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256 results on '"Swint‐Kruse, Liskin"'

9. Rheostatic contributions to protein stability can obscure a position's functional role.

Author

O'Neil, Pierce T., Swint‐Kruse, Liskin, and Fenton, Aron W.

Abstract

Rheostat positions, which can be substituted with various amino acids to tune protein function across a range of outcomes, are a developing area for advancing personalized medicine and bioengineering. Current methods cannot accurately predict which proteins contain rheostat positions or their substitution outcomes. To compare the prevalence of rheostat positions in homologs, we previously investigated their occurrence in two pyruvate kinase (PYK) isozymes. Human liver PYK contained numerous rheostat positions that tuned the apparent affinity for the substrate phosphoenolpyruvate (Kapp‐PEP) across a wide range. In contrast, no functional rheostat positions were identified in Zymomonas mobilis PYK (ZmPYK). Further, the set of ZmPYK substitutions included an unusually large number that lacked measurable activity. We hypothesized that the inactive substitution variants had reduced protein stability, precluding detection of Kapp‐PEP tuning. Using modified buffers, robust enzymatic activity was obtained for 19 previously‐inactive ZmPYK substitution variants at three positions. Surprisingly, both previously‐inactive and previously‐active substitution variants all had Kapp‐PEP values close to wild‐type. Thus, none of the three positions were functional rheostat positions, and, unlike human liver PYK, ZmPYK's Kapp‐PEP remained poorly tunable by single substitutions. To directly assess effects on stability, we performed thermal denaturation experiments for all ZmPYK substitution variants. Many diminished stability, two enhanced stability, and the three positions showed different thermal sensitivity to substitution, with one position acting as a "stability rheostat." The differences between the two PYK homologs raises interesting questions about the underlying mechanism(s) that permit functional tuning by single substitutions in some proteins but not in others. [ABSTRACT FROM AUTHOR]

Published
2024
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11. The intrinsically disordered transcriptional activation domain of CIITA is functionally tuneable by single substitutions: An exception or a new paradigm?

Author

Sreenivasan, Shwetha, primary, Heffren, Paul, additional, Suh, Kyung‐Shin, additional, Rodnin, Mykola V., additional, Kosa, Edina, additional, Fenton, Aron W., additional, Ladokhin, Alexey S., additional, Smith, Paul E., additional, Fontes, Joseph D., additional, and Swint‐Kruse, Liskin, additional

Published
2023
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13. The intrinsically disordered transcriptional activation domain of CIITA is functionally tuneable by single substitutions: An exception or a new paradigm?

Author

Sreenivasan, Shwetha, Heffren, Paul, Suh, Kyung‐Shin, Rodnin, Mykola V., Kosa, Edina, Fenton, Aron W., Ladokhin, Alexey S., Smith, Paul E., Fontes, Joseph D., and Swint‐Kruse, Liskin

Abstract

During protein evolution, some amino acid substitutions modulate protein function ("tuneability"). In most proteins, the tuneable range is wide and can be sampled by a set of protein variants that each contains multiple amino acid substitutions. In other proteins, the full tuneable range can be accessed by a set of variants that each contains a single substitution. Indeed, in some globular proteins, the full tuneable range can be accessed by the set of site‐saturating substitutions at an individual "rheostat" position. However, in proteins with intrinsically disordered regions (IDRs), most functional studies—which would also detect tuneability—used multiple substitutions or small deletions. In disordered transcriptional activation domains (ADs), studies with multiple substitutions led to the "acidic exposure" model, which does not anticipate the existence of rheostat positions. In the few studies that did assess effects of single substitutions on AD function, results were mixed: the ADs of two full‐length transcription factors did not show tuneability, whereas a fragment of a third AD was tuneable by single substitutions. In this study, we tested tuneability in the AD of full‐length human class II transactivator (CIITA). Sequence analyses and experiments showed that CIITA's AD is an IDR. Functional assays of singly‐substituted AD variants showed that CIITA's function was highly tuneable, with outcomes not predicted by the acidic exposure model. Four tested positions showed rheostat behavior for transcriptional activation. Thus, tuneability of different IDRs can vary widely. Future studies are needed to illuminate the biophysical features that govern whether an IDR is tuneable by single substitutions. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Zymomonas mobilis pyruvate kinase: Rise of the unstable zombies

Author

ONeil, Pierce T., primary, Vela, Katheryn, additional, Page, Braelyn M., additional, McFarlane, Jeffrey S., additional, Wright, Collette L., additional, Meneely, Kathleen M., additional, Fenton, Aron W., additional, Lamb, Audrey L., additional, and Swint-Kruse, Liskin, additional

Published
2023
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18. PYK-SubstitutionOME: an integrated database containing allosteric coupling, ligand affinity and mutational, structural, pathological, bioinformatic and computational information about pyruvate kinase isozymes

Author

Swint-Kruse, Liskin, primary, Dougherty, Larissa L, additional, Page, Braelyn, additional, Wu, Tiffany, additional, O’Neil, Pierce T, additional, Prasannan, Charulata B, additional, Timmons, Cody, additional, Tang, Qingling, additional, Parente, Daniel J, additional, Sreenivasan, Shwetha, additional, Holyoak, Todd, additional, and Fenton, Aron W, additional

Published
2023
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20. Identification of a covert evolutionary pathway between two protein folds.

Author

Chakravarty, Devlina, Sreenivasan, Shwetha, Swint-Kruse, Liskin, and Porter, Lauren L.

Subjects
PROTEIN folding, DNA-binding proteins, PROTEIN structure, AMINO acid sequence, AMINO acids
Abstract

Although homologous protein sequences are expected to adopt similar structures, some amino acid substitutions can interconvert α-helices and β-sheets. Such fold switching may have occurred over evolutionary history, but supporting evidence has been limited by the: (1) abundance and diversity of sequenced genes, (2) quantity of experimentally determined protein structures, and (3) assumptions underlying the statistical methods used to infer homology. Here, we overcome these barriers by applying multiple statistical methods to a family of ~600,000 bacterial response regulator proteins. We find that their homologous DNA-binding subunits assume divergent structures: helix-turn-helix versus α-helix + β-sheet (winged helix). Phylogenetic analyses, ancestral sequence reconstruction, and AlphaFold2 models indicate that amino acid substitutions facilitated a switch from helix-turn-helix into winged helix. This structural transformation likely expanded DNA-binding specificity. Our approach uncovers an evolutionary pathway between two protein folds and provides a methodology to identify secondary structure switching in other protein families. Protein secondary structures–α-helices and β-sheets–are generally assumed to be fixed over evolutionary history. By leveraging sequence information and sensitive statistical techniques, this work proposes that secondary structures in naturally occurring DNA-binding proteins switched in response to stepwise mutation. [ABSTRACT FROM AUTHOR]

Published
2023
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32. Rheostat functional outcomes occur when substitutions are introduced at nonconserved positions that diverge with speciation

Author

Swint‐Kruse, Liskin, primary, Martin, Tyler A., additional, Page, Braelyn M., additional, Wu, Tiffany, additional, Gerhart, Paige M., additional, Dougherty, Larissa L., additional, Tang, Qingling, additional, Parente, Daniel J., additional, Mosier, Brian R., additional, Bantis, Leonidas E., additional, and Fenton, Aron W., additional

Published
2021
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34. Extrinsic interactions dominate helical propensity in coupled binding and folding of the lactose repressor protein hinge helix

Author

Zhan, Hongli, Swint-Kruse, Liskin, and Matthews, Kathleen Shive

Subjects
Protein folding -- Research, Lactose -- Chemical properties, Protein binding -- Research, Biological sciences, Chemistry
Abstract

A series of substitutions are made in the LacI hinge helix at position 52, the only site in the helix that does not interact with DNA and/or the inducer-binding domain, in order to examine the hierarchy of these extrinsic interactions. The results have shown that variation in operator sequence can overcome side chain effects on hinge-helix folding and/or hinge-hinge interactions and hence this system provides an example whereby an extrinsic interaction guides internal events that influence folding and functionality.

Published
2006

35. Emerging Features of Rheostat Positions

Author

Swint-Kruse, Liskin, primary, Fenton, Aron W., additional, Ozkan, S. Banu, additional, Hagenbuch, Bruno, additional, Campitelli, Paul, additional, Ruggiero, Melissa, additional, Karanicolas, John, additional, Malhotra, Shipra, additional, Fontes, Joseph, additional, Lamb, Audrey, additional, Ladokhin, Alexey, additional, and Smith, Paul E., additional

Published
2021
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36. Odd one out? Functional tuning of Zymomonas mobilis pyruvate kinase is narrower than its allosteric, human counterpart.

Author

Page, Braelyn M., Martin, Tyler A., Wright, Collette L., Fenton, Lauren A., Villar, Maite T., Tang, Qingling, Artigues, Antonio, Lamb, Audrey, Fenton, Aron W., and Swint‐Kruse, Liskin

Abstract

Various protein properties are often illuminated using sequence comparisons of protein homologs. For example, in analyses of the pyruvate kinase multiple sequence alignment, the set of positions that changed during speciation ("phylogenetic" positions) were enriched for "rheostat" positions in human liver pyruvate kinase (hLPYK). (Rheostat positions are those which, when substituted with various amino acids, yield a range of functional outcomes). However, the correlation was moderate, which could result from multiple biophysical constraints acting on the same position during evolution and/or various sources of noise. To further examine this correlation, we here tested Zymomonas mobilis PYK (ZmPYK), which has <65% sequence identity to any other PYK sequence. Twenty‐six ZmPYK positions were selected based on their phylogenetic scores, substituted with multiple amino acids, and assessed for changes in Kapp‐PEP. Although we expected to identify multiple, strong rheostat positions, only one moderate rheostat position was detected. Instead, nearly half of the 271 ZmPYK variants were inactive and most others showed near wild‐type function. Indeed, for the active ZmPYK variants, the total range of Kapp,PEP values ("tunability") was 40‐fold less than that observed for hLPYK variants. The combined functional studies and sequence comparisons suggest that ZmPYK has evolved functional and/or structural attributes that differ from the rest of the family. We hypothesize that including such "orphan" sequences in MSA analyses obscures the correlations used to predict rheostat positions. Finally, results raise the intriguing biophysical question as to how the same protein fold can support rheostat positions in one homolog but not another. [ABSTRACT FROM AUTHOR]

Published
2022
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47. Structural Plasticity Is a Feature of Rheostat Positions in the Human Na + /Taurocholate Cotransporting Polypeptide (NTCP).

Author

Ruggiero, Melissa J., Malhotra, Shipra, Fenton, Aron W., Swint-Kruse, Liskin, Karanicolas, John, and Hagenbuch, Bruno

Subjects
MEMBRANE transport proteins, MISSENSE mutation, PROTEIN structure, STRUCTURAL stability, MOLECULAR models
Abstract

In the Na+/taurocholate cotransporting polypeptide (NTCP), the clinically relevant S267F polymorphism occurs at a "rheostat position". That is, amino acid substitutions at this position ("S267X") lead to a wide range of functional outcomes. This result was particularly striking because molecular models predicted the S267X side chains are buried, and thus, usually expected to be less tolerant of substitutions. To assess whether structural tolerance to buried substitutions is widespread in NTCP, here we used Rosetta to model all 19 potential substitutions at another 13 buried positions. Again, only subtle changes in the calculated stabilities and structures were predicted. Calculations were experimentally validated for 19 variants at codon 271 ("N271X"). Results showed near wildtype expression and rheostatic modulation of substrate transport, implicating N271 as a rheostat position. Notably, each N271X substitution showed a similar effect on the transport of three different substrates and thus did not alter substrate specificity. This differs from S267X, which altered both transport kinetics and specificity. As both transport and specificity may change during protein evolution, the recognition of such rheostat positions may be important for evolutionary studies. We further propose that the presence of rheostat positions is facilitated by local plasticity within the protein structure. Finally, we note that identifying rheostat positions may advance efforts to predict new biomedically relevant missense variants in NTCP and other membrane transport proteins. [ABSTRACT FROM AUTHOR]

Published
2022
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48. Substitutions at a rheostat position in human aldolase A cause a shift in the conformational population.

Author

Fenton, Kathryn D., Meneely, Kathleen M., Wu, Tiffany, Martin, Tyler A., Swint‐Kruse, Liskin, Fenton, Aron W., and Lamb, Audrey L.

Abstract

Some protein positions play special roles in determining the magnitude of protein function: at such "rheostat" positions, varied amino acid substitutions give rise to a continuum of functional outcomes, from wild type (or enhanced), to intermediate, to loss of function. This observed range raises interesting questions about the biophysical bases by which changes at single positions have such varied outcomes. Here, we assessed variants at position 98 in human aldolase A ("I98X"). Despite being ~17 Å from the active site and far from subunit interfaces, substitutions at position 98 have rheostatic contributions to the apparent cooperativity (nH) associated with fructose‐1,6‐bisphosphate substrate binding and moderately affected binding affinity. Next, we crystallized representative I98X variants to assess structural consequences. Residues smaller than the native isoleucine (cysteine and serine) were readily accommodated, and the larger phenylalanine caused only a slight separation of the two parallel helixes. However, the diffraction quality was reduced for I98F, and further reduced for I98Y. Intriguingly, the resolutions of the I98X structures correlated with their nH values. We propose that substitution effects on both nH and crystal lattice disruption arise from changes in the population of aldolase A conformations in solution. In combination with results computed for rheostat positions in other proteins, the results from this study suggest that rheostat positions accommodate a wide range of side chains and that structural consequences manifest as shifted ensemble populations and/or dynamics changes. PDB Code(s): 6XMH, 6XML, 6XMM and 6XMO; [ABSTRACT FROM AUTHOR]

Published
2022
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