A novel factor required for the assembly of the DnaK and DnaJ chaperones of Thermus thermophilus

We previously reported the isolation of T.DnaK.DnaJ chaperone complex from Thermus thermophilus. Here, we show that a novel factor is necessary for the assembly of T.DnaK and T.DnaJ into the complex. A dnaK gene cluster of T. thermophilus contained five genes, dnaK-grpE-dnaJ-orf4-clpB. Interestingly, T.DnaJ lacks the whole "cysteine-rich region" that has been postulated to be necessary to bind unfolded proteins. The orf4 gene encodes a novel 78-amino acid protein. Curiously, T.DnaK and T.DnaJ expressed in Escherichia coli did not form the complex. Careful reexamination of the T.DnaK.DnaJ complex revealed the presence of a small protein in the complex, which turned out to be a product of orf4. As expected, expression of three genes, dnaK-dnaJ-orf4, resulted in production of a T.DnaK.DnaJ complex in E. coli that was indistinguishable from the authentic complex in its ability to interact with nucleotide and denatured protein. The product of orf4 was also required for in vitro reconstitution of the complex and named T.DafA (T.DnaK.DnaJ assembly factor A). The complex comprises three copies each of T.DnaK, T.DnaJ, and T.DafA. Even though a definite homolog of T.DafA has not been found in the data base, this finding raises a possibility that interaction between DnaK and DnaJ chaperones in other organisms is also mediated by a small protein yet unnoticed.

Location of the non-heme iron center on the alpha subunit of photoreactive nitrile hydratase from Rhodococcus sp. N-771

Nitrile hydratase (NHase) from Rhodococcus sp. N-771, which possesses a non-heme iron center binding nitric oxide (NO), is activated by light irradiation. To localize the iron center in the protein, we quantified Fe atoms and performed FTIR measurements of the isolated alpha and beta subunits. The native NHase and the isolated alpha subunit contained about 1.0 and 0.8 mol Fe per mol protein, respectively, whereas the beta subunit contained only a trace of Fe. An NO stretching band was observed at 1852 cm-1 in the FTIR spectrum of the alpha subunit, but not in that of the beta subunit. Upon light irradiation of the alpha subunit, the affinity of the Fe atom decreased and the NO band disappeared from the FTIR spectrum. These observations indicate that the non-heme iron center, which is responsible for the photoreaction, is present in the alpha subunit.

Photoreactive nitrile hydratase: the photoreaction site is located on the alpha subunit

Nitrile hydratase (NHase) from Rhodococcus sp. N-771 exists in active and inactive forms. The inactive NHase is immediately activated by light irradiation and changes to the active form. To characterize the photoreactive center, the inactive NHase was denatured by 6 M urea, and two kinds of subunits (alpha and beta) were separated and purified by anion-exchange chromatography. In a manner similar to the native NHase, the isolated alpha subunit showed two absorption peaks at 280 and 370 nm, which were diminished by light irradiation. However, irradiation failed to elicit the appearance of absorption peaks at around 400 nm and at 710 nm, which were characteristic of the activated enzyme. The beta subunit seemed not to possess any photoreactive chromophore because its absorption spectrum was not altered by light irradiation. Neither of the subunits showed NHase activity before and after light irradiation, but the inactive NHase was reconstituted by incubating the two subunits together in the dark at 4 degrees C for 1 h. Light irradiation of the beta subunit did not affect subsequent complex formation or NHase activity. However, the irradiated alpha subunit could not assemble with the beta subunit, and no activity was recovered. These results demonstrate that the chromophore(s) responsible for the photoactivation of NHase are entirely located on the alpha subunit, and imply that light irradiation induces conformational change of the alpha subunit.

Gene of heat shock protein of sulfur-dependent archaeal hyperthermophile Desulfurococcus

To elucidate thermoresistance, a gene of a hyperthermophilic heat shock protein (HHSP) was isolated from the hyperthermophile Desulfurococcus strain SY which grows at 95 degrees C. The molecular weight of HHSP deduced from the open reading frame was 59,137 (545 amino acid residues). Sequence alignments of peptides reveal similarities (evolutionary distances) to the alpha (0.279) and beta (0.296) subunits of thermosome, TF55 (0.343) and human t-complex polypeptide 1. The structure of a thermophilic heat shock protein TGroEL (Tamada et al. (1991) Biochem, Biophys. Res. Commun. 179, 565) was quite different from that of HHSP. TGroEL and HSP60 have sequences identical to HHSP at its equatorial domain, while those identical to the alpha subunit of F-type ATPase are at its apical domain.

Solid-phase nested deletion: a new subcloning-less method for generating nested deletions

We have developed a new subcloning-less method for generating nested deletions which we have termed Solid-Phase Nested Deletion. The basic procedure for this method is as follows. The target DNA fragment is cloned in the multiple cloning site of a cloning vector, pUC or its derivatives, and amplified by PCR using a set of primers, one of which is 5'-biotinylated. The amplified DNA is partially digested by a restriction enzyme with a 4-base recognition sequence. The digested DNA is ligated with a synthetic adapter DNA. Monodiverse beads coupled with streptavidin (Dynabeads M-280 streptavidin) are added to the mixture and the biotinylated DNA fragments are separated by applying magnetic field. The unidirectionally deleted DNA fragments are recovered by PCR from the magnetic beads, and size-fractionated by agarose gel electrophoresis. The DNA fragments are amplified by PCR and used for sequencing. We demonstrate the potential of this method using a 4878-bp EcoRI fragment of lambda phage DNA.

Molecular cloning, expression, and characterization of chaperonin-60 and chaperonin-10 from a thermophilic bacterium, Thermus thermophilus HB8

The gene coding a chaperonin from a thermophilic bacterium, Thermus thermophilus HB8, was cloned and sequenced. The operon structure was the same as those of other bacterial chaperonins and the deduced amino acid sequences of both subunits were highly homologous to those of other chaperonins. The cloned genes of chaperonin subunits, chaperonin-10 (T.th cpn10) and chaperonin-60 (T.th cpn60), were separately expressed in Escherichia coli cells. The expressed subunits were easily purified from other host proteins including GroE, a chaperonin of E. coli. T.th cpn60 was expressed as a tetradecameric form, like GroEL of E. coli. Since chaperonin from T. thermophilus HB8 is purified as a holochaperonin, a complex of tetradecameric T.th cpn60 and heptameric T.th cpn10, a tetradecamer of T.th cpn60 without T.th cpn10 has not been obtained before. T.th cpn60 tetradecamer tended to dissociate into monomers during storage. T.th cpn10 expressed in E. coli was purified as a stable oligomer, most likely a heptamer. The activity as holo-chaperonin was reconstituted by mixing both subunits. T.th cpn60 tetradecamer itself arrested refolding of other proteins. The monomerized T.th cpn60 was easily purified from T.th cpn60 oligomer by gel permeation chromatography. Thus-obtained T.th cpn60 monomer had an ATP-independent chaperone activity, as shown for T.th cpn60 monomer isolated from authentic holo-chaperonin.

Effects of linear polyacrylamide concentrations and applied voltages on the separation of oligonucleotides and DNA sequencing fragments by capillary electrophoresis

Oligonucleotides and DNA sequencing fragments have been separated by capillary electrophoresis employing linear polyacrylamide (LPA) as a sieving matrix. A commercially available apparatus equipped with a laser-induced fluorescence (LIF) detection system has been utilized, but the capillary cartridge has been modified to position the capillaries without coiling. The performance of the separation, the relationship between resolution and analysis time, has been examined using poly(dT)16-500 by changing LPA concentration, capillary length, and electric field strength. It was found that, for large DNA fragments, the migration time interval between bands decreases linearly as DNA fragment size increases. This implies that there exists a maximum base number to be resolved, irrespective of the band width (we named the maximum base number Nmax). The higher value of Nmax is obtained when the applied field strength is lower, but this accompanies longer analysis time with a concomitant increase in band width. Simple experimental equations have been proposed to calculate resolution and migration times of DNA fragments separated in our system at given electrophoretic conditions. Using 9% T LPA and an electric field strength of 100 V/cm, single-base resolution of M13mp10 DNA fragments up to 520 nucleotides has been obtained.

High speed polymerase chain reaction in constant flow

A new simple reactor of the tubing type was developed for polymerase chain reaction (PCR). A thin Teflon capillary tube was used as a tubing reactor in which the reaction mixture of PCR was driven by a pump at a constant flow rate. The sample was treated with three successive thermal stages for denaturation, annealing, and elongation of DNA and primers as a function of the position in the tube. The amplification yield was about a half of that obtained by a commercial thermocycler. Moreover, the total reaction time from 12 to 18 min, which was one-tenth of the time generally required by conventional thermocyclers using metal blocks, assured substaintial amplification of a DNA fragment. In addition, this reactor could be also used for rapid cycle-sequences. This new device will be easily incorporated into automated and rapid DNA analysis systems for DNA sequencing.

Properties of aspartate racemase, a pyridoxal 5'-phosphate-independent amino acid racemase

Aspartate racemase from Streptococcus thermophilus contains no pyridoxal 5'-phosphate or other cofactors such as FAD, NAD+, and metal ions. It was affected by neither carbonyl reagents such as hydroxylamine nor sodium borohydride but was strongly inhibited by iodoacetamide and other thiol reagents. Aspartate, cysteate, and cysteine sulfinate were the only substrates. The Km values for L- and D-aspartate were 35 and 8.7 mM, respectively. The enzyme catalyzed the exchange of alpha-hydrogen of the substrate with the solvent hydrogen. Racemization of L-aspartate in 2H2O showed an overshooting in the optical rotation of aspartate before the substrate was fully racemized. This shows that the removal of alpha-hydrogen of the substrate is at least partially rate-determining. When L- or D-aspartate was incubated with aspartate racemase in tritiated water, tritium was incorporated preferentially into the product enantiomer. The results strongly suggest that aspartate racemase contains two hydrogen acceptors.

Distribution and purification of aspartate racemase in lactic acid bacteria

The distribution of aspartate racemase (EC 5.1.1.13) in various kinds of bacteria demonstrated that the enzyme occurs in lactic acid bacteria, such as Streptococcus species and Lactobacillus species. The enzyme from Streptococcus thermophilus IAM10064 was more thermostable than that from Streptococcus lactis IAM1198 which contained the enzyme most abundantly among the lactic acid bacteria we examined here. We purified the enzyme about 3400-fold to homogeneity from cell-free extract of S. thermophilus, which is composed of two identical subunits with a molecular weight of 28,000 as a homodimer. The enzyme utilizes specifically aspartate as a substrate, but not alanine and glutamate. Maximal reaction velocity was observed at 37 degrees C and around pH 8.0. The sequence of the NH2-terminal amino acids of the enzyme was determined to be Met-Glu-Asn-Phe-Phe-Ser-Ile-Leu-Gly-XXX-Met-Gly-Thr-Met-Ala-Thr-Glu-Ser- Phe-.

Molecular cloning and nucleotide sequencing of the aspartate racemase gene from lactic acid bacteria Streptococcus thermophilus

The gene coding aspartate racemase (EC 5.1.1.13) was cloned from the lactic acid bacteria Streptococcus thermophilus IAM10064 and expressed efficiently in Escherichia coli. The 2.1 kilobase pairs long full length clone had an open reading frame of 729 nucleotides coding for 243 amino acids. The calculated molecular weight of 27,945 agreed well with the apparent molecular weight of 28,000 found in sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis of the aspartate racemase purified from S. thermophilus. The N-terminal amino acid sequence from the purified protein exactly matches the derived sequence. In addition, the amino acid composition compiled from the derived sequence is very similar to that obtained from the purified recombinant protein. No significantly homologous proteins were found in a protein sequence data bank. Even the homology scores with alanine racemases of Salmonella typhimurium and Bacillus stearothermophilus were low. Aspartate racemase was overproduced in Escherichia coli NM522 with plasmid pAG6-2-7, which was constructed from two copies of the gene linked with a tac promoter and plasmid vector pUC18. The amount of aspartate racemase increases with the growth of E. coli and almost no degradation of the enzyme was observed. The maximum amount of the produced enzyme reached approx. 20% of the total protein of E. coli.

Purification by dye-ligand chromatography and a crystallization study of the F1-ATPase and its major subunits, beta and alpha, from a thermophilic bacterium, PS3

For a crystallization study, purification methods for F1-ATPase from a thermophilic bacterium, PS3, and its major subunits, beta and alpha, have been improved. The improvement depended on the introduction of dye-ligand chromatography columns to the previously adopted array of chromatography columns: a Blue-B (a blue dye bound to agarose) column was introduced for the F1 preparation, a Green-A column (a green dye attached to agarose) for the beta subunit, and a Blue-A (another blue dye, Cibacron Blue 3GA, bound to agarose) column for the alpha subunit. The improved preparations of all the proteins had purities of nearly 99%. Using the highly purified preparations of the proteins, crystallization conditions were searched for in a systematic way. Large plate crystals (0.2 X 0.5 X 0.5 mm) of F1 were grown from a polyethylene glycol solution. However, neither of the subunits was crystallized, in spite of extensive search for crystallization conditions.

Intracellular distribution of a 32-KDa calcium-dependent phospholipid-binding protein from human placenta

A 32-KDa calcium dependent phospholipid-binding protein was purified to homogeneity from human placenta by affinity adsorption to polyacrylamide-immobilized phosphatidylserine followed by elution with 5 mM EGTA and ion exchange chromatography. Immunochemical studies using the polyclonal antibody against the 32-KDa protein revealed that this protein was present around the nucleus in the cytoplasm but not clearly associated with cell organelles and cytoskeletons. In KB cells treated with insulin, 32-KDa protein was localized in the ruffling membranes in addition to the cytoplasm. Purified 32-KDa protein was shown to coprecipitate with skeletal muscle actin under polymerizing conditions. These findings suggest that the 32-KDa protein interacts with networks of actin filaments in cells.

Site-directed mutagenesis of stable adenosine triphosphate synthase

Evidence was obtained that four ionizable residues in the alpha and beta subunits of thermophilic ATP synthase (TF0F1), corresponding to Lys-21 and Asp-119 in the MgATP binding segments of adenylate kinase, are essential for the normal catalytic activity. TF0F1 was used because it is the only ATP synthase whose alpha-, beta- and gamma-subunits can be reassembled into an active complex in the absence of both ATP and Mg. Lys-164 and Asp-252 of its beta-subunit were modified to isoleucine and asparagine, respectively, by site-directed mutagenesis using a multifunctional plasmid, and these genes were over-expressed in Escherichia coli. The resulting beta I164 and beta N252 subunits were both noncatalytic after re-assembly into the alpha beta gamma-complex, even though both subunits bound significant amounts of ADP. When Lys-175 and Asp-261 of the alpha-subunit were similarly replaced by isoleucine and asparagine, respectively, the resulting alpha I175 subunit reassembled weakly into an oligomer, while the alpha N261 subunit showed an increased dissociation constant for ADP and was reconstituted into an alpha beta gamma-complex that showed no inter-subunit cooperativity.

Sequence and over-expression of subunits of adenosine triphosphate synthase in thermophilic bacterium PS3

The primary structures of all the subunits of thermophilic ATP synthase were determined, and its alpha, beta and gamma subunits could be over-expressed in Escherichia coli, because these subunits were stable and reconstitutable. DNA of 7500 base pairs in length was found to contain a cluster of nine genes for subunits of ATP synthase. The order of their reading frames (size in base pairs) was: I(381): a(630): c(216): b(489): delta(537): alpha(1507): gamma(858): beta(1419): epsilon(396), I being a gene for a small hydrophobic, basic protein expressed in vitro. All the termini of TF0F1 subunits were confirmed by peptide sequencing. Large quantities of the overexpressed thermophilic alpha, beta and gamma subunits were prepared from the extract of E. coli, by a few purification steps.

Single-site catalysis of F1-ATPase from thermophilic bacterium PS3 and its dominance in steady-state catalysis at low ATP concentration

Single-site catalysis by F1-ATPase from a thermophilic bacterium PS3 (TF1) was examined by incubating the enzyme with a submolar amount of radioactive ATP. The profile of single-site catalysis by TF1 at 23 degrees C was different from that of beef heart mitochondrial F1-ATPase (MF1). ATP hydrolysis on the enzyme and release of the products was rapid, and subsequent addition of non-radioactive ATP (cold chase) did not promote the hydrolysis of radioactive ATP, indicating that the rate-limiting step was not the step of product release but the step of ATP binding to the enzyme. Thus, the characteristic features of so-called uni-site catalysis were not observed. At 60 degrees C, whether in the presence or absence of phosphate ion, a small amount of bound [alpha, gamma-32P]ATP and cold chase promotion were observed. However, since bound 32P1 was not detected by centrifugal gel filtration, it is not yet certain whether TF1 has typical uni-site characteristics. Based on the hydrolytic turnover rate for single-site catalysis and analysis of the kinetics of steady-state catalysis, it is proposed that single-site catalysis is dominant even in steady-state catalysis at ATP concentrations of less than about 20 microM.

Single site catalysis of the F1-ATPase from Saccharomyces cerevisiae and the effect of inorganic phosphate on it

The kinetical characteristics of ATP hydrolysis by mitochondrial F1-ATPase from Saccharomyces cerevisiae (yeast) have been studied under conditions where only a single catalytic site per enzyme molecule bound ATP. Four major features were observed, that is, fast ATP binding to the enzyme, slow product release from the enzyme, an equilibrium close to unity between ATP and products on the enzyme, and promotion of ATP hydrolysis on the second addition of a large excess of ATP (cold chase). These are essentially the same as the kinetical characteristics observed for beef heart mitochondrial F1-ATPase, which were called as unisite catalysis by Grubmeyer et al. (Grubmeyer, C. et al. (1982) J. Biol. Chem. 257, 12092-12100), although the release of a hydrolysis product, Pi, from the yeast enzyme appeared to occur significantly faster than that from the beef enzyme, which resulted in a decreased extent of cold chase promotion of ATP hydrolysis of the yeast enzyme. The yeast F1-ATPase showed unisite catalysis even in the absence of Pi in the reaction mixtures, while it was reported for the beef F1-ATPase that the presence of Pi in the reaction mixture was essential for unisite catalysis (Penefsky, H.S. & Grubmeyer, C. (1984) in H+-ATPase (ATP Synthase) (Papa, S. et al., eds.) pp. 195-204, The ICSU Press). Another difference in the Pi effect on the kinetics was that ATP hydrolysis was initiated without a lag time in the absence of Pi in the case of the yeast enzyme when a 1,000-fold molar excess of ATP per enzyme molecular was mixed with the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro mutated beta subunits from the F1-ATPase of the thermophilic bacterium, PS3, containing glutamine in place of glutamic acid in positions 190 or 201 assembles with the alpha and gamma subunits to produce inactive complexes

Using site-directed mutagenesis, Glu-190 or Glu-201 of the beta subunit of the F1-ATPase from the thermophilic bacterium PS3 were replaced with glutamine. It was possible to reconstitute complexes of the mutated beta subunits with alpha and gamma subunits, but the complexes did not have ATPase activity. It is concluded that carboxylic acid side chains of Glu-190 and Glu-201 of the beta subunit are essential for catalytic activity of F1-ATPase.