Many gene-regulatory proteins appear to have a similar alpha-helical fold that binds DNA and evolved from a common precursor

Rice Big Grain1 enhances biomass and plant growth-promoting traits in rhizospheric yeast Candida tropicalis

The Big Grain1 (BG1) gene of rice (Oryza sativa L.) is reported to increase the yield of rice crops; however, its molecular mechanism is largely concealed. To explore its functional prospects, we have taken a structure-function-based approach. In silico analyses suggest OsBG1 is a DNA- and phytohormone-binding protein. Heterologous expression of OsBG1 with galactose-inducible promoter GAL1p in the rhizospheric yeast Candida tropicalis SY005 revealed 7.9- and 1.5-fold higher expression of the gene at 12 and 24 h, respectively, compared to the expression at 36 h post-galactose induction. Functional activity of the induced OsBG1 in engineered yeast increased cell density, specific growth rate, and biomass by 28.5%, 29.8%, and 14.1%, respectively, and decreased the generation time by 21.25%. Flow cytometry-based cell cycle analysis of OsBG1-expressing yeast cells exhibited an increase in the cells of the G2/M population by 15.8% after 12 h of post-galactose induction. The gene expression study of yeast transformants disclosed that OsBG1 regulates cell division by upregulating the expression of the endogenous gene cyclin B1 (CtCYB1) by 1.3- and 1.9-folds at 10 and 12 h, respectively, compared to the control, and is positively influenced by the phytohormone indole acetic acid (IAA). Further, the study revealed that OsBG1 significantly increases biofilm formation, stress tolerance, and IAA production in C. tropicalis SY005, implying its prospective role in enhancing plant growth-promoting traits in microbes. OsBG1-expressing rhizospheric yeast cells significantly improved the germination and growth parameters of the bio-inoculated rice seeds. Altogether, this study suggests OsBG1 can be employed to genetically improve suitable bio-inoculants for their plant growth-promoting traits to augment crop productivity. KEY POINTS: • In silico analyses suggested OsBG1 is a phytohormone-binding transcription factor. • OsBG1 enhanced growth in rhizospheric Candida tropicalis by upregulating CtCYB1. • OsBG1 improved plant growth-promoting traits of the rhizospheric yeast C. tropicalis.

A LysR-Type Transcriptional Regulator LcrX Is Involved in Virulence, Biofilm Formation, Swimming Motility, Siderophore Secretion, and Growth in Sugar Sources in Xanthomonas axonopodis Pv. glycines

Xanthomonas axonopodis pv. glycines (Xag) is a Gram-negative bacterium that causes bacterial pustule disease in soybean. To acclimate to new environments, the expression of genes in bacteria is controlled directly or indirectly by diverse transcriptional factors. Among them, LysR type transcriptional regulators are well-characterized and abundant in bacteria. In a previous study, comparative proteomic analysis revealed that LysR type carbohydrate-related transcriptional regulator in Xag (LcrX) was more abundant in XVM2, which is a minimal medium, compared with a rich medium. However, the functions of LcrX in Xag have not been characterized. In this study, we generated an LcrX-overexpressing strain, Xag(LcrX), and the knockout mutant strain, XagΔlcrX(EV), to elucidate the functions of LcrX. Bacterial multiplication of Xag(LcrX) in soybean was significantly impaired, indicating that LcrX is related to virulence. Comparative proteomic analysis revealed that LcrX is mainly involved in carbohydrate metabolism/transport and inorganic ion transport/metabolism. Based on the results of proteomics analysis, diverse phenotypic assays were carried out. A gel electrophoresis mobility shift assay demonstrated that LcrX specifically bound to the putative promoter regions of genes encoding putative fructose 1,6-bisphosphatase and protease. Through a 96-well plate assay under various conditions, we confirmed that the growth of Xag(LcrX) was dramatically affected in the presence of various carbon sources, while the growth of XagΔlcrX(EV) was only slightly changed. Biofilm formation activity was reduced in Xag(LcrX) but enhanced in XagΔlcrX(EV). The production of siderophores was also decreased in Xag(LcrX) but not altered in XagΔlcrX(EV). In contrast, LcrX was not associated with exopolysaccharide production, protease activity, or bacterial motility. These findings provide new insights into the functions of a carbohydrate-related transcriptional regulator in Xag.

In silico and experimental improvement of bacteriorhodopsin production in Halobacterium salinarum R1 by increasing DNA-binding affinity of Bat through Q661R/Q665R substitutions in HTH motif

DNA-binding motif of bacterioopsin activator (Bat) protein is a Helix-Turn-Helix motif, which binds to bop promoter and induces bacterioopsin (Bop) expression under light and low oxygen tension. Bacterioopsin is linked to retinal to produce bacteriorhodopsin (BR), which in turn supplies energy source in Halobacterium salinarum. In this study, effect of Bat HTH motif-promoter DNA interaction on bacterioopsin (Bop) expression was investigated using in silico and experimental approaches. Molecular docking showed that the most stable DNA-protein complex was generated by Q661R/Q665R mutant. Based on the in silico analysis, HTH motif was mutated using site-directed mutagenesis and Hbt. salinarum recombinant strains were developed by introduction of mutant bat genes. Double positively charged amino acid substitutions (Q661R/Q665R) in second helix of HTH motif increased whereas deletion of this region decreased BR production. However, other single substitutions (Q665R and Q661H) did not change BR production. These findings represent key role of HTH motif stability for DNA binding and regulation of bacterioopsin (Bop) expression and bacteriorhodopsin (BR) production independent of environmental condition.

Structure-based functional characterization of repressor of toxin (Rot), a central regulator of Staphylococcus aureus virulence

Staphylococcus aureus is responsible for a large number of diverse infections worldwide. In order to support its pathogenic lifestyle, S. aureus has to regulate the expression of virulence factors in a coordinated fashion. One of the central regulators of the S. aureus virulence regulatory networks is the transcription factor repressor of toxin (Rot). Rot plays a key role in regulating S. aureus virulence through activation or repression of promoters that control expression of a large number of critical virulence factors. However, the mechanism by which Rot mediates gene regulation has remained elusive. Here, we have determined the crystal structure of Rot and used this information to probe the contribution made by specific residues to Rot function. Rot was found to form a dimer, with each monomer harboring a winged helix-turn-helix (WHTH) DNA-binding motif. Despite an overall acidic pI, the asymmetric electrostatic charge profile suggests that Rot can orient the WHTH domain to bind DNA. Structure-based site-directed mutagenesis studies demonstrated that R(91), at the tip of the wing, plays an important role in DNA binding, likely through interaction with the minor groove. We also found that Y(66), predicted to bind within the major groove, contributes to Rot interaction with target promoters. Evaluation of Rot binding to different activated and repressed promoters revealed that certain mutations on Rot exhibit promoter-specific effects, suggesting for the first time that Rot differentially interacts with target promoters. This work provides insight into a precise mechanism by which Rot controls virulence factor regulation in S. aureus.

Structural and functional insights into the N-terminus of Schizosaccharomyces pombe Cdc5

The spliceosome is a dynamic macromolecular machine composed of five small nuclear ribonucleoparticles (snRNPs), the NineTeen Complex (NTC), and other proteins that catalyze the removal of introns mature to form the mature message. The NTC, named after its founding member Saccharomyces cerevisiae Prp19, is a conserved spliceosome subcomplex composed of at least nine proteins. During spliceosome assembly, the transition to an active spliceosome correlates with stable binding of the NTC, although the mechanism of NTC function is not understood. Schizosaccharomyces pombe Cdc5, a core subunit of the NTC, is an essential protein required for pre-mRNA splicing. The highly conserved Cdc5 N-terminus contains two canonical Myb (myeloblastosis) repeats (R1 and R2) and a third domain (D3) that was previously classified as a Myb-like repeat. Although the N-terminus of Cdc5 is required for its function, how R1, R2, and D3 each contribute to functionality is unclear. Using a combination of yeast genetics, structural approaches, and RNA binding assays, we show that R1, R2, and D3 are all required for the function of Cdc5 in cells. We also show that the N-terminus of Cdc5 binds RNA in vitro. Structural and functional analyses of Cdc5-D3 show that, while this domain does not adopt a Myb fold, Cdc5-D3 preferentially binds double-stranded RNA. Our data suggest that the Cdc5 N-terminus interacts with RNA structures proposed to be near the catalytic core of the spliceosome.

Characterization and comparative sequence analysis of the DNA mismatch repair MSH2 and MSH7 genes from tomato

DNA mismatch repair proteins play an essential role in maintaining genomic integrity during replication and genetic recombination. We successfully isolated a full length MSH2 and partial MSH7 cDNAs from tomato, based on sequence similarity between MutS and plant MSH homologues. Semi-quantitative RT-PCR reveals higher levels of mRNA expression of both genes in young leaves and floral buds. Genetic mapping placed MSH2 and MSH7 on chromosomes 6 and 7, respectively, and indicates that these genes exist as single copies in the tomato genome. Analysis of protein sequences and phylogeny of the plant MSH gene family show that these proteins are evolutionarily conserved, and follow the classical model of asymmetric protein evolution. Genetic manipulation of the expression of these MSH genes in tomato will provide a potentially useful tool for modifying genetic recombination and hybrid fertility between wide crosses.

The helix-turn-helix motif as an ultrafast independently folding domain: the pathway of folding of Engrailed homeodomain

Helices 2 and 3 of Engrailed homeodomain (EnHD) form a helix-turn-helix (HTH) motif. This common motif is believed not to fold independently, which is the characteristic feature of a motif rather than a domain. But we found that the EnHD HTH motif is monomeric and folded in solution, having essentially the same structure as in full-length protein. It had a sigmoidal thermal denaturation transition. Both native backbone and local tertiary interactions were formed concurrently at 4 x 10(5) s(-1) at 25 degrees C, monitored by IR and fluorescence T-jump kinetics, respectively, the same rate constant as for the fast phase in the folding of EnHD. The HTH motif, thus, is an ultrafast-folding, natural protein domain. Its independent stability and appropriate folding kinetics account for the stepwise folding of EnHD, satisfy fully the criteria for an on-pathway intermediate, and explain the changes in mechanism of folding across the homeodomain family. Experiments on mutated and engineered fragments of the parent protein with different probes allowed the assignment of the observed kinetic phases to specific events to show that EnHD is not an example of one-state downhill folding.

Understanding the Folding Mechanism of an α-Helical Hairpin†

The alpha-helical hairpin is the fundamental building block of the widespread helix-turn-helix DNA binding motif. With two antiparallel helices connected by a reverse turn, the alpha-helical hairpin structure may be regarded as a "supersecondary structural element" and, therefore, could exhibit rather unique folding properties. So far, the folding mechanism of alpha-helical hairpins has not been studied in detail and remains elusive. Herein, we examine the effects of the turn, the hydrophobic cluster, and a disulfide cross-linker on the folding kinetics of a designed alpha-helical hairpin, Z34C, using an infrared temperature-jump (T-jump) method in conjunction with site-specific mutagenesis. Our results show that Z34C folds with an ultrafast rate ( approximately 4.0 x 10(5) s(-1)) and support a folding mechanism in which the rate-limiting step corresponds to the formation of the reverse turn. On the other hand, the hydrophobic cluster and the disulfide cross-linker appear to largely stabilize the native state but not the folding transition state.

Structure of peptide sex pheromone receptor PrgX and PrgX/pheromone complexes and regulation of conjugation in Enterococcus faecalis

Many bacterial activities, including expression of virulence factors, horizontal genetic transfer, and production of antibiotics, are controlled by intercellular signaling using small molecules. To date, understanding of the molecular mechanisms of peptide-mediated cell-cell signaling has been limited by a dearth of published information about the molecular structures of the signaling components. Here, we present the molecular structure of PrgX, a DNA- and peptide-binding protein that regulates expression of the conjugative transfer genes of the Enterococcus faecalis plasmid pCF10 in response to an intercellular peptide pheromone signal. Comparison of the structures of PrgX and the PrgX/pheromone complex suggests that pheromone binding destabilizes PrgX tetramers, opening a 70-bp pCF10 DNA loop required for conjugation repression.

Sequence correlations between Cro recognition helices and cognate O(R) consensus half-sites suggest conserved rules of protein-DNA recognition

The O(R) regions from several lambdoid bacteriophages contain the three regulatory sites O(R)1, O(R)2 and O(R)3, to which the Cro and CI proteins can bind. These sites show imperfect dyad symmetry, have similar sequences, and generally lie on the same face of the DNA double helix. We have developed a computational method, which analyzes the O(R) regions of additional phages and predicts the location of these three sites. After tuning the method to predict known O(R) sites accurately, we used it to predict unknown sites, and ultimately compiled a database of 32 known and predicted O(R) binding site sets. We then identified sequences of the recognition helices (RH) for the cognate Cro proteins through manual inspection of multiple sequence alignments. Comparison of Cro RH and consensus O(R) half-site sequences revealed strong one-to-one correlations between two amino acids at each of three RH positions and two bases at each of three half-site positions (H1-->2, H3-->5 and H6-->6). In each of these three cases, one of the two amino acid/base-pairings corresponds to a contact observed in the crystal structure of a lambda Cro/consensus operator complex. The alternate amino acid/base combinations were rationalized using structural models. We suggest that the pairs of amino acid residues act as binary switches that efficiently modulate specificity for different consensus half-site variants during evolution. The observation of structurally reasonable amino acid-to-base correlations suggests that Cro proteins share some common rules of recognition despite their functional and structural diversity.

Cloning of the PpMSH-2 cDNA of Physcomitrella patens, a moss in which gene targeting by homologous recombination occurs at high frequency

In the moss Physcomitrella patens integrative transformants from homologous recombination are obtained at an efficiency comparable to that found for yeast. This property, unique in the plant kingdom, allows the knockout of specific genes. It also makes the moss a convenient model to study the regulation of homologous recombination in plants. We used degenerate oligonucleotides designed from AtMSH2 from Arabidopsis thaliana and other known MutS homologues to isolate the P. patens MSH2 (PpMSH2) cDNA. The deduced sequence of the PpMSH2 protein is respectively 60.8% and 59.6% identical to the maize and A. thaliana MSH2. Phylogenic studies show that PpMSH2 is closely related to the group of plant MSH2 proteins. Southern analysis reveals that the gene exists as a single copy in the P. patens genome.

Guidelines for membrane protein engineering derived from de novo designed model peptides

Notwithstanding great advances in the engineering and structural analysis of globular proteins, relatively limited success has been achieved with membrane proteins--due largely to their intrinsic high insolubility and the concomitant difficulty in obtaining crystals. Progress with de novo synthesis of model membrane-interactive peptides presents an opportunity to construct simpler peptides with definable structures, and permits one to approach an understanding of the properties of the membrane proteins themselves. In the present article, we review how our laboratory and others have used peptide approaches to assess the detailed interactions of peptides with membranes, and primary folding at membrane surfaces and in membranes. Structural studies of model peptides identified the existence of a "threshold hydrophobicity," which controls spontaneous peptide insertion into membranes. Related studies of the relative helicity of peptides in organic media such as n-butanol indicate that the helical propensity of individual residues--not simply their hydrophobicity--may dictate the conformations of peptides in membranes. The overall experimental results provide fundamental guidelines for membrane protein engineering.

Structural features of the plasmid pMV158-encoded transcriptional repressor CopG, a protein sharing similarities with both helix-turn-helix and beta-sheet DNA binding proteins

The small transcriptional repressor CopG protein (45 amino acids) encoded by the streptococcal plasmid pMV158 was purified to near homogeneity. Gel filtration chromatography and analytical ultracentrifugation showed that the native protein is a spherical dimer of identical subunits. Circular dichroism measurements of CopG indicated a consensus average content of more than 50% alpha-helix and 10-35% beta-strand and turns, which is compatible with the predicted secondary structure of the protein. CopG exhibited a prolonged intracellular half-life, but deletions in regions other than the C-terminal affected the global structure of the protein, severely reducing the half-lives of the CopG variants. This indicates that CopG has a compact structure, perhaps constituted by a single domain. Molecular modeling of CopG showed a good fitting between the helix-turn-helix motifs of well-known repressor proteins and a bihelical unit of CopG. However, modeling of CopG with ribbon-helix-helix class of DNA binding proteins also exhibited an excellent fit. Eleven out of the 12 replicons belonging to the pMV158 plasmid family could also encode Cop proteins, which share features with both helix-turn-helix and beta-sheet DNA binding proteins.

Refined structure of Cro repressor protein from bacteriophage lambda suggests both flexibility and plasticity

The structure of the Cro repressor protein from phage lambda has been refined to a crystallographic R-value of 19.3% at 2.3 A resolution. The re fined model supports the structure as originally described in 1981 and provides a basis for comparison with the Cro-operator complex described in the accompanying paper. Changes in structure seen in different crystal forms and modifications of Cro suggest that the individual subunits are somewhat plastic in nature. In addition, the dimer of Cro suggests a high degree of flexibility, which may be important in forming the Cro-DNA complex. The structure of the Cro subunit as determined by NMR agrees reasonably well with that in the crystals (root-mean-square discrepancy of about 2 A for all atoms). There are, however, only a limited number of intersubunit distance constraints and, presumably for this reason, the different NMR models for the dimer vary substantially among themselves (discrepancies of 1.3 to 5.5 A). Because of this variation it is not possible to say whether the range of discrepancies between the X-ray and NMR Cro dimers (2.9 to 7.5 A) represent a significant difference between the X-ray and solution structures. It has previously been proposed that substitutions of Tyr26 in Cro increase thermal stability by the "reverse hydrophobic effect", i.e. by exposing 40% more hydrophobic surface to solvent in the folded form than in the unfolded state. The refined structure, however, suggests that Tyr26 is equally solvent exposed in the folded and unfolded states. The most stabilizing substitution is Tyr26-->Asp and in this case it appears that interaction with an alpha-helix dipole is at least partly responsible for the enhanced stability.

Genetic and biochemical analysis of Msh2p-Msh6p: role of ATP hydrolysis and Msh2p-Msh6p subunit interactions in mismatch base pair recognition

Recent studies have shown that Saccharomyces cerevisiae Msh2p and Msh6p form a complex that specifically binds to DNA containing base pair mismatches. In this study, we performed a genetic and biochemical analysis of the Msh2p-Msh6p complex by introducing point mutations in the ATP binding and putative helix-turn-helix domains of MSH2. The effects of these mutations were analyzed genetically by measuring mutation frequency and biochemically by measuring the stability, mismatch binding activity, and ATPase activity of msh2p (mutant msh2p)-Msh6p complexes. A mutation in the ATP binding domain of MSH2 did not affect the mismatch binding specificity of the msh2p-Msh6p complex; however, this mutation conferred a dominant negative phenotype when the mutant gene was overexpressed in a wild-type strain, and the mutant protein displayed biochemical defects consistent with defects in mismatch repair downstream of mismatch recognition. Helix-turn-helix domain mutant proteins displayed two different properties. One class of mutant proteins was defective in forming complexes with Msh6p and also failed to recognize base pair mismatches. A second class of mutant proteins displayed properties similar to those observed for the ATP binding domain mutant protein. Taken together, these data suggested that the proposed helix-turn-helix domain of Msh2p was unlikely to be involved in mismatch recognition. We propose that the MSH2 helix-turn-helix domain mediates changes in Msh2p-Msh6p interactions that are induced by ATP hydrolysis; the net result of these changes is a modulation of mismatch recognition.

Mutation of a meiosis-specific MutS homolog decreases crossing over but not mismatch correction

MSH4 is a novel meiosis-specific gene required for wild-type levels of spore viability in S. cerevisiae. The predicted product of the MSH4 gene is homologous to the MutS family of proteins; however, msh4-null mutants have no apparent defect in mismatch repair. msh4 mutant strains display wild-type levels of gene conversion and postmeiotic segregation, but they show a reduction in crossing over and a resultant increase in nondisjunction of homologous chromosomes at meiosis I. Immunofluorescence experiments demonstrate that the Msh4 protein is localized to discrete sites on pachytene chromosomes. We propose that Msh4 interacts with a recombination intermediate to influence its resolution.

Chemical synthesis of a fully active transcriptional repressor protein

Plasmid pLS1-encoded 45-amino acid transcriptional repressor CopG (formerly RepA) has been chemically synthesized. A one-step purification of the synthetic protein has been developed, which yields high levels of pure protein with low or no contamination of truncated products. We have compared some properties of the chemical CopG protein with those of the biologically purified CopG. The two proteins were indistinguishable in (i) their ability to generate specific protein-DNA complexes, (ii) their capacity to protect a restriction site included within the CopG DNA target, and (iii) in their in vitro capacity to specifically repress synthesis of copG mRNA.

Families and the structural relatedness among globular proteins

Protein structures come in families. Are families "closely knit" or "loosely knit" entities? We describe a measure of relatedness among polymer conformations. Based on weighted distance maps, this measure differs from existing measures mainly in two respects: (1) it is computationally fast, and (2) it can compare any two proteins, regardless of their relative chain lengths or degree of similarity. It does not require finding relative alignments. The measure is used here to determine the dissimilarities between all 12,403 possible pairs of 158 diverse protein structures from the Brookhaven Protein Data Bank (PDB). Combined with minimal spanning trees and hierarchical clustering methods, this measure is used to define structural families. It is also useful for rapidly searching a dataset of protein structures for specific substructural motifs. By using an analogy to distributions of Euclidean distances, we find that protein families are not tightly knit entities.

Mutations affecting the ability of Escherichia coli Lrp to bind DNA, activate transcription, or respond to leucine

Lrp is a regulatory protein in Escherichia coli that increases expression of some operons and decreases expression of others. Mutations in Lrp were isolated on the basis of their effects on ilvIH, one of the operons regulated positively by Lrp. The ilvIH operon encodes an enzyme involved in the biosynthesis of leucine, valine, and isoleucine, and expression of this operon is repressed when cells are grown in the presence of leucine. Three groups of mutants were isolated. Mutant strains that were resistant to the repressive effects of leucine were termed leucine response mutants. These mutants had changes in the Lrp amino acid sequence between amino acid residues 108 and 149. Mutant strains having low expression of ilvIH in vivo were identified as colonies having reduced expression of a reporter gene. For some of these mutants, called DNA-binding mutants, binding to ilvIH DNA in vitro was markedly reduced. The mutations in these strains caused changes in Lrp between amino acids 16 and 70. Six of ten of these mutations were within a region having a putative helix-turn-helix motif. A third group of mutants had low ilvIH expression in vivo but apparently normal DNA binding in vitro. These mutants were called activation mutants since they affected the ability of Lrp to activate expression. Lrp from these strains had changes in amino acids between residues 76 and 125. This study suggests that Lrp has separate domains responsible for binding DNA, activating transcription, and responding to leucine.

Functional roles of amino acid residues involved in forming the alpha-helix-turn-alpha-helix operator DNA binding motif of Tet repressor from Tn10

The Tn10 derived Tet repressor contains an amino acid segment with high homology to the alpha-helix-turn-alpha-helix motif (HTH) of other DNA binding proteins. The five most conserved amino acids in HTH are probably involved in structural formation of the motif. Their functional role was probed by saturation mutagenesis yielding 95 single amino acid replacement mutants of Tet repressor. Their binding efficiencies to tet operator were quantitatively determined in vivo. All functional mutants contain amino acid substitutions consistent with their proposed role in a HTH. In particular, only the two smallest amino acids (serine, glycine) can substitute a conserved alanine in the proposed first alpha-helix without loss of activity. The last position of the first alpha-helix, the second position in the turn, and the fourth position in the second alpha-helix require mostly hydrophobic residues. The proposed C-terminus of the first alpha-helix is supported by a more active asparagine compared to glutamine replacement mutant of the wt leucine residue. The turn is located close to the protein surface as indicated by functional lysine and arginine replacements for valine. A glycine residue at the first position in the turn can be replaced by any amino acid yielding mutants with at least residual tet operator affinity. A structural model of the HTH of Tet repressor is presented.

Mutations in the araC gene of Salmonella typhimurium LT2 which affect both activator and auto-regulatory functions of the AraC protein

The araC gene encodes a regulatory protein, AraC, that acts as both an activator and a repressor of transcription of the genes involved in the transport and catabolism of L-arabinose in Salmonella typhimurium LT2. Five araC mutants which have altered regulatory properties were characterized. All are point mutations which would result in amino acid substitutions near the C terminus of AraC. Each mutation results in altered activator and auto-regulatory AraC function in vivo. In vitro DNA-binding assays showed that three mutant AraC have measurable lowered affinity for ara controlling site DNA. The data are consistent with a model in which there is a DNA-binding domain in the C terminus of AraC which functions in both activation and repression.

Phylogenetic continuum indicates "galaxies" in the protein universe: preliminary results on the natural group structures of proteins

The markedly nonuniform, even systematic distribution of sequences in the protein "universe" has been analyzed by methods of protein taxonomy. Mapping of the natural hierarchical system of proteins has revealed some dense cores, i.e., well-defined clusterings of proteins that seem to be natural structural groupings, possibly seeds for a future protein taxonomy. The aim was not to force proteins into more or less man-made categories by discriminant analysis, but to find structurally similar groups, possibly of common evolutionary origin. Single-valued distance measures between pairs of superfamilies from the Protein Identification Resource were defined by two chi 2-like methods on tripeptide frequencies and the variable-length subsequence identity method derived from dot-matrix comparisons. Distance matrices were processed by several methods of cluster analysis to detect phylogenetic continuum between highly divergent proteins. Only well-defined clusters characterized by relatively unique structural, intracellular environmental, organismal, and functional attribute states were selected as major protein groups, including subsets of viral and Escherichia coli proteins, hormones, inhibitors, plant, ribosomal, serum and structural proteins, amino acid synthases, and clusters dominated by certain oxidoreductases and apolar and DNA-associated enzymes. The limited repertoire of functional patterns due to small genome size, the high rate of recombination, specific features of the bacterial membranes, or of the virus cycle canalize certain proteins of viruses and Gram-negative bacteria, respectively, to organismal groups.

Genetic analysis of a lactococcal plasmid replicon

The sequence and genetic organization was determined of the 2508 bp lactococcal portion of pFX2, which was derived from a cryptic Lactococcus lactis subsp. lactis plasmid and used as the basis for construction of a series of lactococcal vectors. A lactococcal plasmid plus origin and two replication protein-coding regions (repA and repB) were located. RepA has a helix-turn-helix motif, a geometry typical of DNA-binding proteins. RepB shows a high degree of homology to the plasmid replication initiation proteins from other gram-positive bacteria and Mycoplasma. The transcribed inverted repeat sequence between repA and repB could form an attenuator to regulate pFX2 replication. Up-stream of the ori site, and in a region which was non-essential for replication, a 215 bp sequence identical to the staphylococcal plasmid pE194 and carrying the RSA site was identified. The genetic organization of this lactococcal plasmid replicon shares significant similarity with pE194 group plasmids.

Repression of the E coli recA gene requires at least two LexA protein monomers

To analyze the DNA binding domain of E coli LexA repressor and to test whether the repressor binds as a dimer to DNA, negative dominant lexA mutations affecting the binding domain have been isolated. A large number of amino acid substitutions between amino acid positions 39 and 46 were introduced using cassette mutagenesis. Mutants defective in DNA binding were identified and then examined for dominance to lexA+. A number of substitutions weakened repressor function partially, whereas other substitutions led to a repressor with no demonstrable activity and a defective dominant phenotype. Since the LexA binding site has dyad symmetry, we infer that this dominance results from interaction of monomers of wild-type LexA protein with mutant monomers and that an oligomeric form of repressor binds to operator. The binding of LexA protein to operator DNA was investigated further using a mutant protein, LexA408, which recognizes a symmetrically altered operator mutant but not wild-type operator. A mixture of mutant LexA408 and LexA+ proteins, but neither individual protein, bound to a hybrid recA operator consisting of mutant and wild-type operator half sites. These results suggest that at least 1 LexA protein monomer interacts with each operator half site. We discuss the role of LexA oligomer formation in binding of LexA to operator DNA.

The structure of the homeodomain and its functional implications

The three-dimensional structure of the homeodomain, as determined by nuclear magnetic resonance spectroscopy, reveals the presence of a helix-turn-helix motif, similar to the one found in prokaryotic gene regulatory proteins. Isolated homeodomains bind with high affinity to specific DNA sequences. Thus, the structure-function relationship is highly conserved in evolution.

Improved detection of helix-turn-helix DNA-binding motifs in protein sequences

We present an update of our method for systematic detection and evaluation of potential helix-turn-helix DNA-binding motifs in protein sequences [Dodd, I. and Egan, J. B. (1987) J. Mol. Biol. 194, 557-564]. The new method is considerably more powerful, detecting approximately 50% more likely helix-turn-helix sequences without an increase in false predictions. This improvement is due almost entirely to the use of a much larger reference set of 91 presumed helix-turn-helix sequences. The scoring matrix derived from this reference set has been calibrated against a large protein sequence database so that the score obtained by a sequence can be used to give a practical estimation of the probability that the sequence is a helix-turn-helix motif.

Mutations in the trfA replication gene of the broad-host-range plasmid RK2 result in elevated plasmid copy numbers

Mutated forms of trfA, the replication protein gene of plasmid RK2, that support a minimal RK2 origin plasmid in Escherichia coli at copy numbers up to 23-fold higher than normal have been isolated. Six such high-copy-number (copy-up) mutations were mapped and sequenced. In each case, a single base transition led to an amino acid substitution in the TrfA protein primary sequence. The six mutations affected different residues of the protein and were located within a 69-base-pair region encoding 24 amino acids. Dominance tests showed that each of the mutants can be suppressed by wild-type trfA in trans, but suppression is highly dependent on the amount of wild-type protein produced. Excess mutant TrfA protein provided in trans significantly increased the copy number of RK2 and other self-replicating derivatives of RK2 that contain a wild-type trfA gene. These observations suggest that the mutations affect a regulatory activity of the TrfA replication protein that is a key factor in the control of initiation of RK2 replication.

Activation of ara operons by a truncated AraC protein does not require inducer

The araC gene of Escherichia coli encodes a protein that binds the inducer L-arabinose to activate the transcription of three ara operons. In a study to determine the functional domains within the AraC protein, we have generated a set of overlapping deletions from the proximal end of the araC gene. We found that the removal of up to nearly 60% of the coding sequence of this protein still allows transcriptional activation of the ara operons in vivo, up to 27% that of the wild type. These truncated proteins, however, no longer require arabinose for induction. The ligand-induced conformational change apparently either releases or unmasks an existing functional domain within AraC, rather than generating a new conformation that is required for activation of the promoter of araBAD. Since the truncated protein of the mutant C154 (which lacks 153 amino acid residues from the N terminus) retains DNA binding specificity, the DNA-recognition domain is localized in the C-terminal half of the AraC protein. Truncated proteins were unable to repress araBAD or araC in vivo, even though they were able to bind all ara operators. We propose that the N-terminal half of AraC is essential for the formation of the DNA loops that are responsible for repression of araBAD and for autoregulation of araC.

Molecular characterization of promoters of the Lactococcus lactis subsp. cremoris temperate bacteriophage BK5-T and identification of a phage gene implicated in the regulation of promoter activity

DNA fragments from the temperate lactococcal bacteriophage BK5-T were cloned into the promoter-detecting plasmid pMU1328. Five DNA fragments conferring promoter activity were selected by transformation of Streptococcus sanguis and were functional in Escherichia coli, S. sanguis, and Lactococcus lactis subspp. lactis and cremoris. The nucleotide sequences of these fragments were determined, and primer extension analysis was used to locate the site of initiation of transcription from each promoter in both E. coli and S. sanguis. Transcription was initiated from the same nucleotide in these two organisms, and the promoters contained -10 and -35 regions similar to the consensus sequence for E. coli promoters. The activities of three of the five promoters were decreased two- to threefold when a compatible plasmid containing a 3.8-kilobase-pair EcoRI fragment (EcoRI-f) of BK5-T was coresident with the promoter-containing plasmid in either L. lactis subsp. cremoris or E. coli. Data from Tn5 mutagenesis, subcloning experiments, and DNA sequence analysis indicate that this decrease in promoter activity requires a region of EcoRI-f that contains a 621-base-pair open reading frame. This region has been designated bpi (for BK5-T promoter inhibitor).

DNA sequence analysis of five genes; tnsA, B, C, D and E, required for Tn7 transposition

A region of DNA sequence of the bacterial transposon Tn7, which is required for transposition, has been determined. This DNA sequence completes an 8351 base pair (bp) region containing five long open reading frames (ORF's) that correspond to the genetically defined genes, tnsA, B, C, D and E, required for Tn7 transposition. All of the ORF's are oriented in the same direction, ie. inward from the element's right end. The genes are in a very compact arrangement with the presumed initiation codons never more than two bases beyond the preceding termination codon. Domains with similarity to the helix-turn-helix genre of Cro-like, sequence specific DNA binding sites occur within the deduced amino acid (a.a.) sequence of the TnsA, TnsB, TnsD and TnsE proteins. Translation of the tnsC ORF reveals strong homology to a consensus sequence for nucleotide binding sites as well as a region of similarity to a transcriptional activator (MalT). No striking a.a. sequence similarity to other DNA recombinases is observed. The possible roles of these proteins in Tn7 transposition is discussed in light of the analysis presented.

Alternatively spliced Hox-1.7 transcripts encode different protein products

Two Hox-1.7 cDNAs, GPK5 and GPK6, were isolated from an adult guinea-pig kidney cDNA library by hybridization at low stringency using a Hox-1.7 cDNA probe, MH-1, cloned from mouse F9 teratocarcinoma cells. Sequence analysis of these two Hox-1.7 cDNAs showed that (a) GPK5 contains a putative initiation codon preceding an open reading frame which includes the homeo box, and may represent the complete protein coding region for the corresponding Hox-1.7 transcript; (b) the amino acids encoded by GPK6 and MH-1 are nearly identical (with two changes); (c) both adult guinea-pig kidney cDNA clones share identical homeo domains with the mouse Hox-1.7 cDNA; and (d) both adult guinea-pig kidney cDNA clones are identical in the homeo box region and in the 3' untranslated region but differ significantly starting from the 12th codon upstream from the homeo box. These data, supported by Southern blot analysis, indicate that a splice site is present 5' to the homeo box and that alternative splicing results in transcripts encoding different protein products.

Structural basis of DNA-protein recognition

Recent structure determinations of several repressor-operator complexes have shown how proteins can recognize specific binding sites on DNA. Although each of these repressor proteins belongs to the 'helix-turn-helix' class of DNA-binding proteins, they do not use a simple code for recognition.

SPXX, a frequent sequence motif in gene regulatory proteins

A new DNA-binding unit, composed of four amino acid residues and common in gene regulatory proteins, is proposed. The occurrences of the sequences Ser-Pro-X-X (SPXX) and Thr-Pro-X-X (TPXX) in gene regulatory proteins are compared with those in general proteins. These sequences are found more frequently in gene regulatory proteins including homoeotic gene products, segmentation gene products, steroid hormone receptors and certain oncogene products, than they are in DNA-binding proteins that are not directly involved in gene regulation, such as the core histones, or in general proteins. It is therefore suggested that these sequences contribute to DNA-binding in a manner important for gene regulation. Amino acid residues characteristic of the types of proteins are found as the variable residues X: basic residues, Lys and Arg, in histones, H1 and sea urchin spermatogenous H2B; Tyr in RNA polymerase II; and Ser, Thr, Ala, Leu and Pro in other gene regulatory proteins S(T)PXX sequences are located on either side of other DNA-recognizing units such as Zn fingers, helix-turn-helices, and cores of histones. The structure of a S(T)PXX sequence is presumed to be a beta-turn I stabilized by two hydrogen bonds, and its potential mode of DNA-binding is discussed.

Purification and characterization of RepA, a protein involved in the copy number control of plasmid pLS1

The promiscuous streptococcal plasmid pLS1 encodes for the 5.1 kDa RepA protein, involved in the regulation of the plasmid copy number. Synthesis of RepA was observed both in Bacillus subtilis minicells and in an Escherichia coli expression system. From this system, the protein has been purified and it appears to be a dimer of identical subunits. The amino acid sequence of RepA has been determined. RepA shows the alpha helix-turn-alpha helix motif typical of many DNA-binding proteins and it shares homology with a number of repressors, specially with the TrfB repressor encoded by the broad-host-range plasmid RK2. DNase I footprinting revealed that the RepA target is located in the region of the promoter for the repA and repB genes. Trans-complementation analysis showed that in vivo, RepA behaves as a repressor by regulating the plasmid copy number. We propose that the regulatory role of RepA is by limitation of the synthesis of the initiator protein RepB.

Structure of the amino-terminal domain of phage 434 repressor at 2.0 A resolution

The crystal structure of the amino-terminal domain of phage 434 repressor has been solved using molecular replacement methods and refined to an R-factor of 19.3% against data to 2.0 A resolution. The protein comprises five short alpha-helices. Two of these form a helix-turn-helix motif, very similar to those found in related proteins. The protein is remarkably similar to the Cro protein from the same phage.

Isolation and sequence-specific DNA binding of the Antennapedia homeodomain

The homeodomain encoded by the Antennapedia (Antp) gene of Drosophila was overproduced in a T7 expression vector in Escherichia coli. The corresponding polypeptide of 68 amino acids was purified to homogeneity. The homeodomain was analysed by ultracentrifugation and assayed for DNA binding. The secondary structure of the isolated homeodomain was determined by nuclear magnetic resonance spectroscopy. DNA-binding studies indicate that the isolated homeodomain binds to DNA in vitro. It selectively binds to the same sites as a longer Antp polypeptide and a full-length fushi tarazu (ftz) protein. Therefore, the homeodomain represents the DNA-binding domain of the homeotic proteins.

A tissue-specific transcription factor containing a homeodomain specifies a pituitary phenotype

Multiple related cis-active elements required for cell-specific activation of the rat prolactin gene appear to bind a pituitary-specific positive transcription factor(s), referred to as Pit-1. DNA complementary to Pit-1 mRNA, cloned on the basis of specific binding to AT-rich cell-specific elements in the rat prolactin and growth hormone genes, encodes a 33 kd protein with significant similarity at its carboxyl terminus to the homeodomains encoded by Drosophila developmental genes. Pit-1 mRNA is expressed exclusively in the anterior pituitary gland in both somatotroph and lactotroph cell types, which produce growth hormone and prolactin, respectively. Pit-1 expression in heterologous cells (HeLa) selectively activates prolactin and growth hormone fusion gene expression, suggesting that Pit-1 is sufficient to confer a characteristic pituitary phenotype. The structure of Pit-1 and its recognition elements suggests that metazoan tissue phenotype is controlled by a family of transcription factors that bind to related cis-active elements and contain several highly conserved domains.

The Azorhizobium caulinodans nifA gene: identification of upstream-activating sequences including a new element, the 'anaerobox'

From nucleotide sequencing analyses, the A. caulinodans nifA gene seems to be under dual control by the Ntr (in response to available N) and Fnr (in response to available O2) transcriptional activation/repression systems. Because it fixes N2 in two contexts, the Ntr system might regulate A. caulinodans nif gene expression ex planta, while the Fnr system might similarly regulate in planta. As nifA upstream-activating elements, we have identified: (i) a gpNifA binding site allowing autogenous nifA regulation, (ii) an Ntr-dependent transcription start, presumably the target of gpNifA activation, and (iii) an "anaerobox" tetradecameric nucleotide sequence that is precisely conserved among O2 regulated enteric bacterial genes controlled by the gpFnr transcriptional activator. Because it is precisely positioned upstream of enteric bacterial transcriptional starts, the "anaerobox" sequence may constitute the gpFnr DNA binding site. If so, then a second, Ntr-independent nifA transcription start may exist. We have also deduced the A. caulinodans nifA open reading frame and have compared the gene product (gpNifA) with those of other N2-fixing organisms. These proteins exhibit strongly conserved motifs: (i) sites conserved among ATP-binding proteins, (ii) an interdomain linker region, and (iii) a C-terminal alpha-helix-turn-alpha-helix DNA binding site.

Crystal structure of trp repressor/operator complex at atomic resolution

The crystal structure of the trp repressor/operator complex shows an extensive contact surface, including 24 direct and 6 solvent-mediated hydrogen bonds to the phosphate groups of the DNA. There are no direct hydrogen bonds or non-polar contacts to the bases that can explain the repressor's specificity for the operator sequence. Rather, the sequence seems to be recognized indirectly through its effects on the geometry of the phosphate backbone, which in turn permits the formation of a stable interface. Water-mediated polar contacts to the bases also appear to contribute part of the specificity.

Amino acid sequence template useful for alpha-helix-turn-alpha-helix prediction

Necessary stereochemical requirements for an amino acid sequence segment to fold into an alpha-helix-turn-alpha-helix supersecondary structure are presented in sequence template form. The usefulness of the template is illustrated by alpha-helix-turn-alpha-helix predictions consistent with experimental data from the large T antigens of two polyoma viruses, simian virus 40 (segment 143-165) and mouse polyoma virus (segment 297-319), and the yeast transcription activator GCN4 (segment 256-278).

Structural basis for autogenous regulation of Xenopus laevis ribosomal protein L1 synthesis at the splicing level

It is known that the injection of the Xenopus laevis ribosomal protein L1 gene into oocytes causes the accumulation of immature L1 transcripts due to a specific block of splicing of the second and third introns. In this paper the secondary structures of these introns in pre-mRNA have been constructed. It has been shown that they share homology with 28 S rRNA. The putative RNA-binding segment of L1 has also been predicted. These results are interpreted as the structural basis for autogenous regulation of X. laevis ribosomal protein L1 synthesis at the splicing level.

Flexibility of the DNA-binding domains of trp repressor

An orthorhombic crystal form of trp repressor (aporepressor plus L-tryptophan ligand) was solved by molecular replacement, refined to 1.65 A resolution, and compared to the structure of the repressor in trigonal crystals. Even though these two crystal forms of repressor were grown under identical conditions, the refined structures have distinctly different conformations of the DNA-binding domains. Unlike the repressor/aporepressor structural transition, the conformational shift is not caused by the binding or loss of the L-tryptophan ligand. We conclude that while L-tryptophan binding is essential for forming a specific complex with trp operator DNA, the corepressor ligand does not lock the repressor into a single conformation that is complementary to the operator. This flexibility may be required by the various binding modes proposed for trp repressor in its search for and adherence to its three different operator sites.

Role of glutamic acid-181 in DNA-sequence recognition by the catabolite gene activator protein (CAP) of Escherichia coli: altered DNA-sequence-recognition properties of [Val181]CAP and [Leu181]CAP

It has been proposed that Glu-181 of the catabolite gene activator protein (CAP) makes direct contact with certain base pairs of the specific DNA site. We have purified wild-type CAP and two substituted CAP variants, [Val181]CAP and [Leu181]CAP, and have assessed the DNA-sequence-recognition properties in vitro with respect to positions 5, 6, 7, 8, and 16 of the DNA site. The data indicate that [Val181]CAP and [Leu181]CAP fail to discriminate between the consensus DNA base pair and the three non-consensus-DNA base pairs at 2-fold-related positions 7 and 16 of the DNA site. In contrast, [Val181]CAP and [Leu181]CAP retain the ability to discriminate between different base pairs at positions 5 and 8 of the DNA site. We conclude that Glu-181 of CAP makes a direct contact with 2-fold-related positions 7 and 16 of the DNA site, as proposed previously based on in vivo results. We propose that upon replacement of Glu-181 by valine or leucine, this contact is eliminated and is replaced by no other functional contact. We estimate that the contact by Glu-181 with each position contributes -0.7 kcal/mol to the total CAP-DNA binding free energy.