Oxygen-mediated Inactivation of Peptide Deformylase

126

137

Dedicated machinery for N-terminal methionine excision (NME) was recently identified in plant organelles and shown to be essential in plastids. We report here the existence of mitochondrial NME in mammals, as shown by the identification of cDNAs encoding specific peptide deformylases (PDFs) and new methionine aminopeptidases (MAP1D). We cloned the two full-length human cDNAs and showed that the N-terminal domains of the encoded enzymes were specifically involved in targeting to mitochondria. In contrast to mitochondrial MAP1D, the human PDF sequence differed from that of known PDFs in several key features. We characterized the human PDF fully in vivo and in vitro. Comparison of the processed human enzyme with the plant mitochondrial PDF1A, to which it is phylogenetically related, showed that the human enzyme had an extra N-terminal domain involved in both mitochondrial targeting and enzyme stability. Mammalian PDFs also display non-random substitutions in the conserved motifs important for activity. Human PDF site-directed mutagenesis variants were studied and compared with the corresponding plant PDF1A variants. We found that amino acid substitutions in human PDF specifically altered its catalytic site, resulting in an enzyme intermediate between bacterial PDF1Bs and plant PDF1As. Because (i) human PDF was found to be active both in vitro and in vivo, (ii) the entire machinery is conserved and expressed in most animals, (iii) the mitochondrial genome expresses substrates for these enzymes, and (iv) mRNA synthesis is regulated, we conclude that animal mitochondria have a functional NME machinery that can be regulated.

Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

An Unusual Peptide Deformylase Features in the Human Mitochondrial N-terminal Methionine Excision Pathway

Serero

Giglione

Sardini

et al. 2003

126

137

“…Furthermore, E. coli cultured in unsupplemented medium produced Cam with 7-fold more iron than zinc, although metals analysis of the medium showed it contained 1.6 ppm of iron and 3. (21). Use of strictly anaerobic conditions to prevent oxidation also lead to the identification of Fe 2ϩ as the active site metal in the previously reported Zn 2ϩ -containing methionyl aminopeptidase from E. coli (22) (23).…”

Section: Resultsmentioning

confidence: 99%

A Role for Iron in an Ancient Carbonic Anhydrase

Tripp

Bell

Cruz

et al. 2004

145

123

Since 1933, carbonic anhydrase research has focused on enzymes from mammals (␣ class) and plants (␤ class); however, two additional classes (␥ and ␦) were discovered recently. Cam, from the procaryote Methanosarcina thermophila, is the prototype of the ␥ class and the first carbonic anhydrase to be characterized from either an anaerobic organism or the Archaea domain. All of the enzymes characterized from the four classes have been purified aerobically and are reported to contain a catalytic zinc. Herein, we report the anaerobic reconstitution of apo- Research in the intervening years has shown that CA is one of the most widely distributed enzymes in nature (2, 3) and continues to be intensely investigated. Amino acid sequence comparisons identify four classes (␣, ␤, ␥, and ␦) of independent origins (4). Isozymes of the ␣ class are found in virtually all mammalian tissues where they function in diverse essential processes. The ␤ class is ubiquitous in plants and algae, where it is indispensable for the acquisition and concentration of CO 2 for photosynthesis. CA plays a role in the sequestration of atmospheric CO 2 in carbonates, and the global cycles of silicon and carbon are linked by CA in diatoms (5); thus, CA plays an important role in major geochemical and atmospheric processes. Members of the ␤ and ␥ classes are wide spread in physiologically diverse procaryotes from both the Bacteria and Archaea domains. Indeed, the genome of Escherichia coli contains two ␥ class homologs and two ␤ class homologs (2).Cam, from the procaryote Methanosarcina thermophila, is the prototype of the ␥ class and the first CA to be characterized from either an anaerobic organism or the Archaea domain (6). Sequence analyses approximate the evolution of the ␥ class at the estimated time of the origin of life (2). The crystal structure of Cam purified aerobically from E. coli reveals a homotrimer with a subunit fold composed of a left-handed ␤-helix motif followed by short and long ␣-helix structures (7). Each of the three active sites contain three histidines that coordinate a zinc ion. Two of the metal-binding histidines are donated by one monomer, and the third histidine from an adjacent monomer. Other residues in the active site of Cam are also donated from adjacent monomer faces and bear no resemblance to residues in the active site of the well characterized ␣ class CAs for which specific functions have been assigned.Kinetic investigations of the ␣ class CAs reveal a "zinc hydroxide" mechanism for catalysis (8) that also extends to both the ␤ and ␥ classes (9, 10). The overall enzyme-catalyzed reaction occurs in two mechanistically distinct steps,where E is enzyme, and B is buffer. The first step is the interconversion between CO 2 and bicarbonate (Equations 2 and 3) involving a nucleophilic attack of the zinc-bound hydroxyl on the CO 2 molecule. The second step is regeneration of the zinc-bound hydroxide, which involves intramolecular proton transfer from the zinc-bound water to a proton shuttle residue (Equation 4) and interm...

“…11). The ferrous cation of PDF is extremely sensitive to oxidation, making the enzyme unstable (9,12). This cation can be replaced by Ni 2ϩ (9,13) or Co 2ϩ (14) to give stable variants with little or no loss of catalytic activity.…”

mentioning

confidence: 99%

The Crystal Structure of Mitochondrial (Type 1A) Peptide Deformylase Provides Clear Guidelines for the Design of Inhibitors Specific for the Bacterial Forms

Fieulaine

Juillan-Binard

Serero

et al. 2005

Peptide deformylase (PDF) inhibitors have a strong potential to be used as a new class of antibiotics. However, recent studies have shown that the mitochondria of most eukaryotes, including humans, contain an essential PDF, PDF1A. The crystal structure of the Arabidopsis thaliana PDF1A (AtPDF1A), considered representative of PDF1As in general, has been determined. This structure displays several similarities to that of known bacterial PDFs. AtPDF1A behaves as a dimer, with the C-terminal residues responsible for linking the two subunits. This arrangement is similar to that of Leptospira interrogans PDF, the only other dimeric PDF identified to date. AtPDF1A is the first PDF for which zinc has been identified as the catalytic ion. However, the zinc binding pocket does not differ from the binding pockets of PDFs with iron rather than zinc. The crystal structure of AtPDF1A in complex with a substrate analog revealed that the substrate binding pocket of PDF1A displays strong modifications. The S1 binding pocket is significantly narrower, due to the creation of a floor from residues present in all PDF1As but not in bacterial PDFs. A true S3 pocket is created by the residues of a helical CD-loop, which is very long in PDF1As. Finally, these modified substrate binding pockets modify the position of the substrate in the active site. These differences provide guidelines for the design of bacterial PDF inhibitors that will not target mitochondrial PDFs.