Ubiquitination is a reversible post-translational modification that regulates a myriad of eukaryotic functions. Our ability to study the effects of ubiquitination is often limited by the inaccessibility of homogeneously ubiquitinated proteins. In particular, elucidating the roles of the so-called 'atypical' ubiquitin chains (chains other than Lys48- or Lys63-linked ubiquitin), which account for a large fraction of ubiquitin polymers, is challenging because the enzymes for their biosynthesis are unknown. Here we combine genetic code expansion, intein chemistry and chemoselective ligations to synthesize 'atypical' ubiquitin chains. We solve the crystal structure of Lys6-linked diubiquitin, which is distinct from that of structurally characterized ubiquitin chains, providing a molecular basis for the different biological functions this linkage may regulate. Moreover, we profile a panel containing 10% of the known human deubiquitinases on Lys6- and Lys29-linked ubiquitin and discover that TRABID cleaves the Lys29 linkage 40-fold more efficiently than the Lys63 linkage.
We demonstrate that an orthogonal Methanosarcina barkeri MS pyrrolysyl-tRNA synthetase/tRNA(CUA) pair directs the efficient, site-specific incorporation of N6-[(2-propynyloxy)carbonyl]-L-lysine, containing a carbon-carbon triple bond, and N6-[(2-azidoethoxy)carbonyl]-L-lysine, containing an azido group, into recombinant proteins in Escherichia coli. Proteins containing the alkyne functional group are labeled with an azido biotin and an azido fluorophore, via copper catalyzed [3+2] cycloaddition reactions, to produce the corresponding triazoles in good yield. The methods reported are useful for the site-specific labeling of recombinant proteins and may be combined with mutually orthogonal methods of introducing unnatural amino acids into proteins as well as with chemically orthogonal methods of protein labeling. This should allow the site specific incorporation of multiple distinct probes into proteins and the control of protein topology and structure by intramolecular orthogonal conjugation reactions.
Targeted protein degradation has
emerged as a new paradigm to manipulate
cellular proteostasis. Proteolysis-targeting chimeras (PROTACs) are
bifunctional small molecules that recruit an E3 ligase to a target
protein of interest, promoting its ubiquitination and subsequent degradation.
Here, we report the development of antibody-based PROTACs (AbTACs),
fully recombinant bispecific antibodies that recruit membrane-bound
E3 ligases for the degradation of cell-surface proteins. We show that
an AbTAC can induce the lysosomal degradation of programmed death-ligand
1 by recruitment of the membrane-bound E3 ligase RNF43. AbTACs represent
a new archetype within the PROTAC field to target cell-surface proteins
with fully recombinant biological molecules.
Precise photochemical control of protein function can be achieved through the site-specific introduction of caging groups. Chemical and enzymatic methods, including in vitro translation and chemical ligation, have been used to photocage proteins in vitro. These methods have been extended to allow the introduction of caged proteins into cells by permeabilization or microinjection, but cellular delivery remains challenging. Since lysine residues are key determinants for nuclear localization sequences, the target of key post-translational modifications (including ubiquitination, methylation, and acetylation), and key residues in many important enzyme active sites, we were interested in photocaging lysine to control protein localization, post-translational modification, and enzymatic activity. Photochemical control of these important functions mediated by lysine residues in proteins has not previously been demonstrated in living cells. Here we synthesized 1 and evolved a pyrrolysyl-tRNA synthetase/tRNA pair to genetically encode the incorporation of this amino acid in response to an amber codon in mammalian cells. To exemplify the utility of this amino acid, we caged the nuclear localization sequences (NLSs) of nucleoplasmin and the tumor suppressor p53 in human cells, thus mislocalizing the proteins in the cytosol. We triggered protein nuclear import with a pulse of light, allowing us to directly quantify the kinetics of nuclear import.
The site-specific
incorporation of three new coumarin lysine analogues
into proteins was achieved in bacterial and mammalian cells using
an engineered pyrrolysyl-tRNA synthetase system. The genetically encoded
coumarin lysines were successfully applied as fluorescent cellular
probes for protein localization and for the optical activation of
protein function. As a proof-of-principle, photoregulation of firefly
luciferase was achieved in live cells by caging a key lysine residue,
and excellent OFF to ON light-switching ratios were observed. Furthermore,
two-photon and single-photon optochemical control of EGFP maturation
was demonstrated, enabling the use of different, potentially orthogonal
excitation wavelengths (365, 405, and 760 nm) for the sequential activation
of protein function in live cells. These results demonstrate that
coumarin lysines are a new and valuable class of optical probes that
can be used for the investigation and regulation of protein structure,
dynamics, function, and localization in live cells. The small size
of coumarin, the site-specific incorporation, the application as both
a light-activated caging group and as a fluorescent probe, and the
broad range of excitation wavelengths are advantageous over other
genetically encoded photocontrol systems and provide a precise and
multifunctional tool for cellular biology.
We report evolved orthogonal pyrrolysyl-tRNA synthetase/tRNA(CUA) pairs that direct the efficient, site-specific incorporation of N(ε)-L-thiaprolyl-L-lysine, N(ε)-D-cysteinyl-L-lysine, and N(ε)-L-cysteinyl-L-lysine into recombinant proteins in Escherichia coli . We demonstrate that the unique 1,2-aminothiol introduced by our approach can be efficiently, rapidly, and specifically labeled via a cyanobenzothiazole condensation to quantitatively introduce biophysical probes into proteins. Moreover, we show that, in combination with cysteine labeling, this approach allows the dual labeling of proteins with distinct probes at two distinct, genetically defined sites.
Protein ubiquitination is a post-translational modification that regulates almost all aspects of eukaryotic biology. Here we discover the first routes for the efficient site-specific incorporation of δ-thiol-l-lysine (7) and δ-hydroxy-l-lysine (8) into recombinant proteins, via evolution of a pyrrolysyl-tRNA synthetase/tRNACUA pair. We combine the genetically directed incorporation of 7 with native chemical ligation and desulfurization to yield an entirely native isopeptide bond between substrate proteins and ubiquitin. We exemplify this approach by demonstrating the synthesis of a ubiquitin dimer and the first synthesis of ubiquitinated SUMO.
Lysine methylation is an important post-translational modification of histone proteins that defines epigenetic status and controls heterochromatin formation, X-chromosome inactivation, genome imprinting, DNA repair, and transcriptional regulation. Despite considerable efforts by chemical biologists to synthesize modified histones for use in deciphering the molecular role of methylation in these phenomena, no general method exists to synthesize proteins bearing quantitative site-specific methylation. Here we demonstrate a general method for the quantitative installation of N(epsilon)-methyl-L-lysine at defined positions in recombinant histones and demonstrate the use of this method for investigating the methylation dependent binding of HP1 to full length histone H3 monomethylated on K9 (H3K9me1). This strategy will find wide application in defining the molecular mechanisms by which histone methylation orchestrates cellular phenomena.
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