Ruth K. Kleppe

With the ultimate objective of the total synthesis of a tRNA gene including its transcriptional signals, an Escherichia coli tyrosine suppressor tRNA gene was chosen. The arguments in favor of this choice are presented. A plan for the total synthesis of the 126-nucleotide-long DNA duplex corresponding to a precursor (Altman S., and Smith, J. D. (1971) Nature New Biol. 233, 35) to the above tRNA is formulated. The plan involves: (a) the chemical synthesis of 26 deoxyribooligonucleotide segments, (b) polynucleotide ligase-catalyzed joining of several segments at a time to form a total of four DNA duplexes with appropriate comlementary single-stranded ends, and (c) the joining of the duplexes to form the entire DNA duplex. Ten accompanying papers describe the experimental realization of this objective.

The phosphorylation by T4 polynucleotide kinase of various double-stranded DNAs containing defined 5'-hydroxyl end group structures has been studied. Particular emphasis was placed on finding conditions that allow complete phosphorylation. The DNAs employed were homodeoxyoligonucleotides annealed on the corresponding homopolymers, DNA duplexes corresponding to parts of the genes for alanine yeast tRNA, and a suppressor tyrosine tRNA from Escherichia coli. The rate of phosphoylation of DNAs with 5'-hydroxyl groups in gaps was approximately ten times slower than for the corresponding single-stranded DNA. At low concentrations of ATP, 1 muM, incomplete phosphorylation was obtained, whereas with higher concentrations of ATP, 30 muM, complete phosphorylation was achieved. In the case of DNAs with 5'-hydroxyl groups at nicks approximately 30% phosphorylation could be detected using 30 muM ATP. A DNA containing protruding 5'-hydroxyl group ends was phosphorylated to completion using the same conditions as for single-stranded DNA, i.e., a ratio between the concentrations of ATP and 5'-hydroxyl groups of 5:1 and a concentration of ATP of approximately 1 muM. For a number of DNAs containing protruding 3'-hydroxyl group ends and one DNA containing even ends incomplete phosphorylation was found under similar conditions. For all these DNAs a plateau level was observed varying from 20 to 45% of complete phosphorylation. At 20 muM and higher ATP concentrations, the phosphorylation was complete also for these DNAs. With low concentrations of ATP a rapid production of inorganic phosphate was noted for all the latter DNAs. The apparent equilibrium constants for the forward and reverse reaction were determined for a number of different DNAs, and these data revealed that the plateau levels of phosphorylation obtained at low concentrations of ATP for DNAs with protruding 3'-hydroxyl group and even ends is not a true equilibrium resulting from the forward and reverse reaction. It is suggested that the plateau levels are due to formation of inactive enzyme-substrate and enzyme-product complexes. For all double-stranded DNAs tested, except DNAs containing protruding 5'-hydroxyl group ends, addition of KCl to the reaction mixture resulted in a drastic decrease in the rate of phosphorylation, as well as in the maximum level phosphorylated. Spermine, on the other hand, had little influence. Both of these agents have previously been shown to activate T4 polynucleotide kinase using single-stranded DNAs as substrates (Lillehaug, J.R., and Kleppe, K. (1975), Biochemistry 14, 1221). The inhibition of phosphorylation of double-stranded DNAs by salt might be the result of stabilization of the 5'-hydroxyl group regions of these DNAs.

The kinetics of T4 polynucleotide ligase has been investigated at pH 8,20 degrees C and using the double-stranded DNA substrate (dA)n - [(dT)10]n/10. Double-reciprocal plots of initial rates vs substrate concentrations as well as product inhibition studies have indicated that the enzyme reacts according to a ping-pong mechanism. The overall mechanism was found to be non-processive. The true Km for the DNA substrate was 0.6 muM and that of ATP 100 muM. Several attempts were made to reverse the T4 polynucleotide ligase joining reaction using 32-p-labelled (dA)n - [(DT)40]n/40 as substrate. No breakdown of this DNA could be detected. The joining reaction was inhibited by high concentrations, i.e. above approximately 70mM, of salts such as KCl, NaCl, NH4Cl and CsCl. At a concentration of 200 mM almost 100% inhibition was observed. Polyamines also caused inhibition of the enzyme, the most efficient inhibitor being spermine followed by spermidine. At a concentration of 1 mM spermine, virtually no joining took place. Addition of salts or polyamines resulted in a large increase in the apparent Km for the DNA substrate whereas the apparent Km for ATP remained unchanged. It is suggested that the affinity of the enzyme for the DNA substrate is decreased in the presence of inhibiting agents.

The DNA duplex corresponding to the entire length (126 nucleotides) of the precursor for an Escherichia coli tyrosine tRNA has been synthesized. Duplex [I] (Sekiya, T., Besmer, P., Takeya, T., and Khorana, H. G.(1976) J. Biol. Chem. 251, 634-641), corresponding to the nucleotide sequence 1-26, containing single-stranded ends and carrying one appropriately labeled 5'-phosphate group, was joined to duplex [II] (Loewen, P. C., Miller, R. C., Panet, A., Sekiya, T., and Khorana, H. G. (1976) J. Biol. Chem. 251, 642-650) (nucleotide sequence 23-66 or 23-60) was phosphorylated with [gamma-33P]ATP at the 5'-OH ends. Duplex [III] (Panet, A., Kleppe, R., Kleppe, K., and Khorana, H. G. (1976) J. Biol. Chem. 251, 651-657) (nucleotide sequence 57-94 (Fig. 2)) was also phosphorylated at 5'-ends with [gamma-33P]ATP and was joined to duplex [IV] (Caruthers, M. H., Kleppe, R., Kleppe, K., and Khorana, H. G. (1976) J. Biol. Chem. 251, 658-666) (nucleotide sequence 90-126) which carried a 33P-labeled phosphate group on nucleotide 90. The joined product, duplex [III + IV] (nucleotide sequence 57-126) was characterized. The latter duplex was joined to the duplex [I + II] to give the total duplex. The latter contains singlestranded ends (nucleotides 1 to 6 and 121 to 126) which can either be "filled in" to produce the completely base-paired duplex or may be used to add the promoter and terminator regions at the appropriate ends.