Joakim Näsvall scite author profile

Gene duplications allow evolution of genes with new functions. Here, we describe the innovation-amplification-divergence (IAD) model in which the new function appears before duplication and functionally distinct new genes evolve under continuous selection. One example fitting this model is a preexisting parental gene in Salmonella enterica that has low levels of two distinct activities. This gene is amplified to a high copy number, and the amplified gene copies accumulate mutations that provide enzymatic specialization of different copies and faster growth. Selection maintains the initial amplification and beneficial mutant alleles but is relaxed for other less improved gene copies, allowing their loss. This rapid process, completed in fewer than 3000 generations, shows the efficacy of the IAD model and allows the study of gene evolution in real time.

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The modified wobble nucleoside uridine-5-oxyacetic acid in tRNA^Pro_cmo⁵UGG promotes reading of all four proline codons in vivo

Näsvall¹,

Chen²,

Björk³

2004

RNA

110

137

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Structural and functional innovations in the real-time evolution of new (βα) ₈ barrel enzymes

Newton

Guo

Söderholm

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

107

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New genes can arise by duplication and divergence, but there is a fundamental gap in our understanding of the relationship between these genes, the evolving proteins they encode, and the fitness of the organism. Here we used crystallography, NMR dynamics, kinetics, and mass spectrometry to explain the molecular innovations that arose during a previous real-time evolution experiment. In that experiment, the (βα) 8 barrel enzyme HisA was under selection for two functions (HisA and TrpF), resulting in duplication and divergence of the hisA gene to encode TrpF specialists, HisA specialists, and bifunctional generalists. We found that selection affects enzyme structure and dynamics, and thus substrate preference, simultaneously and sequentially. Bifunctionality is associated with two distinct sets of loop conformations, each essential for one function. We observed two mechanisms for functional specialization: structural stabilization of each loop conformation and substrate-specific adaptation of the active site. Intracellular enzyme performance, calculated as the product of catalytic efficiency and relative expression level, was not linearly related to fitness. Instead, we observed thresholds for each activity above which further improvements in catalytic efficiency had little if any effect on growth rate. Overall, we have shown how beneficial substitutions selected during real-time evolution can lead to manifold changes in enzyme function and bacterial fitness. This work emphasizes the speed at which adaptive evolution can yield enzymes with sufficiently high activities such that they no longer limit the growth of their host organism, and confirms the (βα) 8 barrel as an inherently evolvable protein scaffold.HisA | TrpF | adaptive evolution | enzyme performance threshold

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Evolution of New Functions De Novo and from Preexisting Genes

Andersson

Jerlström-Hultqvist

Näsvall

2015

Cold Spring Harb Perspect Biol

140

107

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The wobble hypothesis revisited: Uridine-5-oxyacetic acid is critical for reading of G-ending codons

Näsvall¹,

Chen²,

Björk³

2007

RNA

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According to Crick's wobble hypothesis, tRNAs with uridine at the wobble position (position 34) recognize A-and G-, but not U-or C-ending codons. However, U in the wobble position is almost always modified, and Salmonella enterica tRNAs containing the modified nucleoside uridine-5-oxyacetic acid (cmo 5 U34) at this position are predicted to recognize U-(but not C-) ending codons, in addition to A-and G-ending codons. We have constructed a set of S. enterica mutants with only the cmo 5 U-containing tRNA left to read all four codons in the proline, alanine, valine, and threonine family codon boxes. From the phenotypes of these mutants, we deduce that the proline, alanine, and valine tRNAs containing cmo 5 U read all four codons including the C-ending codons, while the corresponding threonine tRNA does not. A cmoB mutation, leading to cmo 5 U deficiency in tRNA, was introduced. Monitoring A-site selection rates in vivo revealed that the presence of cmo 5 U34 stimulated the reading of CCU and CCC (Pro), GCU (Ala), and GUC (Val) codons. Unexpectedly, cmo 5 U is critical for efficient decoding of G-ending Pro, Ala, and Val codons. Apparently, whereas G34 pairs with U in mRNA, the reverse pairing (U34-G) requires a modification of U34.

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Joakim Näsvall

Real-Time Evolution of New Genes by Innovation, Amplification, and Divergence

The modified wobble nucleoside uridine-5-oxyacetic acid in tRNA^Pro_cmo⁵UGG promotes reading of all four proline codons in vivo

Structural and functional innovations in the real-time evolution of new (βα) ₈ barrel enzymes

Evolution of New Functions De Novo and from Preexisting Genes

The wobble hypothesis revisited: Uridine-5-oxyacetic acid is critical for reading of G-ending codons

Contact Info

Product

Resources

About

Joakim Näsvall

Real-Time Evolution of New Genes by Innovation, Amplification, and Divergence

The modified wobble nucleoside uridine-5-oxyacetic acid in tRNAProcmo5UGG promotes reading of all four proline codons in vivo

Structural and functional innovations in the real-time evolution of new (βα) 8 barrel enzymes

Evolution of New Functions De Novo and from Preexisting Genes

The wobble hypothesis revisited: Uridine-5-oxyacetic acid is critical for reading of G-ending codons

Contact Info

Product

Resources

About

The modified wobble nucleoside uridine-5-oxyacetic acid in tRNA^Pro_cmo⁵UGG promotes reading of all four proline codons in vivo

Structural and functional innovations in the real-time evolution of new (βα) ₈ barrel enzymes