Evolution of protein specificity: insights from ancestral protein reconstruction

AbstractGlycosidases are phylogenetically widely distributed enzymes that are crucial for the cleavage of glycosidic bonds. Here, we present the exceptional properties of a putative ancestor of bacterial and eukaryotic family-1 glycosidases. The ancestral protein shares the TIM-barrel fold with its modern descendants but displays large regions with greatly enhanced conformational flexibility. Yet, the barrel core remains comparatively rigid and the ancestral glycosidase activity is stable, with an optimum temperature within the experimental range for thermophilic family-1 glycosidases. None of the ∼5500 reported crystallographic structures of ∼1400 modern glycosidases show a bound porphyrin. Remarkably, the ancestral glycosidase binds heme tightly and stoichiometrically at a well-defined buried site. Heme binding rigidifies this TIM-barrel and allosterically enhances catalysis. Our work demonstrates the capability of ancestral protein reconstructions to reveal valuable but unexpected biomolecular features when sampling distant sequence space. The potential of the ancestral glycosidase as a scaffold for custom catalysis and biosensor engineering is discussed.

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SPEER-SERVER: a web server for prediction of protein specificity determining sites

Nucleic Acids Research ◽

10.1093/nar/gks559 ◽

2012 ◽

Vol 40 (W1) ◽

pp. W242-W248 ◽

Cited By ~ 18

Author(s):

Abhijit Chakraborty ◽

Sapan Mandloi ◽

Christopher J. Lanczycki ◽

Anna R. Panchenko ◽

Saikat Chakrabarti

Keyword(s):

Web Server ◽

Protein Specificity

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G-protein Specificity in Signaling Pathways That Mobilize Calcium in Insulin-Secreting -TC3 Cells

Diabetes ◽

10.2337/diab.42.12.1878 ◽

1993 ◽

Vol 42 (12) ◽

pp. 1878-1882 ◽

Cited By ~ 13

Author(s):

G. Baffy ◽

L. Yang ◽

B. A. Wolf ◽

J. R. Williamson

Keyword(s):

Signaling Pathways ◽

G Protein ◽

Protein Specificity

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Protein Specificity in Plant Disease Development: Protein Sharing Between Host and Parasite

Specificity in Plant Diseases ◽

10.1007/978-1-4684-2769-1_13 ◽

1976 ◽

pp. 199-215 ◽

Cited By ~ 7

Author(s):

James E. Devay

Keyword(s):

Plant Disease ◽

Disease Development ◽

Protein Specificity

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An atomic-resolution view of neofunctionalization in the evolution of apicomplexan lactate dehydrogenases

eLife ◽

10.7554/elife.02304 ◽

2014 ◽

Vol 3 ◽

Cited By ~ 45

Author(s):

Jeffrey I Boucher ◽

Joseph R Jacobowitz ◽

Brian C Beckett ◽

Scott Classen ◽

Douglas L Theobald

Keyword(s):

Active Site ◽

Catalytic Mechanism ◽

Duplication Event ◽

Atomic Resolution ◽

Enzymatic Function ◽

Evolutionary Trajectories ◽

Strict Specificity ◽

Functional Shift ◽

Lactate Dehydrogenases ◽

Ancestral Protein

Malate and lactate dehydrogenases (MDH and LDH) are homologous, core metabolic enzymes that share a fold and catalytic mechanism yet possess strict specificity for their substrates. In the Apicomplexa, convergent evolution of an unusual LDH from MDH produced a difference in specificity exceeding 12 orders of magnitude. The mechanisms responsible for this extraordinary functional shift are currently unknown. Using ancestral protein resurrection, we find that specificity evolved in apicomplexan LDHs by classic neofunctionalization characterized by long-range epistasis, a promiscuous intermediate, and few gain-of-function mutations of large effect. In canonical MDHs and LDHs, a single residue in the active-site loop governs substrate specificity: Arg102 in MDHs and Gln102 in LDHs. During the evolution of the apicomplexan LDH, however, specificity switched via an insertion that shifted the position and identity of this ‘specificity residue’ to Trp107f. Residues far from the active site also determine specificity, as shown by the crystal structures of three ancestral proteins bracketing the key duplication event. This work provides an unprecedented atomic-resolution view of evolutionary trajectories creating a nascent enzymatic function.

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Chance, contingency, and necessity in the experimental evolution of ancestral proteins

10.1101/2020.08.29.273581 ◽

2020 ◽

Author(s):

Victoria Cochran Xie ◽

Jinyue Pu ◽

Brian P.H. Metzger ◽

Joseph W. Thornton ◽

Bryan C. Dickinson

Keyword(s):

Protein Evolution ◽

Experimental Evolution ◽

Cell Lymphoma ◽

B Cell Lymphoma ◽

Sequence Evolution ◽

Protein Protein Interaction ◽

Evolutionary Trajectories ◽

Historical Moment ◽

Related Proteins ◽

Ancestral Protein

SUMMARYThe extent to which chance and contingency shaped the sequence outcomes of protein evolution is largely unknown. To directly characterize the causes and consequences of chance and contingency, we combined directed evolution with ancestral protein reconstruction. By repeatedly selecting a phylogenetic series of ancestral proteins in the B-cell lymphoma-2 family to evolve the same protein-protein interaction specificities that existed during history, we show that contingency and chance interact to make sequence evolution almost entirely unpredictable over the timescale of metazoan evolution. At any historical moment, multiple sets of mutations can alter or maintain specificity, and chance decides which ones occur. Contingency arises because historical sequence substitutions epistatically altered which mutations are compatible with new or ancestral functions. Evolutionary trajectories launched from different ancestors therefore lead to dramatically different outcomes over phylogenetic time, with virtually no mutations occurring repeatedly in distantly related proteins, even under identical selection conditions.

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