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7. Lactose repressor hinge domain independently binds DNA

Author

Xu, Joseph S., Hewitt, Madeleine N., Gulati, Jaskeerat S., Cruz, Matthew A., Zhan, Hongli, Liu, Shirley, and Matthews, Kathleen S.

Subjects
structure–function, Collodion, Electrophoretic Mobility Shift Assay, Articles, DNA, Article, allosteric regulation, DNA binding protein, Peptide Fragments, Protein Domains, Lac Repressors, DNA operator, hinge helix, Protein Multimerization, DNA–protein interaction, lactose repressor protein, Sequence Deletion
Abstract

The short 8–10 amino acid “hinge” sequence in lactose repressor (LacI), present in other LacI/GalR family members, links DNA and inducer‐binding domains. Structural studies of full‐length or truncated LacI‐operator DNA complexes demonstrate insertion of the dimeric helical “hinge” structure at the center of the operator sequence. This association bends the DNA ∼40° and aligns flanking semi‐symmetric DNA sites for optimal contact by the N‐terminal helix‐turn‐helix (HtH) sequences within each dimer. In contrast, the hinge region remains unfolded when bound to nonspecific DNA sequences. To determine ability of the hinge helix alone to mediate DNA binding, we examined (i) binding of LacI variants with deletion of residues 1–50 to remove the HtH DNA binding domain or residues 1–58 to remove both HtH and hinge domains and (ii) binding of a synthetic peptide corresponding to the hinge sequence with a Val52Cys substitution that allows reversible dimer formation via a disulfide linkage. Binding affinity for DNA is orders of magnitude lower in the absence of the helix‐turn‐helix domain with its highly positive charge. LacI missing residues 1–50 binds to DNA with ∼4‐fold greater affinity for operator than for nonspecific sequences with minimal impact of inducer presence; in contrast, LacI missing residues 1–58 exhibits no detectable affinity for DNA. In oxidized form, the dimeric hinge peptide alone binds to O1 and nonspecific DNA with similarly small difference in affinity; reduction to monomer diminished binding to both O1 and nonspecific targets. These results comport with recent reports regarding LacI hinge interaction with DNA sequences.

Published
2018

9. Media composition influences yeast one- and two-hybrid results

Author

Gonzalez Kim L, Hsiao Hao-Ching, Merchant Zabeena, Liu Ying, Matthews Kathleen S, and Bondos Sarah E

Subjects
Yeast one-hybrid, yeast two-hybrid, protein-protein interaction, accuracy, false positive, false negative, Medicine (General), R5-920, Biology (General), QH301-705.5
Abstract

Abstract Although yeast two-hybrid experiments are commonly used to identify protein interactions, the frequent occurrence of false negatives and false positives hampers data interpretation. Using both yeast one-hybrid and two-hybrid experiments, we have identified potential sources of these problems: the media preparation protocol and the source of the yeast nitrogen base may not only impact signal range but also effect whether a result appears positive or negative. While altering media preparation may optimize signal differences for individual experiments, media preparation must be reported in detail to replicate studies and accurately compare results from different experiments.

Published
2011
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11. Positions 94-98 of the lactose repressor N-subdomain monomer-monomer interface are critical for allosteric communication

Author

Hongli Zhan, Camargo, Maricela, and Matthews, Kathleen S.

Subjects
Allosteric enzymes -- Structure, Allosteric enzymes -- Chemical properties, Gene mutations -- Analysis, Lactose -- Chemical properties, Substitution reactions -- Analysis, Biological sciences, Chemistry
Abstract

Acidic, basic, polar and apolar mutations are introduced at positions 94-98 in order to explore that a disproportionate number of substitutions in the regions of the monomer-monomer interface has altered the complex features of the Lacl allosteric response. The results have confirmed the critical role of amino acids 94-98 and have shown that the N-subdomain interface has formed a primary pathway in Lacl allosteric response.

Published
2010

12. Exploring the frontiers of the future: 'One of the central challenges for the future is that we don't know what we don't know.' (Science & Technology)

Author

Matthews, Kathleen S.

Subjects
Rice University -- Management, Information technology -- Research -- Forecasts and trends, Biotechnology -- Research -- Forecasts and trends, Environmental sciences -- Research -- Forecasts and trends, Nanotechnology -- Research -- Forecasts and trends, Research -- Forecasts and trends -- Research, General interest, News, opinion and commentary, Company business management, Information technology, Market trend/market analysis, Management, Research, Forecasts and trends
Abstract

AS AN AMERICAN on a long trek overseas in 1996, I was surprised at each stop--Italy, Germany, Egypt, Great Britain--to discover that much of the fare on television consists of [...]

Published
2002

13. Flexibility in the inducer binding region is crucial for allostery in the Escherichia coli lactose repressor

Author

Jia Xu and Matthews, Kathleen S.

Subjects
Allosteric enzymes -- Chemical properties, Allosteric enzymes -- Structure, Escherichia coli -- Physiological aspects, Escherichia coli -- Genetic aspects, Lactose -- Chemical properties, Molecular dynamics -- Usage, Genetic transcription -- Analysis, Biological sciences, Chemistry
Abstract

Targeted molecular dynamics (TMD) techniques were employed to simulate the transition between inducer- and operator-bound states and understand allosteric mechanism related to lactose repressor protein (Lacl)-mediated transcription in Escherichia coli. The double mutant D149C/S193C purified from cell extracts showed decreased sensitivity to inducer binding while retaining wild-type binding affinities and kinetic constants for both operator and inducer.

Published
2009

14. Perturbation from a distance: mutations that alter LacI function through long-range effects

Author

Swint-Kruse, Liskin, Zhan, Hongli, Fairbanks, Bonnie M., Maheshwari, Atul, and Matthews, Kathleen S.

Subjects
Ligand binding (Biochemistry) -- Analysis, Molecular dynamics -- Analysis, Mutation (Biology) -- Influence, Structure-activity relationships (Biochemistry) -- Analysis, Proteins -- Analysis, Proteins -- Structure, Biological sciences, Chemistry
Abstract

Research describes biochemical characterization of three of the LacI mutationsin the core pivot. Simulated targeted molecular dynamics analysis indicate that he mutations alter the behavior of LacI protein in tems of repressor function.

Published
2003

15. Evolution of the activation domain in a Hox transcription factor.

Author

YING LIU, HUANG, ANNIE, BOOTH, REBECCA M., MENDES, GABRIELA GERALDO, MERCHANT, ZABEENA, MATTHEWS, KATHLEEN S., and BONDOS, SARAH E.

Subjects
HOMEOBOX genes, PROTEIN domains, DROSOPHILA evolution, TRANSCRIPTION factors, DROSOPHILA development, PHENOTYPES
Abstract

Linking changes in amino acid sequences to the evolution of transcription regulatory domains is often complicated by the low sequence complexity and high mutation rates of intrinsically disordered protein regions. For the Hox transcription factor Ultrabithorax (Ubx), conserved motifs distributed throughout the protein sequence enable direct comparison of specific protein regions, despite variations in the length and composition of the intervening sequences. In cell culture, the strength of transcription activation by Drosophila melanogaster Ubx correlates with the presence of a predicted helix within its activation domain. Curiously, this helix is not preserved in species more divergent than flies, suggesting the nature of transcription activation may have evolved. To determine whether this helix contributes to Drosophila Ubx function in vivo, wild-type and mutant proteins were ectopically expressed in the developing wing and the phenotypes evaluated. Helix mutations alter Drosophila Ubx activity in the developing wing, demonstrating its functional importance in vivo. The locations of activation domains in Ubx orthologues were identified by testing the ability of truncation mutants to activate transcription in yeast one-hybrid assays. In Ubx orthologues representing 540 million years of evolution, the ability to activate transcription varies substantially. The sequence and the location of the activation domains also differ. Consequently, analogous regions of Ubx orthologues change function over time, and may activate transcription in one species, but have no activity, or even inhibit transcription activation in another species. Unlike homeodomain-DNA binding, the nature of transcription activation by Ubx has substantially evolved. [ABSTRACT FROM AUTHOR]

Published
2018
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17. The Effect of Protein Fusions on the Production and Mechanical Properties of Protein-Based Materials.

Author

Tsai, Shang‐Pu, Howell, David W., Huang, Zhao, Hsiao, Hao‐Ching, Lu, Yang, Matthews, Kathleen S., Lou, Jun, and Bondos, Sarah E.

Subjects
PROTEINS, MATERIALS, SOLUBILITY, CHEMICAL properties, MONOMERS, DIAMETER
Abstract

Proteins implement most of the vital molecular functions of living organisms, including structural support, energy generation, biomolecule sensing, and chemical catalysis, storage, and degradation. While capturing proteins in materials could create devices that mimic these functions, this process is challenging due to the sensitivity of protein structure to the chemical environment. Using recombinant DNA methods, specific functions can be incorporated by fusing the gene encoding a self-assembling protein and the desired functional protein, to produce a single polypeptide that self-assembles into functionalized materials. However, the functional protein has the potential to disrupt protein production, protein assembly, and/or the structure and mechanical properties of the resulting materials. 24 fusion proteins are created based on Ultrabithorax, a Drosophila transcription factor that self-assembles into materials in vitro. The appended proteins dictate the solubility and purification yield of the corresponding protein fusions. Any loss of solubility and yield can be mitigated by fusing a third protein that is highly soluble. All protein fusions self-assemble equally well to produce materials with similar morphologies. Fusing enhanced green fluorescent protein to Ultrabithorax influences mechanical properties of the resulting fibers. It is concluded that a far wider range of proteins can be successfully incorporated into elastomeric protein-based materials than originally anticipated. [ABSTRACT FROM AUTHOR]

Published
2015
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18. The Intrinsically Disordered Regions of the Drosophila melanogaster Hox Protein Ultrabithorax Select Interacting Proteins Based on Partner Topology.

Author

Hsiao, Hao-Ching, Gonzalez, Kim L., Catanese Jr., Daniel J., Jordy, Kristopher E., Matthews, Kathleen S., and Bondos, Sarah E.

Subjects
DROSOPHILA melanogaster, PROTEIN-protein interactions, TRANSCRIPTION factors, SURFACE chemistry, ORGANIC compounds
Abstract

Interactions between structured proteins require a complementary topology and surface chemistry to form sufficient contacts for stable binding. However, approximately one third of protein interactions are estimated to involve intrinsically disordered regions of proteins. The dynamic nature of disordered regions before and, in some cases, after binding calls into question the role of partner topology in forming protein interactions. To understand how intrinsically disordered proteins identify the correct interacting partner proteins, we evaluated interactions formed by the Drosophila melanogaster Hox transcription factor Ultrabithorax (Ubx), which contains both structured and disordered regions. Ubx binding proteins are enriched in specific folds: 23 of its 39 partners include one of 7 folds, out of the 1195 folds recognized by SCOP. For the proteins harboring the two most populated folds, DNA-RNA binding 3-helical bundles and α-α superhelices, the regions of the partner proteins that exhibit these preferred folds are sufficient for Ubx binding. Three disorder-containing regions in Ubx are required to bind these partners. These regions are either alternatively spliced or multiply phosphorylated, providing a mechanism for cellular processes to regulate Ubx-partner interactions. Indeed, partner topology correlates with the ability of individual partner proteins to bind Ubx spliceoforms. Partners bind different disordered regions within Ubx to varying extents, creating the potential for competition between partners and cooperative binding by partners. The ability of partners to bind regions of Ubx that activate transcription and regulate DNA binding provides a mechanism for partners to modulate transcription regulation by Ubx, and suggests that one role of disorder in Ubx is to coordinate multiple molecular functions in response to tissue-specific cues. [ABSTRACT FROM AUTHOR]

Published
2014
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20. Disconnected Interacting Protein 1 binds with high affinity to pre-tRNA and ADAT

Author

Catanese, Daniel J. and Matthews, Kathleen S.

Subjects
*ADENOSINE deaminase, *ULTRACENTRIFUGATION, *DOUBLE-stranded RNA, *GLUTATHIONE transferase, *RNA polymerases, *GENETIC transcription, *GENETIC translation, *NON-coding RNA
Abstract

Abstract: Disconnected Interacting Protein 1 (DIP1), a member of the double-stranded RNA-binding protein family based on amino acid sequence, was shown previously to form complexes with multiple transcription factors in Drosophila melanogaster. To explore this protein further, we have undertaken sedimentation equilibrium experiments that demonstrate that DIP1-c (longest isoform of DIP1) is a dimer in solution, a characteristic common to other members of the dsRNA-binding protein family. The closest sequence identity for DIP1 is found within the dsRBD sequences of RNA editase enzymes. Consistent with this role, we demonstrate binding of DIP1-c to a potential physiological RNA target: pre-tRNA. In addition, DIP1-c was shown to interact with ADAT, a tRNA deaminase that presumably modifies pre-tRNAs. From these data, we hypothesize that DIP1 may serve an integrator role by binding its dsRNA ligand and recruiting protein partners for the appropriate metabolism of the bound RNA. [Copyright &y& Elsevier]

Published
2011
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23. High affinity, dsRNA binding by disconnected interacting protein 1

Author

Catanese, Daniel J. and Matthews, Kathleen S.

Subjects
*PROTEIN binding, *NUCLEOTIDE sequence, *DROSOPHILA melanogaster, *RNA polymerases, *HIV, *GENE expression, *GENETIC transcription regulation
Abstract

Abstract: Disconnected interacting protein 1 (DIP1) appears from sequence analysis and preliminary binding studies to be a member of the dsRNA-binding protein family. Of interest, DIP1 was shown previously to interact with and influence multiple proteins involved in transcription regulation in Drosophila melanogaster. We show here that the longest isoform of this protein, DIP1-c, exhibits a 500-fold preference for dsRNA over dsDNA of similar nucleotide sequence. Further, DIP1-c demonstrated very high affinity for a subset of dsRNA ligands, with binding in the picomolar range for VA1 RNA and miR-iab-4 precursor stem-loop, a potential physiological RNA target involved in regulating expression of its protein partner, Ultrabithorax. [ABSTRACT FROM AUTHOR]

Published
2010
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24. Internal Regulatory Interactions Determine DNA Binding Specificity by a Hox Transcription Factor

Author

Liu, Ying, Matthews, Kathleen S., and Bondos, Sarah E.

Subjects
*MOLECULAR evolution, *TRANSCRIPTION factors, *GENETIC regulation, *NUCLEOTIDE sequence, *DNA, *BINDING sites, *PROTEIN structure
Abstract

Abstract: In developing bilaterans, the Hox transcription factor family regulates batteries of downstream genes to diversify serially repeated units. Given Hox homeodomains bind a wider array of DNA binding sites in vitro than are regulated by the full-length protein in vivo, regions outside the homeodomain must aid DNA site selection. Indeed, we find affinity for disparate DNA sequences varies less than 3-fold for the homeodomain isolated from the Drosophila Hox protein Ultrabithorax Ia (UbxHD), whereas for the full-length protein (UbxIa) affinity differs by more than 10-fold. The rank order of preferred DNA sequences also differs, further demonstrating distinct DNA binding preferences. The increased specificity of UbxIa can be partially attributed to the I1 region, which lies adjacent to the homeodomain and directly impacts binding energetics. Each of three segments within I1—the Extradenticle-binding YPWM motif, the six amino acids immediately N-terminal to this motif, and the eight amino acids abutting the YPWM C-terminus—uniquely contribute to DNA specificity. Combination of these regions synergistically modifies DNA binding to further enhance specificity. Intriguingly, the presence of the YPWM motif in UbxIa inhibits DNA binding only to Ubx–Extradenticle heterodimer binding sites, potentially functioning in vivo to prevent Ubx monomers from binding and misregulating heterodimer target genes. However, removal of the surrounding region allows the YPWM motif to also inhibit binding to Hox-only recognition sequences. Despite a modular domain design for Hox proteins, these results suggest that multiple Hox protein regions form a network of regulatory interactions that coordinate context- and gene-specific responses. Since most nonhomeodomain regions are not conserved between Hox family members, these regulatory interactions have the potential to diversify binding by the highly homologous Hox homeodomains. [Copyright &y& Elsevier]

Published
2009
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25. Allostery in the LacI/GalR family: variations on a theme

Author

Swint-Kruse, Liskin and Matthews, Kathleen S

Subjects
*DNA-binding proteins, *GENETIC regulation, *METABOLITES, *GENETIC transcription, *HOMOLOGY (Biology), *MESSENGER RNA, *OLIGOMERS, *ALLOSTERIC regulation, *BIOLOGICAL variation
Abstract

The lactose repressor protein (LacI) was among the very first genetic regulatory proteins discovered, and more than 1000 members of the bacterial LacI/GalR family are now identified. LacI has been the prototype for understanding how transcription is controlled using small metabolites to modulate protein association with specific DNA sites. This understanding has been greatly expanded by the study of other LacI/GalR homologues. A general picture emerges in which the conserved fold provides a scaffold for multiple types of interactions – including oligomerization, small molecule binding, and protein–protein binding – that in turn influence target DNA binding and thereby regulate mRNA production. Although many different functions have evolved from this basic scaffold, each homologue retains functional flexibility: For the same protein, different small molecules can have disparate impact on DNA binding and hence transcriptional outcome. In turn, binding to alternative DNA sequences may impact the degree of allosteric response. Thus, this family exhibits a symphony of variations by which transcriptional control is achieved. [Copyright &y& Elsevier]

Published
2009
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26. Multiple Intrinsically Disordered Sequences Alter DNA Binding by the Homeodomain of the Drosophila Hox Protein UItrabithorax.

Author

Ying Liu, Matthews, Kathleen S., and Bondos, Sarah E.

Subjects
*ORGANS (Anatomy), *TRANSCRIPTION factors, *DROSOPHILA, *ORGANIC acids, *PRESERVATION of organs, tissues, etc., *PROTEIN analysis
Abstract

During animal development, distinct tissues, organs, and appendages are specified through differential gene transcription by Hox transcription factors. However, the conserved Hox homeodomains bind DNA with high affinity yet low specificity. We have therefore explored the structure of the Drosophila melanogaster Hox protein Ultrabithorax and the impact of its nonhomeodomain regions on DNA binding properties. Computational and experimental approaches identified several conserved, intrinsically disordered regions outside the homeodomain of Ultrabithorax that impact DNA binding by the homeodomain, Full-length Ultrabithorax bound to target DNA 2.5-fold weaker than its isolated homeodomain. Using N-terminal and C-terminal deletion mutants, we demonstrate that the YPWM region and the disordered microexons (termed the 11 region) inhibit DNA binding ~2-fold, whereas the disordered 12 region inhibits homeodomain-DNA interaction a further ~40-fold. Binding is restored almost to homeodomain affinity by the mostly disordered N-terminal 174 amino acids (R region) in a length-dependent manner. Both the 12 and R regions contain portions of the activation domain, functionally linking DNA binding and transcription regulation. Given that (i) the Ii region and a portion of the R region alter homeodomain-DNA binding as a function of pH and (ii) an internal deletion within Ii increases Ultrabithorax-DNA affinity, Ii must directly impact homeodomain-DNA interaction energetics. However, 12 appears to indirectly affect DNA binding in a manner countered by the N terminus. The amino acid sequences of 12 and much of the Ii and R regions vary significantly among Ultrabithorax orthologues, potentially diversifying Hox-DNA interactions. [ABSTRACT FROM AUTHOR]

Published
2008
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27. Allosteric transition pathways in the lactose repressor protein core domains: Asymmetric motions in a homodimer.

Author

Flynn, Terence C., Swint-Kruse, Liskin, Kong, Yifei, Booth, Christopher, Matthews, Kathleen S., and Ma, Jianpeng

Abstract

The crystal structures of lactose repressor protein (LacI) provide static endpoint views of the allosteric transition between DNA- and IPTG-bound states. To obtain an atom-by-atom description of the pathway between these two conformations, motions were simulated with targeted molecular dynamics (TMD). Strikingly, this homodimer exhibited asymmetric dynamics. All asymmetries observed in this simulation are reproducible and can begin on either of the two monomers. Asymmetry in the simulation originates around D149 and was traced back to the pre-TMD equilibrations of both conformations. In particular, hydrogen bonds between D149 and S193 adopt a variety of configurations during repetitions of this process. Changes in this region propagate through the structure via noncovalent interactions of three interconnected pathways. The changes of pathway 1 occur first on one monomer. Alterations move from the inducer-binding pocket, through the N-subdomain β-sheet, to a hydrophobic cluster at the top of this region and then to the same cluster on the second monomer. These motions result in changes at (1) side chains that form an interface with the DNA-binding domains and (2) K84 and K84', which participate in the monomer-monomer interface. Pathway 2 reflects consequent reorganization across this subunit interface, most notably formation of a H74-H74rsquo; π-stacking intermediate. Pathway 3 extends from the rear of the inducer-binding pocket, across a hydrogen-bond network at the bottom of the pocket, and transverses the monomer-monomer interface via changes in H74 and H74rsquo;. In general, intermediates detected in this study are not apparent in the crystal structures. Observations from the simulations are in good agreement with biochemical data and provide a spatial and sequential framework for interpreting existing genetic data. [ABSTRACT FROM AUTHOR]

Published
2003
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31. Operator DNA Sequence Variation Enhances High Affinity Binding by Hinge Helix Mutants of Lactose....

Author

Falcon, Catherine M. and Matthews, Kathleen S.

Subjects
*AMINO acid sequence, *GENETIC repressors, *CHEMICAL affinity
Abstract

Examines the role of operator DNA sequence variation in enhancing affinity binding by hinge helix mutants of lactose repressor protein (Lac1). Interplay between DNA and protein sequence; Details on the binding affinity between mutant series and Lac1 protein; Importance of bases, spacing and base pair sequence in high affinity complex formation.

Published
2000
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32. Relieving repression.

Author

Matthews, Kathleen S., Falcon, Catherine M., and Swint-Kruse, Liskin

Subjects
*GENETIC repressors, *MICROSTRUCTURE, *BINDING sites
Abstract

Offers observation on the high resolution structures for the operator DNA complexes of the tetracycline repressor (TetR) and a dimeric derivative of the lactose repressor (LacI). Overview on LacI and TetR function; Key features of TetR and LacI; Differences on the features of the inducer binding sites of TetT and LacI.

Published
2000
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33. Thermodynamic analysis of unfolding and dissociation in lactose repressor protein.

Author

Barry, Jennifer K. and Matthews, Kathleen S.

Subjects
*DENATURATION of proteins, *UREA, *ULTRACENTRIFUGATION
Abstract

Examines the unfolding and dissociation in lactose repressor protein. Mechanism of action; Utilization of varying concentrations of urea in monitoring structural transitions; Monitor of fluorescence and circular dichroism spectroscopy, analytical ultracentrifugation and functional activities; Stability of lactose repressor protein.

Published
1999
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34. Substitutions at histidine 74 and aspartate 278 alter ligand binding and allostery in lactose...

Author

Barry, Jennifer K. and Matthews, Kathleen S.

Subjects
*LIGAND binding (Biochemistry), *ALLOSTERIC regulation, *LACTOSE
Abstract

Reveals that substitutions at histidine 74 (H74) and aspartate 278 (D278) alter ligand binding and allostery in the lactose repressor protein. Effect of introduction of apolar amino acids; Decrease of operator binding through alanine and leucine substitutions; Individual roles of H74 and D278 on the repressor allostery.

Published
1999
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35. Ligand-induced conformational changes in lactose repressor: A fluorescence study of single...

Author

Barry, Jennifer K. and Matthews, Kathleen S.

Subjects
*LIGANDS (Biochemistry), *SCIENTIFIC experimentation
Abstract

Presents a study conducted to determine ligand-induced conformation changes in lactose repressor using single tryptophan mutants. Materials and methods used; Effects of inducer on reactivity spectroscopic properties of side chains dispersed throughout physical properties of the protein; Generation of mutants and protein purification; Discussion on the study.

Published
1997
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36. Differences in water release with DNA binding by Ultrabithorax and deformed homeodomains.

Author

Li, Likun and Matthews, Kathleen S.

Subjects
*DNA-protein interactions, *DROSOPHILA melanogaster
Abstract

Explains the differences in water release with DNA binding by homeodomain proteins from Drosophila melanogaster. Role of water activity in protein binding; Determinants for the differential water release; Responses to the physical environment in marginal binding; Mechanisms for the occurrence of target site recognition.

Published
1997
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38. Subunit dissociation affects DNA binding in a dimeric lac repressor produced by C-terminal deletion.

Author

Chen, Jie and Matthews, Kathleen S.

Subjects
*DNA-protein interactions, *MONOMERS
Abstract

Studies the thermodynamic linkage between dimer-monomer and protein-DNA equilibria. Reduction in apparent operator binding affinity found for dimeric lac repressor proteins produced by disruption of C-terminal coiled-coil interaction; Denaturation of -11 aa and R3 dimers; Association between R3 and -11 aa.

Published
1994
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39. Effect of lac repressor oligomerization on regulatory outcome.

Author

Chakerian, Artemis E. and Matthews, Kathleen S.

Subjects
OPERONS, MESSENGER RNA, DNA, GENETIC repressors, ESCHERICHIA coli, DIMERS, LEUCINE zippers, MONOMERS, PROTEIN-protein interactions, DNA-binding proteins
Abstract

Regulatory outcome in a bacterial operon depends on the interactions of all the components which influence mRNA production. Levels of mRNA can be altered profoundly by both negative and positive regulatory elements which modulate initiation of transcription. The occupancy of regulatory sites on the DNA by repressors and activators is determined not only by the affinity of these proteins for their cognate site(s) but also by the oligomeric state of the regulatory protein, The lac operon in Escherichia coli provides an excellent prototypic example of the influence of protein assembly on the transcriptional status of the associated structural genes. DNA loop formation is essential for maximal repression of the lac operon and is contingent upon the presence of multiple operator sites in the DNA and the ability of the repressor to self-associate to form a bidentate tetramer, The stability of this looped complex is enhanced significantly by DNA supercolling. Tetramer assembly from dimers apparently occurs via interactions of a 'leucine zipper' motif in the C-terminal domain of the protein, and the tetramer is essential to formation of looped complexes. Furthermore, analysis of the DNA-binding characteristics of dimeric mutants has established that the monomer--dimer association and dimer-DNA binding (monomer does not bind to DNA) are coupled equilibria, Thus, dimer assembly is essential for generating a DNA-binding unit, and tetramer assembly is required for formation of the stable looped DNA structure that maximally represses mRNA synthesis. Protein-protein interactions therefore play a pivotal role in the regulatory activities of the lac repressor and must be considered when analysing the activities of any oligomeric DNA-binding protein. [ABSTRACT FROM AUTHOR]

Published
1992
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40. Flexibility and Disorder in Gene Regulation: LacI/GalR and Hox Proteins.

Author

Bondos, Sarah E., Swint-Kruse, Liskin, and Matthews, Kathleen S.

Subjects
*GENETIC regulation, *GENETIC transcription, *PROTEINS, *PROKARYOTIC genomes, *EUKARYOTIC cells
Abstract

To modulate transcription, a variety of input signals must be sensed by genetic regulatory proteins. In these proteins, flexibility and disorder are emerging as common themes. Prokaryotic regulators generally have short, flexible segments, whereas eukaryotic regulators have extended regions that lack predicted secondary structure (intrinsic disorder). Two examples illustrate the impact of flexibility and disorder on gene regulation: the prokaryotic LacI/GalR family, with detailed information from studies on LacI, and the eukaryotic family of Hox proteins, with specific insights from investigations of Ultrabithorax (Ubx). The widespread importance of structural disorder in gene regulatory proteins may derive from the need for flexibility in signal response and, particularly in eukaryotes, in protein partner selection. [ABSTRACT FROM AUTHOR]

Published
2015
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41. Ligand-induced Conformational Changes and Conformational Dynamics in the Solution Structure of the Lactose Repressor Protein

Author

Taraban, Marc, Zhan, Hongli, Whitten, Andrew E., Langley, David B., Matthews, Kathleen S., Swint-Kruse, Liskin, and Trewhella, Jill

Subjects
*NUCLEIC acids, *GENES, *X-ray scattering, *GENETIC regulation
Abstract

Abstract: We present here the results of a series of small-angle X-ray scattering studies aimed at understanding the role of conformational changes and structural flexibility in DNA binding and allosteric signaling in a bacterial transcription regulator, lactose repressor protein (LacI). Experiments were designed to detect possible conformational changes that occur when LacI binds either DNA or the inducer IPTG, or both. Our studies included the native LacI dimer of homodimers and a dimeric variant (R3), enabling us to probe conformational changes within the homodimers and distinguish them from those involving changes in the homodimer–homodimer relationships. The scattering data indicate that removal of operator DNA (oDNA) from R3 results in an unfolding and extension of the hinge helix that connects the LacI regulatory and DNA-binding domains. In contrast, only very subtle conformational changes occur in the R3 dimer–oDNA complex upon IPTG binding, indicative of small adjustments in the orientations of domains and/or subdomains within the structure. The binding of IPTG to native (tetrameric) LacI–oDNA complexes also appears to facilitate a modest change in the average homodimer–homodimer disposition. Notably, the crystal structure of the native LacI–oDNA complex differs significantly from the average solution conformation. The solution scattering data are best fit by an ensemble of structures that includes (1) ∼60% of the V-shaped dimer of homodimers observed in the crystal structure and (2) ∼40% of molecules with more “open” forms, such as those generated when the homodimers move with respect to each other about the tetramerization domain. In gene regulation, such a flexible LacI would be beneficial for the interaction of its two DNA-binding domains, positioned at the tips of the V, with the required two of three LacI operators needed for full repression. [Copyright &y& Elsevier]

Published
2008
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42. Hox Transcription Factor Ultrabithorax Ib Physically and Genetically Interacts with Disconnected Interacting Protein 1, a Double-stranded RNA-binding Protein.

Author

Bondo, Sarah E., Catanese Jr., Daniel J., Xin-Xing Tan, Bicknell, Alicia, Likun Li, and Matthews, Kathleen S.

Subjects
*TRANSCRIPTION factors, *DOUBLE-stranded RNA, *CARRIER proteins, *DROSOPHILA, *PROTEIN-protein interactions, *MOLECULAR association, *PROTEINS, *BIOCHEMISTRY
Abstract

The Hox protein family consists of homeodomain-containing transcription factors that are primary determinants of cell fate during animal development. Specific Hox function appears to rely on protein-protein interactions; however, the partners involved in these interactions and their function are largely unknown. Disconnected Interacting Protein 1 (DIP1) was isolated in a yeast two-hybrid screen of a 0-12-h Drosophila embryo library designed to identify proteins that interact with Ultrabithorax (Ubx), a Drosophila Hox protein. The Ubx·DIP1 physical interaction was confirmed using phage display, immunoprecipitation, pull-down assays, and gel retardation analysis. Ectopic expression of DIP1 in wing and haltere imaginal discs malforms the adult structures and enhances a decreased Ubx expression phenotype, establishing a genetic interaction. Ubx can generate a ternary complex by simultaneously binding its target DNA and DIP1. A large region of Ubx, including the repression domain, is required for interaction with DIP1. These more variable sequences may be key to the differential Hox function observed in vivo. The Ubx.DIP1 interaction prevents transcriptional activation by Ubx in a modified yeast one-hybrid assay, suggesting that DIP1 may modulate transcriptional regulation by Ubx. The DIP1 sequence contains two dsRNA-binding domains, and DIP1 binds double-stranded RNA with a 1000-fold higher affinity than either single-stranded RNA or double-stranded DNA. The strong interaction of Ubx with an RNA-binding protein suggests a wider range of proteins may influence Ubx function than previously appreciated. [ABSTRACT FROM AUTHOR]

Published
2004
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43. Evolution of the activation domain in a Hox transcription factor.

Author

Liu Y, Huang A, Booth RM, Mendes GG, Merchant Z, Matthews KS, and Bondos SE

Subjects
Animals, Animals, Genetically Modified, Drosophila Proteins genetics, Drosophila melanogaster, Homeodomain Proteins genetics, Phenotype, Transcription Factors genetics, Drosophila Proteins metabolism, Gene Expression Regulation, Homeodomain Proteins metabolism, Mutation, Transcription Factors metabolism, Transcriptional Activation
Abstract

Linking changes in amino acid sequences to the evolution of transcription regulatory domains is often complicated by the low sequence complexity and high mutation rates of intrinsically disordered protein regions. For the Hox transcription factor Ultrabithorax (Ubx), conserved motifs distributed throughout the protein sequence enable direct comparison of specific protein regions, despite variations in the length and composition of the intervening sequences. In cell culture, the strength of transcription activation by Drosophila melanogaster Ubx correlates with the presence of a predicted helix within its activation domain. Curiously, this helix is not preserved in species more divergent than flies, suggesting the nature of transcription activation may have evolved. To determine whether this helix contributes to Drosophila Ubx function in vivo, wild-type and mutant proteins were ectopically expressed in the developing wing and the phenotypes evaluated. Helix mutations alter Drosophila Ubx activity in the developing wing, demonstrating its functional importance in vivo. The locations of activation domains in Ubx orthologues were identified by testing the ability of truncation mutants to activate transcription in yeast one-hybrid assays. In Ubx orthologues representing 540 million years of evolution, the ability to activate transcription varies substantially. The sequence and the location of the activation domains also differ. Consequently, analogous regions of Ubx orthologues change function over time, and may activate transcription in one species, but have no activity, or even inhibit transcription activation in another species. Unlike homeodomain-DNA binding, the nature of transcription activation by Ubx has substantially evolved.

Published
2018
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44. Measuring Hox-DNA binding by electrophoretic mobility shift analysis.

Author

Churion K, Liu Y, Hsiao HC, Matthews KS, and Bondos SE

Subjects
Animals, Drosophila melanogaster, Oligonucleotides metabolism, Protein Binding, DNA metabolism, Electrophoretic Mobility Shift Assay, Homeodomain Proteins metabolism
Abstract

Understanding gene regulation by Hox transcription factors requires understanding the forces that underlie DNA binding by these proteins. Electrophoretic mobility shift analysis (EMSA) not only allows measurement of protein affinity and cooperativity but also permits visualization of differently migrating protein-DNA complexes, including complexes with different compositions or complexes with identical compositions yet assembled in different geometries. Furthermore, protein activity can be measured, allowing correction of binding constants for the percentage of protein that is properly folded and capable of binding DNA. Protocols for measuring protein activity and the equilibrium DNA-binding dissociation constant (K d) are provided. This versatile assay system can be adjusted based on specific needs to measure other parameters, including the kinetic association and dissociation constants (k a and k d) and the formation of heterologous protein-protein interactions.

Published
2014
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45. Media composition influences yeast one- and two-hybrid results.

Author

Liu Y, Merchant Z, Hsiao HC, Gonzalez KL, Matthews KS, and Bondos SE

Abstract

Although yeast two-hybrid experiments are commonly used to identify protein interactions, the frequent occurrence of false negatives and false positives hampers data interpretation. Using both yeast one-hybrid and two-hybrid experiments, we have identified potential sources of these problems: the media preparation protocol and the source of the yeast nitrogen base may not only impact signal range but also effect whether a result appears positive or negative. While altering media preparation may optimize signal differences for individual experiments, media preparation must be reported in detail to replicate studies and accurately compare results from different experiments.

Published
2011
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46. Monitoring DNA binding to Escherichia coli lactose repressor using quartz crystal microbalance with dissipation.

Author

Xu J, Liu KW, Matthews KS, and Biswal SL

Subjects
DNA-Binding Proteins metabolism, Immobilized Proteins metabolism, Protein Binding, Quartz Crystal Microbalance Techniques, DNA, Bacterial metabolism, Escherichia coli Proteins metabolism, Lac Repressors metabolism
Abstract

Lactose repressor protein (LacI) functions as a negative transcription regulator in Escherichia coli by binding to the operator DNA sequence. Our understanding of the immobilized LacI function and the effect of ligand binding on the conformation of LacI-DNA complexes remains poorly understood. Here, we have examined the difference in functionality of wild-type and mutant LacI binding to the target DNA using quartz crystal microbalance with dissipation (QCM-D). To direct the orientation of LacI binding to the gold surface, residue 334 was substituted with cysteine (T334C) to generate a sulfur-gold linkage. Position 334 is located on the surface opposite the DNA-binding domain and remote from the site for inducer binding. With T334C immobilized on the gold surface, our sensors successfully detect operator binding as well as the release of the operator DNA from the repressor in the presence of inducer isopropyl-β-D-thiogalactoside (IPTG). Besides the natural operator DNA sequence (O(1)), a symmetric high-affinity DNA sequence (O(sym)), and a non-specific DNA (O(ns)) sequence with low affinity were also used. In addition, the impact of anti-inducer o-nitrophenyl-beta-d-fucoside (ONPF), which stabilizes LacI operator binding, was examined. The results from immobilized mutant LacI are in good agreement with known solution parameters for LacI-ligand interactions, demonstrating that QCM-D provides a rapid and efficient measurement of DNA binding and impact of ligands upon binding for this complex oligomeric protein., (© 2011 American Chemical Society)

Published
2011
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47. Size dictates mechanical properties for protein fibers self-assembled by the Drosophila hox transcription factor ultrabithorax.

Author

Huang Z, Lu Y, Majithia R, Shah J, Meissner K, Matthews KS, Bondos SE, and Lou J

Subjects
Animals, Biocompatible Materials, Drosophila melanogaster, Materials Testing, Drosophila Proteins physiology, Homeodomain Proteins physiology, Mechanical Phenomena, Proteins ultrastructure, Transcription Factors physiology
Abstract

The development of protein-based materials with diverse mechanical properties will facilitate the realization of a broad range of potential applications. The recombinant Drosophila melanogaster transcription factor Ultrabithorax self-assembles under mild conditions in aqueous buffers into extremely extensible materials. By controlling fiber diameter, both the mechanism of extension and the magnitude of the mechanical properties can be varied. Narrow Ultrabithorax fibers (diameter <10 μm) extend elastically, whereas the predominantly plastic deformation of wide fibers (diameter >15 μm) reflects the increase in breaking strain with increasing diameter, apparently due to a change in structure. The breaking stress/strain of the widest fibers resembles that of natural elastin. Intermediate fibers display mixed properties. Fiber bundles retain the mechanical properties of individual fibers but can withstand much larger forces. Controlling fiber size and generating fiber superstructures is a facile way to manipulate the mechanical characteristics of protein fibers and rationally engineer macroscale protein-based materials with desirable properties.

Published
2010
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48. Positions 94-98 of the lactose repressor N-subdomain monomer-monomer interface are critical for allosteric communication.

Author

Zhan H, Camargo M, and Matthews KS

Subjects
DNA metabolism, Escherichia coli chemistry, Escherichia coli genetics, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Lac Repressors genetics, Models, Molecular, Mutation, Protein Binding, Protein Stability, Protein Structure, Tertiary, Protein Unfolding, Allosteric Regulation, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Lac Repressors chemistry, Lac Repressors metabolism
Abstract

The central region of the LacI N-subdomain monomer-monomer interface includes residues K84, V94, V95, V96, S97, and M98. The side chains of these residues line the β-strands at this interface and interact to create a network of hydrophobic, charged, and polar interactions that significantly rearranges in different functional states of LacI. Prior work showed that converting K84 to an apolar residue or converting V96 to an acidic residue impedes the allosteric response to inducer. Thus, we postulated that a disproportionate number of substitutions in this region of the monomer-monomer interface would alter the complex features of the LacI allosteric response. To explore this hypothesis, acidic, basic, polar, and apolar mutations were introduced at positions 94-98. Despite their varied locations along the β-strands that flank the interface, ∼70% of the mutations impact allosteric behavior, with the most significant effects found for charged substitutions. Of note, many of the LacI variants with minor functional impact exhibited altered stability to urea denaturation. The results confirm the critical role of amino acids 94-98 and indicate that this N-subdomain interface forms a primary pathway in LacI allosteric response.

Published
2010
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49. Flexibility in the inducer binding region is crucial for allostery in the Escherichia coli lactose repressor.

Author

Xu J and Matthews KS

Subjects
Allosteric Regulation genetics, Amino Acid Substitution genetics, Aspartic Acid chemistry, Aspartic Acid genetics, Bacterial Proteins genetics, Binding Sites genetics, Escherichia coli chemistry, Escherichia coli metabolism, Escherichia coli Proteins genetics, Isopropyl Thiogalactoside metabolism, Lac Repressors, Mutagenesis, Site-Directed, Operator Regions, Genetic, Oxidation-Reduction, Protein Binding genetics, Repressor Proteins genetics, Serine chemistry, Serine genetics, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Isopropyl Thiogalactoside chemistry, Repressor Proteins chemistry, Repressor Proteins metabolism
Abstract

Lactose repressor protein (LacI) utilizes an allosteric mechanism to regulate transcription in Escherichia coli, and the transition between inducer- and operator-bound states has been simulated by targeted molecular dynamics (TMD). The side chains of amino acids 149 and 193 interact and were predicted by TMD simulation to play a critical role in the early stages of the LacI conformational change. D149 contacts IPTG directly, and variations at this site provide the opportunity to dissect its role in inducer binding and signal transduction. Single mutants at D149 or S193 exhibit a minimal change in operator binding, and alterations in inducer binding parallel changes in operator release, indicating normal allosteric response. The observation that the double mutant D149A/S193A exhibits wild-type properties excludes the requirement for inter-residue hydrogen bond formation in the allosteric response. The double mutant D149C/S193C purified from cell extracts shows decreased sensitivity to inducer binding while retaining wild-type binding affinities and kinetic constants for both operator and inducer. By manipulating cysteine oxidation, we show that the more reduced state of D149C/S193C responds to inducer more like the wild-type protein, whereas the more oxidized state displays diminished inducer sensitivity. These features of D149C/S193C indicate that the novel disulfide bond formed in this mutant impedes the allosteric transition, consistent with the role of this region predicted by TMD simulation. Together, these results establish the requirement for flexibility in the spatial relationship between D149 and S193 rather than a specific D149-S193 interaction in the LacI allosteric response to inducer.

Published
2009
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50. The Drosophila transcription factor ultrabithorax self-assembles into protein-based biomaterials with multiple morphologies.

Author

Greer AM, Huang Z, Oriakhi A, Lu Y, Lou J, Matthews KS, and Bondos SE

Subjects
Animals, Blotting, Western, DNA genetics, DNA metabolism, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Elastic Tissue chemistry, Macromolecular Substances chemistry, Materials Testing, Protein Interaction Domains and Motifs, Stress, Mechanical, Biocompatible Materials chemistry, Biocompatible Materials metabolism, Drosophila Proteins chemistry, Drosophila Proteins metabolism, Homeodomain Proteins chemistry, Homeodomain Proteins metabolism, Transcription Factors chemistry, Transcription Factors metabolism
Abstract

The use of proteins as monomers for materials assembly enables customization of chemical, physical, and functional properties. However, natural materials-forming proteins are difficult to produce as recombinant protein monomers and require harsh conditions to initiate assembly. We have generated materials using the recombinant transcription factor Ultrabithorax, a Drosophila melanogaster protein not known or anticipated to form extended oligomers in vivo. Ultrabithorax self-assembles at the air-water interface into nanoscale fibers, which further associate to form macroscale films, sheets, ropes, and tethered encapsulates. These materials self-adhere, allowing construction of more complex architectures. The Ultrabithorax sequence contains two regions capable of generating materials, only one of which contains motifs found in elastomeric proteins. However, both minimal regions must be included to produce robust materials. Relative to other protein-based materials, Ultrabithorax assembles at significantly reduced concentrations, on faster timescales, and under gentler conditions, properties that facilitate future materials engineering and functionalization.

Published
2009
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