Stimulation of V(D)J cleavage by high mobility group proteins.

V(D)J recombination requires a pair of signal sequences with spacer lengths of 12 and 23 bp between the conserved heptamer and nonamer elements. The RAG1 and RAG2 proteins initiate the reaction by making double-strand DNA breaks at both signals, and must thus be able to operate on these two different spatial arrangements. We show that the DNA-bending proteins HMG1 and HMG2 stimulate cleavage and RAG protein binding at the 23 bp spacer signal. These findings suggest that DNA bending is important for bridging the longer spacer, and explain how a similar array of RAG proteins could accommodate a signal with either a 12 or a 23 bp spacer. An additional effect of HMG proteins is to stimulate coupled cleavage greatly when both signal sequences are present, suggesting that these proteins also aid the formation of a synaptic complex.     

RAG-2 promotes heptamer occupancy by RAG-1 in the assembly of a V(D)J initiation complex

V(D)J recombination occurs at recombination signal sequences (RSSs) containing conserved heptamer and nonamer elements. RAG-1 and RAG-2 initiate recombination by cleaving DNA between heptamers and antigen receptor coding segments. RAG-1 alone contacts the nonamer but interacts weakly, if at all, with the heptamer. RAG-2 by itself has no DNA-binding activity but promotes heptamer occupancy in the presence of RAG-1; how RAG-2 collaborates with RAG-1 has been poorly understood. Here we examine the composition of RAG-RSS complexes and the relative contributions of RAG-1 and RAG-2 to heptamer binding. RAG-1 exists as a dimer in complexes with an isolated RSS bearing a 12-bp spacer, regardless of whether RAG-2 is present; only a single subunit of RAG-1, however, participates in nonamer binding. In contrast, multimeric RAG-2 is not detectable by electrophoretic mobility shift assays in complexes containing both RAG proteins. DNA-protein photo-cross-linking demonstrates that heptamer contacts, while enhanced by RAG-2, are mediated primarily by RAG-1. RAG-2 cross-linking, while less efficient than that of RAG-1, is detectable near the heptamer-coding junction. These observations provide evidence that RAG-2 alters the conformation or orientation of RAG-1, thereby stabilizing interactions of RAG-1 with the heptamer, and suggest that both proteins interact with the RSS near the site of cleavage.     

An updated definition of V(D)J recombination signal sequences revealed by high-throughput recombination assays

In the adaptive immune system, V(D)J recombination initiates the production of a diverse antigen receptor repertoire in developing B and T cells. Recombination activating proteins, RAG1 and RAG2 (RAG1/2), catalyze V(D)J recombination by cleaving adjacent to recombination signal sequences (RSSs) that flank antigen receptor gene segments. Previous studies defined the consensus RSS as containing conserved heptamer and nonamer sequences separated by a less conserved 12 or 23 base-pair spacer sequence. However, many RSSs deviate from the consensus sequence. Here, we developed a cell-based, massively parallel assay to evaluate V(D)J recombination activity on thousands of RSSs where the 12-RSS heptamer and adjoining spacer region contained randomized sequences. While the consensus heptamer sequence (CACAGTG) was marginally preferred, V(D)J recombination was highly active on a wide range of non-consensus sequences. Select purine/pyrimidine motifs that may accommodate heptamer unwinding in the RAG1/2 active site were generally preferred. In addition, while different coding flanks and nonamer sequences affected recombination efficiency, the relative dependency on the purine/pyrimidine motifs in the RSS heptamer remained unchanged. Our results suggest RAG1/2 specificity for RSS heptamers is primarily dictated by DNA structural features dependent on purine/pyrimidine pattern, and to a lesser extent, RAG:RSS base-specific interactions.     

Dissociation analysis in polymerase chain reaction and 1X SSC buffer as a prerequisite for selection of 13mer microarray probe sets with uniform hybridization behavior

Homogeneous probe hybridization is a prerequisite for the robust design of microarrays. Elaborate algorithms were developed to select for probe sets with uniform melting temperatures (Tm). However, at least short oligonucleotides (<20 bp) show large variation in the on-chip hybridization efficiency even if designed with state-of-the-art algorithms. This variation can be explained by steric effects and interferences on the solid surface as well as by chemical conditions that may deviate from conditions used to develop the algorithms. We designed 412 random 13mer duplexes to study the differences between the Tm of nearest-neighbor algorithms and the Tm values measured by dissociation analysis in polymerase chain reaction (PCR) and 1X SSC buffer. We tested the effects of theoretical vs empirical Tm values on the hybridization variation of 40 duplexes on-chip. Although the empirical approach resulted in a slightly better prediction of hybridization efficiency, less than one-fifth (17%) of the observed variation could be explained by the factor Tm alone. We conclude that state-of-the-art algorithms can be used for a first selection of short oligonucleotide probes, but that it is then necessary to perform an on-chip selection to obtain a probe set with a uniform hybridization behavior.     

Detection of dairy Leuconostoc strains using the polymerase chain reaction

This paper reports the design of a Leuconostoc -specific oligonucleotide based on 16S rRNA sequence data. When this oligonucleotide was used in a polymerase chain reaction (PCR) in conjunction with an oligonucleotide to a conserved region of the 16S rRNA sequence, a Leuconostoc -specific PCR product of approximately 470 bp was produced. The use of a second oligonucleotide to a conserved region allowed the production of an approximately 350 bp product in all PCRs, acting as a positive control. The PCR procedure described was particularly useful for detecting the presence of Leuconostoc in mixed mesophilic starter cultures. The Leuconostoc -specific oligonucleotide was used also as a specific hybridization probe.     

V(D)J recombination frequencies can be profoundly affected by changes in the spacer sequence

Each V, D, and J gene segment is flanked by a recombination signal sequence (RSS), composed of a conserved heptamer and nonamer separated by a 12- or 23-bp spacer. Variations from consensus in the heptamer or nonamer at specific positions can dramatically affect recombination frequency, but until recently, it had been generally held that only the length of the spacer, but not its sequence, affects the efficacy of V(D)J recombination. In this study, we show several examples in which the spacer sequence can significantly affect recombination frequencies. We show that the difference in spacer sequence alone of two V(H)S107 genes affects recombination frequency in recombination substrates to a similar extent as the bias observed in vivo. We show that individual positions in the spacer can affect recombination frequency, and those positions can often be predicted by their frequency in a database of RSS. Importantly, we further show that a spacer sequence that has an infrequently observed nucleotide at each position is essentially unable to support recombination in an extrachromosmal substrate assay, despite being flanked by a consensus heptamer and nonamer. This infrequent spacer sequence RSS shows only a 2-fold reduction of binding of RAG proteins, but the in vitro cleavage of this RSS is approximately 9-fold reduced compared with a good RSS. These data demonstrate that the spacer sequence should be considered to play an important role in the recombination efficacy of an RSS, and that the effect of the spacer occurs primarily subsequent to RAG binding.     

A functional analysis of the spacer of V(D)J recombination signal sequences

During lymphocyte development, V(D)J recombination assembles antigen receptor genes from component V, D, and J gene segments. These gene segments are flanked by a recombination signal sequence (RSS), which serves as the binding site for the recombination machinery. The murine Jβ2.6 gene segment is a recombinationally inactive pseudogene, but examination of its RSS reveals no obvious reason for its failure to recombine. Mutagenesis of the Jβ2.6 RSS demonstrates that the sequences of the heptamer, nonamer, and spacer are all important. Strikingly, changes solely in the spacer sequence can result in dramatic differences in the level of recombination. The subsequent analysis of a library of more than 4,000 spacer variants revealed that spacer residues of particular functional importance are correlated with their degree of conservation. Biochemical assays indicate distinct cooperation between the spacer and heptamer/nonamer along each step of the reaction pathway. The results suggest that the spacer serves not only to ensure the appropriate distance between the heptamer and nonamer but also regulates RSS activity by providing additional RAG:RSS interaction surfaces. We conclude that while RSSs are defined by a “digital” requirement for absolutely conserved nucleotides, the quality of RSS function is determined in an “analog” manner by numerous complex interactions between the RAG proteins and the less-well conserved nucleotides in the heptamer, the nonamer, and, importantly, the spacer. Those modulatory effects are accurately predicted by a new computational algorithm for “RSS information content.” The interplay between such binary and multiplicative modes of interactions provides a general model for analyzing protein–DNA interactions in various biological systems.     

A cloned 23S rRNA gene fragment of Bacillus subtilis and its use as a hybridization probe of conserved character

Abstract A subclone of plasmid p14B8 containing the major part of a 23S rRNA gene of Bacillus subtilis was constructed and designated pJK1. Labeled plasmid pJK1 could be used as a DNA probe with conserved gene sequences. DNA-DNA hybridization experiments between filter-bound DNA from various bacteria and labeled pJK1 showed a good correlation between oligonucleotide sequence analysis of 16S rRNA and DNA homology values. Application of suboptimal or stringent hybridization conditions and an additional short incubation under the same conditions following hybridization yielded the best data for differentiating organisms related to B. subtilis from less or non-related bacteria.     

DNA hybridization on microparticles: determining capture-probe density and equilibrium dissociation constants

Many DNA-probe assays utilize oligonucleotide-coated microparticles for capture of complementary nucleic acids from solution. During development of these assays, as well as in other particle-based nucleic acid applications, it is useful to know both the amount of duplex formation expected under various experimental conditions and the coating density of the capture oligonucleotide on the particle surface. We examined the simplest form of a DNA-probe microparticle assay: hybridization of a particle-bound capture oligonucleotide to its solution-phase complement. Fluorescein-labeled solution-phase oligonucleotide was hybridized to varying amounts of particles, and the amount of labeled oligonucleotide remaining in solution at equilibrium was measured. We present a simple two-state, all-or-none model for bimolecular hybridization of non-self-complementary sequences that can be used to calculate the equilibrium dissociation constant ( Kd ) from hybridization data. With experimental conditions where both the Kd value and the concentration of capture probe in the reaction are small relative to the concentration of labeled complementary oligonucleotide in the reaction, density of the capture probe on the particle's surface can also be determined. Kd values for particle-based hybridization were different from those obtained from solution-phase thermodynamic parameters. At higher temperatures, hybridization on particles was more efficient than hybridization in solution.     

The role of components of recombination signal sequences in immunoglobulin gene segment usage: a V81x model.

It has long been appreciated that some immunoglobulin (and T-cell receptor) gene segments are used much more frequently than others. The VHsegment V81x is a particularly striking case of overusage. Its usage varies with the stage of B-cell development and with the strain of mice, but it is always high in B cell progenitors. We have found that the coding sequence and the recombination signal sequences (RSS) are identical in five mouse strains, including CAST/Ei, a strain derived from the species Mus castaneus. Thus, the strain differences cannot be attributed to sequences within V81x itself. V81x RSS mediated recombination at rates significantly higher than another VHRSS. Although the V81x nonamer differs at one base pair from the consensus sequence, an RSS with this nonamer and a consensus heptamer recombines as well as the consensus RSS. When the V81x spacer is replaced by that of VA1, the frequency of recombination decreases by approximately 5-fold; thus, the contribution of variation in natural spacers to variability in VHusage in vivo is likely to be more than has been previously appreciated. Furthermore, the contribution of the heptamer and nonamer to differential VHusage in our assay is correlated inversely with their conservation throughout the VHlocus.     

Distinct DNA sequence and structure requirements for the two steps of V(D)J recombination signal cleavage.

Cleavage of V(D)J recombination signals by purified RAG1 and RAG2 proteins permits the dissection of DNA structure and sequence requirements. The two recognition elements of a signal (nonamer and heptamer) are used differently, and their cooperation depends on correct helical phasing. The nonamer is most important for initial binding, while efficient nicking and hairpin formation require the heptamer sequence. Both nicking and hairpin formation are remarkably tolerant of variations in DNA structure. Certain flanking sequences inhibit hairpin formation, but this can be bypassed by base unpairing, and even a completely single-stranded signal sequence is well utilized. We suggest that DNA unpairing around the signal-coding border is essential for the initiation of V(D)J combination.     

Effects of base mismatches on joining of short oligodeoxynucleotides by DNA ligases.

The requirement for Watson-Crick base pairing surrounding a nick in duplex DNA to be sealed by DNA ligase is the basis for oligonucleotide ligation assays that distinguish single base mutations in DNA targets. Experiments in a model system demonstrate that the minimum length of oligonucleotide that can be joined differs for different ligases. Thermus thermophilus (Tth) DNA ligase is unable to join any oligonucleotide of length six or less, while T4 DNA ligase and T7 DNA ligase are both able to join hexamers. The rate of oligonucleotide ligation by Tth DNA ligase increases between heptamer and nonamer. Mismatches which cause the duplex to be shortened by fraying, at the end distal to the join, slow the ligation reaction. In the case of Tth DNA ligase, mismatches at the seventh and eighth position 5'to the nick completely inhibit the ligation of octamers. The results are relevant to mechanisms of ligation.     

A novel method for determining linkage between DNA sequences: hybridization to paired probe arrays

Cooperative hybridization has been used to establish physical linkage between two loci on a DNA strand. Linkage was detected by hybridization to a new type of high-density oligonucleotide array. Each synthesis location on the array contains a mixture of two different probe sequences. Each of the two probes can hybridize independently to a different target sequence, but if the two target sequences are physically linked there is a cooperative increase in hybridization yield. The ability to create and control non-linear effects raises a host of possibilities for applications of oligonucleotide array hybridization. The method has been used to assign linkage in 50:50 mixtures of DNA containing single nucleotide polymorphisms (SNPs) separated by 17, 693, 1350 and 2038 bp and to reconstruct haplotypes. Other potential uses include increasing the specificity of hybridization in mutation detection and gene expression monitoring applications, determining SNP haplotypes, characterizing repetitive sequences, such as short tandem repeats, and aiding contig assembly in sequen-cing by hybridization.     

Construction of physical maps from oligonucleotide fingerprints data.

A new algorithm for the construction of physical maps from hybridization fingerprints of short oligonucleotide probes has been developed. Extensive simulations in high-noise scenarios show that the algorithm produces an essentially completely correct map in over 95% of trials. Tests for the influence of specific experimental parameters demonstrate that the algorithm is robust to both false positive and false negative experimental errors. The algorithm was also tested in simulations using real DNA sequences of C. elegans, E. coli, S. cerevisiae, and H. sapiens. To overcome the non-randomness of probe frequencies in these sequences, probes were preselected based on sequence statistics and a screening process of the hybridization data was developed. With these modifications, the algorithm produced very encouraging results.     

Identification of two topologically independent domains in RAG1 and their role in macromolecular interactions relevant to V(D)J recombination

V(D)J recombination is instigated by the recombination-activating proteins RAG1 and RAG2, which catalyze site-specific DNA cleavage at the border of the recombination signal sequence (RSS). Although both proteins are required for activity, core RAG1 (the catalytically active region containing residues 384-1008 of 1040) alone displays binding specificity for the conserved heptamer and nonamer sequences of the RSS. The nonamer-binding region lies near the N terminus of core RAG1, whereas the heptamer-binding region has not been identified. Here, potential domains within core RAG1 were identified using limited proteolysis studies. An iterative procedure of DNA cloning, protein expression, and characterization revealed the presence of two topologically independent domains within core RAG1, referred to as the central domain (residues 528-760) and the C-terminal domain (residues 761-980). The domains do not include the nonamer-binding region but rather largely span the remaining relatively uncharacterized region of core RAG1. Characterization of macromolecular interactions revealed that the central domain bound to the RSS with specificity for the heptamer and contained the predominant binding site for RAG2. The C-terminal domain bound DNA cooperatively but did not show specificity for either conserved RSS element. This domain was also found to self-associate, implicating it as a dimerization domain within RAG1.     

植物病毒检测芯片的杂交条件优化

利用芯片点样仪将5种侵染马铃薯的病毒/类病毒(苜蓿花叶病毒、黄瓜花叶病毒、黄瓜花叶病毒-卫星病毒、马铃薯病毒Y、马铃薯块茎纺锤状类病毒)的保守区寡核苷酸(Oligonucleotide,oligo)探针和PCR探针点样于玻片,并以植物18S rRNA作为内参照制成基因芯片。研究探针浓度、杂交时间、杂交温度以及点样液对芯片杂交的影响,并验证优化后病毒检测芯片的特异性。结果表明,寡核苷酸探针浓度介于5-20 ?mol/L之间对杂交信号强度影响不大,PCR探针浓度与杂交信号强度间呈线性关系;在45℃杂交4 h时,芯片的杂交信号最强,且该条件下进行杂交对两种探针芯片的影响趋势一致;点样液中以DMSO的杂交效果最好。经过整体条件优化后的两种探针芯片在杂交检测上具有较高的特异性,适于检测植物病毒。     

Recognition sequence of a highly conserved DNA binding protein RBP-J kappa.

DNA binding specificity of the RBP-J kappa protein was extensively examined. The mouse RBP-J kappa protein was originally isolated as a nuclear protein binding to the J kappa type V(D)J recombination signal sequence which consisted of the conserved heptamer (CACTGTG) and nonamer (GGTTTTTGT) sequences separated by a 23-base pair spacer. Electrophoretic mobility shift assay using DNA probes with mutations in various parts of the J kappa recombination signal sequence showed that the RBP-J kappa protein recognized the sequence outside the recombination signal in addition to the heptamer but did not recognize the nonamer sequence and the spacer length at all. Database search identified the best naturally occurring binding motif (CACTGTGGGAACGG) for the RBP-J kappa protein in the promoter region of the m8 gene in the Enhancer of split gene cluster of Drosophila. The binding assay with a series of m8 motif mutants indicated that the protein recognized mostly the GTGGGAA sequence and also interacted weakly with ACT and CG sequences flanking this hepta-nucleotide. Oligonucleotides binding to the RBP-J kappa protein were enriched from a pool of synthetic oligonucleotides containing 20-base random sequences by the repeated electrophoretic mobility shift assay. The enriched oligomer shared a common sequence of CGTGGGAA. All these data indicate that the RBP-J kappa protein recognizes a unique core sequence of CGTGGGAA and does not bind to the V(D)J recombination signal without the flanking sequence.     

A dimer of the lymphoid protein RAG1 recognizes the recombination signal sequence and the complex stably incorporates the high mobility group protein HMG2.

RAG1 and RAG2 are the two lymphoid-specific proteins required for the cleavage of DNA sequences known as the recombination signal sequences (RSSs) flanking V, D or J regions of the antigen-binding genes. Previous studies have shown that RAG1 alone is capable of binding to the RSS, whereas RAG2 only binds as a RAG1/RAG2 complex. We have expressed recombinant core RAG1 (amino acids 384-1008) in Escherichia coli and demonstrated catalytic activity when combined with RAG2. This protein was then used to determine its oligomeric forms and the dissociation constant of binding to the RSS. Electrophoretic mobility shift assays show that up to three oligomeric complexes of core RAG1 form with a single RSS. Core RAG1 was found to exist as a dimer both when free in solution and as the minimal species bound to the RSS. Competition assays show that RAG1 recognizes both the conserved nonamer and heptamer sequences of the RSS. Zinc analysis shows the core to contain two zinc ions. The purified RAG1 protein overexpressed in E.coli exhibited the expected cleavage activity when combined with RAG2 purified from transfected 293T cells. The high mobility group protein HMG2 is stably incorporated into the recombinant RAG1/RSS complex and can increase the affinity of RAG1 for the RSS in the absence of RAG2.     

Libraries for each human chromosome, constructed from sorter-enriched chromosomes by using linker-adaptor PCR.

We describe here the production of complex libraries enriched in sequences from each human chromosome type, starting with only a few thousand sorter-purified chromosomes. In this procedure, DNA is extracted from the sorted chromosomes, digested to completion by using the frequently cutting restriction endonuclease Sau3A1, and ligated, on each end, to an adaptor oligonucleotide. These fragments are then amplified using PCR with a sequence homologous to the adaptor oligonucleotide as a primer. We have used this procedure to produce PCR libraries for each of the 24 human chromosomes. These libraries were characterized by gel electrophoresis and found to be composed of a continuum of sequences ranging in size from a few hundred to approximately 1,000 bp. The libraries, when used as probes for fluorescence in situ hybridization, stained the target chromosomes more or less continuously, even after PCR amplification for more than 200 cycles. These libraries are useful as hybridization probes to facilitate molecular cytogenetic studies and as sources of probes either for identification of polymorphic short tandemly repeated sequences or for development of sequence-tagged sites.