Short translational ramp determines efficiency of protein synthesis

Verma, Manasvi; Choi, Junhong; Cottrell, Kyle A.; Lavagnino, Zeno; Thomas, Erica N.; Pavlovic-Djuranovic, Slavica; Szczęsny, Paweł; Piston, David W.; Zaher, Hani; Puglisi, Joseph D.; Djuranović, Sergej

doi:10.1101/571059

Cited by 16 publications

(27 citation statements)

References 56 publications

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“…This result is consistent with two recent studies that stressed the importance of the first 10 codons in regulating protein production (Chu et al, 2014;Szavits-Nossan et al, 2018a). Furthermore, the first codons are also experimentally recognised to be critical in determining protein synthesis (Kudla et al, 2009;Bentele et al, 2014;Cambray et al, 2018;Verma et al, 2019). Finally, this result is also consistent with the "slow ramp" hypothesis (Tuller et al, 2010): a ribosome translating the first (slower) codons will be less prone to interfere with other ribosomes downstream the sequence.…”

Section: Discussionsupporting

confidence: 74%

Inferring efficiency of translation initiation and elongation from ribosome profiling

Szavits-Nossan

Ciandrini

2019

Preprint

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Ribosome profiles are often interpreted with underlying naive models that are unable to grasp the complexity of the biological process. We develop a Non-Equilibrium Analysis of Ribo-seq (NEAR), and provide unprecedented estimates of translation initiation and elongation efficiencies, emphasising the importance of rating these two stages of translation separately. When examining ribosome profiling in yeast, we observe that translation initiation and elongation are close to their optima, and traffic is minimised at the beginning of the transcript to favour ribosome recruitment. However, we find many sites of congestion along the mRNAs where the probability of ribosome interference can reach 50%. Our analysis excludes unreliable datapoints and discusses biases of the experimental technique; as a result, we conclude that current analyses and definitions of translation efficiency are not adapt to quantitatively asses ribosome interference. *

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Section: Discussionsupporting

confidence: 74%

Inferring efficiency of translation initiation and elongation from ribosome profiling

Szavits-Nossan

Ciandrini

2019

Preprint

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“…The strong biases on disfavored DE/P-rich sequences and favored bulky amino acids in the N-terminal regions of bacterial ORFs are in agreement with this assumption (Figure 4 and Figure S4). Many previous studies have pointed out that the sequence features just adjacent to the start codon significantly influence the efficiency of protein biosynthesis (Allert et al, 2010; Goodman et al, 2013; Kudla et al, 2009; Osterman et al, 2020; Salis et al, 2009; Sprengart et al, 1996; Verma et al, 2019). Considering the “bulkiness” of the nascent polypeptide when interpreting the datasets might disclose new landscapes from previous studies.…”

Section: Discussionmentioning

confidence: 99%

Nascent polypeptide within the exit tunnel ensures continuous translation elongation by stabilizing the translating ribosome

Chadani

Sugata

Niwa

et al. 2021

Preprint

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Continuous translation elongation, irrespective of amino acid sequences, is a prerequisite for living organisms to produce their proteomes. However, the risk of elongation abortion is concealed within nascent polypeptide products. Negatively charged sequences with occasional intermittent prolines, termed intrinsic ribosome destabilization (IRD) sequences, destabilizes the translating ribosomal complex. Thus, some nascent chain sequences lead to premature translation cessation. Here, we show that the risk of IRD is maximal at the N-terminal regions of proteins encoded by dozens of Escherichia coli genes. In contrast, most potential IRD sequences in the middle of open reading frames remain cryptic. We found two elements in nascent chains that counteract IRD: the nascent polypeptide itself that spans the exit tunnel and its bulky amino acid residues that occupy the tunnel entrance region. Thus, nascent polypeptide products have a built-in ability to ensure elongation continuity by serving as a bridge and thus by protecting the large and small ribosomal subunits from dissociation.

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“…Our workflows were aided by the use of the high-affinity, 11 amino acid HiBiT tag (87), which is able to complex with a 18 kDa engineered NanoLuc polypeptide (88) and luminesce proportional to the level of HiBiT-tagged protein. We found that this worked well as a C-terminal tag but reduced yields when fused to the N-terminus of sfGFP ( Figure 2 ), perhaps because the HiBiT amino acid sequence is not optimal for early translational elongation (89). Although sfGFP has been optimised to improve folding (90), the minimal size of the HiBiT tag may be less likely to inhibit protein function and accessibility.…”

Section: Discussionmentioning

confidence: 99%

Biofoundry-assisted expression and characterisation of plant proteins

Dudley

Cai

Kallam

et al. 2021

Preprint

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Many goals in synthetic biology, including the elucidation and refactoring of biosynthetic pathways and the engineering of regulatory circuits and networks, require knowledge of protein function. In plants, the prevalence of large gene families means it can be particularly challenging to link specific functions to individual proteins. However, protein characterisation has remained a technical bottleneck, often requiring significant effort to optimise expression and purification protocols. To leverage the ability of biofoundries to accelerate design-built-test-learn cycles, we present a workflow for automated DNA assembly and cell-free expression of plant proteins that accelerates optimisation and enables rapid progression to characterisation. First, we developed a phytobrick-compatible Golden Gate DNA assembly toolbox containing plasmid acceptors for cell-free expression using E. coli or wheat germ lysates as well as a set of N- and C-terminal tag parts for detection, purification, and improved expression/folding. We next optimised automated assembly of miniaturised cell-free reactions using an acoustic liquid handling platform and then compared tag configurations to identify those that increase expression. We additionally developed a luciferase-based system for rapid quantification that requires a minimal 11 aa tag and demonstrate facile removal of tags following synthesis. Finally, we show that several functional characterisation experiments can be performed with cell-free protein synthesis reactions without the need for protein purification. Together, the combination of automated assembly of DNA parts and cell-free expression reactions should significantly increase the throughput of experiments to test and understand plant protein function and enable the direct reuse of DNA parts in downstream plant engineering workflows.

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Short translational ramp determines efficiency of protein synthesis

Cited by 16 publications

References 56 publications

Inferring efficiency of translation initiation and elongation from ribosome profiling

Inferring efficiency of translation initiation and elongation from ribosome profiling

Nascent polypeptide within the exit tunnel ensures continuous translation elongation by stabilizing the translating ribosome

Biofoundry-assisted expression and characterisation of plant proteins

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