Kinetics of maturation of the amino termini of the cell proteins of Escherichia coli

Proteome-wide analysis of the amino terminal status of Escherichia coli proteins at the steady-state and upon deformylation inhibition

A proteome wide analysis was performed in Escherichia coli to identify the impact on protein N-termini of actinonin, an antibiotic specifically inhibiting peptide deformylase (PDF). A strategy and tool suite (SILProNaQ) was employed to provide large-scale quantitation of N-terminal modifications. In control conditions, more than 1000 unique N-termini were identified with 56% showing initiator methionine removal. Additional modifications corresponded to partial or complete Nα-acetylation (10%) and N-formyl retention (5%). Among the proteins undergoing these N-terminal modifications, 140 unique N-termini from translocated membrane proteins were highlighted. The very early time-course impact of actinonin was followed after addition of bacteriostatic concentrations of the drug. Under these conditions, 26% of all proteins did not undergo deformylation any longer after 10 min, a value reaching more than 60% of all characterized proteins after 40 min of treatment. The N-formylation ratio measured on individual proteins increased with the same trend. Upon early PDF inhibition, two major categories of proteins retained their N-formyl group: a large number of inner membrane proteins and many proteins involved in protein synthesis including factors assisting the nascent chains in early cotranslational events. All MS data have been deposited in the ProteomeXchange with identifiers PXD001979, PXD002012 and PXD001983 (http://proteomecentral.proteomexchange.org/dataset/PXD001979, http://proteomecentral.proteomexchange.org/dataset/PXD002012 and http://proteomecentral.proteomexchange.org/dataset/PXD001983).

The intriguing realm of protein biogenesis: Facing the green co-translational protein maturation networks

The ribosome is the cell's protein-making factory, a huge protein-RNA complex, that is essential to life. Determining the high-resolution structures of the stable "core" of this factory was among the major breakthroughs of the past decades, and was awarded the Nobel Prize in 2009. Now that the mysteries of the ribosome appear to be more traceable, detailed understanding of the mechanisms that regulate protein synthesis includes not only the well-known steps of initiation, elongation, and termination but also the less comprehended features of the co-translational events associated with the maturation of the nascent chains. The ribosome is a platform for co-translational events affecting the nascent polypeptide, including protein modifications, folding, targeting to various cellular compartments for integration into membrane or translocation, and proteolysis. These events are orchestrated by ribosome-associated protein biogenesis factors (RPBs), a group of a dozen or more factors that act as the "welcoming committee" for the nascent chain as it emerges from the ribosome. In plants these factors have evolved to fit the specificity of different cellular compartments: cytoplasm, mitochondria and chloroplast. This review focuses on the current state of knowledge of these factors and their interaction around the exit tunnel of dedicated ribosomes. Particular attention has been accorded to the plant system, highlighting the similarities and differences with other organisms.

N-terminal protein modifications: Bringing back into play the ribosome

N-terminal protein modifications correspond to the first modifications which in principle any protein may undergo, before translation is completed by the ribosome. This class of essential modifications can have different nature or function and be catalyzed by a variety of dedicated enzymes. Here, we review the current state of the major N-terminal co-translational modifications, with a particular emphasis to their catalysts, which belong to metalloprotease and acyltransferase clans. The earliest of these modifications corresponds to the N-terminal methionine excision, an ubiquitous and essential process leading to the removal of the first methionine. N-alpha acetylation occurs also in all Kingdoms although its extent appears to be significantly increased in higher eukaryotes. Finally, N-myristoylation is a crucial pathway existing only in eukaryotes. Recent studies dealing on how some of these co-translational modifiers might work in close vicinity of the ribosome is starting to provide new information on when these modifications exactly take place on the elongating nascent chain and the interplay with other ribosome biogenesis factors taking in charge the nascent chains. Here a comprehensive overview of the recent advances in the field of N-terminal protein modifications is given.

Cotranslational processing mechanisms: towards a dynamic 3D model

Recent major advances have been made in understanding how cotranslational events are achieved in the course of protein biosynthesis. Specifically, several studies have shed light into the dynamic process of how nascent chains emerging from the ribosome are supported by protein biogenesis factors to ensure both processing and folding mechanisms. To take into account the awareness that coordination is needed, a new 'concerted model' recently proposed simultaneous action of both processes on the ribosome. In the model, any emerging nascent chain is first encountered by the chaperone trigger factor (TF), which forms an open cradle underneath the ribosomal exit tunnel. This cradle serves as a passive router that channels the nascent chains to the first cotranslational event, the proteolysis event performed by the N-terminal methionine excision machinery. Although fascinating, this model clearly raises more questions than it answers. Does the data used to develop this model stand up to scrutiny and, if not, what are the alternative mechanisms that the data suggest?

The ribosome as a platform for co-translational processing, folding and targeting of newly synthesized proteins

The early events in the life of newly synthesized proteins in the cellular environment are remarkably complex. Concurrently with their synthesis by the ribosome, nascent polypeptides are subjected to enzymatic processing, chaperone-assisted folding or targeting to translocation pores at membranes. The ribosome itself has a key role in these different tasks and governs the interplay between the various factors involved. Indeed, the ribosome serves as a platform for the spatially and temporally regulated association of enzymes, targeting factors and chaperones that act upon the nascent polypeptides emerging from the exit tunnel. Furthermore, the ribosome provides opportunities to coordinate the protein-synthesis activity of its peptidyl transferase center with the protein targeting and folding processes. Here we review the early co-translational events involving the ribosome that guide cytosolic proteins to their native state.

A peptide deformylase-ribosome complex reveals mechanism of nascent chain processing

Messenger-RNA-directed protein synthesis is accomplished by the ribosome. In eubacteria, this complex process is initiated by a specialized transfer RNA charged with formylmethionine (tRNA(fMet)). The amino-terminal formylated methionine of all bacterial nascent polypeptides blocks the reactive amino group to prevent unfavourable side-reactions and to enhance the efficiency of translation initiation. The first enzymatic factor that processes nascent chains is peptide deformylase (PDF); it removes this formyl group as polypeptides emerge from the ribosomal tunnel and before the newly synthesized proteins can adopt their native fold, which may bury the N terminus. Next, the N-terminal methionine is excised by methionine aminopeptidase. Bacterial PDFs are metalloproteases sharing a conserved N-terminal catalytic domain. All Gram-negative bacteria, including Escherichia coli, possess class-1 PDFs characterized by a carboxy-terminal alpha-helical extension. Studies focusing on PDF as a target for antibacterial drugs have not revealed the mechanism of its co-translational mode of action despite indications in early work that it co-purifies with ribosomes. Here we provide biochemical evidence that E. coli PDF interacts directly with the ribosome via its C-terminal extension. Crystallographic analysis of the complex between the ribosome-interacting helix of PDF and the ribosome at 3.7 A resolution reveals that the enzyme orients its active site towards the ribosomal tunnel exit for efficient co-translational processing of emerging nascent chains. Furthermore, we have found that the interaction of PDF with the ribosome enhances cell viability. These results provide the structural basis for understanding the coupling between protein synthesis and enzymatic processing of nascent chains, and offer insights into the interplay of PDF with the ribosome-associated chaperone trigger factor.

Selection for efficient translation initiation biases codon usage at second amino acid position in secretory proteins

The definition of a typical sec-dependent bacterial signal peptide contains a positive charge at the N-terminus, thought to be required for membrane association. In this study the amino acid distribution of all Escherichia coli secretory proteins were analysed. This revealed that there was a statistically significant bias for lysine at the second codon position (P2), consistent with a role for the positive charge in secretion. Removal of the positively charged residue P2 in two different model systems revealed that a positive charge is not required for protein export. A well-characterized feature of large amino acids like lysine at P2 is inhibition of N-terminal methionine removal by methionyl amino-peptidase (MAP). Substitution of lysine at P2 for other large or small amino acids did not affect protein export. Analysis of codon usage revealed that there was a bias for the AAA lysine codon at P2, suggesting that a non-coding function for the AAA codon may be responsible for the strong bias for lysine at P2 of secretory signal sequences. We conclude that the selection for high translation initiation efficiency maybe the selective pressure that has led to codon and consequent amino acid usage at P2 of secretory proteins.

Impact of the N-terminal amino acid on targeted protein degradation

The N-terminus of any protein may be used as a destabilization signal for targeted protein degradation. In the eukaryotic cytosol, the signal - the so-called N-degron--is recognized for degradation by (i) the N-end rule, a well-described degradation process involving epsilon-ubiquitination; or (ii) N-terminal ubiquitination, a more recently described pathway. Dedicated E3 ubiquitin ligases known as N-recognins then act on the protein. The proteolytic pathways involve ATP-dependent chambered proteases, such as the 26S proteasome in the cytosol, which generate short oligopeptides. The N-terminus of the polypeptide chain is also important for post-proteasome degradation by specific aminopeptidases, which complete peptide cleavage to generate free amino acids. Finally, in each compartment of the eukaryotic cell, N-terminal methionine excision creates a variety of N-termini for mature proteins. It has recently been shown that the N-terminal methionine excision pathway has a major impact early in targeted protein degradation.

Unique structural characteristics of peptide deformylase from pathogenic bacterium Leptospira interrogans

Peptide deformylase (PDF), which is essential for normal growth of bacteria but not for higher organisms, is explored as an attractive target for developing novel antibiotics. Here, we present the crystal structure of Leptospira interrogans PDF (LiPDF) at 2.2A resolution. To our knowledge, this is the first crystal structure of PDF associating in a stable dimer. The key loop (named the CD-loop: amino acid residues 66-76) near the active-site pocket adopts "closed" or "open" conformations in the two monomers forming the dimer. In the closed subunit, the CD-loop and residue Arg109 block the entry of the substrate-binding pocket, while the active-site pocket of the open subunit is occupied by the C-terminal tail from the neighbouring molecule. Moreover, a formate group, as one product of deformylisation, is observed bound with the active-site zinc ion. LiPDF displays significant structural differences in the C-terminal region compared to both type-I and type-II PDFs, suggesting a new family of PDFs.

Specificity of chloroplast-localized peptide deformylases as determined with peptide analogs of chloroplast-translated proteins

Peptide deformylase (DEF; EC 3.5.1.88) removes the N-formyl group from nascent polypeptides. Two nuclear-encoded DEFs in Arabidopsis thaliana (At) are localized to chloroplasts, and thus, the N-termini of chloroplast-translated proteins may be a consequence of AtDEFs' substrate specificity. Using peptide analogs of select chloroplast-translated proteins, AtDEF1 activity was as much as 100-fold lower than AtDEF2 activity and showed little variance with peptide sequence. However, AtDEF2 activity was significantly influenced by peptide sequence, with the most efficiently processed substrate mimicking the N-terminus of the nascent D1 polypeptide, a core protein of photosystem II. Though AtDEF2's specificity was predictive of N-formyl retention for some chloroplast proteins, exceptions suggests that additional factors in vivo aid in determining the retention of an N-formyl group.

Peptide deformylase as a target for new generation, broad spectrum antimicrobial agents

Peptide deformylase was discovered 30 years ago, but as a result of its unusually unstable activity it was not fully characterized until very recently. The aim of this paper is to review the many recent data concerning this enzyme and to try to assess its potential as a target for future antimicrobial drugs.

Activation of antibacterial prodrugs by peptide deformylase

5'-Dipeptidyl derivatives of 5-fluorodeoxyuridine (FdU) (1a-d) were synthesized. These compounds are biologically inactive but can be activated by peptide deformylase, which removes the N-terminal formyl group of the dipeptide, to release the active drug FdU via an intramolecular cyclization reaction. Because the deformylase is ubiquitous among bacteria but absent in mammalian cells, 1a-d provide a novel class of potential antibacterial agents.

Control of peptide deformylase activity by metal cations

Previous work indicated that peptide deformylase behaves as a metalloenzyme since the Escherichia coli enzyme was shown to copurify with a zinc ion. The present study establishes that nickel:enzyme complexes can also be isolated provided that nickel salts were added in the buffers throughout the purification. Similar results were obtained with the deformylases from Thermus thermophilus and Bacillus stearothermophilus. As a result of nickel binding, the catalytic efficiencies of peptide deformylases increased by two to three orders of magnitude with respect to those of the forms previously characterized. Using the model substrate N-formyl-Met-Ala-Ser, kcat/Km values of 5.4, 1.2 and 25 10(4)M-1s-1 could be obtained for the E. coli, T. thermophilus and B. stearothermophilus enzymes, respectively. This value satisfyingly accounts for the deformylation turnover required in the cell. In vitro characterization of the E. coli enzyme shows that zinc can readily substitute for the bound nickel with the catalytic efficiency decreasing to 80 M-1s-1 in turn. Conversely, the activity of the zinc-containing protein can be significantly improved by addition of nickel to the enzymatic assay.

Molecular recognition governing the initiation of translation in Escherichia coli. A review

Selection of the proper start codon for the synthesis of a polypeptide by the Escherichia coli translation initiation apparatus involves several macromolecular components. These macromolecules interact in a specific and concerted manner to yield the translation initiation complex. This review focuses on recent data concerning the properties of the initiator tRNA and of enzymes and factors involved in the translation initiation process. The three initiation factors, as well as methionyl-tRNA synthetase and methionyl-tRNA(f)Met formyltransferase are described. In addition, the tRNA recognition properties of EF-Tu and peptidyl-tRNA hydrolase are considered. Finally, peptide deformylase and methionine aminopeptidase, which catalyze the amino terminal maturation of nascent polypeptides, can also be associated to the translation initiation process.

Evidence that peptide deformylase and methionyl-tRNA(fMet) formyltransferase are encoded within the same operon in Escherichia coli

Overexpression of the fms gene, the first translation unit of a dicistronic operon that also encodes methionyl-tRNA(fMet) formyltransferase in Escherichia coli, sustains the overproduction of peptide deformylase activity in crude extracts. This suggests that the fms gene encodes the peptide deformylase. Moreover, the fms gene product has a motif characteristic of metalloproteases, an activity compatible with deformylase. The corresponding protein could be purified to homogeneity. However, its enzymatic activity could not be retained during the purification procedure. As could be expected from the occurrence in its amino acid sequence of a zinc-binding motif characteristic of metallopeptidases, the purified fms product displayed one tightly bound zinc atom.

Methionine as translation start signal: a review of the enzymes of the pathway in Escherichia coli

Methionine is the universal translation start but the first methionine is removed from most mature proteins. This review focuses on our present knowledge of the five enzymes sustaining the methionine pathway in translation initiation in Escherichia coli: methionyl-tRNA synthetase, methionyl-tRNA(fMet) formyltransferase, peptidyl-tRNA hydrolase, peptide deformylase and methionine aminopeptidase. The possible significance of retaining methionine as initiation signal is discussed.

Extent of N-terminal methionine excision from Escherichia coli proteins is governed by the side-chain length of the penultimate amino acid

In a significant fraction of the Escherichia coli cytosolic proteins, the N-terminal methionine residue incorporated during the translation initiation step is excised. The N-terminal methionine excision is catalyzed by methionyl-aminopeptidase (MAP). Previous studies have suggested that the action of this enzyme could depend mainly on the nature of the second amino acid residue in the polypeptide chain. In this study, to achieve a systematic analysis of the specificity of MAP action, each of the 20 amino acids was introduced at the penultimate position of methionyl-tRNA synthetase of E. coli and the extent of in vivo methionine excision was measured. To facilitate variant protein purification and N-terminal sequence determination, an expression shuttle vector based on protein fusion with beta-galactosidase was used. From our results, methionine excision catalyzed by MAP is shown to obey the following rule: the catalytic efficiency of MAP, and therefore the extent of cleavage, decreases in parallel with the increasing of the maximal side-chain length of the amino acid in the penultimate position. This molecular model accounts for the rate of N-terminal methionine excision in E. coli, as deduced from the analysis of 100 protein N-terminal sequences.

Processing of the initiation methionine from proteins: properties of the Escherichia coli methionine aminopeptidase and its gene structure

Methionine aminopeptidase (MAP) catalyzes the removal of amino-terminal methionine from proteins. The Escherichia coli map gene encoding this enzyme was cloned; it consists of 264 codons and encodes a monomeric enzyme of 29,333 daltons. In vitro analyses with purified enzyme indicated that MAP is a metallo-oligopeptidase with absolute specificity for the amino-terminal methionine. The methionine residues from the amino-terminal end of the recombinant proteins interleukin-2 (Met-Ala-Pro-IL-2) and ricin A (Met-Ile-Phe-ricin A) could be removed either in vitro with purified MAP enzyme or in vivo in MAP-hyperproducing strains of E. coli. In vitro analyses of the substrate preference of the E. coli MAP indicated that the residues adjacent to the initiation methionine could significantly influence the methionine cleavage process. This conclusion is consistent, in general, with the deduced specificity of the enzyme based on the analysis of known amino-terminal sequences of intracellular proteins (S. Tsunasawa, J. W. Stewart, and F. Sherman, J. Biol. Chem. 260:5382-5391, 1985).

Analysis of the distribution of charged residues in the N-terminal region of signal sequences: implications for protein export in prokaryotic and eukaryotic cells

A statistical analysis of the distribution of charged residues in the N-terminal region of 39 prokaryotic and 134 eukaryotic signal sequences reveals a remarkable similarity between the two samples, both in terms of net charge and in terms of the position of charged residues within the N-terminal region, and suggests that the formyl group on Metf is not removed in prokaryotic signal sequences.

Initiation of protein synthesis in bacillus subtilis in the presence of trimethoprim or aminopterin

Initiation of protein synthesis has been studied in the presence of the tetrahydrofolic acid analogues trimethoprim or aminopterin in Bacillus subtilis. This bacterium can grow in the presence of the inhibitors, when the medium is supplemented with the low molecular weight products of tetrahydrofolate-dependent pathways. In an attempt to show whether formylation of initiator tRNA is a prerequisite for the iniation of protein synthesis in procaryotic cells, the amount of N-formylmethionine in tRNA and in protein has been determined. The level of formylation of methionyl-tRNA was found to be 70% in control cells and approximately 2% in inhibitor-treated cells. The content of formyl groups in protein has also been found to be drastically reduced. Trimethoprim or aminopterin did not alter the amount of tRNAMet nor the degree of aminoacylation of tRNAMet in vivo. These results indicate that in B. subtilis inititation of protein synthesis is possible without prior formylation of initiator tRNA.

The polypeptide chain growth rate in amino acid-starved Escherichia coli determined by a novel method

The proteins synthesized by arginine-requiring Escherichia coli during growth or arginine starvation were characterized by polyacrylamide gel electrophoresis in sodium dodecyl sulfate to give size distributions. The proteins made during amino acid starvation were smaller than those made by growing cells. This was true for otherwise isogenic rel- ("relaxed") and rel+ ("stringent") bacteria. Also using electrophoretic profiles, the peptide chain growth rate was estimated by a novel method based on comparison of theoretically predicted and observed kinetics of pulse labeling protein chains of different sizes. During arginine starvation, the rate was 2--5 amino acids/s for both rel- and rel+ cells, compared to 20 amino acids/s for growing cells. The results rule out chain growth-rate differences as an aspect of the "relaxed" phenomenon.

Physiological roles of pneumococcal peptidases

A methionyl-specific dipeptidase from Streptococcus pneumoniae has been described. This enzyme and the pneumococcal tripeptidase have been shown to be intracellular, soluble, and constitutive. In addition to their function in cleavage of peptide nutrients, these peptidases may play a role in protein synthesis and turnover.

Steady-state measurement of the turnover of amino acid in the cellular proteins of growing Escherichia coli: existence of two kinetically distinct reactions

Turnover of cellular protein has been estimated in Escherichia coli during continuous exponential growth and in the absence of extensive experimental manipulation. Estimation is based upon the cumulative release into carrier pools of free leucine-1-(14)C over a number of time intervals after its pulsed incorporation into protein. Breakdown rates obtained with other labeled amino acids are similar to those obtained with leucine. Two kinetically separate processes have been shown. First, a very rapid turnover of 5% of the amino acid label occurs within 45 sec after its incorporation, most likely indicating maturative cleavages within the proteins after their assembly. A slower heterogeneous rate of true protein turnover follows, falling by 39% in the remaining proteins for each doubling of turnover time. At 36 C, the total breakdown rate of cellular protein is 2.5 and 3.0% per hr over a threefold range of growth rate in glucose and acetate medium, respectively. This relatively constant breakdown rate is maintained during slower growth by more extensive protein replacement, one fifth of the protein synthesized at any time in the acetate medium being replaced after 4.6 doubling times. Intracellular proteolysis thus appears to be a normal and integral reaction of the growing cell. The total rate equals minimal estimates obtained by others for arrested or decelerated growth but is kinetically more heterogeneous. Quantitatively proteolysis is not directly affected by growth arrestment per se as caused by alpha-methylhistidine, chloramphenicol, or uncouplers of oxidative phosphorylation, but qualitatively it can gradually become more homogeneous kinetically as a secondary event of starvation. Under more extreme conditions as with extensive washing, prolonged phosphorylative uncoupling, or acidification of the growth medium, the proteolytic rate can increase severalfold.

Taxonomic comparison of the amino termini of microbial cell proteins

A comparison was made of the distribution of amino terminal end groups in the cellular proteins of a number of microbes. Among the procaryotes, methionine is a highly variable but virtually ubiquitous major protein end group. This is consistent with its possible role as a general amino acid initiator of protein biosynthesis in the procaryotes. Generally, however, alanine is the most abundant of the major end groups, followed in decreasing order by serine, threonine, the acidic amino acids, and occasionally lysine. No other new major end-groups were found. Among 15 representatives of the Enterobacteriaceae, retention of the initiating methionine terminus of the cellular protein varies considerably at a tribal level and is randomized at a familial level. The profiles of the five remaining end groups, however, are strikingly uniform, and are, for example, close to but significantly different from those of the Erwineae. Among the taxonomically more heterogeneous Bacillaceae, end-group profiles vary more and are sometimes unrelated. End-group analysis is thus particularly useful as a molecular criterion of taxonomy in assessing familial homogeneity. Free NH(2) termini in eucaryote cell proteins are fewer, and they have increased acidic amino acid components and no methionine; they are otherwise similar to those of the procaryotes.