Mutagenesis of amino acid residues required for binding of corepressors to the purine repressor

Engineering Alternate Ligand Recognition in the PurR Topology: A System of Novel Caffeine Biosensing Transcriptional Antirepressors

Recent advances in synthetic biology and protein engineering have increased the number of allosteric transcription factors used to regulate independent promoters. These developments represent an important increase in our biological computing capacity, which will enable us to construct more sophisticated genetic programs for a broad range of biological technologies. However, the majority of these transcription factors are represented by the repressor phenotype (BUFFER), and require layered inversion to confer the antithetical logical function (NOT), requiring additional biological resources. Moreover, these engineered transcription factors typically utilize native ligand binding functions paired with alternate DNA binding functions. In this study, we have advanced the state-of-the-art by engineering and redesigning the PurR topology (a native antirepressor) to be responsive to caffeine, while mitigating responsiveness to the native ligand hypoxanthine-i.e., a deamination product of the input molecule adenine. Importantly, the resulting caffeine responsive transcription factors are not antagonized by the native ligand hypoxanthine. In addition, we conferred alternate DNA binding to the caffeine antirepressors, and to the PurR scaffold, creating 38 new transcription factors that are congruent with our current transcriptional programming structure. Finally, we leveraged this system of transcription factors to create integrated NOR logic and related feedback operations. This study represents the first example of a system of transcription factors (antirepressors) in which both the ligand binding site and the DNA binding functions were successfully engineered in tandem.

Data on publications, structural analyses, and queries used to build and utilize the AlloRep database

The AlloRep database (www.AlloRep.org) (Sousa et al., 2016) [1] compiles extensive sequence, mutagenesis, and structural information for the LacI/GalR family of transcription regulators. Sequence alignments are presented for >3000 proteins in 45 paralog subfamilies and as a subsampled alignment of the whole family. Phenotypic and biochemical data on almost 6000 mutants have been compiled from an exhaustive search of the literature; citations for these data are included herein. These data include information about oligomerization state, stability, DNA binding and allosteric regulation. Protein structural data for 65 proteins are presented as easily-accessible, residue-contact networks. Finally, this article includes example queries to enable the use of the AlloRep database. See the related article, “AlloRep: a repository of sequence, structural and mutagenesis data for the LacI/GalR transcription regulators” (Sousa et al., 2016) [1].

Multiple co-evolutionary networks are supported by the common tertiary scaffold of the LacI/GalR proteins

Protein families might evolve paralogous functions on their common tertiary scaffold in two ways. First, the locations of functionally-important sites might be "hard-wired" into the structure, with novel functions evolved by altering the amino acid (e.g. Ala vs Ser) at these positions. Alternatively, the tertiary scaffold might be adaptable, accommodating a unique set of functionally important sites for each paralogous function. To discriminate between these possibilities, we compared the set of functionally important sites in the six largest paralogous subfamilies of the LacI/GalR transcription repressor family. LacI/GalR paralogs share a common tertiary structure, but have low sequence identity (≤ 30%), and regulate a variety of metabolic processes. Functionally important positions were identified by conservation and co-evolutionary sequence analyses. Results showed that conserved positions use a mixture of the "hard-wired" and "accommodating" scaffold frameworks, but that the co-evolution networks were highly dissimilar between any pair of subfamilies. Therefore, the tertiary structure can accommodate multiple networks of functionally important positions. This possibility should be included when designing and interpreting sequence analyses of other protein families. Software implementing conservation and co-evolution analyses is available at https://sourceforge.net/projects/coevolutils/.

Allostery in the LacI/GalR family: variations on a theme

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.

Controlled transcriptional regulation in eukaryotes by a novel transcription factor derived from Escherichia coli purine repressor

Unlike the DNA-binding domains (DBD) of most eukaryotic transcription factors, Escherichia coli LacI family transcription factors are unable to bind to specific target DNA sequences without a cofactor-binding domain. In the present study, we reconstructed a novel DBD designated as PurHG, which binds constitutively to a 16bp purine repressor operator, by fusion of the purine repressor (PurR) DBD (residues 1-57) and the GAL4 dimerization domain (DD, residues 42-148). Binding of PurHG to DNA requires the dimerization and a hinge helix of PurR DBD. When the PurHG was expressed as a fusion protein in a form of a transcription activator (PurAD) or an artificial nuclear receptor (PurAPR or PurAER) responding to ligand, such as RU486 or beta-estradiol, it could regulate the expression of the reporter genes in NIH3T3 cells. The prerequisite region of the GAL4 DD for DNA-binding was amino acid residues from 42 to 98 in the form of PurAD, while the amino acid residues from 42 to 75 were sufficient for ligand-dependent regulation in the form of PurAPR. These results suggest that the dimerization function of the progesterone ligand-binding domain could be substituted for region 76-98 of the GAL4 DD. In summary, the fusion of the PurR DBD and the GAL4 DD generates fully active DNA-binding protein, PurHG, in vitro and in vivo, and these results provide the direct evidence of structural predictions that the proximate positioning of PurR hinge helical regions is critical for DNA-binding.

Functional analysis of three amino acid residues of purR repressor, Trpl47, Gln-218 and Gln-292 in Salmonella typhimurium

The amber mutation sites of 6 purR(am) mutants were determined by cloning and DNA sequencing. The results showed that the mutations were distributed at three different sites in PurR coding region, G(721)(-->A), C(933)(-->T) and C(1155)(-->T), which respectively turn Trp-147, Gln-218 and Gln-292 of PurR into TAG terminal codon. To determine the effect of the three amino acid residues on regulatory function of PurR protein 5 different kinds of tRNA suppressor genes, Su3, Su4, Su6, Su7 and Su9 were used for creating the PurR protein variants with single amino acid substitution. The results indicated that Cys, Glu, Gly, His and Arg which substituted Trp-147 respectively all could not recover the regulation function of PurR. It confirmed that Trp-147 is a critical amino acid for the PurR function. Gln-292 substituted respectively by the same amino acids also could not recover the PurR function, demonstrating that Gln-292 is also an important amino acid residue in PurR.

trans-sialidase of Trypanosoma cruzi: location of galactose-binding site(s)

Trypanosoma cruzi expresses a trans-sialidase on its surface, which catalyzes the transfer of sialic acid from mammalian host glycans to its own surface glycoproteins. It has been proposed that the enzyme consists of three domains prior to a long C-terminal repeating sequence that is not required for enzyme activity. The first of these domains shares significant sequence identity with bacterial sialidases which catalyse the hydrolysis of sialic acid. Here we report the sequence of the N-terminal domains of the TS19y trans-sialidase gene, which was expressed in bacteria with the same specific activity as natural enzyme of T. cruzi. Various deletion mutants of TS19y, without the C-terminal tandem repeat, have been cloned and expressed and their trans-sialidase and sialidase activities measured. These experiments show that all three N-terminal domains are required for full trans-sialidase activity, though only the first is necessary for sialidase activity. Some transferase activity is observed, however, even with the shortest construct comprising the first N-terminal domain. Deletion mutants to probe the role of the N-terminal residues of the first domain suggest that the first 33 residues are also required for trans-sialidase activity, but not for sialidase activity. Molecular modelling of the first N-terminal domain of TS19y based on our structures of bacterial sialidases and site-directed mutations suggests the location of a galactose-binding site within this domain.

Kinetic and thermodynamic studies of purine repressor binding to corepressor and operator DNA

The kinetic and thermodynamic parameters for purine repressor (PurR)-operator and PurR-guanine binding were determined using fluorescence spectroscopy and nitrocellulose filter binding. Operator binding affinity was increased by the presence of guanine as demonstrated previously (Choi, K. Y., Lu, F., and Zalkin, H. (1994) J. Biol. Chem. 269, 24066-24072; Rolfes, R. J., and Zalkin, H. (1990) J. Bacteriol. 172, 5637-5642), and conversely guanine binding affinity was increased by the presence of operator. Guanine enhanced operator affinity by increasing the association rate constant and decreasing the dissociation rate constant for binding. Operator had minimal effect on the association rate constant for guanine binding; however, this DNA decreased the dissociation rate constant for corepressor by approximately 10-fold. Despite significant sequence and structural similarity between PurR and LacI proteins, PurR binds to its corepressor ligand with a lower association rate constant than LacI binds to its inducer ligand. However, the rate constant for PurR-guanine binding to operator is approximately 3-fold higher than for LacI binding to its cognate operator under the same solution conditions. The distinct metabolic roles of the enzymes under regulation by these two repressor proteins provide a rationale for the observed functional differences.

Mechanism of corepressor-mediated specific DNA binding by the purine repressor

The modulation of the affinity of DNA-binding proteins by small molecule effectors for cognate DNA sites is common to both prokaryotes and eukaryotes. However, the mechanisms by which effector binding to one domain affects DNA binding by a distal domain are poorly understood structurally. In initial studies to provide insight into the mechanism of effector-modulated DNA binding of the lactose repressor family, we determined the crystal structure of the purine repressor bound to a corepressor and purF operator. To extend our understanding, we have determined the structure of the corepressor-free corepressor-binding domain of the purine repressor at 2.2 A resolution. In the unliganded state, structural changes in the corepressor-binding pocket cause each subunit to rotate open by as much as 23 degrees, the consequences of which are the disengagement of the minor groove-binding hinge helices and repressor-DNA dissociation.

Crystal structure of LacI member, PurR, bound to DNA: minor groove binding by alpha helices

The three-dimensional structure of a ternary complex of the purine repressor, PurR, bound to both its corepressor, hypoxanthine, and the 16-base pair purF operator site has been solved at 2.7 A resolution by x-ray crystallography. The bipartite structure of PurR consists of an amino-terminal DNA-binding domain and a larger carboxyl-terminal corepressor binding and dimerization domain that is similar to that of the bacterial periplasmic binding proteins. The DNA-binding domain contains a helix-turn-helix motif that makes base-specific contacts in the major groove of the DNA. Base contacts are also made by residues of symmetry-related alpha helices, the "hinge" helices, which bind deeply in the minor groove. Critical to hinge helix-minor groove binding is the intercalation of the side chains of Leu54 and its symmetry-related mate, Leu54', into the central CpG-base pair step. These residues thereby act as "leucine levers" to pry open the minor groove and kink the purF operator by 45 degrees.