sequence and identification of the nucleotide binding site for the
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Volume 15 Number 22 1987 Nucleic Acids Research
Sequence and identiflcation of the nucieotide binding site for the elongation factor Tu fromThermits thermophtius HB8
Lothar Seidler, Marcus Peter, Franz Meissner and Mathias Sprinzl
Laboratorium fur Biochemie and Institut fur makromolekulare Forschung, UniversitSt Bayreuth,Postfach 10 12 51, D-8580 Bayreuth, FRG
Received August 20, 1987; Revised and Accepted October 12, 1987
ABSTRACTTwo structural genes for the Thermus thermophilus elongation
factor Tu (tuf) were identified by cross-hybridization with thetufA gene from E. coli. The sequence of one of these tuf genes,localized on a 6.6 kb Bam HI fragment, was determined and con-firmed by partial protein sequencing of an authentic elongationfactor Tu from T.thermophilus HB8. Expression of this tuf gene inE. coli minicells provided a low amount of immuno-precipitablethermophilic EF-Tu. Affinity labeling of the T.thermophilus EF-Tuand sequence comparison with homologous proteins from other orga-nisms were used to identify the guanosine-nucleotide bindingdomain.
INTRODUCTION
Elongation factor Tu (EF-Tu) from E .coli mediates the binding
of aminoacyl-tRNA to programmed ribosomes (1) and plays a role in
maintaining the fidelity of translation (2) . Amino acid sequen-
ces were determined for the procaryotic elongation factors from
E. coli (3, 4), yeast mitochondrium (5) chloroplasts of Euqlena
qracilis (6) as well as for several eucaryotic elongation factor
I a species (7, 8, 9). EF-Tu possesses some sequence homologies
with eucaryotic elongation factor la and G-proteins mainly in the
guanosin-nucleotide binding domain (10).
EF-Tu from T.thermophilus HB8 is temperature insensitive up
to 65 °C (11) in contrast to EF-Tu from E.coli. It forms stable
aa-tRNA»EF-Tu>GTP ternary complexes and is well suited for physi-
cal and biochemical investigations. We used this thermophilic EF-
Tu to construct affinity columns for the isolation of aminoacyl-
tRNAs (12) and for the investigation of aminoacyl-tRNA • EF-Tu*GTP
interactions (13). In order to prepare sufficient quantities of
the thermophilic elongation factor and its mutants for physical
© IR L Press Limited, Oxford, England. 9 2 6 3
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studies the expression of its genes in E.coli was attempted. In
this communication we present the sequence of one of the two
T.thermophilus EF-Tu genes and the identification, by affinity
labeling, of the nucleotide binding site in the protein.
MATERIALS AND METHODS
Enzymes, deoxynucleoside-5'-triphosphates and dideoxynucleo-
sides-5'-triphosphates were obtained from Pharmacia (Uppsala,
Sweden), BRL (Eggenstein, FRG) and Boehringer (Mannheim, FRG).
[3H]GDP (11.3 Ci/mmole), [U14C]GTP (500 mCi/mmole), 35S-labeled
methionine (1275 Ci/mmole) and 'Amplify' were purchased from
Amersham-Buchler (Braunschweig, FRG). [ P ]orthophosphate
and P-labeled dATP (800 Ci/ mmole) were obtained from Du
Pont/New England Nuclear (Bad Nauheim, FRG). [G32P]GDP (1000
Ci/mmole) was prepared as described elsewhere (14). CM-Sepharose
CL-6B and Sephadex LH-60 were from Pharmacia. NalO., NaBH3(CN)
and NaBH. were from Serva (Heidelberg, FRG). Acrylamide and N,N'-
methylenebisacrylamide were obtained from BRL. All other reagents
were of analytical grade and purchased from Merck (Darmstadt,
FRG).
The plasmid pPR 1 carrying the 1.0 kbp Nrul/Hpal fragment of
the E.coli tufA gene was obtained from Dr. L. Bosch (Leiden).
E.coli strains RR1 and Kill were U8ed for cloning experiments.
The E.coli strain R312A which was used for minicell expression
was from Dr. N. Schumann (Bayreuth).
For hybridization experiments 20 p.g of T•thermophilus chromo-
somal DNA were digested with several restriction enzymes using
33 mM Tri8-acetate pH 7.9, 66 mM potassium acetate, 10 mM magne-
sium acetate, 0.5 mM DTT, 0.1 mg/ml BSA as incubation buffer, in
a final volume of 60 jil. Cleavage was complete after 3 h at 37 C
in the presence of 20 units of restriction enzyme. The resulting
DNA fragments were separated by horizontal gel electrophoresis
(1.3 % agarose in 40 mM Tris-acetate pH 7.9, 25 mM sodium ace-
tate, 0.5 mM EDTA) run at 3 V/cm for 4 h. Transfer of separated32DNA to a nitrocellulose filter and hybridization to the P-
labeled E.coli tufA fragment of pPR 1 were carried out as pub-
lished elsewhere (15, 16).
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For cloning the T.thermophilus chromosomal DNA, it was cleaved
and separated as described above. 2 jig of isolated T.thermophilus
DNA (Bam HI or Bgl II restriction fragments) was incubated with
1 jig BamHI cleaved, dephosphorylated pBR 322 DNA at 15°C, over-
night. The ligation was performed in 50 mH Tris-HCl pH 8.0, 10 mH
HgCl2, 20 mH DTT, with 10 units T4 DNA ligase in a total volume
of 30 u.1 . Transformation was carried out according to the method
of Inone and Curtiss (17). Isolated plasmid DNA of positive
transformants was blotted onto nitrocellulose and hybridized32
with P-labeled E.coli tufA probe.
The subcloned 1.6 kbp Smal fragment was sequenced in both
directions using the Sanger H13/dideoxy method (18).
Minicell preparation, S-protein labeling in vivo, and gel
electrophoresis of crude cell lysates were done as described
elsewhere (19, 20).
EF-Tu'GDP was purified from T.Thermopnilus cells, strain HB8,
as described by Leberman et al. (21). Nucleotide-free EF-Tu was
prepared as follows: Purified EF-Tu-GDP ( 30 mg in a volume of
2 ml) was diluted ten fold with 10 mM NH H P0 pH 5.65, 5 M
urea, 10 mM Q-mercaptoethanol and 10 \i» PMSF (buffer A). The pH
was adjusted to 5.65 with acetic acid . The solution was then
applied to an equilibrated (buffer A) CM-Sepharose CL-6B column
(2 x 10 cm), and further washed with 50 ml of the same buffer.
GDP-free EF-Tu was obtained by elution with buffer B (buffer A +
200 mM KC1, pH adjusted to 7.5). Urea was then removed by dialy-
sis against labeling buffer (50 mM Na-borate, pH 7.5. 50 mM KC1
and 10 mM MgCl_). The protein had a GDP-binding activity of^ 3
21,000 U/mg. The [ H]GDP activity was measured by the nitrocellu-
lose membrane filter binding assay (11).
Affinity labeling with periodate oxidized GTP: 20 (iM of nu-
cleotide- free EF-Tu was incubated with 10 jiM [U14C]GTP for 10 min
at 37 °C in labeling buffer and dialyzed twice for two hours at
4 C against the same buffer. Oxidation was performed in situ
with 1 mM NalO. for one min at 37 C. The reduction then followed
by treatment with 20 mM NaBH,(CN) for one min at 37 °C. The
reaction was stopped by addition af 25 mM NaBH., the mixture was
desalted on a NAP-Column (Pharmacia), and lyophilized.
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3 2Photoaffinity labeling with [6 P]GDP: 20 jiM nucleotide-free
EF-Tu was incubated with 1 u.M [ 632P]GDP for 10 rain at 37 °C in
50 mM Tris/HCl pH 8.0, 100 mH NaCl, 5 mH MgCL. and 1 mH Q-
mercaptoethanol . 1 mH ATP was added and the reaction mixture was
irradiated on ice with a laser beam at 257 nm using an argon ion
laser (model 2000, Spectra Physics, Mountain View, USA) with a
KDP crystal at an intensity of 5 mW/cm for 5 min. The sample was
desalted as described above.
Peptide analysis: A 500 jig sample of labeled EF-Tu was dis-
solved in 500 (il of 70 % formic acid containing 12.5 mg CNBr.
After 24 hrs in the dark the mixture was diluted ten fold with
water and lyophilized. Labeled peptides were analyzed by a modi-
fication of the slab gel system described by Swank and Munkres
(22); 12.5 % acrylamide, 1.0 % N,N'-methylenebisacrylamide, 5 M
urea, 0.1 % SDS, 0.1 H Na-phosphate, pH 6.8 with an upper gel (3
cm high) containing 8 % acrylamide, 0.064 % N,N'-methylenebis-
auiylaniide in the same buffer. The gel was atained with Coomaasie
blue, treated for 30 min with "Amplify", and dried. Labeled
peptides were identified by autoradiography using Kodak XAR-5
film.
Sequencing of cyanogen bromide fragments was done as follows:
22 mg of EF-Tu were incubated with 220 mg CNBr in 22 ml of 0.1 N
HC1 for 48 hrs in the dark. After dilution with 200 ml of H O and
lyophilisation the peptides were purified on a Sephadex LH-60
column (2 x 100 cm) according to Gerber et al. (23). Further
purification was performed on reverse phase HPLC column (Vydac C.
300 8, Macherey und Nagel, Duren, FRG). Sequencing of the large
CNBr-fragments was carried out with a liquid phase sequencer.
RESULTS
Chromosomal DNA from T.thermophilus HB8 was isolated and di-
gested with Bam HI or Bgl II restriction endonucleases. The frag-
ments were separated by eletrophoresis and hybridized to an
E.coli tuf A probe. Bam HI fragments of 6.6 and 4.5 kbp could be
hybridized to E .coli tufA-DNA while Bgl II fragments of 9.0 kbp
and 6.6 kbp provided a positive signal (fig. 1 ) . This indicates
the presence of two EF-Tu genes in T.thermophilus, a situation
similar to E.coli (24). The two 6.6 kbp restriction fragments
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kb
- 4.0
Fig. 1. Hybridization of bacterialchromosomal DNA against a ^ P-labeledE.coli tufA probe. Lane 1: E.coliDNA, EcoRI-cleaved; lane 2:T.thermophilus DNA, BamHI-cleaved;lane 3: T.thermophilus DNA,Bglll-cleaved.
were cloned into pBR 322 using the Bam HI site. Attempts to clone
the 4.5 kbp and 9.0 kbp fragments containing the putative second
T.thermophilus tuf gene were not successful. In fig. 2 the re-
striction map of the cloned DNA fragments is shown. The smallest
region providing a positive hybridization signal with E.coli tuf
A is located on a 1.6 kbp Sma I restriction fragment. This DNA
was sequenced using the M13/Sanger sequencing system. The entire
sequence is presented in fig. 3. The T.thermophilus tufl gene
codes for a protein of molecular weight 44600 D. It is 70 %
homologous to the E. coli EF-Tu on the protein level.
k
n
f 1 , 1J T 1 1
<I
>T f r
pLS652
PLS601
8 kbp
Fig. 2. Restriction map of the two cloned T.thermophilus DNA-fragments and their orientation in the genome. There are about 12Smal sites in the 6.6 kbp BamHI fragment, though only 6 sites areshown in the map. PLS 601 was identified as tufl by hybridizationunder stringent conditions with 1.3 kb BamHI/HindllI restrictionfragment obtained from pLS 652 (indicated by batching). Somecommon restriction site of pLS 652 and pLS 601 were identified asindicated. Restriction endonuclease cleavage sites: BamHI (•)Bglll (o), Hindll (•), Hindlll (•) , Kpnl (T ) , Pvul (V), Smal (x).
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<CCC>CGC«UCGCCAOTUTCCCCCCirrrCCTSCCme«eCiUTSTTCCTACeCCACeUCCTeC.CTCCUUCCUCCCCCCACCCTCCTTCCTUIH 1LII l_CUCTACUC^CC^CCCCUSUGCTCCA«iCAACCTUTCAASCCTCUTACCSCCCCTrCCSCCT6CCCl 1111 IA6CCCC
75194
Ihiln-Dllgirw.cccccuiu.ii U_UCUSSACCCAC
ill LT< Sly «"» Pht Til 1 0 I»r L*l Fro I_l Til U l Til Clr Thr II. Sly Bit Til U p III
cc« uc «c us m en c« i n uc ca cu m uc en o« ACC ATT ccc uc CTC uc uc
• • I • 30 40 50I I I Lli Tkr Ikr I n m U i 111 Us Tbr Trr Til U« U i Alt els UD Pro Un Til Sin Til Lrt Up lyr Clr Up l i t Up LrtSSS U S ACS ICC CTS ICC CCC CCC TTA ICC TIT STC CCS CCC CCC U C U C CCS U T STA C1C CTT UC CAC TIC CM SAC I T T GAC U S
(0 70 10U i Fro Gls Clu Arg H i Arg Cly l i t Tbr III i in Thr H i Bit Til e l l TTT Cl« Thr H i Lrt Arg lit Tyr ttr l i t Vil Up CytCCC CCS U C IUC CCT CCC CCC CCC I T T ICC ITC U C ICC CCC C1C CTC C1C TIC U O ACC CCC AAS CCS UC TIT TCC CIC CTC CAT TCC
______ll_______! |L_LJJO 'lOO 110
Pro Clr lit H i U p Tyr lit Lr« Atn Htt lit Thr Cly H i All clt Hit U p Sly H i lit L M Til Til ttr Alt Alt U p Sly ProCCT SCC CAC CCC GAC TAC ATC U C U C ATC ATC KC OCT CCC CCC CAO ATC U C CCC CCC ATC CTT STS CTC TCC CCC CCC SAC SCS CCS
-1 CB 7 CB 7 11 CB 11 | L _ _ _ _ _• • • • • • 120 130 14?
Hit Pro Cln Thr Arg Sis Bit l i t Ua I n H i lrg sin Til c ly Til Pro Tyr III Til Til Pht l i t U i Lyt Ttl U p Hit Til U pATC CCC U C ACC CCC U C U C ATT TTS CTS OCC CCC CAC CTC SSS STS CCS TAC ATT CTC CTS TTC ATC U C U C CTC CAC ATO CTO SAC
Cl 9 |.C1 i-50 H O 170
U p Pro 61a U s U s U p U a Til Clt Htt Cla Til Arg U p U a U a All Cln Tyr Clt Pbt PTO Clr U p Clt Til PTO Til lit ArgCAC CCC U G TTC CTC CAC CTC CTC CAS ATC U C CTC CCC U C CTT TTS AAC U C TAC U S TTT CCT SSS UC U S CTT CCC STS ATT CSS
110 • • • • • • • • • • • • • • • • • •Clr <tr 111 U i Lto H i U I Cla Cln Hit Bit lrg Un Pro Lrt Ttr Arg Arg Clr Cla U n Clt Trp Til U p Lrt l i t Trp Sis U sSCC ACT CCT CTT TTC CCC CTT U S U S ATC UC UC UC CCC AAC ACS ACC CCT CCC UC U C U S TSS STS UC UC ATT TCS U S CTS
• • • 210 220 230U t U p H i lit U p Sis Tyr lit Pro Thr Pro Til Arg U p Til U p Lyt Pro Pht U i Hit Pro Til Cls U p Til Pht Thr lit TbrTTC CAC CCC ATT CAC SAS TAC ATT CCC ACS CCC CTS CSS U C STS SAC U S CCC TTC TTC ATC CCC CTG U C U C CTS TTT ACC ATC ACS
240 250 2t0Cly Arg Cly Thr Til H i Thr Sly Arg lit Sis lrg Sly Lrt Vil Lrt Til Cly U p Cla Til Sis lit Til Cly Ua H i Pro Cla ThrOCT CCT CCC ACS STS CCC ACC CST CCS ATT CAC CCC CCC U C GTS U S STT SCS U C SAS CTC U C ATT CTS SSC CTT CCT CCC SAC 1CS
JTO " • • • • • • • • • I t _T 290lrg Arg Thr Til Til Thr Sly Til Cla Htt 111 lrg Lyt Thr U a Cln cla Glr lit H i Sir U p U n Til Clr Til U a U a Arg 01rCSC ACC ICC STS STS ACC SCT CTS U S ATC U C CCC U C ACC TTG U S SAS SSC ATT CCT CCC U C U T CTS CCC CTC CTC CTC CSC GST
300 310 320Til Itr irg Sin Slo Til Sit Arg Sir Sin Til U s All Lyt Pro Cly S«r lit Thr Pro III Thr Lrt Pht Cls H i Sir Vil Tyr VilCTC ACC CCC CAC G1C CTC U C CCC CCC CAC CTC CTC CCC AAC CCT SCO ACC ATT ICC CCC U C ACC AAG TTT GAC CCC TCS STO TAT GTS
330 340 350Ltt Lrt lyt Cls Clt Cly Clr Arg lit Thr Clr Pht Pht Sir Clr TTT Arg Pro Sin Pht Tyr Pht Arg Thr Thr U p Til Thi '.ly TilTTS U C U C U S SAC S«T SSA CCS CAC ACS CCC TTT TTT TCS CCC TAC CCT CCC CAC TTT TAC TTT CCS ACS ACS SAC STS ACS SCC STS
T i l S i t Lts Pro Pro S i r T i l Cls Btt T i l Htt Pro C_r Asp Aim T t l Thr Phi Thr T i l Cls U s I I I Lrt Pro T i l Clr Lta cTo ClaSTS CAS TTC CCT CCC CCC CTC UC ATC CTC ATC CCT CCC CAC U C CTC ACS TTT ACS STS U C CTC ATC U S CCS CTC CCC CTS SAC CAC
Sir Ltt Art Pht All l i t Arf Sla Clr Clr Arg Thr Til Clr All Clr Til Til Tbr Lyt l i t Ua Cla »**CCT TTC CSS TTT CCC ATC CCT U S CCT CCC CCC ICC CTC CSC CCC CCC CTC CTC ACC U C ATC a s SAS T U SCTUCCTATCCCCUCATCCCC M l !
ATCUCCTCCC6CI.111 IIUCUCAAUCCCTCUCCCCTCCCrtUCAAUTCCTCSACSCSSCCCSCCCTTCCCCCCCCCACCTCTCCCCCCCUTCCCCCTACCCACCC [CCCI 1577
Fig. 3. Sequence of the tufl gene of T.thermophilus. The cyanogenbromide fragments CB1-CB12 were identified by protein sequencing(•) and deduced from the positions of methionine residues. CB1and CB4 indicated by thick lines were labeled by GTP . andphotolabeled by GDP, respectively. The putative Shine-Dalgarnosequence is indicated.
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Table 1. Nucleotide composition of the codons used in theEF-Tu genes of T.thermophilus tufl (TT) and E. coli tufA
(EC) in percent.
Nucl.
GATC
totalTT EC
41.818.718.620.9
27.424.122.625.9
1stTT
44.325.110.120.5
letterEC
42.225.19.622.9
2ndTT
17.830.531.221.0
letterEC
17.030.730.322.0
3rdTT
63.30.514.521.2
letterEC
22.816.527.932.8
The nucleotide composition in the codons of the thermophilic
tufl gene is summarized in table 1 and compared to the tufA gene
of E.coli. As expected, the G+C content in the thermophilic gene
is higher than that in E. coli. This difference is much more
pronounced in the third letter of the codons. Futhermore, in the
case of the T.thermophilua gene G is an especially prefered
nucleotide in this position. The structural gene is preceded by a
purine-rich, putative ribosomal binding sequence which continues
up to the ATG protein initiation site. The codon usage in T. ther-
mophilus is considerably different from that in E.coli (table 2).
Table 2. Comparison of the codon usage in the T. thermophilus tufl(TT) and E. coli tufA (EC) genes.
TTEC
TTEC
TTEC
TTEC
GlyGGG
241
ArgAGG
3
TrpTGG
21
CGG
19
*GGA
1
AGA
—
0
TGA
1
*
CGA
-
GGT
819
SerAGT
1
CysTGT
1
*
CGT
521
GGC
721
*AGC
2
*
TGC
12
*
CGC
2
GluGAG
377
LysAAG
205
o
TAG
GinCAG
00 C
O
*GAA
30
*AAA
18
0
TAA
1
*CAA
-
AspGAT
14
AsnAAT
2
TyrTAT
32
HisCAT
1
*GAC
2320
*AAC
97
ft
TAC
CO
C
O
*CAC
1210
ValGTG
454
MetATG
1210
LeuTTG
11
LeuCTG
1027
*GTA
110
HeATA
-
*TTA
-
*
CTA
—
*GTT
424
*ATT
133
PheTTT
101
*
CTT
51
*GTC
2
*
ATC
826
*
TTC
213
*
CTC
1
AlaGCG
198
ThrACG
29
SerTCG
3
ProCCG
1519
*GCA
5
*ACA
1
*TCA
-
*
CCA
1
*
GCT
313
*ACT
13
ft
TCT
7
*CCT
6
ft
GCC
51
*ACC
316
ft
TCC
13
*ccc
2
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I V H T C T I C B * D B G K T T L T A A
I V N V C T I C B f D B C K T T L T A A
P B V N I C T I C K V D B C K T T L T A A
EtRTEP D I M I C T I C I V D B C K T T L T A A
II P M V E Vtkj) Y CBI DKAPEERA R C
T i t CAAtAFDQ-
CANFLDYAA|l DKAPEERARC
-C NSK
' 6 0
99
96
9 *
I T I N T A K T E V E T A I R B Y S I V D C P C I A D T I I NHITCAAOHD CAILVVEAAD CPMPQTDEKlJ 110
ITIHtQlVET Q I P T « « T Q I V DCPCBADrfvjl NHITCAAOHD C A I L V V|ALJT|D GPHPOTREBID 119
I T I ^ T A I T E I ElAIRKTSBf DCPCBADYII NHITCAAQHD C A iQ f «|AJA|TJD CgMP9T I [^L 196
ITIMTABVEr E1 H m B T[A]I V DCPClADvfvlt MMITCAAgMD CAILVVBAAD CPMPQTKEBl| lit
TT
EC
SC
ES
L L A U I t V P T I V I F M I V D H
L L A H I C l k
LLAKOVCVI
VDDPELLDLV EHEV
i vrh.biK]CJDH VDDHELLELV EMEV
IVVFV4KVD|T HDDPEQ.ELV EH
mjEHg [7pp f l r LLEL I EJTIEII
TEFPCD E*PV
TEFPCDDI
I I C S A L L A L E
THI v ICSALIKALE
I_fl«CSAL(c ALE
PV IP SSALLS^E
1 to
1 T9
116
179
VDETI PTPE
vrjspr 1 PTPTITB
n *2 1 «
Fig• 4. Comparison of the tight domain of the EF-Tu sequencesfrom T.thermophiluB (TT), E. coll EF-TuA (EC), 5.cerevieiae mito-chondrium (SC) and Euqlena qracilis chloroplast (EG) . Regions ofhomology are framed. Amino acids of the putatiue GDP bindingdomain are underlined. The cys-81 which have all elongationfactors Tu in common is marked by an asterisk.
For example the lysine codon AAG is used twenty times in the
T.thermophilus EF-Tu gene but AAA is absent. On the other hand,
in the E.coli tufA gene the codon AAG is used only five times
whereas AAA appears eighteen times. The only exceptions to the
preference for G and C at position 3 of the codon exists for
phenylalanine and isoleucine. In these cases T is prefered over
C in the third position. This is in accordance to the observation
that in T.thermophilus codons with a C in the third position are
generally avoided (table 2).
The protein sequence of T.thermophilus elongation factor Tu is
highly homologous to the E.coli elongation factor. In fig. 4 the
sequences of elongation factor Tu from T . thermophilus, E . coli
(3, 4), Saccharomyces cerevisae mitochondrium (5) and Euqlena
qracilis chloroplasts (6) are compared. Identical regions were
found in the sequences of all four proteins. In general the four
proteins show a high degree of homology especially in the guano-
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sine nucleotide binding domain. Regions where the four sequences
are not homologous are confined mostly to loops. A remarkable
feature of the T.thermophilus elongation factor Tu are ten amino
acids in the region 181 - 190. This sequence is absent in E.coli
and is partially absent in yeast mitochondrial EF-Tu. In Euqle-
na qracilis chloroplast EF-Tu this sequence is present and con-
tains several basic amino acids as is the case with T.thermophi-
lus . By comparing the amino acid sequences there is no obvious
structural feature which could be attributed to the thermostabi-
lity of T.thermophilus EF-Tu. In contrast to an earlier work
which reported the presence of a disulfide bridge (11) we identi-
fied only one cysteine residue in the protein.
Expression of T . thermophilus EF-Tu was achieved by transferring
pLS 601 and pLS 652 carrying the 6.6 kb Bglll and the 6.6 kb
BamHI fragment, respectively, to an E.coli minicell producing
strain. In case of pLS 601 EF-Tu was identified as a radioactive
protein band comigrating with the T.thermophilus EF-Tu sample
(fig. 5, lane 3). This band showed a positive reaction with anti
EF-Tu GDP antibodies from rabbit (data not shown). Three addi-
tional proteins were expressed from pLS 601.
No expression occurs using pLS 652 suggesting that the promo-
tor region is situated at least 1.5 kbp upstream from the T.ther-
mophilus tufl gene.
In order to identify the nucleotide binding domain of EF-Tu
from T.thermophilus and especially to clarify the role of the
insertion of the additional 10 amino acids (residues 181-190) in
the protein, we performed affinity labeling experiments. Elonga-
tion factor Tu was therefore prepared in a nucleotide-free form
and charged with radioactive guanosine-5'-diphosphate or guanosi-
ne-5'-triphosphate. In one experiment EF-Tu*[ C]GTP was oxidized
by sodium periodate and subsequently reduced with sodium cyanobo-
rohydride. After cyanogen bromide cleavage of the labeled protein
the radioactive fragment was identified by autoradiography
(fig. 6). Assignment of cyanogen bromide fragments was performed
by their partial sequencing in a liquid phase sequenator. GTP
binds specifically to a region containing the 10.1 kD cyanogen
bromide fragment CB1 (fig. 3) . This part of the elongation
factor Tu originates from the N-terminus and contains a so called
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1 2 3 kDI
— - 80
50
- 30Fig• 5 . Autoradiography. of 35S-labeled
,- 20
crude cell lysatea of E. coli minicellacarrying different T.thermophilus DNAfragments cloned in pBR 322.Lane 1: minicells harbouring pBR 322;lane 2: minicella harbouring pLS 652;lane 3: minicells harbouring pLS 601.
glycine loop (residues 20-28) which was suggested to be a part
of the GDP binding domain in the E•coli protein (25). In another
affinity labeling experiment the nucleotide-free EF-Tu was char-32
ged with [B P]GDP and the complex irradiated with a laser. In
this case the 5.0 KD fragment CB4 (fig. 3) was predominantly
labeled by a guanosine nucleotide. This fragment contains a part
of T.thermophilus EF-Tu which corresponds to the helical domain F
of the E.coli protein (25). Eight of ten aminoacids comprising
the extra loop (residues 181-190) which is not found in E .coli
EF-Tu is localized at the N-terminus of this fragment.
The results of both affinity labeling experiments are consis-
tent with placing the extra loop in the vicinity of the GDP-
binding site in T.thermophilus.
DISCUSSION
The elongation factor Tu from T.thermophilus has a molecular
weight of 44,600 D, only slightly higher than the EF-Tu from
E. coli • Determination of the molecular weight by SDS-PAGE pro-
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A BkD 1 2 3 4 kD
10.1 -
I- 5.0
Fig. 6. Affinity labeling of the GDP/GTP-binding site of EF-Tu.E^jTu was labeled by [U C]GTP . (A) and photolabeled by[ P]GDP (B). Cyanogen bromide fragments were separated by SDS-urea-polyacrylamide gelectrophoresis (lane 1 and 3). The gel wasdried and analysed by autoradiography (lane 2 and 4). The 10.1 kDand the 5.0 kD cyanogen bromide fragments correspond to CB1 andCB4 in fig. 3. For details see 'materials and methods' .
vides a considerably higher value of 51,000 D. This apparent
difference is not as large as that found for the E•coli EF-
Tu (26), probably due to the more lipophilic character of the
thermophilic protein.
A typical feature of proteins from thermophilic bacteria is
their low cysteine content (27). Correspondingly, the T•thermo-
philus EF-Tu has only one cysteine residue compared to three in
the E. coli and B.stearothermophilus elongation factors Tu (28).
The cysteine present in the T.thermophilus EF-Tu corresponds to
residue 81 in the homologous E.coli protein. This cysteine is
conserved in all procaryotic elongation factors Tu and can be
specifically labeled with N-tosyl-L-phenylalanylchloromethane
(28). This modified EF-Tu interacts with guanosine nucleotides as
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does the native protein but binds the aminoacyl-tRNA poorly.
Therefore cys-81 is probably involved in the binding of aminoa-
cyl-tRNA to EF-Tu'GTP (28). This hypothesis is supported by the
fact that the sequence corresponding to residues 79 - 88 of the
T.thermophilus EF-Tu is identical for all known procaryotic fac-
tors Tu .
Typical changes are apparent comparing the amino acid compo-
sition of homologous proteins from thermophilic and mesophilic
bacteria. For instance in thermophilic proteins glutamic acid is
preferentially used in place of aspartic acid and arginine is
prefered over lysine (29). These changes result from an increased
usage of codons with a high G+C content in thermophilic bacteria.
In the case of EF-Tu from T.thermophilus there is a preference
for valine (38 in E. coli and 52 in T.thermophilus) over isoleu-
cine (29 in E.coli and 21 in T.thermophilus) . This is related to
the base composition of the codons for these amino acids. T.ther-
mophiluH uses the GTG valine codon very often whereas the ATA,
ATC and ATT codons for isoleucine are avoided. The evolutionary
pressure towards codons with a high G+C content is obvious for
almost all codons used in the T.thermophilus EF-Tu gene. A high
G+C content is most pronounced in the first and third codon
letter. This phenomenon was also observed for the moderate ther-
mophilic B.BtearothermophiluB genes (30, 31) - in a less pro-
nounced manner - and confirmed for the gene of isopropylmalate
dehydrogenase in T. thermophilus (32), where a very high G+C
content (89 %) in the third letter was found. A remarkable excep-
tion for the preference of codons with a high G+C content in
thermophilic genes is found in the codons for phenylalanine and
isoleucine. In the T • thermophilus tufl gene the phenylalanine
codon TTT is used ten times and the codon TTC only three times,
whereas an opposite ratio of 1 to 13 is found in the E.coli tufA
gene. Similarily the codon ATT is prefered over ATC for isoleu-
cine in the thermophilic protein in contrast to the mesophilic
variant. For unknown reasons in the thermophilic tuf gene the TTT
(ATT) codon has an advantage over the TTC (ATC) codon. However,
this is not the case in the T.thermophilus isopropylmalate dehy-
drogenase gene. Parker and Precup recently reported that leucine
is misincorporated with a higher frequency at UUC than UUU in
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E•coli (33), a finding which may reflect the stability of
codon : anticodon interactions involving UUN codons. As an alter-
native explanation the differences in codon usage for phenylala-
nine in E.coli and T. thermophilus tuf genes could be due to
different concentrations of tRNA isoacceptora in both bacteria.
However, in E . coli as well as in T.thermophilus only a tRNA
with an anticodon GAA was identified (K. Watanabe, M. Sprinzl,
unpublished). A possible explanation for the unusual phenylala-
nine and isoleucine codon usage Mould be the different distribu-
tion of the respective codons in the two T.thermophilus tuf
genes. In such a case, the unusual UUU and AUU codons could have
a regulatory function in expression of the different tuf genes.
The tuf2 gene of T.thermophilus has to be sequenced to test this
possibility .
The T.thermophilus EF-Tu gene has a long open reading frame in
the complementary DNA strand. Whether this is connected to the
fact that in highly expressed genes the codons complementary to
nonsense codons are extremely rare (34) or this arrangement is
important for a regulatory principle connected with an anti-sense
mRNA remains to be clarified.
Expression of T . thermophilus EF-Tu in E . coli is possible but
not efficient. There are several factors which could negatively
influence the expression. A toxic effect of the thermophilic EF-
Tu on the translation system of E.coli can be excluded since
other proteins encoded on the plasmid pLS 601 (e.g. Q-lactamase)
are normally expressed. Comparison of the translation products of
pBR 322 and pLS 601 indicates the additional expression of four
proteins. If the tuf 1 gene of T.thermophilus is a part of a
polycistronic mRNA, homologous to the E.coli str mRNA (35), these
translational products could correspond to the T. thermophilus
variants of the E.coli EF-G, EF-Tu and ribosomal proteins S7 and
S12. An identical gene organization exists for Bacillus stearo-
thermophilus (H. Kimura, personal communication). Since the two
putative S7 and S12 proteins (17 kD and 22 kD) are expressed to
an appreciable amount in the minicell system a misfunction of
their T.thermophilus promotor in E.coli is not likely. The long
ribosomal binding sequence in T.thermophilus as compared to E.co-
li (36) may be a reason for the low expression rate of T • thermo-
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philus EF-Tu in E. coli • Work is in progress to clarify these open
questions.
Acknowledgements
We thank Dr. B. Wittmann-Liebold and J. Brockmoller for se-
quencing the EF-Tu cyanogen bromide fragments, Dr. N. Schumann
for advice with the minicell expression system, R. Marmorstein
and Dr. H.G. Faulhammer for discussions and J. Beck for technical
assistance. This work mas supported by the Deutsche For-
schungsgemeinschaft SFB 213/D5 and Fonds der Chemiachen
Indus trie.
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