Project description:N-terminal acetylation is one of the most common protein modifications in eukaryotes, with emerging roles in regulating protein quality and stoichiometry and targeting and complex formation. The NatC complex is one of the three major N-terminal acetyltransferases (NATs). Here, we partially defined the in vivo human NatC Nt-acetylome by combining siNAA30 mediated knockdown with positional proteomics. We identified 51 human NatC substrates and expanded our current knowledge on the substrate repertoire of NatC which now includes proteins harboring Met-Leu, Met-Ile, Met-Phe, Met-Trp, Met-Tyr, Met-Trp, Met-Met, Met-His and Met-Lys N-termini. Next to cytosolic proteins, several organellar proteins were identified as NatC substrates. Interestingly, upon Naa30 depletion, the levels of several organellar proteins were reduced, in particular those of mitochondrial proteins. Further, knockdown of Naa30 induced the loss of membrane potential, clearing and fragmentation of mitochondria. Naa30 depletion also led to disassembly of the Golgi apparatus. However, Naa30 depletion did not affect ER morphology, endosome or peroxisome distribution or microtubule and actin cytoskeletal architecture, suggesting that the observed mitochondrial fragmentation and clearance and Golgi scattering are not due to general disruption of organelles or microtubules. In conclusion, NatC Nt-acetylates a large variety of cytosolic and organellar proteins and is essential for cis-Golgi integrity and mitochondrial function.

Project description:N-terminal (Nt) acetylation, catalyzed by N-terminal acetyltransferases (NATs), has emerged as an important co-translational modification in eukaryotes, and involves the transfer of the acetyl moiety from acetyl-CoA (Ac-CoA) to the α-amino group of a nascent polypeptide. Here, we report the first global study of Nt-acetylation in response to changes in nutrient availability in S. cerevisiae. Despite major fluctuations in Ac-CoA and histone acetylation levels, our study reveals that the steady-state levels of protein Nt-acetylation remains largely unaffected by changes in cellular metabolism. Accordingly, Ac-CoA does not appear to act as a master switch for protein Nt-acetylation. Interestingly however, we identified two distinct sets of N-termini that are differentially Nt-acetylated following nutrient starvation. The first set of proteins, enriched for annotated N-termini, generally displayed an increased Nt-acetylation in stationary phase compared to exponential growth phase, despite a significant reduction in Ac-CoA levels. In contrast, the second set of proteins, enriched for alternative non-annotated N-termini (i.e. N-terminal proteoforms), generally became less acetylated in stationary phase. In particular, the degree of Nt-acetylation of Pcl8, a negative regulator of glycogen biosynthesis and two components of the pre-ribosome complex (Rsa3 and Rpl7a) increased during starvation. Moreover, the levels of these proteins were regulated by both starvation and the presence of NatA activity. Overall, our data provide the first proteome-wide survey on metabolic regulation of Nt-acetylation, and propose Nt-acetylation-mediated steering of metabolism and ribosome biogenesis.

Project description:Abstract still has to be written. The obtained peptide mixtures were introduced into an LC-MS/MS system, the Ultimate 3000 (Dionex, Amsterdam, The Netherlands) in-line connected to an LTQ Orbitrap XL mass spectrometer (Thermo Fisher Scientific, Bremen, Germany). Samples were first loaded on a trapping column (made in-house, 100 um internal diameter (I.D.) x 20 mm, 5 um beads C18 Reprosil-HD, Dr. Maisch). After back-flushing from the trapping column, the sample was loaded on a reverse-phase column (made in-house, 75 um I.D. x 150 mm, 5 um beads C18 Reprosil-HD, Dr. Maisch). Peptides were loaded with solvent A (0.1% trifluoroacetic acid, 2% acetonitrile), and were separated with a linear gradient from 2% solvent A' (0.05% formic acid) to 55% solvent B' (0.05% formic acid and 80% acetonitrile) at a flow rate of 300 nL/min followed by a wash reaching 100% solvent B'. The mass spectrometer was operated in data-dependent mode, automatically switching between MS and MS/MS acquisition for the six most abundant peaks in a given MS spectrum. Full scan MS spectra were acquired in the Orbitrap at a target value of 1E6 with a resolution of 60,000. The six most intense ions were then isolated for fragmentation in the linear ion trap, with a dynamic exclusion of 60 s. Peptides were fragmented after filling the ion trap at a target value of 1E4 ion counts. From the MS/MS data in each LC run, Mascot Generic Files were created using the Mascot Distiller software (version 2.3.01, Matrix Science). While generating these peak lists, grouping of spectra was allowed with a maximum intermediate retention time of 30 s and a maximum intermediate scan count of 5 was used where possible. Grouping was done with 0.005 Da precursor tolerance. A peak list was only generated when the MS/MS spectrum contained more than 10 peaks. There was no de-isotoping and the relative signal to noise limit was set at 2. These peak lists were then searched with the Mascot search engine (Matrix Science) using the Mascot Daemon interface (version 2.3, Matrix Science). Spectra were searched against the human (H. sapiens) Swiss-Prot database. 13C2D3-acetylation of lysine side-chains, carbamidomethylation of cysteine and methionine oxidation to methionine-sulfoxide were set as fixed modifications for the N-terminal COFRADIC analyses. Variable modifications were 13C2D3-acetylation and acetylation of protein N-termini. Pyroglutamate formation of N-terminal glutamine was additionally set as a variable modification. Mass tolerance on precursor ions was set to 10 ppm (with Mascot's C13 option set to 1) and on fragment ions to 0.5 Da. Endoproteinase semi-Arg-C/P (Arg-C specificity with arginine-proline cleavage allowed) was set as enzyme allowing no missed cleavages. The peptide charge was set to 1+, 2+, 3+ and instrument setting was put to ESI-TRAP. Only peptides that were ranked one and scored above the threshold score, set at 99% confidence, were withheld. Quantification of the degree of Nt-Acetylation was performed as described previously (1). All data management was done in ms_lims (2).

Project description:Co-translational N-terminal (Nt-) acetylation of nascent polypeptides is catalyzed by N-terminal acetyltransferases (NATs). The very N-terminal amino acid sequence is the major factor determining whether or not a given protein is Nt-acetylated. In humans, six different NATs, denoted NatA-NatF, are identified. In the current study we used N-terminal COFRADIC analysis to define the in vivo substrate specificity of Naa50 (Nat5)/NatE as this has long remained elusive. Three yeast strains were generated; a control strain endogenously expressing yNaa50, a deletion strain depleted of yNaa50 and a strain deleted of yNaa50 but ectopically expressing human Naa50. When comparing the Nt-acetylation status of different N-termini in the control strain with the deletion strain, a reduction in Nt-acetylation for several yeast proteins was observed. To our surprise, these substrates were not of the predicted NatE-type substrates, but rather canonical NatA substrates. Further, ectopic expression of hNaa50 mainly resulted in the Nt-acetylation of a selected class of otherwise Nt-free yeast N-termini besides increasing the degree of Nt-acetylation of several other yeast proteins, and as such (partially) complementing those N-termini displaying reduced Nt-acetylation upon yNAA50-deletion. The preferred substrates of hNaa50 were predominantly Met-starting N-termini including Met-Lys-, Met-Val-, Met-Ala-, Met-Tyr-, Met-Phe-, Met-Leu-, Met-Ser- and Met-Thr, and highly overlapped with the previously identified human Naa60/NatF substrate specificity profile. Identification of several hNaa50 substrates with a small amino acid in the second position also revealed a potential interplay between the NATs and methionine aminopeptidases (MetAPs). The initiator Methionine (iMet) is normally cleaved off by MetAPs when the second amino acid is small, but our in vitro data suggest that in contrast to a free iMet, an Nt-acetylated iMet is not hydrolyzed by MetAPs. Thus, Naa50-mediated Nt-acetylation may potentially act as a mechanism to retain the iMet of proteins with a small amino acid at the second position that normally would be hydrolyzed.

Project description:Proteogenomics is a research field where proteome data is used to improve gene annotation. To achieve this, customized protein databases are constructed to match proteomic data. We perform a proteogenomic analysis using N-terminal COFRADIC data in order to identify novel translational initiation start sites. We use a multistage search strategy where spectra that remained unidentified after searching the Arabidopsis proteome are used for our proteogenomic analysis. Here, the unidentified spectra were searched against a customized N-terminal peptide library derived from a six-frame translation of the Arabidopsis (Arabidopsis thaliana) genome as well as Augustus predicted gene models.

Project description:The impact of NatC subunits NAA30, NAA35 and NAA38 on the human N-terminal acetylome. Analysis of HAP1 WT, NAA30 KO, NAA35 KO and NAA38 KO cells

Project description:To understand the impact of alternative translation initiation on a proteome, we performed the first large-scale study of protein turnover rates in which we distinguish between N-terminal proteoforms pointing to translation initiation events. Using pulsed SILAC combined with N-terminal COFRADIC we monitored the stability of 1,941human N-terminal proteoforms, including 147 proteoform pairs with heterogeneous N-termini originating from the same gene that result from alternative translation initiation and incomplete processing of the initiator methionine. N-terminally truncated proteoforms were on average less abundant than canonical proteoforms, many had different stabilities and exhibited both faster and slower turnover rates compared to their canonical counterparts. These differences in stability did not depend on the length of truncation but on individual protein characteristics. In silico simulation of N-terminal proteoforms in macromolecular complexes revealed possible consequences for complex integrity such as replacement of unstable canonical subunits. The extent of intrinsic disorder in N-terminal protein structures correlated with turnover times, indicating that a change in the structural flexibility of protein N-termini in truncated proteoforms might impact proteoform stability. Interestingly, removal of the initiator methionine by methionine aminopeptidases reduced the stability of processed proteoforms while susceptibility for N-terminal acetylation, another common co-translational modification, did not seem to impact on turnover rates. Taken together, our findings reveal differences in protein stability between N-terminal proteoforms and point to a role for alternative translation initiation and co-translational initiator methionine removal in the overall regulation of proteome homeostasis.

Project description:The impact of NatC subunits NAA30, NAA35 and NAA38 on the human proteome (protein abundance). Analysis of HAP1 WT, NAA30 KO, NAA35 KO and NAA38 KO cells

Project description:The X-linked lethal Ogden syndrome was the first reported human genetic disorder associated with a mutation in an N-terminal acetyltransferase gene. The affected males harbour a Ser37Pro mutation in the gene encoding hNaa10, the catalytic subunit of NatA, themajor human NAT. In order to understand the detrimental impact of hNaa10 Ser37Pro, we performed structural, molecular and cellular investigations. Structural models and molecular dynamics simulations of the human NatA and its Ser37Pro mutant suggest differences in regions involved in catalysis and at the interface between hNaa10 and the auxiliary subunit hNaa15. In agreement, biochemical data demonstrate a reduced catalytic capacity and an impaired NatA complex formation with hNaa10 Ser37Pro. Patient derived Naa10 mutant cells show reduced Nt-acetylation for a subset of NatA/NatE-type substrates compared to wild type Naa10 cells. Ogden syndrome fibroblasts further display abnormal cell proliferation and migration capacity, possibly linked to perturbed Retinoblastoma- and MYLK-pathways, respectively. Differential N-terminal combined fractional diagonal chromatography (COFRADIC) was used to quantify the degree and define the patterns of in vivo protein Nt-acetylation and here used to investigate whether patient cells derived from an affected Ogden male (carrying the Naa10 S37P mutation) displayed altered levels of protein Nt-acetylation at the proteome-wide level.

Project description:N-terminal acetylation is a major and vital protein modification catalysed by N-terminal acetyltransferases (NATs). NatF or Nα-acetyltransferase 60 (Naa60) was recently identified as a NAT in higher eukaryotes. Here, we found that Naa60 differs from all other known NATs by its Golgi localization. A new membrane topology assay named PROMPT and a selective membrane permeabilization assay established Naa60 to face the cytosolic side of intracellular membranes. An Nt-acetylome analysis of NAA60 knockdown cells revealed that Naa60, as opposed to other NATs, specifically acetylates transmembrane proteins, and that is has a preference for N-termini facing the cytosol. Moreover, NAA60 knockdown caused Golgi fragmentation, indicating an important role in maintenance of Golgi structural integrity. This work uncovers the first NAT associated with membranous compartments and establishes N-terminal acetylation as a common modification among transmembrane proteins, a thus far poorly characterized part of the N-terminal acetylome.