Báo cáo khoa học: Origin and properties of cytoplasmic and mitochondrial isoforms of taurocyamine kinase pptx

One of the two cDNA-derived amino acid sequences of TKs shows a high amino acid identity to lombricine kinase, another phosphagen kinase unique to anne-lids, and appears to be a cytoplas

isoforms of taurocyamine kinase

Kouji Uda1, Naoto Saishoji1, Shuichi Ichinari1, W Ross Ellington2and Tomohiko Suzuki1

1 Laboratory of Biochemistry, Faculty of Science, Kochi University, Japan

2 Institute of Molecular Biophysics and Department of Biological Science, Florida State University, Tallahassee, FL, USA

Keywords

taurocyamine kinase; creatine kinase;

phosphagen kinase; cDNA sequence;

mitochondrial

Correspondence

T Suzuki, Laboratory of Biochemistry,

Faculty of Science, Kochi University,

Kochi 780–8520, Japan

Fax: +81 88 844 8356

Tel: +81 88 844 8693

E-mail: suzuki@cc.kochi-u.ac.jp

(Received 9 March 2005, revised 23 April

2005, accepted 13 May 2005)

doi:10.1111/j.1742-4658.2005.04767.x

Taurocyamine kinase (TK) is a member of the highly conserved family of phosphagen kinases that includes creatine kinase (CK) and arginine kinase

TK is found only in certain marine annelids In this study we used PCR to amplify two cDNAs coding for TKs from the polychaete Arenicola brasil-iensis, cloned these cDNAs into the pMAL plasmid and expressed the TKs

as fusion proteins with the maltose-binding protein These are the first TK cDNA and deduced amino acid sequences to be reported One of the two cDNA-derived amino acid sequences of TKs shows a high amino acid identity to lombricine kinase, another phosphagen kinase unique to anne-lids, and appears to be a cytoplasmic isoform The other sequence appears

to be a mitochondrial isoform; it has a long N-terminal extension that was judged to be a mitochondrial targeting peptide by several on-line programs and shows a higher similarity in amino acid sequence to mitochondrial creatine kinases from both vertebrates and invertebrates The recombinant cytoplasmic TK showed activity for the substrates taurocyamine and lombricine (9% of that of taurocyamine) However, the mitochondrial TK showed activity for taurocyamine, lombricine (30% of that of taurocyam-ine) and glycocyamine (7% of that of taurocyamtaurocyam-ine) Neither TK catalyzed the phosphorylation of creatine Comparison of the deduced amino acid sequences of mitochondrial CK and TK indicated that several key residues required for CK activity are lacking in the mitochondrial TK sequence Homology models for both cytoplasmic and mitochondrial TK, construc-ted using CK templates, provided some insight into the structural corre-lation of differences in substrate specificity between the two TKs A phylogenetic analysis using amino acid sequences from a broad spectrum

of phosphagen kinases showed that annelid-specific phosphagen kinases (lombricine kinase, glycocyamine kinase and cytoplasmic and mitochond-rial TKs) are grouped in one cluster, and form a sister-group with CK sequences from vertebrate and invertebrate groups It appears that the annelid-specific phosphagen kinases, including cytoplasmic and mitochond-rial TKs, evolved from a CK-like ancestor(s) early in the divergence of the protostome metazoans Furthermore, our results suggest that the cytoplas-mic and mitochondrial isoforms of TK evolved independently

Abbreviations

AK, arginine kinase; CK, creatine kinase; GK, glycocyamine kinase; GS, guanidino specificity; LK, lombricine kinase; MiCK, mitochondrial creatine kinase; MiTK, mitochondrial taurocyamine kinase; TK, taurocyamine kinase.

Phosphagen kinases are enzymes that catalyze the

reversible transfer of the gamma phosphoryl group of

ATP to naturally occurring guanidino compounds such

as creatine, glycocyamine, taurocyamine, lombricine

and arginine, yielding ADP and a phosphorylated

guanidine typically referred to as a phosphagen

(phos-phocreatine, phosphoglycocyamine, etc.) Members of

this enzyme family play a key role in the

interconnec-tion between energy producinterconnec-tion and utilizainterconnec-tion in

ani-mals [1] In vertebrates, phosphocreatine is the only

phosphagen, and the corresponding phosphagen kinase

is creatine kinase (CK) In invertebrates, at least

six unique phosphagens and corresponding kinases,

phosphoglycocyamine (glycocyamine kinase, GK),

phosphotaurocyamine (taurocyamine kinase, TK),

phospholombricine (lombricine kinase, LK),

phospho-opheline (phospho-opheline kinase, OK),

phosphohypotauro-cyamine (hypotaurocyamine kinase, HTK) and

phosphoarginine (arginine kinase, AK), are present in

addition to phosphocreatine [2–5] The former four

enzymes, GK, LK, TK and OK, are found only in

annelid and annelid-allied worms Some species of

annelids may also contain CK or AK

A broad spectrum of invertebrate AK and

verteb-rate, protochordate and invertebrate CK sequences are

now available In terms of phosphagen kinases

restric-ted to annelid groups, sequences for polychaete GKs

[6–8] and LKs from the earthworm Eisenia [9] and the

marine echiuroid worm Urechis [10] have appeared

Comparison of the available CK, AK, GK and LK

sequences suggest that they have evolved from a

com-mon ancestor [6,9,11], but the evolutionary

relation-ships are not fully understood Phylogenetic analyses

have shown that there were two major evolutionary

lineages in the phosphagen kinases, CK and AK,

which probably diverged from their ancestral gene at

the dawn of the radiation of multicellular animals [12]

The available evidence would suggest that GK and LK

evolved within the CK lineage after the divergence of

the lophotrochozoan and ecdysozoan protostomes [9]

There have been extensive studies on the structure,

function and evolution of vertebrate and invertebrate

CKs Recently we showed that three CK isoforms,

cytoplasmic (CK), flagellar (fCK) and mitochondrial

(MiCK), diverged at an early stage of metazoan

evo-lution [13] MiCK, which is targeted to the

inter-membrane compartment of mitochondria and exists

primarily as a homo-octamer, plays a key role in

intra-cellular energy transport from mitochondria to

cyto-plasm [14], and fCK is present in primitive-type

spermatozoa in some species of invertebrates as an

unusual contiguous trimer [15] Recently, Sona et al

[16] have shown that sponges, the most primitive of

extant multicellular animals, have a true MiCK and what appear to be protoflagellar CKs

TK was first isolated from the body wall muscle of polychaete lugworm Arenicola marina [17,18] It shows considerable activity for hypotaurocyamine (about 50% of that of the main target substrate, taurocyam-ine), and weak activity for lombricine and glycocyam-ine [19] TK is a dimeric enzyme like LK and GK [18], and the partial 16 amino acid sequence of an internal peptide was very similar to that of the corresponding peptide of LK [20] It is interesting to note that anti-sera against TK cross-reacted with LK and OK, but not with CK or AK [21] The bulk of TK activity in Arenicola marinais cytoplasmic but 6–8% of the activ-ity was associated with the mitochondrial fraction of body wall muscle [19] Surprisingly, Ellington and Hines [22] could not detect TK activity in the mito-chondria of a congenor Arenicola cristata

The relaxed substrate specificity of TKs for lombri-cine, their dimeric quaternary structure and immuno-logical similarities would suggest that TKs are related

to LKs and possibly to the other phosphagen kinases restricted to annelid groups To probe these relation-ships, the structural correlations of this relaxed sub-strate specificity and the possibility of cytoplasmic and mitochondrial isoforms of TK, we have amplified two cDNAs coding for Arenicola brasiliensis TKs and cloned them into pMAL plasmid One of the two cDNA-derived amino acid sequences corresponds to a cytoplasmic isoform, and the other appears to be a mitochondrial isoform Incorporating these new TK sequences in a phylogenetic analysis of phosphagen kinases showed that annelid-specific enzymes, GK, LK and TKs (cytoplasmic and mitochondrial) evolved from a common ancestor, and that they diverged from

a primordial gene for CK at an early stage of meta-zoan evolution Furthermore, the evolution of the cytoplasmic and mitochondrial isoforms of TK may have occurred independently Our amino acid sequence comparisons with other phosphagen kinases provide insight into the nature of the observed differences in guanidine specificity in these two TKs

Results and Discussion

Cytoplasmic and mitochondrial isoforms of TK are present in Arenicola brasiliensis

We succeeded in amplifying two complete cDNAs coding for TK from the cDNA pool of the bodywall muscle of Arenicola brasiliensis One was identified as

a cytoplasmic form of TK, and the other with a long N-terminal extension of amino acid sequence was

identified as a mitochondrial isoform (referred to

henceforth as MiTK) as described below The cDNA

for the cytoplasmic TK consists of 1811 bp with an

ORF of 1098 bp and 5¢ and 3¢ untranslated regions of

21 and 692 bp, respectively The ORF codes for a

pro-tein containing 366 amino acid residues (Fig 1) with a

calculated molecular mass of 41 351.39 Da and an

esti-mated pI of 7.62 The cDNA sequence of the

cytoplas-mic TK from Arenicola brasiliensis has been deposited

in DDBJ under the Accession No AB186411 The

cDNA for the MiTK consists of 1680 bp with an ORF

of 1239 bp and 5¢ and 3¢ untranslated regions of 68 bp

and 373 bp, respectively The ORF codes for a protein

containing 412 amino acid residues (Fig 1) with a

calculated mass of 46 201.38 Da and estimated pI of

8.55 The cDNA sequence of the MiTK has been

deposited in DDBJ (AB186412)

The deduced amino acid sequence of MiTK appears

to have an N-terminal extension of 40 residues

com-pared to the cytoplasmic TK (Fig 1, underlined

resi-dues) Analyses of the amino acid sequence of this

region revealed that this extension region has a high

probability of being a mitochondrial targeting

sequence Alignment of the mitochondrial targeting

sequences from two invertebrate MiCKs and four

ver-tebrate MiCKs (Fig 2) indicates that the cleavage site

of Ala is conserved also in Arenicola MiTK

The amino acid sequence of Arenicola cytoplasmic

TK showed 69% identity with those of annelid LKs,

57–58% with annelid GKs, 49–58% with the three

CK isoforms including sequences from annelids, and

25–41% with AKs The partial amino acid sequence

(LGYLGTCPTNIGTGLR) of a tryptic peptide of TK

isolated from bodywall muscle of Arenicola marina [20]

is identical to the corresponding sequence of Arenicola

brasiliensiscytoplasmic TK except for one position It

has been shown that the Arenicola marina TK contains

a higher number of cysteine residues than other

phos-phagen kinases [29] In agreement with this, the

sequence of Arenicola brasiliensis cytoplasmic TK

con-tains eight cysteine residues (Fig 1), the same number

of cysteines estimated to be in Arenicola marina TK

Interestingly, the amino acid sequence of Arenicola

MiTK showed 63–67% identity with invertebrate

MiCKs, 57–62% with cytoplasmic CKs, 56–60% with

annelid enzymes (GK, LK and cytoplasmic TK

deter-mined in this study), and 24–42% with AKs Thus the

entire sequence of Arenicola MiTK displays a much

greater sequence similarity to the MiCKs than to the

cytoplasmic TK

The recombinant enzymes were successfully

expressed as soluble proteins, purified by affinity

chro-matography, and appeared to be nearly homogeneous

on SDS⁄ PAGE The enzyme activities of Arenicola TKs were measured using the substrates taurocyamine, lombricine, glycocyamine, creatine and arginine (Table 1) Arenicola cytoplasmic TK showed activity for the substrates taurocyamine and lombricine (9% that of taurocyamine) in agreement with the previous report on Arenicola marina TK [19] On the other hand, mitochondrial TK showed activity for tauro-cyamine, lombricine (30% of that of taurocyamine) and glycocyamine (7% of that of taurocyamine) Recombinant Arenicola MiTK was incapable of phos-phorylating creatine even though this TK has a higher degree of sequence similarity to MiCKs than to LKs and other phosphagen kinases Clearly, both cytoplas-mic and mitochondrial proteins from Arenicola are true TKs in that taurocyamine is their primary guani-dine substrate

To compare Arenicola cytoplasmic TK and MiTK with each other and typical CKs, homology models for both were constructed using the Swiss-Model auto-mated modeling server [46] with chicken and human MiCKs serving as templates The predicted structures

of TK and MiTK, both in the open (apo-) state, were very similar to each other, except for the length of the

GS loop (one of the important determinants of guani-dine substrate recognition) described below (Fig 3, loop indicated by the arrow) The open catalytic pocket is delineated by the GS loop and the identified residues (discussed below)

Arenicola MiTK is very similar to typical mitochondrial creatine kinases

Wyss et al [14] reviewed the functional role of MiCK

in intracellular energy transport from the mitochondria

to the cytoplasm The MiCK isoenzymes are specific-ally localized within the intermembrane space of mito-chondria, where creatine is rapidly phosphorylated to phosphocreatine by ATP exiting the adenine nucleotide translocase for export into the cytoplasm The octa-meric form of MiCK and its targeting to the inter-membrane space evolved before the divergence of the protostomes and deuterstomes [30–32] These results show that a mitochondrial isoform of TK is present in Arenicola and that this protein displays great similarit-ies to octameric MiCKs

Vertebrate and invertebrate MiCKs typically have higher pI values than their cytoplasmic isoform coun-terparts [14,32], which produces a net positive charge

to the enzyme under physiological conditions Arenicola MiTK also has a higher pI than the cytoplasmic TK It has been proposed that this would facilitate the binding

of MiCK to the negatively charged cardiolipin on the

Fig 1 Multiple sequence alignment of Arenicola TK and MiTK with other phosphagen kinases, namely AKs from the horsehoe crab Limulus and the silkworm Bombyx, the b subunits of the GK from the polychaete Neanthes and Nereis, the MiCKs from the polychaete Chaetopte-rus and Neanthes, LKs from the oligochaete Eisenia and the echiuroid Urechis, and the cytoplasmic muscle CKs from human and the electric ray Torpedo The underlined N-terminal sequence in Arenicola MiTK corresponds to a putative mitochondrial targeting sequence The boxed sequences define the GS region in all phosphagen kinases Arrow a, Ile69 equivalent residue in the GS region of all CKs; arrow b, position

130 (Arg95 equivalent in CK) containing phosphagen kinase specific residues; arrow c, Trp304 present in all MiCKs; arrow d, Val325 equival-ent presequival-ent in all CKs The basic residues in the C-terminus of Arenicola MiTK that could potequival-entially mediate membrane interaction are shown in bold.

outer portion of the inner mitochondrial membrane

[14] The amino acid residues responsible for membrane

binding have been identified as six or seven basic amino

acid residues in the C-terminal region of the protein

[33–35] In the Arenicola MiTK sequence, five lysine

residues (Lys401, Lys405, Lys407, Lys408, Lys418) and

two arginines (Arg395, Arg402) are conserved in the

C-terminal region (Fig 1, bold) An internal lysine

resi-due in MiCKs (Lys110 in chicken sarcomeric MiCK)

has also been implicated in membrane interaction [35];

this residue is absolutely conserved in all MiCKs [12] This Lys110 equivalent residue is also present in Areni-cola MiTK (Fig 1, position 149), but not in cytoplas-mic TK, LK, GK and CK These results suggest that Arenicola MiTK will also interact electrostatically with the inner mitochondrial membrane

A tryptophan residue (Trp264 in chicken sarcomeric MiCK) plays a key role in octamer stability of MiCKs

as demonstrated by site-directed mutagenesis studies and by several X-ray crystal structures (reviewed in

Fig 3 Prediction of three-dimensional structures of Arenicola TK and MiTK by Swiss-Model [46] Four key amino acid residues, a–d in Fig 1, are shown The GS loop is indicated by the arrow and the N-terminus of each protein is denoted by ‘N’.

Fig 2 Alignment of mitochondrial targeting sequences of vertebrate and invertebrate MiCKs and Arenicola MiTK Sequences correspond to ubiquitous (uMiCK) and sarcomeric (sMiCK) MiCKs from man and chicken and MiCKs from the polychaetes Neanthes and Chaetopterus The boxed region is the cleavage site.

Table 1 Enzyme activity of recombinant Arenicola TK and MiTK for various guanidino compounds Percentages are relative to the activity for the taurocyamine v values were obtained in the presence of 4.75 m M guanidino compounds NA, No activity.

[35]) This residue is absolutely conserved in all

proto-stome and deuteroproto-stome MiCKs but is not present in

cytoplasmic and flagellar CKs as well as in other

phosphagen kinases such as AK, LK and GK

[12,13,32] In the MiCK from the sponge Tethya

aurantia, however, this residue is replaced by a

tyro-sine, and the MiCK forms dimers, not octamers [16]

The Arenicola MiTK has this conserved Trp residue

(Figs 1 and 3, arrow c) suggesting that this protein has

the potential to form octamers The equivalent

posi-tion in Arenicola cytoplasmic TK is an Arg residue

(Figs 1 and 3) It seems highly likely that this MiTK

exists in the octameric state in vivo where it can

effect-ively interact with membranes in the intermembrane

space Expression and characterization of the

oligo-meric state of the mature Arenicola MiTK should be

most revealing

Evolution of cytoplasmic and mitochondrial

taurocyamine kinases

To evaluate the evolutionary relationships of

cytoplas-mic and mitochondrial TKs with other phosphagen

kinases, a phylogenetic tree was constructed from the

amino acid sequences of cytoplasmic TK, MiTK, LK,

GK and CK isoforms by the neighbor-joining method

(Fig 4) The neighbor-joining tree separates the

sequences into two major groups: a group for CK

iso-forms (presented schematically) and a group for

annelid-specific enzymes, GK, LK and TK Arenicola

cytoplasmic TK is grouped with the other annelid-specific enzymes, especially adjacent to LKs, in accord with their immunological cross-reactivity and enzy-matic nature Arenicola MiTK is clustered just outside the annelid cytoplasmic enzymes Clearly, the annelid-specific phosphagen kinases (including cytoplasmic and mitochondrial TKs) and the cytoplasmic, mitochond-rial and flagellar CKs evolved from a common ances-tor The oldest extant metazoans (sponges) have both mitochondrial and protoflagellar CK genes; the proto-flagellar CKs are probably ancestral not only to the fCKs but also to the cytoplasmic CKs [16] Given this fact, we suggest that both cytoplasmic and mitochond-rial TKs evolved from CK ancestors In fact an attractive, albeit speculative, scenario based on the sequence, catalytic and phylogenetic results, is that cytoplasmic TK and mitochondrial TK evolved inde-pendently; this latter event potentially took place much later in time in the course of annelid evolution, as there is no evidence for mitochondrial LK activities [22] We have shown previously that echinoderm AKs, and probably all deuterostome AKs, evolved secondar-ily from a CK ancestor [36]

Structural basis for the catalytic properties of Arenicola cytoplasmic TK and MiTK

A previous amino acid sequence alignment of phos-phagen kinases indicated that the guanidino specificity (GS) region, having significant amino acid deletions, is

Fig 4 Neighbor-joining tree for the amino acid sequences of phosphagen kinases The tree was constructed using the program available on the home page of DDBJ (http://www.ddbj.nig.ac.jp/) Bootstrap values are shown at the branch points The cluster of the CK portion is shown schematically by the representatives of three isoforms; cytoplasmic, mitochondrial and flagellar (a total of 71 CK sequences, available

on the database of DDBJ, were used for tree construction) Limulus AK was used as the outgroup The position of the Arenicola MiTK sequence appears to be unstable If the number of CK sequences is reduced during phylogenetic tree construction, the Arenicola MiTK sequence is, in some cases, included in the CK cluster.

a possible candidate for the guanidine-recognition site

[9] (Fig 1, boxed region) There is a proportional

rela-tionship between the size of the deletion in the GS

region and the mass of the phosphagen substrate LK

and AK each have five amino acid deletions in this

region and use relatively large guanidine substrates

CK has one such amino acid deletion while GK, which

uses the smallest substrate glycocyamine, has no

dele-tions (Fig 1) The GS region encompasses part of the

flexible loop in the N-terminal domain of the crystal

structures of Limulus AK and Torpedo CK [37,38]

Our previous studies, using Nautilus AK, Stichopus

AK, Danio CK [39–41] and Eisenia LK [42], showed

that amino acid mutations introduced in the GS region

greatly reduced their enzymatic activity Interestingly,

replacement by site-directed mutagenesis of the entire

GS loop of Limulus AK with the equivalent and longer

loop of CK resulted in a construct displaying reduced

but appreciable AK activity [43] The extended loop of

CK in this AK construct did not preclude arginine⁄

phosphoarginine binding

Arenicola cytoplasmic TK has a five amino acid

deletion in the GS region as in LK and AK, in

agree-ment with the proposed relationship between the size

of guanidine substrate and the number of amino acids

deleted [9] In addition, the amino acid sequence of GS

region of cytoplasmic TK was very similar to that of

EiseniaLK (Fig 1) This feature is consistent with the

following enzymatic properties: LK shows considerable

activity for taurocyamine (about one-third that of the

main target substrate, lombricine) [42], while TK

shows considerable activity for lombricine (Table 1)

Phylogenetic analysis also suggests that TK and LK

have evolved from a common ancestor (Fig 4)

Areni-cola MiTK unexpectedly had only one amino acid

deletion in the GS region, unlike cytoplasmic TK but

similar to MiCKs This does not fit with the proposed

relationship between the size of guanidine substrate

and the number of deletions in the GS region The

dif-ference in the length of the GS region is easily seen in

the homology models (Fig 3, arrows) However, if we

consider that Arenicola MiTK shows broader substrate

specificity than cytoplasmic TK (Table 1), the

five-residue deletion in the GS region is preferable to the

original target activity for taurocyamine

It has recently been shown in rabbit muscle CK that

two key residues form a ‘specificity pocket’ [44] Ile69,

which is in the so-called GS loop, and Val325 stabilize

the methyl group of creatine⁄ phosphocreatine The

equivalent Ile69 residue is lacking in AKs, GKs and

LKs, while the Val325 equivalent is an absolutely

con-served Glu residue in these latter three phosphagen

kinases [44] All noncreatine phosphagens and

guanidine substrates lack the characteristic methyl group of creatine but instead have a proton in this position These results show that in both Arenicola TKs the Ile69 equivalent residue is not present but for different reasons; firstly the cytoplasmic TK has the characteristic GS loop deletions, including the Ile69 equivalent, and secondly the MiTK has the four CK-like GS loop insertions but has a threonine residue (Fig 3, Thr103) instead of the Ile69 equivalent (Fig 1, arrow a in the boxed GS region) Note that both cyto-plasmic TK and MiTK have the characteristic Glu residue near the C-terminal region (Figs 1 and 3, arrow d)

Because AK, LK, GK and TK lack the equivalent

CK Ile69 and Val325 residues that form a specificity pocket for creatine in CKs, what are the structural correlates of guanidine specificity for the other phos-phagen kinases? How can one explain the somewhat broader specificity for TKs (and LKs) and the differ-ences in capacity for utilization of lombricine and glyco-cyamine by cytoplasmic TK and MiTK? The amino acid residue at position 130 (equivalent to position 95

in rabbit muscle CK) in the alignment of Fig 1 (arrow b) is strictly conserved in each of phosphagen kinases, namely Arg in CK, Ile in GK, Tyr in AK and Lys in

LK While this residue is not directly involved in sub-strate binding in CK and AK crystal structures, it is located close to the guanidine substrate binding site The replacement of this residue dramatically reduced the activity of rabbit muscle CK [45] Moreover, replacement of Lys by Tyr in Eisenia LK altered the major target substrate of the enzyme from lombricine

to taurocyamine [42] Arenicola cytoplasmic TK has a histidine at position 130 (Fig 3) that is a unique resi-due compared to the other phosphagen kinases; this residue may tune the active site to enhance substrate specificity for taurocyamine and minimize the activity with other guanidine substrates Arenicola MiTK, like

LK, has a Lys (Fig 3), in accordance with the higher activity of MiTK for lombricine than that of cytoplas-mic TK (Table 1) Catalysis in AK and CK involves the very precise positioning of the substrates in the active site through a variety of intermolecular contacts [37,38] A similar array of such contacts, likely to be present, remains to be elucidated in TKs and, in fact, the other annelid-specific phosphagen kinases

General conclusions Both cytoplasmic and mitochondrial TKs appear to have evolved independently in the annelid lineage Arenicola MiTK evolved from a mitochondrial CK, and still potentially retains many of the features of

MiCKs including octameric quaternary structure and

capacity for binding to the inner mitochondrial

mem-brane Both cytoplasmic TK and MiTK utilize

tauro-cyamine as their primary substrate but MiTK is less

specific and utilizes lombricine and glycocyamine to

some extent This relaxed specificity can be partially

explained by differences in key amino acid residues in

these two TKs

Experimental procedures

cDNA amplification and sequence determination

of cytoplasmic TK and mitochondrial TK (MiTK)

from A brasiliensis

A specimen of A brasiliensis was collected on the sea shore

at Tokushima, Japan Total RNA was isolated from the

body wall muscle by the acid guanidinium thiocyanate⁄

phenol⁄ chloroform extraction method [23] mRNA was

purified from total RNA using a poly(A)+ isolation kit

(Nippon Gene, Tokyo, Japan) The single stranded cDNA

was synthesized with Ready-To-Go You-Prime First-Strand

Beads (Amersham Pharmacia Biotech, Piscataway, NJ,

USA) with a lock-docking oligo(dT) primer [24]

The 3¢ half of the TK cDNA was amplified using the

lock-docking oligo(dT) primer and a 256-fold ‘universal’

phosphagen kinase primer (5¢-GTNTGGGTNAAYGAR

GARGAYCA-3¢) designed from the highly conserved

sequences of phosphagen kinases [6] Ex Taq DNA

poly-merase (Takara, Kyoto, Japan) was used as the amplifying

enzyme PCR amplification was performed for 30 cycles,

each consisting of 30 s at 94
C for denaturation, 30 s at

60
C for annealing and 2 min at 72
C for primer

exten-sion The amplified products were purified by agarose gel

electrophoresis and subcloned into the pGEM-T Easy

Vec-tor (Promega, Madison, WI, USA) Nucleotide sequences

were determined with an ABI PRISM 3100-Avant DNA

sequencer using a BigDye Terminators v3.1 Cycle

Sequen-cing Kit (Applied Biosystems, Foster City, CA, USA)

A poly(G)+tail was added to the 3¢ end of the Arenicola

cDNA pool with terminal deoxynucleotidyl transferase

(Promega) The 5¢ half of the TK cDNA was then amplified

using the oligo(dC) primer (5¢-GAATTC18-3¢) and a specific

primer (5¢-GGCCCTTGGCCTTCATCAGG-3¢ for

cyto-plasmic TK, or 5¢-CTCGAAGACCTGCTTCATGTTTC-3¢

for MiTK) designed from the sequence of the 3¢ region

The amplified products were purified, subcloned and

sequenced as described above

Cloning and expression of Arenicola TKs

The open reading frames (ORFs) of Arenicola TKs were

amplified and cloned into the EcoRI⁄ HindIII site of

pMAL-c2 (New England Biolabs, Beverly, MA, USA) In

the case of MiTK, the mitochondrial targeting sequence was removed The maltose binding protein (MBP)-TK fusion protein was expressed in Escherichia coli TB1 cells

by induction with 1 mm isopropyl thio-b-d-galactoside at

25
C for 24 h The cells were resuspended in 5· Tris⁄ EDTA buffer, sonicated, and the soluble protein was extracted Recombinant TK was purified by affinity chro-matography using amylose resin (New England Biolabs) The purity of the recombinant enzyme was verified by SDS⁄ PAGE The enzymes were placed on ice until use, and enzymatic activity was determined within 12 h

Analyses of N-terminal amino acid sequences

of Arenicola TK and MiTK

Analyses were done using several on-line tools, the targetp (http://www.cbs.dtu.dk/services/TargetP/) [27], sosuisignal (http://sosui.proteome.bio.tuat.ac.jp/sosuisignal/sosuisignal_ submit.html) and signalp (http://www.cbs.dtu.dk/services/ SignalP/) [28]

Modeling of three-dimensional structures

Predictions of the three-dimensional structures of Arenicola

TK and MiTK were made by using the Swiss-Model auto-mated modeling server (http://www.expasy.org/swissmod/ SWISS-MODEL.html; the First Approach Method set at default parameters) [46] Swiss-Pdb viewer version 3.7 was used to generate a three-dimensional image Under these conditions, models for Arenicola TK and MiTK were con-structed, based on the structures of chicken and human MiCKs

Alignment of amino acid sequences of phosphagen kinases and construction of phylogenetic tree

Multiple sequence alignment of Arenicola TK and MiTK and other phosphagen kinases was done with the clustalw program available on DDBJ homepage (http://www ddbj.nig.ac.jp/Welcome-j.html) The phylogenetic tree was constructed with the neighbor-joining method available on the DDBJ homepage Amino acid sequences were taken from DDBJ and GenBank Limulus AK was used as the outgroup

Enzyme assays

Enzyme activity was measured using the NADH-linked spectrophotometric assay at 25
C [25] and determined for the forward reaction (phosphagen synthesis) Details are as described previously [26] Protein concentration was estima-ted from the absorbance at 280 nm (0.77 at 280 nm in a

1 cm cuvette corresponds to 1 mg proteinÆmL)1)

This work was supported by a grant from the

presi-dent of Kochi University to TS, a grant (17570062)

from the Grants-In-Aid for Scientific Research of

Japan to TS, and a grant from the U.S National

Sci-ence Foundation (IBN-0130024) to WRE

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