Nucleic Acids Research Advance Access published online on July 24, 2008
Nucleic Acids Research, doi:10.1093/nar/gkn462
© 2008 The Author(s)
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/2.0/uk/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
A unique conformation of the anticodon stem-loop is associated with the capacity of tRNAfMet to initiate protein synthesis
Pierre Barraud1,
Emmanuelle Schmitt2,
Yves Mechulam2,
Frédéric Dardel1 and
Carine Tisné1,*
1Laboratoire de Cristallographie et RMN Biologiques, Université Paris Descartes, CNRS, 4 avenue de l’Observatoire, 75006 Paris and 2Laboratoire de Biochimie, Ecole Polytechnique, CNRS, 91128 Palaiseau, France
*To whom correspondence should be addressed. Tel: +33 1 53 73 15 72; Fax: +33 1 53 73 99 25; Email: carine.tisne{at}univ-paris5.fr
Received May 26, 2008. Revised June 30, 2008. Accepted July 2, 2008.
 |
ABSTRACT
|
|---|
In all organisms, translational initiation takes place on the
small ribosomal subunit and two classes of methionine tRNA are
present. The initiator is used exclusively for initiation of
protein synthesis while the elongator is used for inserting
methionine internally in the nascent polypeptide chain. The
crystal structure of
Escherichia coli initiator tRNA
fMet has
been solved at 3.1 Å resolution. The anticodon region
is well-defined and reveals a unique structure, which has not
been described in any other tRNA. It encompasses a Cm32•A38
base pair with a peculiar geometry extending the anticodon helix,
a base triple between A37 and the G29-C41 pair in the major
groove of the anticodon stem and a modified stacking organization
of the anticodon loop. This conformation is associated with
the three GC basepairs in the anticodon stem, characteristic
of initiator tRNAs and suggests a mechanism by which the translation
initiation machinery could discriminate the initiator tRNA from
all other tRNAs.
|
INTRODUCTION
|
|---|
During translation initiation, the start codon of the message
must be identified and aligned in the P-site of the 30S subunit,
so that it basepairs with the anticodon of initiator tRNA. In
Escherichia coli, this step involves initiation factor IF3 and
requires the presence of three consecutive GC base pairs closing
the anticodon loop. Interestingly, these GC base pairs are an
exclusive hallmark of cytoplasmic initiator tRNAs from all living
organisms (
1). It has been shown for a long time that three
consecutive GC pairs in the anticodon stem are a crucial feature
that distinguishes initiator tRNA from elongator tRNAs during
translational initiation (
2–5). The presence of this specific
sequence in the anticodon stem is associated with a modified
reactivity towards nucleases and chemical reagents, suggesting
that it induces structural differences related to the translation
initiation process (
2–4). However, currently available
structures of initiator tRNA have so far provided little clues
as to what this specific anticodon conformation might be, probably
because this stem-loop is often less ordered in crystal structures
(
6,
7). An NMR study comparing initiator and elongator stem-loop
structures showed that they have closely similar solution structures
(
8). However, in the same study, NMR data collected at low temperature
revealed a possible second conformation of the initiator stem-loop
that could not be further analyzed for technical reasons. In
addition, despite the large amount of structural data accumulated
on the ribosome (
9–11), it is not yet fully understood
how the initiator tRNA is selected among all other tRNAs during
initiation. Recent crystal structures of 70S ribosome functional
complexes (
9–11) provide a detailed description of how
the ribosome interacts with its mRNA and tRNA partners [for
a recent review, (
12)]. Actually, the ribosome makes a number
of contacts with the anticodon arm of tRNA in the P-site. Among
these, the universally conserved nucleotides G1338 and A1339
which are located in the head of the small subunit form type
II and type I A-minor interactions (
13) with the GC base pairs
29:41 and 30:40 of initiator tRNA. By mutational studies (
14,
15),
these interactions were demonstrated to help in differentiating
between the initiator and the elongator tRNAs. However, displacement
by IF3 of initiator-like tRNAs that contain these two GC pairs
indicates that an additional feature allow to distinguish them
from authentic initiator tRNAs (
14,
15). Additionally, although
the three GC pairs are required for discrimination of initiation
tRNA by IF3, they are not sufficient to specify the identity
of initiator tRNA (
4,
16). These results are in favor with the
formation of an additional interaction possibly specific to
the anticodon region of the initiator tRNA that would favor
its binding to the P-site in the presence of IF3.
We have determined the crystal structure of E. coli initiator tRNAfMet at 3.1 Å resolution. Overall, tRNAfMet has the classical L-shape geometry, with usual tertiary interactions. However, its structure reveals a unique conformation of the anticodon stem-loop, which explains previous biochemical data and provides information of its specific function in translation initiation.
|
MATERIALS AND METHODS
|
|---|
tRNA purification
The
E. coli tRNA
fMet was overexpressed from plasmid pBSTtRNA
fMet in
E. coli JM101TR using a protocol derived from that of Meinnel
et al. (
17). Briefly, after phenol extraction of RNAs from bacteria,
total tRNA was separated by gel filtration on a HiLoad 26/60
Superdex 75 prepgrade chromatography column (Amersham Biosciences)
equilibrated in 25 mM Tris–HCl pH 7.0. The overexpressed
tRNA
fMet was then separated from other tRNAs by an anion exchange
step (Resource Q column) equilibrated in 25 mM Tris–HCl
pH 7.0. tRNAs were eluted using a 350–550 mM NaCl gradient
in the same buffer. The tRNA
fMet was further purified by a hydrophobic
interaction step (Phenyl Superose column) equilibrated in 10
mM ammonium acetate pH 6.5, 1.7 M ammonium sulfate. tRNA
fMet was eluted using a 1.7–1.0 M ammonium sulfate reverse
gradient. The fractions containing the purified tRNA
fMet were
pooled, dialyzed against 50 mM Tris–HCl pH 8.0, 100 mM
KCl, concentrated using Amicon® Ultra (Millipore) and stored
at –20°C.
Crystallization and crystal characterization
tRNAfMet was prepared at a initial concentration of 3 mg/ml in 50 mM Tris–HCl pH 8.0, 100 mM KCl and 10 mM MgCl2 and crystallized by the vapor diffusion method at 19°C in several conditions. All conditions contained at least 2.0 M ammonium sulfate as a precipitating agent. Suitable crystals for diffraction data collection, were grown up at two different pH conditions: pH 4.6 (2.0 M ammonium sulfate, 100 mM AcOH/AcONa pH 4.6) and 8.0 (2.0 M ammonium sulfate, 50 mM Tris–HCl pH 8.0). Crystals grew up to 100 µm within 1 week. The hexagonal crystals belonged to space group P6422 with one tRNAfMet per asymmetric unit and with a particularly high solvent content of 79% (Table 1 for statistics).
Data collection, structure solution and refinement
The crystals were harvested, soaked in a cryoprotectant solution
[2.2–2.4 M ammonium sulfate, MgCl
2 10 mM, glycerol 20%
(v/v), and 50 mM AcOH/AcONa pH 4.6 or 50 mM Tris–HCl pH
8.0 depending the pH at which the crystals were grown up] for
about 1–5 min and flash-frozen in liquid nitrogen before
data collection. Diffraction data were collected at beam lines
ID14–3 and ID29 of the European Synchrotron Radiation
Facility (ESRF, Grenoble, France). All crystallographic calculations
were performed using the CCP4 suite version 6 (
18) as implemented
in the graphical user interface (
19). X-ray diffraction data
were processed using MOSFLM (
20) and scaled with SCALA (
21).
The structure of tRNA
fMet was solved by molecular replacement
using the program PHASER (
22) and the coordinates of tRNA
fMet from the
E. coli tRNA
fMet/formylase complex (PDB entry code
2FMT) as a model. Model and map visualizations for manual reconstruction
were performed with the program COOT (
23). In the last stages
of refinement, TLS parameters (
24) were refined using one group
for the entire tRNA molecule. The acidic structure was refined
as described in the following paragraph, and the model was then
used to refined the basic structure.
Coordinates and structure factors of E. coli tRNAfMet have been deposited at the Protein Data Bank with the accession code 3CW5 and 3CW6.
|
RESULTS AND DISCUSSION
|
|---|
Structure determination
We have solved the crystal structure of the
E. coli initiator
tRNA
fMet at two pH conditions (i.e. 4.6 and 8.0) using careful
treatment of data anisotropy. Indeed, the diffraction patterns
of the two crystal forms were severely anisotropic, with the
acidic condition giving however higher resolution limits (
Table 1).
For instance, in the acidic condition, diffraction limits are
2.8 Å along the
a* and
b* directions, and 3.4 Å
along the
c* direction. We first attempted to refine the structure
using the anisotropic scaling procedure applied by REFMAC (
25).
However, the obtained electron density maps were relatively
featureless, especially around the anticodon stem-loop. To improve
map quality, we then tried the procedure described by David
Eisenberg's group (
26) to deal with highly anisotropic data
(
http://www.doe-mbi.ucla.edu/~sawaya/anisoscale/). Briefly,
data falling outside an ellipse centered at the reciprocal lattice
origin and having vertices at 1/2.8, 1/2.8 and 1/3.4 Å
–1 along
a*,
b* and
c*, respectively, were removed. After this
ellipsoidal truncation, anisotropic scale factors were applied.
Lastly, a negative isotropic B factor was used to restore the
magnitude of the high-resolution reflections diminished by anisotropic
scaling. The statistics of the anisotropically scaled dataset
are shown in
Table 1. The structure was then refined to a resolution
of 3.1 Å against the anisotropically scaled data using
the program REFMAC (
25). This yielded maps of very good quality
including for the anticodon region (
Figure 1 and
Supplementary Figure 1).
The final model shows a
R-factor of 24.1% and a
Rfree factor
of 27.0% (
Table 1). Data from crystals grown under basic conditions
were processed similarly. The corresponding structure was refined
to a resolution of 3.3 Å (
R = 23.1%;
Rfree = 27.4%). Otherwise
stated, we will describe the tRNA
fMet structure obtained in
the acidic conditions that is solved at a higher resolution.
Overall model and crystal packing
The overall tertiary structure of tRNA
fMet matches the well-known
L-shape structure first revealed in yeast tRNA
Phe (
27) with
usual tertiary interactions (
Figure 2): the reverse-Hoogsteen
base pairs s
4U8•A14 and T54•A58, the
trans Watson–Crick
G15•C48 (‘Levitt pair’), the one bond imino-4-carbonyl
G18•
55, the Watson–Crick base pair G19–C56
forming the corner of the L, the Watson–Crick like G26•A44,
the ‘U-turn’ at U33 in the anticodon loop and at
55 in the T loop, and finally the base triples A46•(G22–C13)
and G45•(G10–C25). The base triple equivalent to
the A9•(A23–U12) found in tRNA
Phe, i.e. G9•(C23–G12)
was not formed in tRNA
fMet where N7-G9 is at 5.2 Å away
from N4-C23.
View larger version (19K):
[in this window]
[in a new window]
[Download PowerPoint slide]
|
Figure 2. Tertiary interactions on the secondary structure of E. coli tRNAfMet. Solid lines represent base–base tertiary interaction through hydrogen bonds, and dashed lines represent base stacking interactions.
|
|
The crystal packing is quite remarkable. First, the acceptor
arm of the tRNA molecule interacts with the major groove of
the acceptor stem of a symmetry-related tRNA molecule, thereby
forming a triple helix (
Figure 3a and b). Namely, nt 72–76
of one tRNA molecule are basepaired in an antiparallel manner
to G2-G6 of the acceptor stem of another tRNA molecule. The
C1 nucleotide is very mobile and is not visible in electron
density maps. However the triple helix formation necessarily
rejects C1 in the solvent with G2 rather stacks on A72. Therefore,
the always mismatched 1 and 72 bases, characteristic of bacterial
initiator tRNAs, are not face-to-face. Another packing region
involves anticodon–anticodon base pairing (
Figure 3c and
d). Anticodon loops interact through pairing between C
34A
35U
36A
38 and the four same bases in a symmetry-related tRNA molecule,
thereby forming two Watson–Crick AU pairs and two non-canonical
CA pairs. The same packing interaction at the level of the anticodon
was previously observed in the
E. coli tRNA
fMet/formylase complex
(PDB entry code 2FMT) and in the yeast initiator tRNA crystal
structure (PDB entry code 1YFG). In tRNA
Asp, the crystal packing
also involves anticodon–anticodon interactions (
28). We
cannot exclude that the crystal packing at the level of the
anticodon loop, in particular contacts between C34 and A38,
could contribute to the stabilization of the anticodon loop
conformation, in particular stabilisation of the non-canonical
Cm32•A38 base pair described in the following paragraph.
Although the overall structure globally resembles that of elongator
tRNAs, there are however striking features at the level of the
anticodon arm that deserve discussion.
The anticodon stem-loop of initiator tRNA adopts a non-canonical conformation
The structure of the anticodon stem-loop region can be described by three specific features (Figure 4): (i) an additional Cm32•A38 unusual base pair extending the anticodon stem (Figure 4c). (ii) Formation of a base triple between A37 in the anticodon loop and G29-C41 in the stem (Figure 4d). This induces a large turn in the phosphate backbone just after the anticodon triplet. (iii) An unusual stacking pattern for the anticodon loop: A38 is directly stacked onto the last base of the anticodon (U36), whereas it is stacked on nt 37 in all other tRNA structures (Figure 4a and b). Overall, this induces a more compact and constrained geometry, stabilized by additional specific interactions involving the first and the last initiator-characteristic GC pairs. The Cm32•A38 wobble-like base pair, not encountered in other tRNA structures (29), is stabilized by stacking onto G31-C39 and by a crystal contact between A38 and C34. It involves a polar contact between N1(A38) and O2(Cm32) in addition to the N3(Cm32)–N6(A38) hydrogen bond and suggests that the N1 group of A38 is protonated (Figure 4c). The particular Cm32•A38 wobble-like base pair is probably formed because of the acidic pH of the crystallization conditions. Unfortunately, the lower resolution of the model refined from crystals grown at pH 8.0 did not allow us to confirm this proposal, since the prediction on the protonation state from the structure depends on small variations in base pair orientation that could not be strongly reliable at this resolution. In the structure of the E. coli tRNAfMet/formylase complex (30), which was determined using crystals grown at pH 6.6, the Cm32•A38 base pair is less tight than in the present structure. However, the two bases are also facing each other. Such an (A+)•C base pair was already shown to occur, with a pKa of about 6.0, in the NMR structures of hypomodified tRNA3Lys anticodon stem-loop (31). In tRNAfMet, as a consequence of the (A+)•C pairing, the anticodon stem extends to Cm32•A38.
View larger version (24K):
[in this window]
[in a new window]
[Download PowerPoint slide]
|
Figure 4. Unique conformation of the anticodon arm of the E. coli initiator tRNAfMet: (a) the anticodon arm of tRNAfMet, (b) for comparison tRNAPhe anticodon arm (PDB ID 1EHZ
[PDB]
), (c) the Cm32•A38 wobble-like base pair observed in crystal structure of tRNAfMet and (d) the A37• (G29-C41) base triple observed in crystal structure of tRNAfMet.
|
|
Additionally, A37 participates in a base triple within the major
groove of the anticodon stem. The Watson–Crick edge of
A37 interacts with the Hoogsteen edge of G29 and is stabilized
by an hydrogen bond between A37 O4' and C39 N4 (
Figure 2d).
This triple interaction is probably strengthened by protonation
of A37 N1. The A37•(G29-C41) interaction has never been
described and is clearly observed in the present structures
obtained from crystals at two pH conditions (see
Supplementary Figure 2 for the basic structure). As a consequence, the major groove
of the anticodon stem is severely obstructed at the level of
the three GC pairs. This could explain the previously reported
unreactivity of the N7 groups of G29, G30, G31 in the major
groove of
E. coli initiator tRNA anticodon stem (
32). In particular,
the N7 group of G30 which is reactive in all elongator tRNAs
does not react with dimethyl-sulfate in tRNA
fMet. In conclusion,
two features are undoubtedly conserved in the tRNA
fMet structures
solved at two pH conditions: the peculiar stacking of bases
in the anticodon loop and the base triple made by A37.
E. coli initiator tRNA was previously crystallized in complex with methionyl–tRNAfMet transformylase (30). The anticodon stem-loop region does not interact with the protein. In this structure, A37, although not involved in a base-triple with G29-C41, also fails to stack between U36 and A38 (Figure 3a and b), in contrast to what is observed in all available elongator tRNA structures (27,33–38). Differences observed for the position of A37 in the present structure and in the tRNAfMet/formylase complex structure are in favor of its mobility. In this context, it should be noted that in the structure of tRNAfMet/formylase complex the position of the adenine ring of base 37 was only tentatively modelled (30). Increased mobility of A37 in the tRNAfMet/formylase complex is also supported by an increased RNase sensitivity at phosphate G29, G30 upon binding of tRNAfMet to the formylase (39). Finally, although in yeast initiator tRNA structure the anticodon region is poorly defined (6), a similar organization of the anticodon bases was observed, with U36 stacked on A38 and A37 rejected in the solvent. Therefore, in available X-ray structures, initiator tRNAs appear consistently different from elongator tRNAs at the level of the base stacking of the anticodon loop. This corroborates their unique S1 nuclease cleavage pattern (2,3,40). Indeed, all initiator tRNAs (E. coli, yeast and mammalian) are cleaved after C34 and A35 (2), while the anticodon loops of elongator tRNAs, including elongator tRNAMet, are much more sensitive, being cleaved after U33, C34, A35 and U36 (2,40). Interestingly, in yeast, the anticodon loop sequences of initiator and elongator tRNAMet are identical, including for the post-transcriptional base modification. These observations led to the proposal that the three conserved GC base pairs of the initiator anticodon stem were the key determinants for an unusual conformation of the anticodon loop (2–4). This hypothesis is in full agreement with the structure reported here.
Relevance for initiator tRNA discrimination
Mutagenesis of the anticodon or stem-loop showed that the S1 cleavage pattern correlates with the initiator function and selection by IF3 (3,4). This strongly suggests that the peculiar conformation of the anticodon loop of initiator tRNAs is required for their initiator function. This raises the question of the detailed underlying mechanism. In the structure of the Thermus thermophilus 70S ribosome, tRNAfMet is paired with the initiation codon in the P-site (9), and the canonical conformation of the anticodon loop is restored, with A37 stacked between U36 and A38 (Figure 3c). Such a conformation was also seen in the structure of E. coli ribosome with a tRNAfMet anticodon stem-loop paired to mRNA in the P-site (41). This conformation is stabilized by a number of contacts within the P-site. Among these, universally conserved bases G1338 and A1339 make types I and II A-minor interactions with G29-C41 and G30-C40, respectively (9–11). Although the GC pairs are crucial for IF3-dependent tRNAfMet discrimination, they are too far from its 30S subunit binding site to be directly inspected by IF3, according to the current understanding of the position of IF3 (42). This led these authors to propose that under the influence of IF3 binding, G1338 and A1339 might check the identity of tRNAfMet through their minor groove interactions with these conserved GC. By mutational studies, these interactions were actually shown to play a role in the IF3-dependent tRNAfMet discrimination (14,15). However, tRNAs that contain two consecutive GC pairs at positions 29–41 and 30–40 are not resistant to rejection by IF3, indicating that discrimination must involve recognition of at least one additional feature of the tRNAfMet anticodon stem-loop (15). The singular structure of the anticodon stem-loop that we report here strongly supports this idea.
Relevance for translation initiation
Clearly, the ‘37-unstacked’ conformation observed in the anticodon loop of free initiator tRNA is markedly different from the ‘37-stacked’ observed in P-site-bound tRNAfMet. Therefore, the available data suggests that an initiator tRNA must switch between the two conformations during the initiation process. An attractive hypothesis would be that a ‘37-unstacked’ conformation is required at the first stages of initiator tRNA accommodation by the ribosomal P-site and IF3. Recognizing a ‘37-unstacked’ conformation would help to reject elongator tRNAs (Figure 5). In a second step, stabilization of the ‘37-stacked’ conformation would require correct pairing with the AUG initiation codon. Such a conformational transition could be used as a ‘sensor’ that a correct initiation codon has been found. Interestingly, in the present structure as well as in that of the formylase/tRNAfMet complex and in that of yeast initiator tRNA, crystal packing involves only two Watson–Crick base pairs of the anticodon (A35 and U36; see Supplementary Figure 2). In the context of the above hypothesis, such a structure may mimic pairing with an incorrect start codon, unable to trigger a ‘37-stacked’ conformation of the anticodon loop.
View larger version (21K):
[in this window]
[in a new window]
[Download PowerPoint slide]
|
Figure 5. Comparison of the anticodon loop base stacking. (a) E. coli tRNAfMet, (b) E. coli tRNAfMet in the complex with formylase (PDB ID 2FMT), (c) in the P-site (PDB ID 2J00). The ‘37-unstacked’ conformation refers to (a) and (b) structures and the ‘37-stacked’ to the (c) one.
|
|
|
SUPPLEMENTARY DATA
|
|---|
Supplementary Data are available on NAR Online.
|
ACKNOWLEDGEMENTS
|
|---|
The authors acknowledge the European Synchrotron Radiation Facility
for providing the synchrotron radiation facilities on beamlines
ID14-3 and ID29. P.B. was supported by a studentship from the
‘Ministère de la recherche’. We thank the
CNRS for financial support. Funding to pay the Open Access publication
charges for this article was provided by CNRS, French National
Agency of Research.
Conflict of interest statement. None declared.
|
REFERENCES
|
|---|
- Marck C, Grosjean H. tRNomics: analysis of tRNA genes from 50 genomes of Eukarya, Archaea, and Bacteria reveals anticodon-sparing strategies and domain-specific features. RNA (2002) 8:1189–1232.[Abstract]
- Wrede P, Woo NH, Rich A. Initiator tRNAs have a unique anticodon loop conformation. Proc. Natl Acad. Sci. USA (1979) 76:3289–3293.[Abstract/Free Full Text]
- Seong BL, RajBhandary UL. Escherichia coli formylmethionine tRNA: mutations in GGGCCC sequence conserved in anticodon stem of initiator tRNAs affect initiation of protein synthesis and conformation of anticodon loop. Proc. Natl Acad. Sci. USA (1987) 84:334–338.[Abstract/Free Full Text]
- Hartz D, Binkley J, Hollingsworth T, Gold L. Domains of initiator tRNA and initiation codon crucial for initiator tRNA selection by Escherichia coli IF3. Genes Dev (1990) 4:1790–1800.[Abstract/Free Full Text]
- Varshney U, Lee CP, RajBhandary UL. From elongator tRNA to initiator tRNA. Proc. Natl Acad. Sci. USA (1993) 90:2305–2309.[Abstract/Free Full Text]
- Basavappa R, Sigler PB. The 3 A crystal structure of yeast initiator tRNA: functional implications in initiator/elongator discrimination. EMBO J (1991) 10:3105–3111.[ISI][Medline]
- Woo NH, Roe BA, Rich A. Three-dimensional structure of Escherichia coli initiator tRNAfMet. Nature (1980) 286:346–351.[CrossRef][ISI][Medline]
- Schweisguth DC, Moore PB. On the conformation of the anticodon loops of initiator and elongator methionine tRNAs. J. Mol. Biol (1997) 267:505–519.[CrossRef][ISI][Medline]
- Selmer M, Dunham CM, Murphy FVt, Weixlbaumer A, Petry S, Kelley AC, Weir JR, Ramakrishnan V. Structure of the 70S ribosome complexed with mRNA and tRNA. Science (2006) 313:1935–1942.[Abstract/Free Full Text]
- Korostelev A, Trakhanov S, Laurberg M, Noller HF. Crystal structure of a 70S ribosome-tRNA complex reveals functional interactions and rearrangements. Cell (2006) 126:1065–1077.[CrossRef][ISI][Medline]
- Yusupov MM, Yusupova GZ, Baucom A, Lieberman K, Earnest TN, Cate JH, Noller HF. Crystal structure of the ribosome at 5.5 A resolution. Science (2001) 292:883–896.[Abstract/Free Full Text]
- Korostelev A, Noller HF. The ribosome in focus: new structures bring new insights. Trends Biochem. Sci (2007) 32:434–441.[CrossRef][ISI][Medline]
- Nissen P, Ippolito JA, Ban N, Moore PB, Steitz TA. RNA tertiary interactions in the large ribosomal subunit: the A-minor motif. Proc. Natl Acad. Sci. USA (2001) 98:4899–4903.[Abstract/Free Full Text]
- Abdi NM, Fredrick K. Contribution of 16S rRNA nucleotides forming the 30S subunit A and P sites to translation in Escherichia coli. RNA (2005) 11:1624–1632.[Abstract/Free Full Text]
- Lancaster L, Noller HF. Involvement of 16S rRNA nucleotides G1338 and A1339 in discrimination of initiator tRNA. Mol. Cell (2005) 20:623–632.[CrossRef][ISI][Medline]
- Mangroo D, Limbach PA, McCloskey JA, RajBhandary UL. An anticodon sequence mutant of Escherichia coli initiator tRNA: possible importance of a newly acquired base modification next to the anticodon on its activity in initiation. J. Bacteriol (1995) 177:2858–2862.[Abstract/Free Full Text]
- Meinnel T, Mechulam Y, Fayat G. Fast purification of a functional elongator tRNAMet expressed from a synthetic gene in vivo. Nucleic Acids Res (1988) 16:8095–8096.[Free Full Text]
- Collaborative Computational Project Number 4. The CCP4 suite: programs for protein crystallography. Acta Crystallogr. D (1994) 50:760–763.[CrossRef][Medline]
- Potterton E, Briggs P, Turkenburg M, Dodson E. A graphical user interface to the CCP4 program suite. Acta Crystallogr. D (2003) 59:1131–1137.[CrossRef][Medline]
- Leslie AG. The integration of macromolecular diffraction data. Acta Crystallogr. D (2006) 62:48–57.[CrossRef][Medline]
- Evans P. Scaling and assessment of data quality. Acta Crystallogr. D (2006) 62:72–82.[CrossRef][Medline]
- McCoy AJ, Grosse-Kunstleve RW, Storoni LC, Read RJ. Likelihood-enhanced fast translation functions. Acta Crystallogr (2005) 61:458–464.[ISI]
- Emsley P, Cowtan K. Coot: model-building tools for molecular graphics. Acta Crystallogr. D (2004) 60:2126–2132.[CrossRef][Medline]
- Winn MD, Isupov MN, Murshudov GN. Use of TLS parameters to model anisotropic displacements in macromolecular refinement. Acta Crystallogr. D (2001) 57:122–133.[CrossRef][Medline]
- Murshudov GN, Vagin AA, Dodson EJ. Refinement of macromolecular structures by the maximum-likelihood method. Acta Crystallogr. D (1997) 53:240–255.[CrossRef][Medline]
- Strong M, Sawaya MR, Wang S, Phillips M, Cascio D, Eisenberg D. Toward the structural genomics of complexes: crystal structure of a PE/PPE protein complex from Mycobacterium tuberculosis. Proc. Natl Acad. Sci. USA (2006) 103:8060–8065.[Abstract/Free Full Text]
- Kim SH, Quigley GJ, Suddath FL, McPherson A, Sneden D, Kim JJ, Weinzierl J, Rich A. Three-dimensional structure of yeast phenylalanine transfer RNA: folding of the polynucleotide chain. Science (1973) 179:285–288.[Abstract/Free Full Text]
- Moras D, Dock AC, Dumas P, Westhof E, Romby P, Ebel JP, Giege R. Anticodon-anticodon interaction induces conformational changes in tRNA: yeast tRNAAsp, a model for tRNA-mRNA recognition. Proc. Natl Acad. Sci. USA (1986) 83:932–936.[Abstract/Free Full Text]
- Auffinger P, Westhof E. Singly and bifurcated hydrogen-bonded base-pairs in tRNA anticodon hairpins and ribozymes. J. Mol. Biol (1999) 292:467–483.[CrossRef][ISI][Medline]
- Schmitt E, Panvert M, Blanquet S, Mechulam Y. Crystal structure of methionyl-tRNAfMet transformylase complexed with the initiator formyl-methionyl-tRNAfMet. EMBO J (1998) 17:6819–6826.[CrossRef][ISI][Medline]
- Durant PC, Davis DR. Stabilization of the anticodon stem-loop of tRNALys,3 by an A+-C base-pair and by pseudouridine. J. Mol. Biol (1999) 285:115–131.[CrossRef][ISI][Medline]
- Wakao H, Romby P, Westhof E, Laalami S, Grunberg-Manago M, Ebel JP, Ehresmann C, Ehresmann B. The solution structure of the Escherichia coli initiator tRNA and its interactions with initiation factor 2 and the ribosomal 30 S subunit. J. Biol. Chem (1989) 264:20363–20371.[Abstract/Free Full Text]
- Robertus JD, Ladner JE, Finch JT, Rhodes D, Brown RS, Clark BF, Klug A. Structure of yeast phenylalanine tRNA at 3 Å resolution. Nature (1974) 250:546–551.[CrossRef][ISI][Medline]
- Suddath FL, Quigley GJ, McPherson A, Sneden D, Kim JJ, Kim SH, Rich A. Three-dimensional structure of yeast phenylalanine transfer RNA at 3.0angstroms resolution. Nature (1974) 248:20–24.[CrossRef][ISI][Medline]
- Jovine L, Djordjevic S, Rhodes D. The crystal structure of yeast phenylalanine tRNA at 2.0 A resolution: cleavage by Mg(2+) in 15-year old crystals. J. Mol. Biol (2000) 301:401–414.[CrossRef][ISI][Medline]
- Shi H, Moore PB. The crystal structure of yeast phenylalanine tRNA at 1.93 A resolution: a classic structure revisited. RNA (2000) 6:1091–1105.[Abstract]
- Westhof E, Dumas P, Moras D. Crystallographic refinement of yeast aspartic acid transfer RNA. J. Mol. Biol (1985) 184:119–145.[CrossRef][ISI][Medline]
- Benas P, Bec G, Keith G, Marquet R, Ehresmann C, Ehresmann B, Dumas P. The crystal structure of HIV reverse-transcription primer tRNA(Lys,3) shows a canonical anticodon loop. RNA (2000) 6:1347–1355.[Abstract]
- Ramesh V, Mayer C, Dyson MR, Gite S, RajBhandary UL. Induced fit of a peptide loop of methionyl-tRNA formyltransferase triggered by the initiator tRNA substrate. Proc. Natl Acad. Sci. USA (1999) 96:875–880.[Abstract/Free Full Text]
- Wrede P, Rich A. Stability of the unique anticodon loop conformation of E.coli tRNAfMet. Nucleic Acids Res (1979) 7:1457–1467.[Abstract/Free Full Text]
- Berk V, Zhang W, Pai RD, Cate JH. Structural basis for mRNA and tRNA positioning on the ribosome. Proc. Natl Acad. Sci. USA (2006) 103:15830–15834.[Abstract/Free Full Text]
- Dallas A, Noller HF. Interaction of translation initiation factor 3 with the 30S ribosomal subunit. Mol. Cell (2001) 8:855–864.[CrossRef][ISI][Medline]
CiteULike 
Connotea 
Del.icio.us What's this?
TOP
ABSTRACT
INTRODUCTION
.