Dissection of the beta subunit in the Escherichia coli RNA polymerase into domains by proteolytic cleavage.

The 1342 amino acid long beta subunit of Escherichia coli RNA polymerase includes a dispensable region (residues 940-1040) that is absent in homologous RNA polymerase subunits from chloroplasts, eukaryotes, and archaebacteria (Borukhov, S., Severinov, K., Kashlev, M., Lebedev, A., Bass, I., Rowland, G. C., Lim, P.-P., Glass, R. E., Nikiforov, V., and Goldfarb, A. (1991) J. Biol. Chem. 266, 23921-23926). Genetic disruption of this region by in-frame deletion or insertion sensitizes the beta subunit in assembled RNA polymerase molecules to attack by trypsin. We demonstrate that RNA polymerase with the beta polypeptide cleaved in the dispensable region retains normal in vitro activity. Moreover, the RNA polymerase activity is completely restored after denaturation and reconstitution of the enzyme carrying cleaved beta subunit indicating that its carboxyl- and amino-terminal parts fold and assemble into RNA polymerase as separate entities.     

Substrate specificity of the exonuclease activity that degrades H4 histone mRNA

We have investigated the substrate specificity of an exonuclease that degrades human H4 histone mRNA, using synthetic RNA templates incubated in a cell-free mRNA decay system (Ross, J., and Kobs, G. (1986) J. Mol. Biol. 188, 579-593). Five RNAs that lacked poly(A), including histone, were degraded rapidly in vitro. Polyadenylated histone mRNA was degraded at least 10-fold more slowly than unmodified histone mRNA. Double-stranded RNA and DNA were very stable. Single-stranded DNA was degraded approximately 20-fold more slowly than single-stranded, non-polyadenylated RNA, and RNA with a 3' phosphoryl group was degraded more slowly than RNA with a 3'-hydroxyl group. Uncapped RNAs were degraded rapidly in the unfractionated system but were stable in reactions containing a ribosomal high salt wash extract. Therefore, the exonuclease activity released from ribosomes by high salt extraction was separated from the enzyme(s) that degraded uncapped RNAs.     

Synthesis of adenylated molybdopterin: an essential step for molybdenum insertion

The molybdenum cofactor (Moco) is part of the active site of all molybdenum (Mo)-dependent enzymes, except nitrogenase. Moco consists of molybdopterin (MPT), a phosphorylated pyranopterin with an enedithiolate coordinating Mo and it is synthesized by an evolutionary old multistep pathway. The plant protein Cnx1 from Arabidopsis thaliana catalyzes with its two domains (E and G) the terminal step of Moco biosynthesis, the insertion of Mo into MPT. Recently, the high-resolution MPT-bound structure of the Cnx1 G domain (Cnx1G) has been determined (Kuper, J., Llamas, A., Hecht, H. J., Mendel, R. R., and Schwarz, G. (2004) Nature 430, 803-806). Besides defining the MPT-binding site a novel and unexpected modification of MPT has been identified, adenylated MPT. Here we demonstrate that it is Cnx1G that catalyzes the adenylation of MPT. In vitro synthesized MPT was quantitatively transferred from Escherichia coli MPT synthase to Cnx1G. The subsequent adenylation reaction by Cnx1G was Mg(2+)- and ATP-dependent. Whereas Mn(2+) could partially replace Mg(2+), ATP was the only nucleotide accepted by Cnx1G. Consequently the formation of pyrophosphate was demonstrated, which was dependent on the ability of Cnx1G to bind MPT. Pyrophosphate, either formed in the reaction or added externally, inhibited the Cnx1G-catalyzed MPT adenylation reaction. Catalytically inactive Cnx1G mutant variants showed impaired MPT adenylation confirming that MPT-AMP is the reaction product of Cnx1G. Therefore Cnx1G is a MPT adenylyltransferase catalyzing the activation of MPT, a universal reaction in the Moco synthetic pathway because Cnx1G is able to reconstitute also bacterial and mammalian Moco biosynthesis.     

Chemical synthesis and expression of a synthetic gene for the flavodoxin from Clostridium MP

A gene coding for the flavodoxin from Clostridium MP was designed, synthesized, and expressed in Escherichia coli. The sequence of the coding region was derived from the published amino acid sequence of the protein (Tanaka, M., Haniu, M., Yasunobu, K.T., and Mayhew, S. G. (1974) J. Biol. Chem. 249, 4393-4397) and was designed for optimal expression and for use of the cassette mutagenesis approach. The structural gene was subassembled in three sections, each of which was constructed by the enzymatic ligation of three complementary pairs of chemically synthesized oligodeoxyribonucleotides having short single-stranded ends complementary to that of the adjacent pair. Coligation of the three sections produced the final structural gene which consists of 420 nucleotides. The synthetic gene was cloned behind the hybrid tac promoter (Amman, E., Brosius, J., and Ptashne, M. (1983) Gene (Amst.) 25, 167-178) in the pKK223-3 vector or adjacent to the strong T7 RNA polymerase promoter in the pET-3a expression vector (Rosenberg, A.H., Lade, B. N., Chui, D-S., Lin, S-W., Dunn, J. J., and Studier, F. W. (1987) Gene (Amst.) 56, 125-135) for expression in E. coli. Upon induction with isopropyl-beta-D-thiogalactoside, the flavodoxin polypeptide was expressed from the artificial gene to levels approaching 20% of total extractable proteins using either expression system. The flavodoxin was purified from cellular extracts as the holoprotein containing bound flavin mononucleotide. The recombinant flavodoxin protein was found to have an ultraviolet/visible spectrum, amino-terminal sequence, and amino acid composition identical to the wild-type flavodoxin protein purified from Clostridium MP. This work represents the first chemical synthesis and expression in E. coli of an artificial gene coding for a bacterial flavodoxin.