From the Department of Biochemistry and Molecular Biology, the University of Chicago, Chicago, Illinois 60637
Received for publication, January 27, 2003 , and in revised form, April 24, 2003.
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ABSTRACT |
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INTRODUCTION |
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The reaction catalyzed by Flp and other tyrosine recombinases minimally requires four protein monomers and two DNA segments containing specific sequences recognized by the enzyme (Fig. 1a). The reaction proceeds in a stepwise fashion, with only one strand of each duplex cleaved at a time. Thus, only two of the four protomers are active in each step of the reaction. For Flp, the required DNA site, named FRT (Flp recognition target), is made up of two 13-bp Flp-binding sequences inverted around an 8-bp spacer region, with a third nonessential Flp-binding site separated by 1 bp from the rest of the sequence. However, whereas most other enzymes in this family assemble the catalytic center in cis, using residues from one protomer, Flp uses a unique in trans mechanism, with its active site consisting of residues from two protomers (3, 4). The -helix (helix M) containing the catalytic tyrosine (Tyr343) is donated to an adjacent protomer and cleaves DNA in conjunction with the other active site residues provided by that protomer. Corresponding to half of the sites activity, only one DNA cleavage reaction takes place within an Flp dimer, two of which come together to form a synaptic complex. Each of the two exposed 5'-hydroxyl groups then attacks the phosphotyrosyl linkage in the other Flp dimer of the complex. The resulting Holliday junction intermediate can subsequently isomerize and activate the two protomers whose catalytic tyrosines were dormant during the first half of the reaction. These two tyrosines then engage in a second round of DNA cleavage and ligation reactions, ultimately yielding recombined products. Interestingly, structural and biochemical studies have shown significant differences in the mechanisms by which different recombinases control the activity of their catalytic sites (59).
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The DNA relaxation reaction catalyzed by type IB topoisomerases also proceeds through a 3'-phosphotyrosyl intermediate, and the catalytic similarities between these two families of enzymes correspond to a conserved core structure that harbors the active site (10). Several structures from both families have been determined, including -integrase (11), Cre (1215), HP1 integrase (16), XerD (17), and Flp (4) from the site-specific recombinase family and vaccinia topoisomerase (18) and human topoisomerase I (1921) from the topoisomerase family. Despite low sequence homology among these proteins, the secondary and tertiary structures of their catalytic domains are strikingly similar, and they probably share a common ancestor (10, 22). There are, however, clear differences among these enzymes as well. For example, the topoisomerases act as monomers, whereas the recombinases act as tetramers, and Flp differs from other members of both families in the trans assembly of its active site.
The active sites of both families include, in addition to the nucleophilic tyrosine, five other highly conserved amino acid residues (reviewed in Refs. 2325). In Flp, these are Arg191, Arg308, His305, Lys223, and Trp330. The two arginines and the histidine, but not the lysine and the tryptophan, have been extensively studied in this system (2630). The arginines presumably position the scissile phosphate and stabilize the build-up of negative charge in the transition state. The histidine (replaced by lysine in topoisomerases) is appropriately positioned in the Flp and Cre complex structures to act as the general base that accepts a proton from the attacking tyrosine, although mutagenesis data suggest that it is not essential (27, 30, 31).2 The lysine is essential for catalysis in other recombinases and has been shown to act as a general acid in the cleavage step in the vaccinia topoisomerase reaction, protonating the leaving 5'-hydroxyl group with the help of one of the arginines (8, 3235). The tryptophan is replaced by histidine in most related enzymes, although tryptophan is found at this position in Cre as well. The DNA complex structures of Cre and human topoisomerase I show that the side chain of this tryptophan/histidine forms a hydrogen bond with a nonbridging oxygen of the scissile phosphate, whereas in Flp-DNA structures, Trp330 sometimes forms a hydrogen bond with the free 5'-OH in the active site. Mutation of the equivalent histidines to alanine in vaccinia topoisomerase (His265) and human topoisomerase I (His632) decreased the reaction rates substantially, whereas the effects of glutamine and asparagine replacements were less drastic (36, 37). Experiments on vaccinia virus topoisomerase using phosphorothioate-containing substrates showed that this histidine forms a catalytically important hydrogen bond to one of the nonbridging phosphate oxygens (38). All of these results supported a hypothesis that the key feature of the tryptophan/histidine is its ability to hydrogen-bond with DNA. However, this question had not been addressed experimentally in the tyrosine recombinases.
To investigate the roles that Lys223 and Trp330 play in Flp-mediated recombination, mutagenesis and activity studies have been performed on these two residues in Flpe. Whereas our results confirmed the importance of Lys223, they also provided some surprising insights into the function of Trp330, indicating that it might be more important in maintaining a viable active site through its van der Waals interactions with neighboring amino acids rather than stabilizing a reaction intermediate through its hydrogen bonding capability. We confirmed this by determining the structure of the W330F protein complexed with DNA.
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EXPERIMENTAL PROCEDURES |
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Protein Expression and PurificationThe protein was expressed and purified using a new method recently published (5). Two columns were used: a Talon column that bound the His tag and a DNA affinity column containing Flp-binding sequences. The whole purification process took only 1 day (beginning with frozen cell pellets), yielding an average of 1 mg of protein from 1 liter of cell culture. The protein was stored at 80 °C. It was later dialyzed against 50 mM HEPES (pH 7.1), 1 mM EDTA, 1 mM dithiothreitol, and 15% glycerol and 1 M NaCl overnight and aliquoted before usage. The purification and dialysis were performed at 4 °C.
DNA Recombination AssaysPlasmid pJFS39 was originally provided by Dr. Michael Cox (39). It was amplified in DH5 cells and purified with Qiagen Miniprep kits. 15 pmol of SalI-digested pJFS39 plasmid was labeled with [
-32P]ATP and T4 polynucleotide kinase. Qiagen nucleotide removal kits were used to remove the enzyme and nucleotide afterward. The recombination assay was performed at 30 °C in a 10-µl reaction volume with 2 nM radioactively labeled SalI-cleaved pJFS39, 120 nM Flpe protein, 25 mM Taps (pH 8.0), 200 mM NaCl, 12% glycerol, 2 mM EDTA, and 1 mg/ml bovine serum albumin. The concentration of the DNA was calculated based on the assumption that no DNA was lost during the purification procedure after labeling, and the actual concentration might be slightly lower than 2 nM. The reaction was terminated with 0.4% SDS, and the products were separated on a 0.8% agarose gel. The reaction conditions were similar to those used by Gates et al. (39) with minor modifications. Although polyethylene glycol was used in previous studies to enhance activity, it did not increase the reaction rate in our assays and only induced the appearance of reaction intermediates. It was therefore omitted from the reaction buffer.
DNA Cleavage AssaysSynthentic oligonucleotides were purchased from the Keck biotechnology facility at Yale University and purified by urea polyacrylamide gel electrophoresis. S3 (TAA TCC AGT GGA AGT TCC TAT TCT T) was labeled with [-32P]ATP and purified as described under "DNA Recombination Assays." It was then annealed with S4P (5'-phospho-CTA GAA GAA TAG GAA CTT CCA CTG GAT TA) to form a suicide substrate containing one Flp-binding site. The final substrate for the DNA cleavage assays consisted of both radioactively labeled and unlabeled suicide substrates at a ratio of 1:9. Each 10-µl reaction contained 4 nM DNA substrate, 120 nM Flpe protein, 25 mM Taps (pH 8.0), 200 mM NaCl, 12% glycerol, 2 mM EDTA, and 1 mg/ml bovine serum albumin. The assay was carried out at 30 °C and terminated with 0.4% SDS. The products were separated on a 15% SDS-PAGE gel. Results were quantified using an Amersham Biosciences PhosphorImager. The data were processed using Origin software, and the curves were fit to a hyperbola equation to attain the apparent rate constant for a second order reaction.
Crystallization and Structure DeterminationThe complex of W330F Flpe and T4B4 (T4: TAA GTT CCT ATT CT; B4: TTT AAA AGA ATA GGA ACT TC) was prepared with the same procedure as the original Flp-Holliday junction complex (4). A slightly higher protein concentration, 0.48 mM, was used. Crystals appeared in hanging drops containing 20 mM HEPES (pH 7.0), 11% polyethylene glycol 5000 monomethyl ether, 20% xylitol, 100 mM NaCl, 2 mM dithiothreitol, 10 mM CaCl2, approximately 1 week after the trays were set up. Data were collected from crystals with a size of 0.2 x 0.2 x 0.4 mm at the BioCARS 14BM-C beamline at the Advanced Photon Source using an ADSC Q4 CCD detector. The crystals were in space group P21, with unit cell dimensions of a = 80 Å, b = 117 Å, c = 142 Å, and = 97.3°. The diffraction was anisotropic, with <I/
I> falling below
2 at 2.7, 3.0, and 2.9 Å along the three axes. The data were processed with the HKL suite (40). Initial phases were provided by the WT Flpe structure, which crystallized isomorphously (Protein Data Bank number 1M6X
[PDB]
) (5). The structure was refined with CNS_SOLVE (41), using a combination of 2- and 4-fold noncrystallographic symmetry restraints. Differences in the refined structures of the WT and mutant were in agreement with difference Fourier maps ((FWT FW330F)
WT and (FWT FW330F)
W330F). In addition to changes in the active site discussed under "Results," the DNA strand in the catalytic site of the inactive monomer D could be modeled better as nicked rather than intact. Structure figures were generated with Ribbons (42). Buried surfaces were calculated using CNS_SOLVE with the side chain atoms of the His/Trp residue as molecule 1 and the surrounding protein as molecule 2. The result was the total buried surface area from molecule 1 and molecule 2, and should be divided by 2 when considering only one molecule in the interface.
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RESULTS |
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Trp330 and Lys223 Are Important for ActivitySingle mutations were introduced at Trp330 and Lys223 to study the roles of these two residues in Flp-mediated recombination. Trp330 was substituted with alanine, histidine, glutamine, and phenylalanine, whereas Lys223 was replaced by alanine and arginine. The effects of these mutations were first tested in full recombination assays. The linearized plasmid substrate for the assay, pJFS39, contains a single FRT site with a symmetrical spacer. It can be recombined in two different orientations, one of which regenerates the substrate, whereas the other produces DNA molecules of different lengths (Fig. 1b).
Although recombination catalyzed by the wild type protein reached equilibrium within several hours under our conditions, overnight reactions were carried out for the mutants to allow detection of low activity levels (Fig. 1c). Protein and DNA concentrations were also raised in one experiment to further increase the sensitivity (Fig. 1d). W330A, W330Q, and K223A failed to generate any detectable amount of recombined products. W330H was capable of mediating recombination at a much slower rate, whereas K223R showed an extremely low activity only in the assay where the protein and DNA concentrations were increased. In contrast to the poor performances of the other mutants, W330F displayed an activity level indistinguishable from the wild type in these experiments, a surprising observation in light of the previous hypotheses that the hydrogen bond between the Trp330 side chain and the DNA would be important for catalysis.
The fact that mutating Lys223 to alanine abolished activity whereas K223R restored some enzymatic capability is consistent with previous findings that this lysine acts as a general acid in vaccinia topoisomerase. In Flp, the side chain of Lys223 is also involved in direct contact with a base in the minor groove and therefore may be important for DNA binding. K223A and K223R showed decreased affinities for the DNA column during protein purification (data not shown), suggesting that part of the activity loss might result from impaired DNA binding capabilities.
The long incubation time for the overnight reactions with WT and W330F Flp led to the appearance of some doubly cleaved side products. These double strand cleavage products, like the reaction intermediates, have been observed by others and probably result from slow hydrolysis of the covalent phosphotyrosine intermediate (39, 45).
Comparison of Wild Type and W330F in Recombination AssaysA more detailed comparison was carried out between the activities of the wild type and the W330F mutant by measuring the formation of recombined products at time points before equilibrium (Fig. 2). No detectable difference was observed between the reactions catalyzed by the two proteins, suggesting again that the role of Trp330 in Flp-mediated recombination might be different from previous hypotheses. However, the full recombination reaction requires many steps, and the rate-limiting one may actually be a conformational change in the Holliday junction (46). This could mask a small decrease in the mutant's catalytic activity. A second group of experiments, DNA cleavage assays, was used to determine whether there is any defect in the ability of W330F to catalyze the chemical reactions.
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Comparison of Wild Type and W330F in Cleavage Assays DNA cleavage is the first chemical step in the reactions mediated by this family of enzymes. Our assay used suicide substrates shown in Fig. 3a. The attack of Tyr343 between the Flp-binding site and the spacer region results in a covalent protein-DNA linkage and the excision of two thymines at the end of the DNA top strand, which diffuse into the bulk solution. The reaction is trapped at this stage due to the absence of the 5'-hydroxyl group on the first thymine, which is necessary for the reverse reaction or the subsequent ligation reaction of the recombination process. Because of half of the sites activity, a theoretical 50% of the substrate duplex will be covalently linked to the enzyme when the protein is present in excess. A modest decrease in reaction rate was observed for the W330F mutant, compared with that of the wild type (Fig. 3). The appearance of the covalent protein-DNA product fit better to a second order reaction curve than to a first order one, consistent with the requirement for two DNA-bound Flp protomers to form a single active site. The apparent rate constant for the wild type was estimated to be 1.0 x 108 M1 min1, whereas that for the mutant was roughly 5-fold lower, 0.18 x 108 M1 min1. This decrease probably reflects a slight defect in catalysis rather than in DNA binding, because these assays were carried out with a large excess of protein, above the estimated Kd (47), and because our preliminary mobility shift assays using a single Flp-binding site indicated no difference in affinity between the two proteins (data not shown).
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Radioactive and nonradioactive cleavage assays were also performed on the other mutants. The results were consistent with those of recombination assays, except that W330Q was able to yield covalent protein-DNA adduct at a rate that is slower than the wild type but slightly faster than W330H (Fig. 3b), in contrast to the apparently higher activity level of W330H in the overall recombination assay. This suggests that W330Q is even more defective in the later stages of recombination than in the cleavage step.
When compared with the dramatic activity decrease in W330H and W330Q, the small reaction rate difference between the wild type and W330F mutant suggests that hydrogen-bonding capability is not the critical feature of Trp330. Examination of the previous Flp-DNA complex structure revealed an extensive network of amino acids contacted by Trp330 through van der Waals interactions within or close to the catalytic site. The most essential role of Trp330 in the reaction may be maintaining a stable local architecture. To investigate whether the high activity level of the mutant stemmed from the ability of phenylalanine to retain those van der Waals contacts, W330F mutant protein was crystallized with DNA, and a structure of W330F-Holliday junction complex was determined.
Structure of W330F Mutant Protein Complexed with DNA W330F Flpe was cocrystallized with the same DNA substrate as used in the WT Flp and Flpe complex structures (4, 5). Phases were provided by a newly determined structure of a wild type Flpe-DNA complex (5). The overall structure of the mutant is the same as that of the wild type Flpe. The complex has approximate 2-fold symmetry and consists of a mutant tetramer bound to a DNA Holliday junction (Fig. 4a). Two catalytic centers contain a covalent phosphotyrosyl linkage and a free 5'-OH, whereas the other two contain a continuous or nicked DNA strand with Tyr343 displaced from the scissile phosphate. The mutant structure was refined to R and Rfree values of 23.6 and 27.5%, respectively (Table I). 87.6% of the nonglycine protein residues are in the most favored conformational regions of the Ramachandran plot (as defined by Procheck (48)). One of the two active protomers ("chain B," with Tyr343 donated by chain C) was significantly better ordered than the other. Discussions of the active site geometry thus pertain to this protomer.
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The slightly higher resolution of the W330F Flpe structure, compared with WT Flpe, allows us to model the C-terminal His6 tag. The His6 tag of protein chain B is involved in crystal packing. It forms a short -helix, with two histidine side chains stacked against the bases at the end of a DNA arm from the neighboring Holliday junction. It is interesting to note that in some other structures where ordered His6 tags are seen, they are in extended conformations (Protein Data Bank numbers 1GKK
[PDB]
and 1LW6
[PDB]
) (49, 50). Thus, His6 is clearly a sequence that can adopt different secondary structures in different environments.
Other than a small shift in the position of the two inactive protomers, which is probably due to minor differences in crystal packing, the only significant differences between the mutant and WT Flpe structures are at Trp330 and in its immediate vicinity. A prominent peak at the position of the Trp330 side chain was observed in a difference map comparing the data of the wild type and the mutant, corresponding to the alteration of tryptophan to phenylalanine and a small change in the 1 dihedral angle. Other peaks correspond to a shift in the proximal residues of the trans helix, including Tyr343, and the scissile phosphate to which it is covalently attached. There are only rather subtle changes that are difficult to interpret at this resolution in the other active site side chains (Fig. 5). The 5'-hydroxyl group formed a hydrogen bond with the side chain of Trp330 in the Flp structure and was only 3.6 Å away from the tryptophan N
atom in the WT Flpe model. This hydrogen bond is necessarily broken in the W330F structure. The 5'-hydroxyl is not well defined in the electron density, but it is possible that it could form an alternative hydrogen bonding interaction with Arg191.
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The phenylalanine side chain maintained most of the van der Waals interactions between Trp330 and neighboring residues. Trp330 interacts with several amino acids residing in its own protomer and on the trans-helix donated from the adjacent one, burying a total of 383 Å2 in the active site containing the phosphotyrosyl linkage. Phe330 still contacts the majority of these residues, with a buried area of 340 Å2, a slight decrease due to the smaller size of the phenylalanine side chain. Of the amino acids contacted by residue 330, Arg308 and Tyr343 are directly involved in catalysis, whereas the others are near the active site. Three (including Tyr343) lie on the trans helix, suggesting that Trp330 helps position this helix and Tyr343 for DNA cleavage. The loss of activity in the W330A, W330H, and W330Q mutants may reflect the loss of some or most of these stabilizing hydrophobic interactions.
Docking Helix MThe van der Waals interactions of Trp330 may be particularly important in Flp because of its trans cleavage mechanism. The correct docking of the Tyr343-bearing helix appears to be crucial to Flp-mediated recombination and is clearly regulated by the protein to achieve half of the sites activity. To further investigate the docking of helix M, Asn325, whose side chain forms two hydrogen bonds to the trans polypeptide segment (Fig. 6), was mutated to alanine. The N325A mutation caused a significant decrease in both the overall recombination rate and the initial DNA cleavage rate (data not shown).
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We also mutated two residues (Thr224 and Ser331) that lie near the conserved pentad and contact the incoming DNA strand near the 5'-hydroxyl to see if they were also important in positioning catalytic groups (Fig. 6). However, the activity of the T224A and S331A mutants in recombination assays was not significantly different from that of WT Flpe (data not shown).
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DISCUSSION |
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The van der Waals interactions involving Trp330 may be particularly important in the Flp case because of this enzyme's unique trans cleavage mechanism. The importance of the correct docking of the tyrosine-bearing helix M is further illustrated by the experiments on N325A, which is also involved in intermolecular contacts with the trans polypeptide segment. Previous mutational studies also highlighted residues involved in the packing of this helix into the active site cavity of the neighboring protomer. Trp330 packs against one face of this helix, contacting Ser336 and Ala339 in addition to the catalytic Tyr343. Mutations at Ser336 and Ala339, which are strictly conserved in Flp-like tyrosine recombinases from other yeast species, caused defects in DNA cleavage and the formation of dimeric complexes (27, 51) (shown in Fig. 6). The roles of His309 and His345, also involved in contacts between helix M and its "host" protomer, have been extensively investigated as well (52). Together with our experiments on Trp330 and Asn325, these results show that the correct positioning of Tyr343, which is essential to the activity of Flp, involves multiple residues inside or close to the active site.
These intermolecular contacts must be strong enough to properly position helix M in the two active catalytic centers yet weak enough to be reversible, since they are not seen in the two inactive catalytic centers. In fact, the half of the sites activity of Flp is thought to be regulated by the disruption of these contacts and displacement of Tyr343 due to the increased distance between the two contributing protomers in the inactive catalytic centers (5). In Cre, where the active site is assembled in cis, Trp315 and its surrounding residues bury nearly the same amount of interface area in both active site states (385 Å2), despite changes in the protein backbone and some side chain conformations. It would thus be interesting to know whether or not a W315F mutation in Cre behaves similarly to the W330F mutation in Flp.
Some variability was seen within the topoisomerase family as well, where the histidine that is equivalent to Trp330 of Flp has been studied extensively. In vaccinia virus topoisomerase, H265A, H265Q, and H265N mutations reduced the activity by 100-, 4-, and 3-fold, respectively. In human topoisomerase I, the mutations H632A, H632Q, H632N, and H632W resulted in decreases of 6000-, 100-, 180-, 12,000-fold in the cleavage reaction rate. The different extents to which the two alanine mutations affected the enzymatic activity suggest that the importance of this histidine's role may vary. For Flp, it is difficult to accurately quantify extremely low activity, because it requires relatively long reaction times. This is complicated by the protein's instability and side reactions such as hydrolysis of the phosphotyrosyl bond. Judging from the sensitivity of our recombination assay, the W330A mutation slowed down the appearance of product by at least 2500-fold, a severe reduction reminiscent of H632A in human topoisomerase I. The topoisomerase histidine buries 294 Å2 of surface area in the protein-DNA complex (Protein Data Bank number 1EJ9 [PDB] ) (21) and thus presumably contributes to the stability of the local active site architecture as well. However, this residue has not been substituted with a hydrophobic residue with comparable side chain size to test the relative importance of its hydrogen bonding and steric roles.
The studies on His265 and His632 in the two topoisomerases, respectively, have also ruled out the possibility that this histidine could act as a general acid in the reaction. Instead, during the cleavage reaction, the leaving 5'-OH group is protonated by the highly conserved lysine, as shown by experiments with vaccinia virus topoisomerase (33). Our results on the corresponding lysine, Lys223, are consistent with the previous findings. K223A showed no detectable activity, whereas K223R was able to produce a minimal amount of products in the recombination assays. The equivalent lysine is essential for catalysis in Cre, XerD, and -integrase as well (8, 34, 35).
We suggest that the conservation of the histidine/tryptophan residue in the active sites of tyrosine recombinases and type IB topoisomerases reflects two requirements: the need for a hydrogen bond donor and the need for a relatively large hydrophobic group that can help maintain a stable local architecture through van der Waals interactions. The relative importance of these two functionalities may vary greatly in different systems, however, and it appears that in Flp the ability to donate a hydrogen bond is nearly dispensable, whereas the ability to form extensive van der Waals interactions is crucial. This may reflect the unique trans assembly of the Flp active site.
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FOOTNOTES |
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* This work was supported by National Institutes of Health (NIH) Grant GM58827. Use of the Advanced Photon Source was supported by the United States Department of Energy, Basic Energy Sciences, Office of Science, under Contract W-31-109-Eng-38. Use of the BioCARS Sector 14 was supported by the NIH, National Center for Research Resources, under Grant RR07707. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 773-834-1723; Fax: 773-702-0439; E-mail: price{at}midway.uchicago.edu.
1 The abbreviations used are: WT, wild type; Taps, 3-{[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]amino}-1-propanesulfonic acid.
2 Y. Chen and P. A. Rice, unpublished data.
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ACKNOWLEDGMENTS |
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REFERENCES |
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