The mammalian target of rapamycin (mTOR), a phosphoinositide 3-kinase related protein kinase, controls cell growth in response to nutrients and growth factors and is frequently deregulated in cancer. Here we report co-crystal structures of a truncated mTOR-mLST8 complex with an ATP transition state mimic and with ATP-site inhibitors. The structures reveal an intrinsically active kinase conformation, with catalytic residues and mechanism remarkably similar to canonical protein kinases. The active site is highly recessed due to the FKBP12-Rapamycin binding (FRB) domain and an inhibitory helix protruding from the catalytic cleft. mTOR activating mutations map to the structural framework that holds these elements in place, indicating the kinase is controlled by restricted access. In vitro biochemistry indicates that the FRB domain acts as a gatekeeper, with its rapamycin-binding site interacting with substrates to grant them access to the restricted active site. FKBP12-rapamycin inhibits by directly blocking substrate recruitment and by further restricting active site access. The structures also reveal active site residues and conformational changes that underlie inhibitor potency and specificity.
Lasso peptides are a class of ribosomally-derived natural products typified by their threaded rotaxane structure. The conversion of a linear precursor peptide into a lasso peptide structure requires two enzymatic activities: cleavage of the precursor via a cysteine protease and cyclization via isopeptide bond formation. In vitro studies of lasso peptide enzymology have been hampered by difficulties in obtaining pure, soluble enzymes. We reasoned that thermophilic bacteria would be a good source for well-behaved lasso peptide biosynthetic enzymes. The genome of the thermophilic actinobacterium Thermobifida fusca encodes for a lasso peptide with an unprecedented Trp residue at its N-terminus, a peptide we have named fuscanodin. Here we reconstitute fuscanodin biosynthesis in vitro with purified components, establishing a minimal fuscanodin synthetase. These experiments have allowed us to probe the kinetics of lasso peptide biosynthesis for the first time, and we report initial rates of fuscanodin biosynthesis. The fuscanodin biosynthetic enzymes are insensitive to substrate concentration and operate in a near single-turnover regime in vitro. While lasso peptides are often touted for their stability to both chaotropic and thermal challenges, fuscanodin is found to undergo a conformational change consistent with lasso peptide unthreading in organic solvents at room temperature.
Lasso peptides are a family of ribosomally synthesized and post-translationally modified peptides (RiPPs) defined by their threaded structure. Besides the class-defining isopeptide bond, other post-translational modifications (PTMs) that further tailor lasso peptides have been previously reported. Using genome mining tools, we identified a subset of lasso peptide biosynthetic gene clusters (BGCs) that are colocalized with genes encoding protein l-isoaspartyl methyltransferase (PIMT) homologues. PIMTs have an important role in protein repair, restoring isoaspartate residues formed from asparagine deamidation to aspartate. Here we report a new function for PIMT enzymes in the post-translational modification of lasso peptides. The PIMTs associated with lasso peptide BGCs first methylate an l-aspartate side chain found within the ring of the lasso peptide. The methyl ester is then converted into a stable aspartimide moiety, endowing the lasso peptide ring with rigidity relative to its unmodified counterpart. We describe the heterologous expression and structural characterization of two examples of aspartimide-modified lasso peptides from thermophilic Gram-positive bacteria. The lasso peptide cellulonodin-2 is encoded in the genome of actinobacterium Thermobifida cellulosilytica, while lihuanodin is encoded in the genome of firmicute Lihuaxuella thermophila. Additional genome mining revealed PIMT-containing lasso peptide BGCs in 48 organisms. In addition to heterologous expression, we have reconstituted PIMT-mediated aspartimide formation in vitro, showing that lasso peptide-associated PIMTs transfer methyl groups very rapidly as compared to canonical PIMTs. Furthermore, in stark contrast to other characterized lasso peptide PTMs, the methyltransferase functions only on lassoed substrates.
Microviridins and other ω−ester linked peptides (OEPs) are characterized by sidechain-sidechain linkages installed by ATP-grasp enzymes. Here we describe the discovery of a new family of OEPs, the gene clusters of which also encode an O-methyltransferase with homology to the protein repair catalyst protein L-isoaspartyl methyltransferase (PIMT). We produced the first example of this new ribosomally synthesized and post-translationally modified peptide (RiPP), fuscimiditide, via heterologous expression. NMR analysis of fuscimiditide revealed that the peptide contains two ester crosslinks forming a stem-loop macrocycle. Furthermore, an unusually stable aspartimide moiety is found within the loop macrocycle. We have also fully reconstituted fuscimiditide biosynthesis in vitro establishing that ester formation catalyzed by the ATP-grasp enzyme is an obligate, rate-limiting first biosynthetic step. Aspartimide formation from aspartate is catalyzed by the PIMT homolog in the second step. The aspartimide moiety embedded in fuscimiditide hydrolyzes regioselectively to isoaspartate (isoAsp). Surprisingly, this isoAspcontaining protein is also a substrate for the PIMT homolog, thus driving any hydrolysis products back to the aspartimide form. Whereas aspartimide is often considered a nuisance product in protein formulations, our data here suggest that some RiPPs have aspartimide residues intentionally installed via enzymatic activity.
Lasso peptide isopeptidase is an enzyme that specifically hydrolyzes the isopeptide bond of lasso peptides, rendering these peptides linear. To carry out a detailed structure-activity analysis of the lasso peptide isopeptidase AtxE2 from Asticcacaulis excentricus, we solved NMR structures of its substrates astexin-2 and astexin-3. Using in vitro enzyme assays, we show that the C-terminal tail portion of these peptides is dispensable with regards to isopeptidase activity. A collection of astexin-2 and astexin-3 variants with alanine substitutions at each position within the ring and the loop was constructed, and we showed that all of these peptides except for one were cleaved by the isopeptidase. Thus, much like the lasso peptide biosynthetic enzymes, lasso peptide isopeptidase has broad substrate specificity. Quantitative analysis of the cleavage reactions indicated that alanine substitutions in loop positions of these peptides led to reduced cleavage, suggesting that the loop is serving as a recognition element for the isopeptidase.Ribosomally synthesized and post-translationally modified peptides (RiPPs) 3 (1) are a diverse set of natural products that are formed by the action of maturation enzymes on a linear peptide substrate. An emerging theme in the biosynthesis of RiPPs is that the maturation enzymes tend to have broad substrate specificity (2-8). Lasso peptides are a class of RiPPs, characterized by a threaded structure resembling a slipknot (9 -11). The internal macrocycle is realized via a single isopeptide bond installed post-translationally by two maturation enzymes (12). While there is a quickly expanding literature about the lasso peptide maturation enzymes (12-14), there is little known about the catabolism of these molecules. Recently, we reported an enzyme, lasso peptide isopeptidase, that specifically hydrolyzes the isopeptide bond of lasso peptides (Fig. 1A) (15). This enzyme, related to prolyl oligopeptidases, was found in the vicinity of a lasso peptide gene cluster in the freshwater ␣-proteobacterium Asticcacaulis excentricus. This organism has two separate lasso peptide gene clusters, each with an associated isopeptidase gene (15, 16). There have been a large number of lasso peptides discovered in proteobacteria (11,17), and an isopeptidase is commonly associated with such clusters (9).We named the two isopeptidases in A. excentricus AtxE1 and AtxE2. The gene for AtxE1 is found next to the gene cluster that encodes for the biosynthesis of astexin-1, while the AtxE2 gene is located next to the gene cluster encoding astexins-2 and -3 (Fig. 1B) (15). We have previously characterized AtxE2 in vitro (15). This enzyme cleaves astexin-2 and astexin-3, but no crossreactivity was observed between AtxE2 and astexin-1. Whereas astexin-2 and astexin-3 share relatively high sequence homology (identity at 13/24 positions), the astexin-1 sequence is more divergent (Fig. 1C). In addition, we have shown that, at least for astexin-2, the thermally unthreaded variant of the peptide is not a substrate for Atx...
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