Sequence of the site-specific recombinase gene cin and of its substrates serving in the inversion of the C segment of bacteriophage P1.

Inversion of the 4.2-kb C segment flanked by 0.6-kb inverted repeats on the bacteriophage P1 genome is mediated by the P1-encoded site-specific cin recombinase. The cin gene lies adjacent to the C segment and the C inversion cross-over sites cixL and cixR are at the external ends of the inverted repeats. We have sequenced the DNA containing the cin gene and these cix sites. The cin structural gene consists of 561 nucleotides and terminates at the inverted repeat end where the cixL site is located. Only two nucleotides in the cixL region differ from those in the cixR and they are within the cin TAA stop codon. The cin promoter was localized by transposon mutagenesis within a 0.1-kb segment, which contains probable promoter sequences overlapping with a 'pseudo-cix' sequence cixPp. In a particular mutant, integration of an IS1-flanked transposon into the cin control region promoted weak expression of the cin gene. The cin and cix sequences show homology with corresponding, functionally related sequences for H inversion in Salmonella and with cross-over sites for G inversion in phage Mu. Based on a comparison of the DNA sequences and of the gene organizations, a possible evolutionary relationship between these three inversion systems and the possible significance of the cixPp sequence in the cin promoter are discussed.     

Cin-mediated recombination at secondary crossover sites on the Escherichia coli chromosome.

The Cin recombinase is known to mediate DNA inversion between two wild-type cix sites flanking genetic determinants for the host range of bacteriophage P1. Cin can also act with low frequency at secondary (or quasi) sites (designated cixQ) that have lower homology to either wild-type site. An inversion tester sequence able to reveal novel operon fusions was integrated into the Escherichia coli chromosome, and the Cin recombinase was provided in trans. Among a total of 13 Cin-mediated inversions studied, three different cixQ sites had been used. In two rearranged chromosomes, the breakpoints of the inversions were mapped to cixQ sites in supB and ompA, representing inversions of 109 and 210 kb, respectively. In the third case, a 2.1-kb inversion was identified at a cixQ site within the integrated sequences. This derivative itself was a substrate for a second inversion of 1.5 kb between the remaining wild-type cix and still another cixQ site, thus resembling a reversion. In analogy to that which is known from DNA inversion on plasmids, homology of secondary cix sites to wild-type recombination sites is not a strict requirement for inversion to occur on the chromosome. The chromosomal rearrangements which resulted from these Cin-mediated inversions were quite stable and suffered no growth disadvantage compared with the noninverted parental strain. The mechanistic implications and evolutionary relevance of these findings are discussed.     

Expression of the bacteriophage P1 cin recombinase gene from its own and heterologous promoters

The cin recombinase of bacteriophage P1, a protein that catalyses site-specific DNA inversions, has been identified and its structural gene has been cloned under the control of different promoters. One of the DNA sequences used for the site-specific recombination, cixL, overlaps with the 3' end of the gene, but we show that the presence of this site does not affect cin gene expression from strong promoters. To assay cin activity we have constructed plasmids that carry antibiotic resistance genes within the invertible segment that are transcribed from promoters outside the segment. DNA inversion switches on or off genes for chloramphenicol or kanamycin resistance. These tester plasmids are used to study cin-mediated DNA inversion both in vivo and in vitro.     

Localized conversion at the crossover sequences in the site-specific DNA inversion system of bacteriophage P1

The crossover sites for site-specific C inversion consist of imperfect 12 bp inverted repeats with the dinucleotide TT at the center of symmetry. The phage P1 Cin recombinase acts not only at these cix sites but also less efficiently at cix-related sequences called quasi-cix sites, cixQ. When cixQ contains a central dinucleotide TT, crossover occurs in vivo at the 2 bp sequence TT in the normal and the quasi-cix sites. If cixQ carries only one T residue, inversion-associated localized conversion can occur at the mismatched position within the 2 bp sequence. The results indicate that Cin generates 2 bp staggered cuts in vivo and that reciprocal strand exchanges occur at these 2 bp crossover sequences.     

The Min DNA inversion enzyme of plasmid p15B of Escherichia coli 15T−: a new member of the Din family of site-specific recombinases

Plasmid p15B is a bacteriophage P1-related resident of Escherichia coli 15T-. Both genomes contain a segment in which DNA inversion occurs, although this part of their genomes is not identical. This DNA segment of p15B was cloned in a multicopy vector plasmid. Like its parent, the resulting plasmid, pAW800, undergoes complex multiple DNA inversions: this DNA inversion system is therefore called Min. The min gene, which codes for the p15B Min DNA invertase, can complement the P1 cin recombinase gene. The Min inversion system is thus a new member of the Din family of site-specific recombinases to which Cin belongs. The DNA sequence of the min gene revealed that Min is most closely related to the Pin recombinase of the e14 defective viral element on the E. coli K12 chromosome. Like other members of the Din family, the min gene contains a recombinational enhancer element which stimulates site-specific DNA inversion 300-fold.     

A site-specific, conservative recombination system carried by bacteriophage P1. Mapping the recombinase gene cin and the cross-over sites cix for the inversion of the C segment.

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. With insertion and deletion mutants of P1 derivatives the site-specific recombinase gene cin for C inversion) has been mapped adjacent to the C segment and the cix sites (for C inversion cross-over) have been located at the outside ends of the inverted repeats. Inversion of the C segment functions as a biological switch and controls expression of the gene(s) responsible for phage infectivity carried on the C segment. The cin gene product can promote recombination between a 'quasi- cix ' site on plasmid pBR322 and a cix site on P1 DNA. The junctions formed on the resulting co-integrate can also serve as cix sites. This observation implies a potential evolutionary process to bring genes under the control of a biological switch acting by DNA inversion.     

Purification and DNA-binding properties of FIS and Cin, two proteins required for the bacteriophage P1 site-specific recombination system, cin

An Escherichia coli chromosomally coded factor termed FIS (Factor for Inversion Stimulation) stimulates the Cin protein-mediated, site-specific DNA inversion system of bacteriophage P1 more than 500-fold. We have purified FIS and the recombinase Cin, and studied the inversion reaction in vitro. DNA footprinting studies with DNase I showed that Cin specifically binds to the recombination site, called cix. FIS does not bind to cix sites but does bind to a recombinational enhancer sequence that is required in cis for efficient recombination. FIS also binds specifically to sequences outside the enhancer, as well as to sequences unrelated to Cin inversion. On the basis of these data, we discuss the possibility of additional functions for FIS in E. coli.     

Gene organization in the multiple DNA inversion region min of plasmid p15B of E.coli 15T-: assemblage of a variable gene.

The bacteriophage P1-related plasmid p15B of E. coli 15T- contains a 3.5 kb long region which frequently undergoes complex rearrangements by DNA inversion. Site-specific recombination mediated by the Min DNA invertase occurs at six crossover sites and it eventually results in a population of 240 isomeric configurations of this region. We have determined 8.3-kb sequences of the invertible DNA and its flanking regions. The result explains how DNA inversion fuses variable 3' parts to a constant 5' part, thereby alternatively assembling one out of six different open reading frames (ORF). The resulting variable gene has a coding capacity of between 739 and 762 amino acids. A large portion of its constant part is composed of repeated sequences. The p15B sequences in front of the variable fusion gene encode a small ORF and a phage-specific late promoter and are highly homologous to P1 DNA. Adjacent to the DNA invertase gene min, we have found a truncated 5' region of a DNA invertase gene termed psi cin which is highly homologous to the phage P1 cin gene. Its recombinational enhancer segment is inactive, but it can be activated by the substitution of two nucleotides.     

Motile properties of the kinesin-related Cin8p spindle motor extracted from Saccharomyces cerevisiae cells

We have developed microtubule binding and motility assays for Cin8p, a kinesin-related mitotic spindle motor protein from Saccharomyces cerevisiae. The methods examine Cin8p rapidly purified from crude yeast cell extracts. We created a recombinant form of CIN8 that fused the biotin carrying polypeptide from yeast pyruvate carboxylase to the carboxyl terminus of Cin8p. This form was biotinated in yeast cells and provided Cin8p activity in vivo. Avidin-coated glass surfaces were used to specifically bind biotinated Cin8p from crude extracts. Microtubules bound to the Cin8p-coated surfaces and moved at 3.4 +/- 0.5 micrometer/min in the presence of ATP. Force production by Cin8p was directed toward the plus ends of microtubules. A mutation affecting the microtubule-binding site within the motor domain (cin8-F467A) decreased Cin8p's ability to bind microtubules to the glass surface by >10-fold, but reduced gliding velocity by only 35%. The cin8-3 mutant form, affecting the alpha2 helix of the motor domain, caused a moderate defect in microtubule binding, but motility was severely affected. cin8-F467A cells, but not cin8-3 cells, were greatly impaired in bipolar spindle forming ability. We conclude that microtubule binding by Cin8p is more important than motility for proper spindle formation.     

Mitotic spindle function in Saccharomyces cerevisiae requires a balance between different types of kinesin-related motors.

Two Saccharomyces cerevisiae kinesin-related motors, Cin8p and Kip1p, perform an essential role in the separation of spindle poles during spindle assembly and a major role in spindle elongation. Cin8p and Kip1p are also required to prevent an inward spindle collapse prior to anaphase. A third kinesin-related motor, Kar3p, may act antagonistically to Cin8p and Kip1p since loss of Kar3p partially suppresses the spindle collapse in cin8 kip1 mutants. We have tested the relationship between Cin8p and Kar3p by overexpressing both motors using the inducible GAL1 promoter. Overexpression of KAR3 results in a shrinkage of spindle size and a temperature-dependent inhibition of the growth of wild-type cells. Excess Kar3p has a stronger inhibitory effect on the growth of cin8 kip1 mutants and can completely block anaphase spindle elongation in these cells. In contrast, overexpression of CIN8 leads to premature spindle elongation in all cells tested. This is the first direct demonstration of antagonistic motors acting on the intact spindle and suggests that spindle length is determined by the relative activity of Kar3p-like and Cin8p/Kip1p-like motors.     

Saccharomyces Cerevisiae Pac2 Functions with Cin1, 2 and 4 in a Pathway Leading to Normal Microtubule Stability

The products of the Saccharomyces cerevisiae CIN1, CIN2 and CIN4 genes participate in a nonessential pathway required for normal microtubule function. In this article, we demonstrate that the product of PAC2 also functions in this pathway. PAC2 deletion mutants displayed phenotypes and genetic interactions similar to those caused by cin1Δ, cin2Δ and cin4Δ. These include cold-sensitive microtubule structures and sensitivity to the microtubule depolymerizing agent benomyl. Involvement in a common functional pathway is indicated by the observation that all double mutant combinations are viable and no more affected than any single mutant. In addition, extra copies of CIN1 were found to suppress the benomyl sensitivity of pac2Δ, cin2Δ and cin4Δ, but not that caused by other mutations that affect microtubule function. Cin1p and Pac2p were found to be related in sequence to mammalian proteins that aid in the folding of β-tubulin into an assembly-competent state. Alleles of CIN1 were identified that could suppress the benomyl sensitivity of cin4-4 in a highly specific fashion. Our findings suggest that the guanine nucleotide-binding Cin4p interacts with Cin1p and regulates its tubulin folding activity.     

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.     

Loss of Function of Saccharomyces Cerevisiae Kinesin-Related Cin8 and Kip1 Is Suppressed by Kar3 Motor Domain Mutations

The kinesin-related products of the CIN8 and KIP1 genes of Saccharomyces cerevisiae redundantly perform an essential function in mitosis. The action of either gene-product is required for an outwardly directed force that acts upon the spindle poles. We have selected mutations that suppress the temperature-sensitivity of a cin8-temperature-sensitive kip1-δ strain. The extragenic suppressors analyzed were all found to be alleles of the KAR3 gene. KAR3 encodes a distinct kinesin-related protein whose action antagonizes Cin8p/Kip1p function. All seven alleles analyzed were altered within the region of KAR3 that encodes the putative force-generating (or ``motor') domain. These mutations also suppressed the inviability associated with the cin8-δ kip1-δ genotype, a property not shared by a deletion of KAR3. Other properties of the suppressing alleles revealed that they were not null for function. Six of the seven were unaffected for the essential karyogamy and meiosis properties of KAR3 and the seventh was dominant for the suppressing trait. Our findings suggest that despite an antagonistic relationship between Cin8p/Kip1p and Kar3p, aspects of their mitotic roles may be similar.     

A pathway containing the Ipl1/aurora protein kinase and the spindle midzone protein Ase1 regulates yeast spindle assembly

It is critical to elucidate the pathways that mediate spindle assembly and therefore ensure accurate chromosome segregation during cell division. Our studies of a unique allele of the budding yeast Ipl1/Aurora protein kinase revealed that it is required for centrosome-mediated spindle assembly in the absence of the BimC motor protein Cin8. In addition, we found that the Ase1 spindle midzone-associated protein is required for bipolar spindle assembly. The cin8 ipl1 and cin8 ase1 double mutant cells exhibit similar defects, and Ase1 overexpression completely restores spindle assembly in cin8 ipl1 strains. Consistent with the possibility that Ipl1 regulates Ase1, an ase1 mutant lacking the Ipl1 consensus phosphorylation sites cannot assemble spindles in the absence of Cin8. In addition, Ase1 phosphorylation and localization were altered in an ipl1 mutant. We therefore propose that Ipl1/Aurora and Ase1 constitute a previously unidentified spindle assembly pathway that becomes essential in the absence of Cin8.     

Mutational analysis of a prokaryotic recombinational enhancer element with two functions.

The site-specific DNA inversion system Cin encoded by the bacteriophage P1 consists of a recombinase, two inverted crossing-over sites and a recombinational enhancer. The latter approximately 75 bp long genetic element is bifunctional due to its location within the 5' part of the cin gene encoding the recombinase. In order to determine the essential nucleotides for each of its two biological functions we randomly mutated the recombinational enhancer sequence sis(P1) and analysed both functions of the mutants obtained. Three distinct regions of this sequence were found to be important for the enhancer activity. One of them occupies the middle third of the enhancer sequence and it can suffer a number of functionally neutral base substitutions, while others are detrimental. The other two regions occupy the two flanking thirds of the enhancer. They coincide with binding sites of the host-coded protein FIS (Factor for Inversion Stimulation) needed for efficient DNA inversion in vitro. These sequences appear to be highly evolved allowing only a few mutations without affecting either of the biological functions. Taking the effect of mutations within these FIS binding sites into account a consensus sequence for the interaction with FIS was compiled. This FIS consensus implies a palindromic structure for the recombinational enhancer. This is in line with the orientation independence of enhancer action with respect to the crossing-over sites.     

Heterologous expression, isotopic-labeling and immuno-characterization of Cin1, a novel protein secreted by the phytopathogenic fungus Venturia inaequalis

The phytopathogenic fungus Venturia inaequalis causes scab of apple. Once this fungus penetrates the plant surface, it forms a specialized body called a stroma between the inner cuticle surface and the epidermal cell wall. A novel V. inaequalis gene, cin1, is strongly up-regulated in the early stages of infection. This gene codes for a 523 residue secreted protein, containing eight imperfect repeats of 60 amino acids. Cin1 was expressed in the methanolytic yeast Pichia pastoris using the pPICZ vector system. A protein of 57 kDa was secreted by these transformants and peptide fingerprinting indicated that it was the Cin1 protein product. Multiple angle laser light scattering confirmed the predicted mass of Cin1, showing it was not glycosylated by Pichia and was monomeric in solution. Through measurements of the hydrodynamic properties of Cin1, the experimental Stokes radius of Cin1 was calculated and corresponded to the theoretical value for a natively folded globular protein of size 57 kDa. The mobility of recombinant Cin1 on native PAGE was also consistent with that of a folded protein. To simplify future structural analyses, a two-domain truncated version, Cin1-2D, consisting of domains one and two, was also expressed using the same vector system. Both proteins were purified to homogeneity. Conditions for maximal (>98%) incorporation of ¹³C and ¹⁵N were determined. A mouse polyclonal antibody and three monoclonal antibodies (MAbs) were raised against the full-length version of Cin1. Analysis of the three MAbs using surface plasmon resonance indicated binding to distinct epitopes on the Cin1 protein. Western blots confirmed the different specificities of each MAb.     

Site-specific recombinase genes in three Shigella subgroups and nucleotide sequences of a pinB gene and an invertible B segment from Shigella boydii.

Inversional switching systems in procaryotes are composed of an invertible DNA segment and a site-specific recombinase gene adjacent to or contained in the segment. Four related but functionally distinct systems have previously been characterized in detail: the Salmonella typhimurium H segment-hin gene (H-hin), phage Mu G-gin, phage P1 C-cin, and Escherichia coli e14 P-pin. In this article we report the isolation and characterization of three new recombinase genes: pinB, pinD, and defective pinF from Shigella boydii, Shigella dysenteriae, and Shigella flexneri, respectively. The genes pinB and pinD were detected by the complementation of a hin mutation of Salmonella and were able to mediate inversion of the H, P, and C segments. pinB mediated H inversion as efficiently as the hin gene did and mediated C inversion with a frequency three orders of magnitude lower than that of the cin gene. pinD mediated inversion of H and P segments with frequencies ten times as high as those for the genes intrinsic to each segment and mediated C inversion with a frequency ten times lower than that for cin. Therefore, the pinB and pinD genes were inferred to be different from each other. The invertible B segment-pinB gene cloned from S. boydii is highly homologous to the G-gin in size, organization, and nucleotide sequence of open reading frames, but the 5' constant region outside the segment is quite different in size and predicted amino acid sequence. The B segment underwent inversion in the presence of hin, pin, or cin. The defective pinF gene is suggested to hae the same origin as P-pin on e14 by the restriction map of the fragment cloned from a Pin+ transductant that was obtained in transduction from S. flexneri to E. coli delta pin.     

A gene for DNA invertase and an invertible DNA in Escherichia coli K-12

An assay system for the pin gene function, which suppresses the vh2 mutation of Salmonella, was developed and used to show that most strains of Escherichia coli K-12 are Pin+, whereas all the strains of E. coli C examined are Pin-. An E. coli host strain was constructed and used for detection of DNA fragments carrying the E. coli K-12 pin gene cloned in the plasmid vector pBR322. Restriction analysis of the cloned fragments showed that the invertible DNA (designated P region) is adjacent to the pin gene and that its inversion is mediated by the pin gene product. The pin gene was found to be functionally homologous to the gin gene of Mu phage and the cin gene of P1 phage. The P region most probably resides within the cryptic prophage e14, and the Pin- phenotype is likely to be associated with the loss of e14.     

Structure, dynamics and domain organization of the repeat protein Cin1 from the apple scab fungus

Venturia inaequalis is a hemi-biotrophic fungus that causes scab disease of apple. A recently-identified gene from this fungus, cin1 (cellophane-induced 1), is up-regulated over 1000-fold in planta and considerably on cellophane membranes, and encodes a cysteine-rich secreted protein of 523 residues with eight imperfect tandem repeats of ~60 amino acids. The Cin1 sequence has no homology to known proteins and appears to be genus-specific; however, Cin1 repeats and other repeat domains may be structurally similar. An NMR-derived structure of the first two repeat domains of Cin1 (Cin1-D1D2) and a low-resolution model of the full-length protein (Cin1-FL) using SAXS data were determined. The structure of Cin1-D1D2 reveals that each domain comprises a core helix-loop-helix (HLH) motif as part of a three-helix bundle, and is stabilized by two intra-domain disulfide bonds. Cin1-D1D2 adopts a unique protein fold as DALI and PDBeFOLD analysis identified no structural homology. A (15)N backbone NMR dynamic analysis of Cin1-D1D2 showed that a short stretch of the inter-domain linker has large amplitude motions that give rise to reciprocal domain-domain mobility. This observation was supported by SAXS data modeling, where the scattering length density envelope remains thick at the domain-domain boundary, indicative of inter-domain dynamics. Cin1-FL SAXS data models a loosely-packed arrangement of domains, rather than the canonical parallel packing of adjacent HLH repeats observed in α-solenoid repeat proteins. Together, these data suggest that the repeat domains of Cin1 display a "beads-on-a-string" organization with inherent inter-domain flexibility that is likely to facilitate interactions with target ligands.