Dual Biosynthesis Pathway for Longer-Chain Polyamines in the Hyperthermophilic Archaeon Thermococcus kodakarensis

Long-chain and/or branched-chain polyamines are unique polycations found in thermophiles. Cytoplasmic polyamines were analyzed for cells cultivated at various growth temperatures in the hyperthermophilic archaeon Thermococcus kodakarensis. Spermidine [34] and N⁴-aminopropylspermine [3(3)43] were identified as major polyamines at 60°C, and the amounts of N⁴-aminopropylspermine [3(3)43] increased as the growth temperature rose. To identify genes involved in polyamine biosynthesis, a gene disruption study was performed. The open reading frames (ORFs) TK0240, TK0474, and TK0882, annotated as agmatine ureohydrolase genes, were disrupted. Only the TK0882 gene disruptant showed a growth defect at 85°C and 93°C, and the growth was partially retrieved by the addition of spermidine. In the TK0882 gene disruptant, agmatine and N¹-aminopropylagmatine accumulated in the cytoplasm. Recombinant TK0882 was purified to homogeneity, and its ureohydrolase characteristics were examined. It possessed a 43-fold-higher k_cat/K_m value for N¹-aminopropylagmatine than for agmatine, suggesting that TK0882 functions mainly as N¹-aminopropylagmatine ureohydrolase to produce spermidine. TK0147, annotated as spermidine/spermine synthase, was also studied. The TK0147 gene disruptant showed a remarkable growth defect at 85°C and 93°C. Moreover, large amounts of agmatine but smaller amounts of putrescine accumulated in the disruptant. Purified recombinant TK0147 possessed a 78-fold-higher k_cat/K_m value for agmatine than for putrescine, suggesting that TK0147 functions primarily as an aminopropyl transferase to produce N¹-aminopropylagmatine. In T. kodakarensis, spermidine is produced mainly from agmatine via N¹-aminopropylagmatine. Furthermore, spermine and N⁴-aminopropylspermine were detected in the TK0147 disruptant, indicating that TK0147 does not function to produce spermine and long-chain polyamines.Polyamines are positively charged aliphatic compounds. Putrescine [4], spermidine [34], and spermine [343] are common polyamines observed in various living organisms, from viruses to humans (16). Polyamines, which play important roles in cell proliferation and cell differentiation (19, 34), are thought to contribute to adaptation against various stresses (9, 26). In thermophilic microorganisms, polyamines contribute to growth under high-temperature conditions. Indeed, in the thermophilic bacterium Thermus thermophilus, a mutant strain lacking the enzyme related to polyamine biosynthesis shows defective growth at high temperatures (23). Furthermore, thermophilic archaea and bacteria possess long-chain and branched-chain polyamines such as N⁴-aminopropylspermidine [3(3)4], N⁴-aminopropylspermine [3(3)43], and N⁴-bis(aminopropyl)spermidine [3(3)(3)4], in addition to common polyamines (11, 13, 14). N⁴-aminopropylspermine was detected in the cells of thermophiles, such as Saccharococcus thermophilus, thermophilic Bacillus and Geobacillus spp. (Bacillus caldolyticus, B. caldotenax, B. smithii, Geobacillus stearothermophilus, and G. thermocatenulatus), Caldicellulosiruptor spp. (C. kristjanssonii and C. owensensis) and Calditerricola spp. (C. satsumensis and C. yamamurae) (10, 12, 22), but it was not detected in archaea. These unique polyamines are thought to support the growth of thermophilic microorganisms under high-temperature conditions. An in vitro study indicated that long-chain and branched-chain polyamines effectively stabilized DNA and RNA, respectively (32).Polyamines are synthesized from amino acids such as arginine, ornithine, and methionine (26). In most eukaryotes, putrescine is synthesized directly from ornithine by ornithine decarboxylase (34). Plants and some bacteria possess additional or alternative putrescine biosynthesis pathways in which putrescine is synthesized from arginine via agmatine (18, 31, 35). In this pathway, agmatine is synthesized by arginine decarboxylase, and agmatine is converted to putrescine by agmatine ureohydrolase or a combination of agmatine iminohydrolase and N-carbamoylputrescine amidohydrolase. Longer polyamines are then produced by the addition of the aminopropyl group from decarboxylated S-adenosylmethionine. This pathway is shown on the left in Fig. ​Fig.11 (pathway I). On the other hand, the thermophilic bacterium T. thermophilus possesses a unique polyamine-biosynthetic pathway (23) in which spermidine is synthesized from agmatine via N¹-aminopropylagmatine by aminopropyl transferase followed by ureohydrolase, as shown on the right in Fig. ​Fig.11 (pathway II).Open in a separate windowFIG. 1.Predicted biosynthetic pathway of polyamines in T. kodakarensis. (A) Predicted biosynthetic pathway. Pyruvoyl-dependent arginine decarboxylase proenzyme (TK0149), arginine/agmatine ureohydrolases (TK0240/TK0474/TK0882), aminopropyl transferase (TK0147), and pyruvoyl-dependent S-adenosylmethionine decarboxylase proenzyme (TK1592) are shown based on the genome analysis. (B) Structures of unique polyamines.A sulfur-reducing hyperthermophilic archaeon, Thermococcus kodakarensis KOD1, was isolated from Kodakara Island, Kagoshima, Japan (1, 21). This archaeon grows at temperatures between 60°C and 100°C but optimally at 85°C. Under low- or high-temperature-stressed conditions, T. kodakarensis produces cold- or heat-inducible chaperones to adapt to unfavorable growth environments (4, 5, 30). The lipid composition of the membrane also changes depending on the growth shift (20). In addition to acting as such tolerance factors, polyamines have been suggested to play an important role in maintaining nucleosomes in high-temperature environments (15). A complete genome analysis of T. kodakarensis has been performed, and the pathway of polyamine biosynthesis has been predicted (Fig. ​(Fig.1)1) (6, 7). It has been speculated that putrescine is synthesized from arginine via agmatine by arginine decarboxylase (PdaD_Tk) and agmatine ureohydrolase. Long- and/or branched-chain polyamines are then produced by the addition of the aminopropyl group derived from decarboxylated S-adenosylmethionine. Previously, we revealed that PdaD_Tk catalyzed the first step of polyamine biosynthesis and was essential for cell growth (6). The strain DAD, which lacks the gene pdaD_Tk, does not grow in medium without agmatine. Archaeal cells are known to use agmatine to synthesize agmatidine, which is an agmatine-conjugated cytidine found at the anticodon wobble position of archaeal tRNA^Ile (17). Agmatine is important for agmatidine synthesis as well as long-chain polyamine. In the present study, we focused on the subsequent steps in polyamine biosynthesis, especially from agmatine to spermidine. T. kodakarensis possesses three agmatine ureohydrolase homologues (TK0240, TK0474, and TK0882); however, it is unclear which one is dominantly functional in T. kodakarensis cells. In a closely related genus, Pyrococcus, TK0474 and TK0882 orthologues have been identified, but the TK0240 orthologue is missing in Pyrococcus genomes. In Pyrococcus horikoshii, PH0083, which is an orthologue of TK0882, was shown to possess agmatine ureohydrolase activity (8). TK0882, hence, appears to possess agmatine ureohydrolase activity as well. It is unclear whether other agmatine ureohydrolase homologues (TK0240 and TK0474) are involved in polyamine synthesis and cell growth in T. kodakarensis. In addition to agmatine ureohydrolase, aminopropyl transferase plays a crucial role in the synthesis of polyamines. TK0147 was annotated first as spermidine synthase and shares sequence identity with aminopropyl transferase (PF0127) from Pyrococcus furiosus (3). It is therefore expected to harbor the function of aminopropyl transferase for long-chain-polyamine synthesis. Recombinant PF0127 showed broad amine acceptor specificity for agmatine, 1,3-diaminopropane (3), putrescine, cadaverine (5), sym-nor-spermidine (33), and spermidine. While maximal catalytic activity was observed with cadaverine, agmatine was most often preferred on the basis of the k_cat/K_m value (3), suggesting that pathway II is a dominant route for polyamine synthesis in P. furiosus. In the present study, various disruptants lacking genes for polyamine biosynthesis were constructed in order to understand the physiological roles of these enzymes in T. kodakarensis. The cell growth profiles and cytoplasmic polyamines of the wild type and the disruptants were analyzed and compared. Recombinant enzymes were also purified and characterized. The obtained results are expected to provide useful information regarding the specific roles of polyamines in thermophiles.     

The scaling rule for environmental organizing systems in a gravitational field

A recent thermodynamics and information study examined the basis of a scaling rule for simple living organisms. The present paper examines a scaling rule for the relationship between the integrated scaled metabolic energy and the mass of a system for a wide range of masses, from animals to the 4He cores of main-sequence stars, considering the effect of gravitational energy. The expected specific scaled energy for animals and the 4He cores of main-sequence stars is 1600 times greater than the specific scaled energy for fundamental living organisms, such as unicellular organisms. This difference results from their organization in a gravitational field or the lack thereof.     

Rediagnosis of the monotypic genus Lepadicyathus Prokofiev 2005 (Gobiesocidae: Diademichthyinae) and redescription of Lepadicyathus minor (Briggs 1955), new combination

Ichthyological Research - A revised diagnosis is provided for the poorly known clingfish genus Lepadicyathus Prokofiev 2005. The genus belongs to Diademichthyinae (sensu Conway et al.) and is...     

Rat tripeptidyl peptidase I: molecular cloning, functional expression, tissue localization and enzymatic characterization

We purified tripeptidyl peptidase I (TPP I) to homogeneity from a rat kidney lysosomal fraction and determined its physicochemical properties, including its molecular weight, substrate specificity and partial amino acid sequence. The molecular weight of the enzyme was calculated to be 280,000 and 290,000 by non-denaturing PAGE and gel filtration, respectively, and to be 43 000 and 46 000 on SDS-PAGE in the absence and presence of beta-ME, respectively. These findings suggest that the enzyme is composed of six identical subunits. The Km, Vmax, kcat and kcat/Km values of TPP I at optimal pH (pH 4.0) were 680 microM, 3.7 micromol x mg(-1) x min(-1), 33.1 s(-1) and 4.87 x 10(4) s(-1) x M(-1) for Ala-Ala-Phe-MCA, respectively. TPP I was significantly inhibited by PCMBS and HgCl2, and moderately by DFP. These findings also suggest that TPP I is an exotype serine peptidase that is regulated by SH reagent. TPP I released the tripeptide Arg-Val-Tyr from angiotensin III more rapidly than from Ala-Ala-Phe-MCA, and also released Gly-Asn-Leu from neuromedin B with the same velocity as from Ala-Ala-Phe-MCA. Angiotensin III and neuromedin B have recently been found to be good natural substrates for lysosomal TPP I. Furthermore, we determined the rat liver cDNA structure and deduced the amino acid sequence. The cDNA, designated as lambdaRTI-1, is composed of 2485 bp and encodes 563 amino acids in the coding region. By Northern blot analysis, the order for TPP I mRNA expression was kidney > or = liver > heart > brain > lung > spleen > skeletal muscle and testis. In parallel experiments, the TPP I antigen was detected in various rat tissues by immunohistochemical staining.     

The complete mitogenome of the hydrothermal vent crab Gandalfus yunohana (Crustacea: Decapoda: Brachyura): a link between the Bythograeoidea and Xanthoidea

Yang, J.‐S., Nagasawa, H., Fujiwara, Y., Tsuchida, S. & Yang, W.‐J. The complete mitogenome of the hydrothermal vent crab Gandalfus yunohana (Crustacea: Decapoda: Brachyura): a link between the Bythograeoidea and Xanthoidea. —Zoologica Scripta, 39, 621–630. Metazoan mitochondrial genomes (mitogenomes) are often used for all‐level phylogenetic analyses and evolution modelling. Although mitochondrial fragments facilitate studying the occurrence and dispersal of hydrothermal‐vent species, few complete mitogenomes have been determined for comprehensive analyses. We determined the complete nucleotide sequence of the bythograeid crab Gandalfus yunohana. The G. yunohana mitogenome is 15 567 bp in length and with an AT content of 69.9%. A putative control region of 625 bp was identified due to its position (between rrnS and trnI) and AT richness (72.8%), which exhibits high similarity with that of the Australian giant crab Pseudocarcinus gigas. The mitochondrial gene order is identical to the typical brachyuran mode. Codon usage, nucleotide composition and bias are well conserved as the Brachyura. Phylogenetic analyses from protein‐coding genes indicated its closest relationship with P. gigas. All the results support the close evolution distance between the Bythograeoidea and Xanthoidea, which might imply the possible origin that the only superfamily of vent crabs underwent. The G. yunohana mitogenome exhibits highly conserved characteristics with those of other decapods, especially its close relative brachyurans. A recent origin rather than the relic fauna was suggested. The present study will supply considerable data of use for both genomics and evolutionary research on hydrothermal vent ecosystems.     

Two new modes of smooth muscle myosin regulation by the interaction between the two regulatory light chains, and by the S2 domain

Previous studies indicated that single-headed smooth muscle myosin and S1 (a single head fragment) are not regulated through phosphorylation of the regulatory light chain (RLC). To investigate the importance of the double-headedness of myosin and of the S2 region for the phosphorylation-dependent regulation, we made three types of recombinant mutant smooth muscle HMMs with one intact head and an N-terminally truncated head. The truncated head of Delta MD lacked the motor domain, that of Delta(MD+ELC) lacked the motor and essential light chain binding domains, and single-headed HMM had one intact head alone. The basal ATPase activities of the three mutants decreased as the KCl concentration became less than 0.1 M. Such a decrease was not observed for S1, which had no S2 region, suggesting that S2 is necessary for this myosin behavior. This activity decrease also disappeared when RLCs of Delta MD and Delta(MD+ELC), but that of single-headed HMM, were phosphorylated. When their RLCs were unphosphorylated, the three mutants exhibited similar actin-activated ATPase levels. However, when they were phosphorylated, the actin-activated ATPase activities of Delta MD and Delta(MD+ELC) increased to the S1 level, while that of single-headed HMM remained unchanged. Even in the phosphorylated state, the actin-activated ATPase activities of the three mutants and S1 were much lower than that of wild-type HMM. We propose that S2 has an inhibitory function that is canceled by an interaction between two phosphorylated RLCs. We also propose that a cooperative interaction between two motor domains is required for a higher level of actin activation.