Discovery and characterization of a novel C-terminal peptide carboxyl methyltransferase in a lassomycin-like lasso peptide biosynthetic pathway.

Lasso peptides belong to a peculiar family of ribosomally synthesized and post-translationally modified peptides (RiPPs)-natural products with an unusual isopeptide-bonded slipknot structure. Except for assembling of this unusual lasso fold, several further post-translational modifications of lasso peptides, including C-terminal methylation, phosphorylation/poly-phosphorylation, citrullination, and acetylation, have been reported recently. However, most of their biosynthetic logic have not been elucidated except the phosphorylated paeninodin lasso peptide. Herein, we identified two novel lassomycin-like lasso peptide biosynthetic pathways and, for the first time, characterized a novel C-terminal peptide carboxyl methyltransferase involved in these pathways. Our investigations revealed that this new family of methyltransferase could specifically methylate the C terminus of precursor peptide substrates, eventually leading to lassomycin-like C-terminal methylated lasso peptides. Our studies offer another rare insight into the extraordinary strategies of chemical diversification adopted by lasso peptide biosynthetic machinery and predicated two valuable sources for methylated lasso peptide discovery.

ATP-dependent carboxylation of acetophenone by a novel type of carboxylase.

Anaerobic ethylbenzene metabolism in the betaproteobacterium Aromatoleum aromaticum is initiated by anaerobic oxidation to acetophenone via (S)-1-phenylethanol. The subsequent carboxylation of acetophenone to benzoylacetate is catalyzed by an acetophenone-induced enzyme, which has been purified and studied. The same enzyme is involved in acetophenone metabolism in the absence of ethylbenzene. Acetophenone carboxylase consists of five subunits with molecular masses of 70, 15, 87, 75, and 34 kDa, whose genes (apcABCDE) form an apparent operon. The enzyme is synthesized at high levels in cells grown on ethylbenzene or acetophenone, but not in cells grown on benzoate. During purification, acetophenone carboxylase dissociates into inactive subcomplexes consisting of the 70-, 15-, 87-, and 75-kDa subunits (apcABCD gene products) and the 34-kDa subunit (apcE gene product), respectively. Acetophenone carboxylase activity was restored by mixing the purified subcomplexes. The enzyme contains 1 Zn(2+) ion per alphabetagammadelta core complex and is dependent on the presence of Mg(2+) or Mn(2+). In spite of the presence of Zn in the enzyme, it is strongly inhibited by Zn(2+) ions. Carboxylation of acetophenone is dependent on ATP hydrolysis to ADP and P(i), exhibiting a stoichiometry of 2 mol ATP per mol acetophenone carboxylated. The enzyme shows uncoupled ATPase activity with either bicarbonate or acetophenone in the absence of the second substrate. These observations indicate that both substrates may be phosphorylated, which is consistent with isotope exchange activity observed with deuterated acetophenone and inhibition by carbamoylphosphate, a structural analogue of carboxyphosphate. A potential mechanism of ATP-dependent acetophenone carboxylation is suggested.

New and easy strategy for cloning, expression, purification, and characterization of the 5S subunit of transcarboxylase from Propionibacterium f. shermanii.

Methylmalonyl CoA-oxalacetate transcarboxylase (EC 2. 1. 3. 1) from Propionibacterium f. shermanii is a biotin dependent enzyme which transfers CO2 from methylmalonyl-CoA (MMCoA) to pyruvate via a carboxylated biotin group to form oxalacetate. It is composed of three subunits, the central cylindrical hexameric 12S subunit, the outer six dimeric 5S subunit, and the twelve 1.3S linkers. We here report the cloning, sequencing, expression, and purification of the 5S subunit. The gene was identified by matching the amino acid sequence with that of deposited in the NCBI database. For cloned 5S subunit sequence shows regions of high homology with that of pyruvate carboxylase and oxaloacetate decarboxylase. The gene encoding the 5S subunit was cloned into the pTXB1 vector. The expressed 5S subunit was purified to apparent homogeneity by a single step process by using Intein mediated protein ligation (IPL) method. The cloned 5S gene encodes a protein of 505 amino acids and of M(r) 55,700.

Acetylornithine transcarbamylase: a novel enzyme in arginine biosynthesis.

Ornithine transcarbamylase is a highly conserved enzyme in arginine biosynthesis and the urea cycle. In Xanthomonas campestris, the protein annotated as ornithine transcarbamylase, and encoded by the argF gene, is unable to synthesize citrulline directly from ornithine. We cloned and overexpressed this X. campestris gene in Escherichia coli and show that it catalyzes the formation of N-acetyl-L-citrulline from N-acetyl-L-ornithine and carbamyl phosphate. We now designate this enzyme as an acetylornithine transcarbamylase. The K(m) values for N-acetylornithine and carbamyl phosphate were 1.05 mM and 0.01 mM, respectively. Additional putative transcarbamylases that might also be misannotated were found in the genomes of members of other xanthomonads, Cytophaga, and Bacteroidetes as well as in DNA sequences of bacteria from environmental isolates. It appears that these different paths for arginine biosynthesis arose very early in evolution and that the canonical ornithine transcarbamylase-dependent pathway became the prevalent form. A potent inhibitor, N(alpha)-acetyl-N(delta)-phosphonoacetyl-L-ornithine, was synthesized and showed a midpoint of inhibition at approximately 22 nM; this compound may prove to be a useful starting point for designing inhibitors specific to this novel family of transcarbamylases.

Transcarboxylase 5S structures: assembly and catalytic mechanism of a multienzyme complex subunit.

Transcarboxylase is a 1.2 million Dalton (Da) multienzyme complex from Propionibacterium shermanii that couples two carboxylation reactions, transferring CO(2)(-) from methylmalonyl-CoA to pyruvate to yield propionyl-CoA and oxaloacetate. Crystal structures of the 5S metalloenzyme subunit, which catalyzes the second carboxylation reaction, have been solved in free form and bound to its substrate pyruvate, product oxaloacetate, or inhibitor 2-ketobutyrate. The structure reveals a dimer of beta(8)alpha(8) barrels with an active site cobalt ion coordinated by a carbamylated lysine, except in the oxaloacetate complex in which the product's carboxylate group serves as a ligand instead. 5S and human pyruvate carboxylase (PC), an enzyme crucial to gluconeogenesis, catalyze similar reactions. A 5S-based homology model of the PC carboxyltransferase domain indicates a conserved mechanism and explains the molecular basis of mutations in lactic acidemia. PC disease mutations reproduced in 5S result in a similar decrease in carboxyltransferase activity and crystal structures with altered active sites.

Expression and crystallization of several forms of the Propionibacterium shermanii transcarboxylase 5S subunit.

The dimeric outer 5S subunit of transcarboxylase has been expressed in three different forms and crystallized: native 5S, 5S-His(6) and selenomethione-5S-His(6). All the crystals have an orthorhombic space group, but while native 5S forms primitive orthorhombic crystals, 5S-His(6) crystals are either C-centered or primitive and SeMet-5S-His(6) crystals are C-centered. Crystallization of native 5S requires the addition of lithium sulfate, whereas this salt prevented crystallization of 5S-His(6). All 5S crystals diffract to approximately 2.0 A resolution with synchrotron radiation. Efforts are under way to solve the structure of SeMet-5S-His(6) using MAD.

Crystallization and preliminary X-ray analysis of the 12S central subunit of transcarboxylase from Propionibacterium shermanii.

The hexameric 12S central subunit of transcarboxylase has been crystallized in both free and substrate-bound forms. The apo crystals belong to the cubic space group P4(2)32, with unit-cell parameters a = b = c = 188.5 A, and diffract to 3.5 A resolution. Crystals of two substrate-bound complexes, 12S with methylmalonyl CoA and 12S with malonyl CoA, are isomorphous and belong to space group C2, with unit-cell parameters a = 115.5, b = 201.4, c = 146.9 A, beta = 102.7 degrees. These crystals diffract to 1.9 A resolution with synchrotron radiation. Two useful heavy-atom phasing derivatives of methylmalonyl CoA-bound crystals have been obtained by co-crystallization or crystal soaking.

Metabolic biotinylation of recombinant proteins in mammalian cells and in mice.

The avidin-biotin system is a fundamental technology in biomedicine for immunolocalization, imaging, nucleic acid blotting, and protein labeling. While this technology is robust, it is limited by the fact that mammalian proteins must be expressed and purified prior to chemical biotinylation using cross-linking agents which modify proteins at random locations to heterogeneous levels and can inactivate protein function. To circumvent this limitation, we demonstrate the ability to metabolically biotinylate tagged proteins in mammalian cells and in mice using the endogenous biotinylation enzymes of the host. Endogenously biotinylated proteins were readily purified from mammalian cells using monomeric avidin and eluted under nondenaturing conditions using only biotin as the releasing agent. This technology should allow recombinant proteins and fragile protein complexes to be produced and purified from mammalian cells as well as from transgenic plants and animals. In addition, this technology may be particularly useful for cell-targeting applications in which proteins or viral gene therapy vectors can be biotinylated at genetically defined sites for combination with other targeting moieties complexed with avidin.

Expression and biotinylation of a mutant of the transcarboxylase carrier protein from Propioni shermanii.

A deletion mutant (residues 10 to 48 cut) of the biotinyl subunit (tcc) from the enzyme transcarboxylase (EC 2.1.3.1) of Propioni shermanii was overexpressed in Escherichia coli. Complete biotinylation of the protein was achieved by addition of exogenous biotin and coexpression of the biotin holoenzyme synthetase (EC 6.3. 4.15.) from E. coli. The transcription of both genes was put under control of different operators/promoters, thus achieving independent control of expression levels and optimized yields of the holo-tcc. Bacteria were grown in a biotin-supplemented minimal medium (M9) that contained [(13)C]glucose as the carbon source and [(15)N]NH(4)Cl as the sole nitrogen source. The target protein could be purified to homogeneity by ion-exchange chromatography and concentrated to NMR-suitable concentrations (2 mM) without aggregation.