20 research outputs found
Correcting errors in synthetic DNA through consensus shuffling
Although efficient methods exist to assemble synthetic oligonucleotides into genes and genomes, these suffer from the presence of 1–3 random errors/kb of DNA. Here, we introduce a new method termed consensus shuffling and demonstrate its use to significantly reduce random errors in synthetic DNA. In this method, errors are revealed as mismatches by re-hybridization of the population. The DNA is fragmented, and mismatched fragments are removed upon binding to an immobilized mismatch binding protein (MutS). PCR assembly of the remaining fragments yields a new population of full-length sequences enriched for the consensus sequence of the input population. We show that two iterations of consensus shuffling improved a population of synthetic green fluorescent protein (GFPuv) clones from ∼60 to >90% fluorescent, and decreased errors 3.5- to 4.3-fold to final values of ∼1 error per 3500 bp. In addition, two iterations of consensus shuffling corrected a population of GFPuv clones where all members were non-functional, to a population where 82% of clones were fluorescent. Consensus shuffling should facilitate the rapid and accurate synthesis of long DNA sequences
KRAS is vulnerable to reversible switch-II pocket engagement in cells.
Current small-molecule inhibitors of KRAS(G12C) bind irreversibly in the switch-II pocket (SII-P), exploiting the strong nucleophilicity of the acquired cysteine as well as the preponderance of the GDP-bound form of this mutant. Nevertheless, many oncogenic KRAS mutants lack these two features, and it remains unknown whether targeting the SII-P is a practical therapeutic approach for KRAS mutants beyond G12C. Here we use NMR spectroscopy and a cellular KRAS engagement assay to address this question by examining a collection of SII-P ligands from the literature and from our own laboratory. We show that the SII-Ps of many KRAS hotspot (G12, G13, Q61) mutants are accessible using noncovalent ligands, and that this accessibility is not necessarily coupled to the GDP state of KRAS. The results we describe here emphasize the SII-P as a privileged drug-binding site on KRAS and unveil new therapeutic opportunities in RAS-driven cancer
CRISPR-Mediated Tagging of Endogenous Proteins with a Luminescent Peptide
Intracellular
signaling pathways are mediated by changes in protein
abundance and post-translational modifications. A common approach
for investigating signaling mechanisms and the effects induced by
synthetic compounds is through overexpression of recombinant reporter
genes. Genome editing with CRISPR/Cas9 offers a means to better preserve
native biology by appending reporters directly onto the endogenous
genes. An optimal reporter for this purpose would be small to negligibly
influence intracellular processes, be readily linked to the endogenous
genes with minimal experimental effort, and be sensitive enough to
detect low expressing proteins. HiBiT is a 1.3 kDa peptide (11 amino
acids) capable of producing bright and quantitative luminescence through
high affinity complementation (<i>K</i><sub>D</sub> = 700
pM) with an 18 kDa subunit derived from NanoLuc (LgBiT). Using CRISPR/Cas9,
we demonstrate that HiBiT can be rapidly and efficiently integrated
into the genome to serve as a reporter tag for endogenous proteins.
Without requiring clonal isolation of the edited cells, we were able
to quantify changes in abundance of the hypoxia inducible factor 1A
(HIF1α) and several of its downstream transcriptional targets
in response to various stimuli. In combination with fluorescent antibodies,
we further used HiBiT to directly correlate HIF1α levels with
the hydroxyproline modification that mediates its degradation. These
results demonstrate the ability to efficiently tag endogenous proteins
with a small luminescent peptide, allowing sensitive quantitation
of the response dynamics in their regulated expression and covalent
modifications
CRISPR-Mediated Tagging of Endogenous Proteins with a Luminescent Peptide
Intracellular
signaling pathways are mediated by changes in protein
abundance and post-translational modifications. A common approach
for investigating signaling mechanisms and the effects induced by
synthetic compounds is through overexpression of recombinant reporter
genes. Genome editing with CRISPR/Cas9 offers a means to better preserve
native biology by appending reporters directly onto the endogenous
genes. An optimal reporter for this purpose would be small to negligibly
influence intracellular processes, be readily linked to the endogenous
genes with minimal experimental effort, and be sensitive enough to
detect low expressing proteins. HiBiT is a 1.3 kDa peptide (11 amino
acids) capable of producing bright and quantitative luminescence through
high affinity complementation (<i>K</i><sub>D</sub> = 700
pM) with an 18 kDa subunit derived from NanoLuc (LgBiT). Using CRISPR/Cas9,
we demonstrate that HiBiT can be rapidly and efficiently integrated
into the genome to serve as a reporter tag for endogenous proteins.
Without requiring clonal isolation of the edited cells, we were able
to quantify changes in abundance of the hypoxia inducible factor 1A
(HIF1α) and several of its downstream transcriptional targets
in response to various stimuli. In combination with fluorescent antibodies,
we further used HiBiT to directly correlate HIF1α levels with
the hydroxyproline modification that mediates its degradation. These
results demonstrate the ability to efficiently tag endogenous proteins
with a small luminescent peptide, allowing sensitive quantitation
of the response dynamics in their regulated expression and covalent
modifications
NanoLuc Complementation Reporter Optimized for Accurate Measurement of Protein Interactions in Cells
Protein-fragment
complementation assays (PCAs) are widely used
for investigating protein interactions. However, the fragments used
are structurally compromised and have not been optimized nor thoroughly
characterized for accurately assessing these interactions. We took
advantage of the small size and bright luminescence of NanoLuc to
engineer a new complementation reporter (NanoBiT). By design, the
NanoBiT subunits (i.e., 1.3 kDa peptide, 18 kDa polypeptide) weakly
associate so that their assembly into a luminescent complex is dictated
by the interaction characteristics of the target proteins onto which
they are appended. To ascertain their general suitability for measuring
interaction affinities and kinetics, we determined that their intrinsic
affinity (<i>K</i><sub>D</sub> = 190 μM) and association
constants (<i>k</i><sub>on</sub> = 500 M<sup>–1</sup> s<sup>–1</sup>, <i>k</i><sub>off</sub> = 0.2 s<sup>–1</sup>) are outside of the ranges typical for protein interactions.
The accuracy of NanoBiT was verified under defined biochemical conditions
using the previously characterized interaction between SME-1 β-lactamase
and a set of inhibitor binding proteins. In cells, NanoBiT fusions
to FRB/FKBP produced luminescence consistent with the linear characteristics
of NanoLuc. Response dynamics, evaluated using both protein kinase
A and β-arrestin-2, were rapid, reversible, and robust to temperature
(21–37 °C). Finally, NanoBiT provided a means to measure
pharmacology of kinase inhibitors known to induce the interaction
between BRAF and CRAF. Our results demonstrate that the intrinsic
properties of NanoBiT allow accurate representation of protein interactions
and that the reporter responds reliably and dynamically in cells
Engineered Luciferase Reporter from a Deep Sea Shrimp Utilizing a Novel Imidazopyrazinone Substrate
Bioluminescence methodologies have been extraordinarily
useful
due to their high sensitivity, broad dynamic range, and operational
simplicity. These capabilities have been realized largely through
incremental adaptations of native enzymes and substrates, originating
from luminous organisms of diverse evolutionary lineages. We engineered
both an enzyme and substrate in combination to create a novel bioluminescence
system capable of more efficient light emission with superior biochemical
and physical characteristics. Using a small luciferase subunit (19
kDa) from the deep sea shrimp <i>Oplophorus gracilirostris</i>, we have improved luminescence expression in mammalian cells ∼2.5
million-fold by merging optimization of protein structure with development
of a novel imidazopyrazinone substrate (furimazine). The new luciferase,
NanoLuc, produces glow-type luminescence (signal half-life >2 h)
with
a specific activity ∼150-fold greater than that of either firefly
(<i>Photinus pyralis</i>) or <i>Renilla</i> luciferases
similarly configured for glow-type assays. In mammalian cells, NanoLuc
shows no evidence of post-translational modifications or subcellular
partitioning. The enzyme exhibits high physical stability, retaining
activity with incubation up to 55 °C or in culture medium for
>15 h at 37 °C. As a genetic reporter, NanoLuc may be configured
for high sensitivity or for response dynamics by appending a degradation
sequence to reduce intracellular accumulation. Appending a signal
sequence allows NanoLuc to be exported to the culture medium, where
reporter expression can be measured without cell lysis. Fusion onto
other proteins allows luminescent assays of their metabolism or localization
within cells. Reporter quantitation is achievable even at very low
expression levels to facilitate more reliable coupling with endogenous
cellular processes