findings provide an important resource for unravelling the adaptive evolution of fireflies in terms of luminescence and vision.

Diversity and evolution of serotonergic cells in taste buds of elasmobranchs and ancestral actinopterygian fish.

A subset of gustatory cells are serotonin immunoreactive (ir) in the mammalian taste bud. In the taste bud of lamprey, elongated gustatory-like cells are also serotonin-ir. In contrast, flattened serotonin-ir cells are located only in the basal region of the taste buds in the teleosts and amphibians. These serotonin-ir cells are termed as basal cells. To evaluate the evolution and diversity of serotonergic cells in the taste bud of amniote animals, we explored the distribution and morphology of serotonin-ir cells in the taste buds of ancestral actinopterygian fish (spotted gar, sturgeon, Polypterus senegalus) and elasmobranch (stingray). In all examined animals, the taste buds contained serotonin-ir cells in their basal part. The number of serotonin-ir basal cells in each taste bud was different between these fish species. They were highest in the stingray and decreased in the order of the Polypterus, sturgeon, and gar. While serotonin immunoreactivity was observed only in the basal cells in the taste buds of the ancestral actinopterygian fish, some elongated cells were also serotonin-ir in addition to the basal cells in the stingray taste buds. mRNA of tryptophan hydroxylase 1 (tph1), a rate-limiting enzyme of the serotonin synthesis, is expressed in both the elongated and basal cells of stingray taste buds, indicating that these cells synthesize the serotonin by themselves. These results suggest that the serotonin-ir basal cells arose from the ancestor of the cartilaginous fish, and serotonin-ir cells in the elasmobranch taste bud exhibit an intermediate aspect between the lamprey and actinopterygian fish.

X-ray crystallographic and mutational analysis of the NylC precursor: catalytic mechanism of autocleavage and substrate hydrolysis of nylon hydrolase.

Nylon hydrolase (NylC), a member of the N-terminal nucleophile (Ntn) hydrolase superfamily, is responsible for the degradation of various aliphatic nylons, including nylon-6 and nylon-66. NylC is initially expressed as an inactive precursor (36 kDa), but the precursor is autocatalytically cleaved at Asn266/Thr267 to generate an active enzyme composed of 27 and 9 kDa subunits. We isolated various mutants with amino acid changes at the catalytic centre. X-ray crystallographic analysis revealed that the NylC precursor forms a doughnut-shaped quaternary structure composed of four monomers (molecules A-D) with D2 symmetry. Catalytic residues in the precursor are covered by loop regions at the A/B interface (equivalent to the C/D interface). However, the catalytic residues are exposed to the solvent environment through autocleavage followed by movements of the loop regions. T267A, D306A and D308A mutations resulted in a complete loss of autocleavage. By contrast, in the T267S mutant, autocleavage proceeded slowly at a constant reaction rate (k = 2.8 × 10-5  s-1 ) until complete conversion, but the reaction was inhibited by K189A and N219A mutations. Based on the crystallographic and molecular dynamic simulation analyses, we concluded that the Asp308-Asp306-Thr267 triad, resembling the Glu-Ser-Ser triad conserved in Ntn-hydrolase family enzymes, is responsible for autocleavage and that hydrogen-bonding networks connecting Thr267 with Lys189 and Asn219 are required for increasing the nucleophilicity of Thr267-OH in both the water accessible and water inaccessible systems. Furthermore, we determined that NylC employs the Asp308-Asp306-Thr267 triad as catalytic residues for substrate hydrolysis, but the reaction requires Lys189 and Tyr146 as additional catalytic/substrate-binding residues specific for nylon hydrolysis.

Biosynthesis-Inspired Deracemizative Production of D-Luciferin In Vitro by Combining Luciferase and Thioesterase.

Due to the strict enantioselectivity of firefly luciferase (FLuc), only D-luciferin can be used as a substrate for the bioluminescence (BL) reaction. Unfortunately, luciferin racemizes easily and accumulation of nonluminous L-luciferin has negative influences on the light-emitting reaction. By a detailed analysis of luciferin chirality, however, it becomes clarified that L-luciferin is the biosynthetic precursor of D-luciferin in fireflies and undergoes the enzymatic chiral inversion. By the chiral inversion reaction, the enantiopurity of luciferin can be maintained in the reaction mixture for applications using FLuc. Thus, chirality is crucial for the BL reaction and essential for investigating and applying the biosynthesis of D-luciferin. Here, we describe the methods for the analysis of chiral inversion reaction using high-performance liquid chromatography (HPLC) with a chiral column. We also introduce an example of an in vitro deracemizative BL reaction system using a combination of FLuc and fatty acyl-CoA thioesterase, which is inspired by the chiral inversion mechanism in the biosynthetic pathway of D-luciferin.

Immobilization of Baeyer-Villiger monooxygenase from acetone grown Fusarium sp.

OBJECTIVE: A novel biocatalyst for Baeyer-Villiger oxidations is necessary for pharmaceutical and chemical industries, so this study aims to find a Baeyer-Villiger monooxygenase (BVMO) and to improve its stability by immobilization. RESULTS: Acetone, the simplest ketone, was selected as the only carbon source for the screening of microorganisms with a BVMO. A eukaryote, Fusarium sp. NBRC 109816, with a BVMO (FBVMO), was isolated from a soil sample. FBVMO was overexpressed in E. coli and successfully immobilized by the organic-inorganic nanocrystal formation method. The immobilization improved the thermostability of FBVMO. Substrate specificity investigation revealed that both free and immobilized FBVMO were found to show catalytic activities not only for Baeyer-Villiger oxidation of ketones to esters but also for oxidation of sulfides to sulfoxides. Furthermore, a preparative scale reaction using immobilized FBVMO was successfully conducted. CONCLUSIONS: FBVMO was discovered from an environmental sample, overexpressed in E. coli, and immobilized by the organic-inorganic nanocrystal formation method. The immobilization successfully improved its thermostability.

Morphological analysis of the cerebellum and its efferent system in a basal actinopterygian fish, Polypterus senegalus.

Although all vertebrate cerebella contain granule cells, Purkinje cells, and efferent neurons, the cellular arrangement and neural circuitry are highly diverse. In amniotes, cerebellar efferent neurons form clusters, deep cerebellar nuclei, lie deep in the cerebellum, and receive synaptic inputs from Purkinje cells but not granule cells. However, in the cerebellum of teleosts, the efferent neurons, called eurydendroid cells, lie near the cell bodies of Purkinje cells and receive inputs both from axons of Purkinje cells and granule cell parallel fibers. It is largely unknown how the cerebellar structure evolved in ray-finned fish (actinopterygians). To address this issue, we analyzed the cerebellum of a bichir Polypterus senegalus, one of the most basal actinopterygians. We found that the cell bodies of Purkinje cells are not aligned in a layer; incoming climbing fibers terminate mainly on the basal portion of Purkinje cells, revealing that the Polypterus cerebellum has unique features among vertebrate cerebella. Retrograde labeling and marker analyses of the efferent neurons revealed that their cell bodies lie in restricted granular areas but not as deep cerebellar nuclei in the cerebellar white matter. The efferent neurons have long dendrites like eurydendroid cells, although they do not reach the molecular layer. Our findings suggest that the efferent system of the bichir cerebellum has intermediate features between teleosts and amniote vertebrates, and provides a model to understand the basis generating diversity in actinopterygian cerebella.

Structural and functional characterization of nylon hydrolases.

Biodegradation of synthetic polymers is recognized as a useful way to reduce their environmental load and pollution, loss of natural resources, extensive energy consumption, and generation of greenhouse gases. The potential use of enzymes responsible for the degradation of the targeted polymers is an effective approach which enables the conversion of the used polymers to original monomers and/or other useful compounds. In addition, the enzymes are expected to be applicable in industrial processes such as improving the surface structures of the polymers. Especially, conversion of the solid polymers to soluble oligomers/monomers is a key step for the biodegradation of the polymers. Regarding the hydrolysis of polyamides, three enzymes, 6-aminohexanoate-cyclic-dimer hydrolase (NylA), 6-aminohexanoate-dimer hydrolase (NylB), and 6-aminohexanoate-oligomer endo-hydrolase (nylon hydrolase, NylC), are found in several bacterial strains. In this chapter, we describe our approach for the screening of microorganisms which degrade nylons and related compounds; preparation of substrates; assay of hydrolytic activity for soluble and insoluble substrates; and X-ray crystallographic and computational approaches for analysis of structure and catalytic mechanisms of the nylon-degrading enzymes.

Evaluation of the population structure and phylogeography of the Japanese Genji firefly, Luciola cruciata, at the nuclear DNA level using RAD-Seq analysis.

The Genji firefly, Luciola cruciata, is widely distributed throughout the major Japanese islands (Honshu, Shikoku, and Kyushu) and distinguished into two ecological types on the basis of the flash interval of the mate-seeking males (4-sec slow-flash or 2-sec fast-flash intervals). The boundary of the ecological types corresponds to the Fossa Magna, a great rupture zone that separates eastern and western Japan. Although the degree of genetic differentiation of the two types has been evaluated using allozyme and mitochondrial DNA sequence data, it has not been evaluated using genome-wide data. Based on the genome-wide data obtained using single-end restriction-site-associated DNA (RAD-Seq), principal component, gene-level phylogenetic tree, admixture, and Wright's fixation index analyses, we identified three phylogenetic groups in L. cruciata: East-Honshu, West-Honshu, and Kyushu. This grouping corresponds to the ecological types: East-Honshu to the slow-flash type and West-Honshu and Kyushu to the fast-flash type. Although introgression was exceptionally observed around adjacent or artificially transplanted areas, gene flow among the groups was almost absent in the natural populations. The phylogenetic tree under the coalescent model also evaluated differentiation among the East-Honshu, West-Honshu and Kyushu groups. Furthermore, because the distribution patterns of the three groups are consistent with the geological history of Japanese islands, a vicariant speciation scenario of L. cruciata is concluded. In addition, we identified genetic markers that can be used to distinguish the three genetic groups for genetic management of firefly transplantation in nature conservation and regeneration.

Efficient Screening and Design of Variable Domain of Heavy Chain Antibody Ligands Through High Throughput Sequencing for Affinity Chromatography to Purify Fab Fragments.

To design an affinity ligand for purification of antigen-binding fragment (Fab) antibody, variable domain of heavy chain antibody (VHH) phage libraries were constructed from Fab-immunized Alpaca and subjected to biopanning against Fabs. To find the specific binders, we directly applied high-throughput sequencing (HTS) analysis of the VHH sequences in the panned phages on next-generation sequencer. The efficiently enriched sequences were aligned for construction of the phylogenetic tree to be categorized into five groups. VHHs from three major groups were first selected to analyze their properties as an affinity ligand. However, those VHHs were not suitable as an affinity ligand because of lack of resistance against alkaline pH and/or difficulty in acidic elution from the affinity column. So, we further searched the candidates from minor group sequences. Among five, one VHH showed the binding ability but with low affinity against Fabs. Therefore, we improved its affinity-by-affinity maturation through error-prone PCR library techniques. The final designed VHH showed highly alkaline pH resistance and easy acidic elution together with high affinity to Fabs. These results indicate that HTS techniques combined with biopanning and followed by error-prone PCR library techniques is powerful in designing specific binders with desired properties.

Structural basis of the correct subunit assembly, aggregation, and intracellular degradation of nylon hydrolase.

Nylon hydrolase (NylC) is initially expressed as an inactive precursor (36 kDa). The precursor is cleaved autocatalytically at Asn266/Thr267 to generate an active enzyme composed of an α subunit (27 kDa) and a ß subunit (9 kDa). Four αß heterodimers (molecules A-D) form a doughnut-shaped quaternary structure. In this study, the thermostability of the parental NylC was altered by amino acid substitutions located at the A/D interface (D122G/H130Y/D36A/L137A) or the A/B interface (E263Q) and spanned a range of 47 °C. Considering structural, biophysical, and biochemical analyses, we discuss the structural basis of the stability of nylon hydrolase. From the analytical centrifugation data obtained regarding the various mutant enzymes, we conclude that the assembly of the monomeric units is dynamically altered by the mutations. Finally, we propose a model that can predict whether the fate of the nascent polypeptide will be correct subunit assembly, inappropriate protein-protein interactions causing aggregation, or intracellular degradation of the polypeptide.

Characterization of the 3-methyl-4-nitrophenol degradation pathway and genes of Pseudomonas sp. strain TSN1.

3-Methyl-4-nitrophenol (3M4NP) is formed in soil as a hydrolysis product of fenitrothion, one of the major organophosphorus pesticides. A Pseudomonas strain was isolated as a 3M4NP degrader from a crop soil and designated TSN1. This strain utilized 3M4NP as a sole carbon and energy source. To elucidate the biodegradation pathway, we performed transposon mutagenesis with pCro2a (mini-Tn5495) and obtained three mutants accumulating a dark pink compound(s) from 3M4NP. Rescue cloning and sequence analysis revealed that in all mutants, the transposon disrupted an identical aromatic compound meta-cleaving dioxygenase gene, and a monooxygenase gene was located just downstream of the dioxygenase gene. These two genes were designated mnpC and mnpB, respectively. The gene products showed high identity with the methylhydroquinone (MHQ) monooxygenase (58%) and the 3-methylcatechol 2,3-dioxygenase (54%) of a different 3M4NP degrader Burkholderia sp. NF100. The transposon mutants converted 3M4NP or MHQ into two identical metabolites, one of which was identified as 2-hydroxy-5-methyl-1,4-benzoquinone (2H5MBQ) by GC/MS analysis. Furthermore, two additional genes (named mnpA1 and mnpA2), almost identical to the p-nitrophenol monooxygenase and the p-benzoquinone reductase genes of Pseudomonas sp. WBC-3, were isolated from the total DNA of strain TSN1. Disruption of mnpA1 resulted in the complete loss of the 3M4NP degradation activity, demonstrating that mnpA1 encodes the initial monooxygenase for 3M4NP degradation. The purified mnpA2 gene product could efficiently reduce methyl p-benzoquinone (MBQ) into MHQ. These results suggest that strain TSN1 degrades 3M4NP via MBQ, MHQ, and 2H5MBQ in combination with mnpA1A2 and mnpCB, existing at different loci on the genome.

Correction to: Metabolic pathway of 6-aminohexanoate in the nylon oligomer-degrading bacterium Arthrobacter sp. KI72: identification of the enzymes responsible for the conversion of 6-aminohexanoate to adipate.

The original publication of this paper contains mistakes for Tables 1 and 2 legends as well as the sublabels in Figs. 2, 4, 5, 6, and 7.

Metabolic pathway of 6-aminohexanoate in the nylon oligomer-degrading bacterium Arthrobacter sp. KI72: identification of the enzymes responsible for the conversion of 6-aminohexanoate to adipate.

Arthrobacter sp. strain KI72 grows on a 6-aminohexanoate oligomer, which is a by-product of nylon-6 manufacturing, as a sole source of carbon and nitrogen. We cloned the two genes, nylD 1 and nylE 1 , responsible for 6-aminohexanoate metabolism on the basis of the draft genomic DNA sequence of strain KI72. We amplified the DNA fragments that encode these genes by polymerase chain reaction using a synthetic primer DNA homologous to the 4-aminobutyrate metabolic enzymes. We inserted the amplified DNA fragments into the expression vector pColdI in Escherichia coli, purified the His-tagged enzymes to homogeneity, and performed biochemical studies. We confirmed that 6-aminohexanoate aminotransferase (NylD1) catalyzes the reaction of 6-aminohexanoate to adipate semialdehyde using α-ketoglutarate, pyruvate, and glyoxylate as amino acceptors, generating glutamate, alanine, and glycine, respectively. The reaction requires pyridoxal phosphate (PLP) as a cofactor. For further metabolism, adipate semialdehyde dehydrogenase (NylE1) catalyzes the oxidative reaction of adipate semialdehyde to adipate using NADP+ as a cofactor. Phylogenic analysis revealed that NylD1 should be placed in a branch of the PLP-dependent aminotransferase sub III, while NylE1 should be in a branch of the aldehyde dehydrogenase superfamily. In addition, we established a NylD1/NylE1 coupled system to quantify the aminotransferase activity and to enable the conversion of 6-aminohexaoate to adipate via adipate semialdehyde with a yield of > 90%. In the present study, we demonstrate that 6-aminohexanoate produced from polymeric nylon-6 and nylon oligomers (i.e., a mixture of 6-aminohexaoate oligomers) by nylon hydrolase (NylC) and 6-aminohexanoate dimer hydrolase (NylB) reactions are sequentially converted to adipate by metabolic engineering technology.

IgY-binding peptide screened from a random peptide library as a ligand for IgY purification.

Chicken egg yolk immunoglobulin (IgY) is a functional substitute for mammalian IgG for antigen detection. Traditional IgY purification methods involve multi-step procedures resulting in low purity and recovery of IgY. In this study, we developed a simple IgY purification system using IgY-specific peptides identified by T7 phage display technology. From disulfide-constrained random peptide libraries constructed on a T7 phage, we identified three specific binding clones (Y4-4, Y5-14, and Y5-55) through repeated biopanning. The synthetic peptides showed high binding specificity to IgY-Fc and moderate affinity for IgY-Fc (Kd : Y4-4 = 7.3 ± 0.2 µM and Y5-55 = 4.4 ± 0.1 µM) by surface plasmon resonance analysis. To evaluate the ability to purify IgY, we performed immunoprecipitation and affinity high-performance liquid chromatography using IgY-binding peptides; the result indicated that these peptides can be used as affinity ligands for IgY purification. We then used a peptide-conjugated column to purify IgY from egg yolks pre-treated using an optimized delipidation technique. Here, we report the construction of a cost-effective, one-step IgY purification system, with high purity and recovery. © 2017 The Authors. Journal of Peptide Science published by European Peptide Society and John Wiley & Sons Ltd.

Biosynthesis-inspired deracemizative production of d-luciferin by combining luciferase and thioesterase.

Due to the strict enantioselectivity of firefly luciferase, only d-luciferin can be used as a substrate for bioluminescence reactions. Unfortunately, luciferin racemizes easily and accumulation of nonluminous l-luciferin has negative influences on the light emitting reaction. Thus, maintaining the enantiopurity of luciferin in the reaction mixture is one of the most important demands in bioluminescence applications using firefly luciferase. In fireflies, however, l-luciferin is the biosynthetic precursor of d-luciferin, which is produced from the L-form undergoing deracemization. This deracemization consists of three successive reactions: l-enantioselective thioesterification by luciferase, in situ epimerization, and hydrolysis by thioesterase. In this work, we introduce a deracemizative luminescence system inspired by the biosynthetic pathway of d-luciferin using a combination of firefly luciferase from Luciola cruciata (LUC-G) and fatty acyl-CoA thioesterase II from Escherichia coli (TESB). The enzymatic reaction property analysis indicated the importance of the concentration balance between LUC-G and TESB for efficient d-luciferin production and light emission. Using this deracemizative luminescence system, a highly sensitive quantitative analysis method for l-cysteine was constructed. This LUC-G-TESB combination system can improve bioanalysis applications using the firefly bioluminescence reaction by efficient deracemization of D-luciferin.

Draft Genome Sequence of the Nylon Oligomer-Degrading Bacterium Arthrobacter sp. Strain KI72.

We report here the 4.6-Mb genome sequence of a nylon oligomer-degrading bacterium, Arthrobacter sp. strain KI72. The draft genome sequence of strain KI72 consists of 4,568,574 bp, with a G+C content of 63.47%, 4,372 coding sequences (CDSs), 54 tRNAs, and six rRNAs.

The complete mitochondrial genome sequence and phylogenetic analysis of Luciola lateralis, one of the most famous firefly in Japan (Coleoptera: Lampyridae).

We will report the complete mitochondrial genome sequence of Japanese firefly 'Heike Botaru', Luciola lateralis (Coleoptera: Lampyridae). Total length of this mitogenome was 16,719 bp and the composition of each base was A (42.50%), C (9.01%), G (14.16%), T (34.33%), respectively. The obtained sequence fulfils general mitogenome composition of metazoan (13 protein coding sequences (CDSs), 22 tRNA genes, two rRNA subunits, and an AT-rich region). From the phylogenetic tree analysis using 25 kinds of insect mitogenome including firefly family was found that L. lateralis is the closest to the genus Aquatica.

The complete mitogenome and phylogenetic analysis of Japanese firefly 'Genji Botaru' Luciola cruciata (Coleoptera: Lampyridae).

We performed mitogenome analysis of Japanese firefly Luciola cruciata (Coleoptera: Lampyridae), which is unique species in Japan. It is classified into six haplotypes based on the difference of COII sequence on mitochondrial DNA. The complete mitogenome sequence of Tohoku group has been registered so far, we newly analysed West Japan groups which belong to different haplotype. The total length of analysed mitogenome was 15,990 bp, being one base longer than the case of Tohoku's firefly. The base substitution was found at 273 positions over the whole mitochondrial sequence, while amino acid substitution accompanying it was observed at only 11 positions.

Structural basis of cucumisin protease activity regulation by its propeptide.

Cucumisin [EC 3.4.21.25], a subtilisin-like serine endopeptidase, was isolated from melon fruit, Cucumis melo L. Mature cucumisin (67 kDa, 621 residues) is produced by removal of the propeptide (10 kDa, 88 residues) from the cucumisin precursor by subsequence processing. It is reported that cucumisin is inhibited by its own propeptide. The crystal structure of mature cucumisin is reported to be composed of three domains: the subtilisin-like catalytic domain, the protease-associated domain and the C-terminal fibronectin-III-like domain. In this study, the crystal structure of the mature cucumisin•propeptide complex was determined by the molecular replacement method and refined at 1.95 Å resolution. In this complex, the propeptide had a domain of the α-ß sandwich motif with four-stranded antiparallel ß-sheets, two helices and a strand of the C-terminal region. The ß-sheets of the propeptide bind to two parallel surface helices of cucumisin through hydrophobic interaction and 27 hydrogen bonds. The C-terminus of the propeptide binds to the cleft of the active site as peptide substrates. The inhibitory assay suggested that the C-terminal seven residues of the propeptide do not inhibit the cucumisin activity. The crystal structure of the cucumisin•propeptide complex revealed the regulation mechanism of cucumisin activity.

Mutations affecting the internal equilibrium of the reaction catalyzed by 6-aminohexanoate-dimer hydrolase.

UNLABELLED: The enzyme 6-aminohexanoate-dimer hydrolase catalyzes amide synthesis. The yield of this reverse reaction in 90% t-butyl alcohol was found to vary drastically when enzyme mutants with substitutions of several amino acids located at the entrance of the catalytic cleft were used. Movement of the loop region and the flip-flop of Tyr170 generate a local hydrophobic environment at the catalytic center of the enzyme. Here, we propose that the shift of the internal equilibrium between the enzyme-substrate complex and enzyme-product complex by the 'water-excluding effect' alters the rate of the forward and reverse reactions. Moreover, we suggest that the local hydrophobic environment potentially provides a reaction center suitable for efficient amide synthesis. DATABASE: PDB code 3VWL: Hyb-24DNY-S(187) PDB code 3VWM: Hyb-24DNY-A(187) PDB code 3VWN: Hyb-24DNY-G(187) PDB code 3A65: Hyb-24DN-A(112) /Ahx complex PDB code 3A66: Hyb-24DNY-A(112) /Ahx complex PDB code 3VWP: Hyb-24DNY-S(187) A(112) /Ahx complex PDB code 3VWQ: Hyb-24DNY-A(187) A(112) /Ahx complex PDB code 3VWR: Hyb-24DNY-G(187) A(112) /Ahx complex.