Reciprocal recombination products of VK-JK joining reactions in human lymphoid cell lines

[Antibody engineering: barnase-barstar module as a molecular constructor]

Today, antibody engineering for clinical applications is a rapidly progressing field of science and a big business. The basic functions of an antibody can be spatially differentiated and attributed to various structural domains of a molecule. Therefore, each of them may be an object for engineering with the aim of using a definite antibody function. In this sense, the potential of antibodies is unique. In this article, recent achievements and current problems of antibody engineering are briefly reviewed. The main attention is focused on a molecular constructor that allows for obtaining, with the help of a versatile barnase-barstar module, mono- and multiva-lent miniantibodies and their derivatives with outlined properties.

The reading frame BPLF1 of Epstein-Barr virus: a homologue of herpes simplex virus protein VP16

The open reading frame BPLF1 of Epstein-Barr virus (EBV) shows homology to the Herpes simplex virus 1 (HSV1) protein VP16. This protein is a structural tegument component playing a pivotal role for HSV replication as trans-activator of viral immediate-early genes. An EBV gene with a comparable function has not been described so far. However, computer analysis indicated that BPLF1 may be a tegument protein homologous to VP16. This is the first report on the characterisation of the BPLF1 gene, its transcription, and expression of its gene product in vitro and in vivo. Using RT-PCR and Northern blot assays we demonstrated that the BPLF1 gene belongs to the class of late lytic cycle genes of EBV. Besides a full length transcript of 9.5 kb also a polyadenylated transcript of approximately 3 kb is synthesised. However, no consensus splice sites could be identified. Northern blot experiments using partially overlapping probes and sequencing of a BPLF1-specific cDNA revealed 1,550 nucleotides of the BPLF1 transcript, collinear in sequence with the viral genome from position 64547 to 66097. A recombinant Western blot assay detected BPLF1-specific antibodies in seropositive individuals, in particular in cases with elevated viral replication like infectious mononucleosis, chronic active infection, and nasopharyngeal carcinoma. This demonstrated expression of the BPLF1 protein in vivo. Thus, experimental data and computer analysis strongly support the hypothesis of BPLF1 being a tegument protein of the EBV homologous to VP16 of HSV1 and ORF22 of Varicella zoster virus.

Comparison of human germ-line kappa gene sequences to sequence data from the literature

The question of which germ-line V kappa genes are expressed was studied by sequencing 70 different cDNA clones from a human spleen library and one clone from a fetal liver library. The sequences were compared to a data base containing all germ-line V kappa gene and pseudogene sequences. In addition, 51 rearranged genomic V kappa genes, 170 cDNA and 74 kappa proteins from the literature were assigned to specific germ-line V kappa genes and included in the comparisons. Not all the known, potentially functional V kappa genes were found to be expressed, while some genes with minor defects are. The total number of expressed genes is smaller than expected: so far 21 germ-line genes and 5 pairs of duplicated identical genes are known to be transcribed. The corresponding numbers for rearranged genomic V kappa genes and kappa proteins are 17 plus 4 and 7 plus 7, respectively. A second aim of the study was to find out whether the expressed repertoire contains derivatives of germ-line V kappa genes still missing in our data base; no evidence for the existence of such genes was found. Several cDNA clones contained additional nucleotides between the V kappa and J kappa gene segments, which may be germ-line derived, inserted by terminal deoxynucleotidyl transferase or introduced by other mechanisms. Somatic gene conversion seems not to play a major role in creating the human kappa gene diversity. Various aspects of the hypermutation of kappa genes are discussed and the formation of block mutations, i.e. the alterations of two or more adjacent nucleotides is stressed as a remarkable feature of the process.

The human immunoglobulin kappa locus. Characterization of the partially duplicated L regions

The L regions are parts of the C kappa proximal (p) and distal (d) copies of the human immunoglobulin kappa locus and are therefore called the Lp and Ld regions. The two regions with their 25 V kappa genes and pseudogenes have now been cloned, thus completing the cloning of the kappa locus. Lp has been linked to the neighboring Ap and B regions, while Ld was linked to Ad. There is good evidence that at the other side of Ld, i.e. towards the centromere, the end of the locus has been reached. Most of the cloning and linking was achieved by chromosomal walking, employing cosmid and phage lambda clones. No such clones could be found for three small gaps. Two of them were closed by a polymerase chain reaction strategy; the third one was characterized by genomic blot hybridization experiments and eventually bridged by a yeast artificial chromosome clone. Early in evolution, a stretch of about 25 kb which comprised three V kappa genes near the 5' end of the L region precursor must have been duplicated, such that the later duplication of large parts of the kappa locus resulted in the appearance of two very similar three-gene regions in each, Lp and Ld. Two deletions in the central parts of the L regions, on the other hand, must have occurred after the duplication of the locus, since they are found in Lp and Ld in different positions.

Ongoing V kappa-J kappa recombination after formation of a productive V kappa-J kappa coding joint

V kappa genes of man can recombine with the J kappa gene segments either by an inversion or by a deletion mechanism. Back-to-back fusion products of the respective recombination signal sequences (signal joints) are retained on the chromosome after the formation of a V kappa-J kappa coding joint by an inversion. Our knowledge of the structure of the human kappa locus and the application of the polymerase chain reaction allowed us now to establish a direct relationship between different kappa recombination products in the lymphoid cell line JI. Two consecutive inversions fully explain the existence of two coding joints and two signal joints on the same chromosome of this cell line. Although the initially formed coding joint is productively rearranged and expressed, a second V kappa-J kappa rearrangement took place which leads to an aberrant joint. In this process a J kappa gene segment of the signal joint that had been created in the first V kappa-J kappa joining was used as the recombination target. The sequence of the two rearrangements is unequivocal since a product of the first (productive) reaction is a partner in the second (aberrant) one.

Equilibrium binding of thrombin to recombinant human thrombomodulin: effect of hirudin, fibrinogen, factor Va, and peptide analogues

Thrombomodulin is an endothelial cell surface receptor for thrombin that acts as a physiological anticoagulant. The properties of recombinant human thrombomodulin were studied in COS-7, CHO, CV-1, and K562 cell lines. Thrombomodulin was expressed on the cell surface as shown by the acquisition of thrombin-dependent protein C activation. Like native thrombomodulin, recombinant thrombomodulin contained N-linked oligosaccharides, had Mr approximately 100,000, and was inhibited or immunoprecipitated by anti-thrombomodulin antibodies. Binding studies demonstrated that nonrecombinant thrombomodulin expressed by A549 carcinoma cells and recombinant thrombomodulin expressed by CV-1 and K562 cells had similar Kd's for thrombin of 1.3 nM, 3.3 nM, and 4.7 nM, respectively. The Kd for DIP-thrombin binding to recombinant thrombomodulin on CV-1(18A) cells was identical with that of thrombin. Increasing concentrations of hirudin or fibrinogen progressively inhibited the binding of 125I-DIP-thrombin, while factor Va did not inhibit binding. Three synthetic peptides were tested for ability to inhibit DIP-thrombin binding. Both the hirudin peptide Hir53-64 and the thrombomodulin fifth-EGF-domain peptide Tm426-444 displaced DIP-thrombin from thrombomodulin, but the factor V peptide FacV30-43 which is similar in composition and charge to Hir53-64 showed no binding inhibition. The data exclude the significant formation of a ternary complex consisting of thrombin, thrombomodulin, and hirudin. These studies are consistent with a model in which thrombomodulin, hirudin, and fibrinogen compete for binding to DIP-thrombin at the same site.

Megabase inversions in the human genome as physiological events

The genes of the immunoglobulin kappa light chains are assembled during B-cell differentiation by somatic recombination of one of the V kappa (variable) gene segments and the J kappa-C kappa (joining-constant) gene region. This seems to occur by deletion of the DNa between V kappa and J kappa-C kappa if they are arranged in germ-line DNA in the same transcriptional polarity or by inversion of a fragment containing the V kappa gene if the polarities are opposite. We have cloned 75 V kappa genes and pseudogenes of the human kappa locus and linked them in large contigs. There seem to be no more than 85 such genes, less than 50 of these being potentially functional. Thirty-eight of the cloned genes have the same transcriptional polarity as J kappa-C kappa and are part of the so-called J kappa proximal cluster; 35 genes in a distal cluster (the result of a duplication event in evolution) have a polarity that was suggested to be opposite to the one of J kappa-C kappa. We now show that the V kappa genes of the proximal cluster rearrange by a deletion mechanism whereas the others join J kappa-C kappa by inversion of megabase-sized DNA fragments.

Junctional sequences of T cell receptor gamma delta genes: implications for gamma delta T cell lineages and for a novel intermediate of V-(D)-J joining

Nucleotide sequences of a large number of V-(D)-J junctions of T cell receptor (TCR) gamma and delta genes show that most fetal thymocytes express on their surface one of just two gamma delta TCRs known to be expressed by epidermal gamma delta T cells (s-IEL) or intraepithelial gamma delta T cells associated with female reproductive organs (r-IEL). In contrast, gamma delta TCRs expressed on adult thymocytes are highly diverse as a result of multiple combinations of gene segments as well as junctional deletions and insertions, indicating that developmental time-and cell lineage-dependent mechanisms exist that control the extent of gamma delta TCR diversity. In addition, this study revealed a new type of junctional insertion (P nucleotides), which led to a new model of V-(D)-J joining generally applicable to immunoglobulin and TCR genes.

Excision products of immunoglobulin gene rearrangements

We have isolated circular DNAs from splenocytes of euthymic and athymic mice, and prepared the DNA libraries of 1.5 X 10(6) clones. Hundreds of clones homologous to immunoglobulin (Ig) heavy chain segments (DSP2 and DQ52-JH) or light chain segments (J kappa and J lambda) have been identified. Southern hybridization predicted that three of 12 euthymic mouse clones homologous to DQ52-JH and four of 10 athymic mouse clones homologous to DSP2 contained reciprocal recombination products of D-J joining. Some of these clones were characterized by sequencing: two clones contained the precise excision product of the recombination of a DSP2 segment with either JH2 or JH3 segment; two clones showed imprecise ligation of the DSP2-JH2 coding joint and precise ligation of the DFL16.1-JH3 reciprocal joint in the same molecule. They seem to represent a replacement of the pre-existing DSP2-JH2 rearrangement by joining an upstream DFL16 segment to a downstream JH3 segment. The presence in extrachromosomal DNA of a reciprocal recombination product of DH-JH joining is consistent with the view that immunoglobulin genes, like T cell receptor (TCR) genes, can be rearranged in B cell lineage by the looping-out and excision of chromosomal DNA.

Isolation of an IgH gene circular DNA clone from human bone marrow

Circular DNA was obtained from human bone marrow. Then a phage library was prepared and screened by use of two probes of the IgH gene; 5'-DHQ52, containing the 5' flanking region of DHQ52, and JH4.3, containing the sequence from JH3 to the 3' flanking region of JH6. One clone, HBMC-1, that was DHQ52+JH4.3- was obtained. HBMC-1 had the germline IgH region upstream of JH1 and the 3' flanking region of DXP1. A recombination signal sequence flanking the 5' side of the JH1 segment was attached to the recombination signal sequence flanking the 3' side of DXP1 forming a head-to-head structure of two 7mers with 10 nucleotides in-between. HBMC-1 is thus considered to be a circular DNA deleted as a consequence of DXP1-JH1 joining of the IgH gene.

Lymphoid V(D)J recombination: nucleotide insertion at signal joints as well as coding joints

The coding regions of antigen receptor genes assembled by variable-diversity-joining region [V(D)J] recombination are known in many cases to have undergone deletions of several nucleotides and also to contain insertions of noncoded nucleotides at the recombined junction (the coding joint). By using extrachromosomal recombination substrates to transfect lymphoid cell lines, we show that the signal joint (the fusion of the corresponding recognition signal sequences) can also contain insertions; however, nucleotide loss from the signals is very rare. The frequency of nucleotide addition varies among pre-B-cell lines in a manner proportional to their content of terminal deoxynucleotidyltransferase. We also find frequent nucleotide additions (and deletions) at coding joints, but in this case there is no strong correlation with the level of terminal deoxynucleotidyltransferase activity. Inserts at both signal and coding joints are rich in G + C, consistent with the base utilization preference of this enzyme.

Structure of extrachromosomal circular DNAs excised from T-cell antigen receptor alpha and delta-chain loci

Small polydisperse circular (spc) DNA was isolated from mouse thymocytes, fragmented by HindIII digestion and cloned into the vector. Sixty DNA clones were randomly selected from the 10,400 phage library. The average size of insert was one-fifth of the original circular molecule. Twenty spc-DNA clones were homologous to DNA probes derived from T-cell antigen receptor (TCR) alpha-chain loci. We have characterized nine clones by DNA sequencing; they contain new germline sequences of the TCR alpha-chain variable (V alpha) and joining (J alpha) gene segments and the products out of the recombination of a V alpha with a J alpha gene segment. An additional four spc-DNA clones carried a new rearranging gene of the TCR delta-chain that is located between V alpha and J alpha genes. At least nine of 60 DNA clones carried the recombination junction of a heptamer-heptamer head-to-head structure expected from an excised product of V-J joining. This shows that most extrachromosomal circular DNAs in the thymus are formed by a sequence-dependent recombination mechanism. We suggest that a functional T-cell receptor V alpha gene can be constructed by somatic random rearrangements through successive looping-out, excision and deletion.

The J kappa proximal region of the human K locus contains three uncommon V kappa genes which are arranged in opposite transcriptional polarities

The structure of one of the V kappa gene-containing regions of the locus coding for the human immunoglobulin light chains of the kappa type is described. This so-called B region contains three genes: B1, B2 and B3. According to its sequence B1 is a pseudogene which does not fit well into the present subgroup classification. In lymphoid cell lines the B1 gene region is frequently deleted. B2 and B3 are the previously reported EV15 and V kappa IV genes. The transcriptional polarity of the B1 gene is found to be opposite to one of the B2 and B3 genes. This observation together with the fact that the B region is proximal to the J kappa C kappa gene segment leads to the conclusions to the mechanism of the V kappa-J kappa recombination and allows us to explain the formation of the recombination products in a particular cell line by two consecutive inversions.

Rearrangement of exogenous immunoglobulin VH and DJH gene segments after retroviral transduction into immature lymphoid cell lines

A model substrate for the joining of Ig VH and DJH elements has been constructed in a retroviral vector carrying a selectable marker whose expression is independent of the arrangement of the resident Ig gene segments. The substrate was introduced into lymphoid and nonlymphoid cells, and site-specific recombination between the VH and DJH elements was monitored by a direct hybridization assay. Joining of the exogenous gene segments was observed in cell lines representative of three distinct stages in early B cell differentiation. Rearrangement was not observed in three cell lines derived from mature B cells, or in a fibroblastoid cell line. The VH and DJH elements were initially arranged so that the VH-DJH junction and the recombined flanking sequences could be recovered after rearrangement. By molecular cloning and nucleotide sequence determination, VH-DJH junctions formed upon rearrangement of the substrate were found to resemble closely similar junctions in functional H chain genes. The joining of VH and DJH elements was observed to be asymmetric; loss of nucleotides occurred at the coding joints, but not at the junctions between flanking sequences. Our results suggest that Ig H and L chain gene segments are joined by a common mechanism that is more active in B cell precursors than in mature B cells. These observations provide further evidence that the rearrangement of Ig gene segments occurs by a nonreciprocal recombinational mechanism. The model substrate described here is likely to be of use in defining the nucleotide sequences that mediate rearrangement and in examining the developmental specificity of this process.

Linking of the human immunoglobulin VK and JKCK regions by chromosomal walking

The linking of the human VK and JKCK gene regions (abbreviations in ref. 1) by chromosomal walking is reported. Hybridization experiments with the DNA of a somatic cell hybrid containing the region between JKCK and the telomer show that none of the major VK gene clusters is located downstream of CK. The distance between the VK and JK genes was found to be 23 kb. The JK proximal VK gene is the B3 gene which is the only representative of subgroup IV in the genome. This gene and the neighbouring B2 gene (accompanying paper) are arranged in opposite orientation to JKCK and can therefore rearrange only by an inversion mechanism. This finding is used, together with previous data, to delineate the rearrangement processes in the Burkitt lymphoma derived cell line BL21 as comprising an inversion in the first and a deletion in the second step.

Physical map of the human immunoglobulin K locus and its implications for the mechanisms of VK-JK rearrangement

Genomic regions containing numerous cloned VK genes (abbreviations in ref. 2) were investigated by pulsed-field gel electrophoresis. 31 and 32 genes were linked within 1.0 and 1.3 Mb NotI fragments, respectively; the latter fragment includes also the JKCK gene segment. A 0.25 Mb NotI fragment comprises further 10 VK genes. Since the transcriptional polarities of the VK genes within the genomic regions are known the linking of the regions allows us now to answer unequivocally some longstanding questions concerning the mechanism of VK-JK rearrangement. The VK genes of the 1.3 Mb NotI fragment except for the two JK proximal ones (accompanying paper) are arranged in the same transcriptional polarity as JKCK and therefore must rearrange by a deletion mechanism. The VK genes of the 1.0 Mb NotI fragment which has not yet been linked to VKJK have identical polarity within the fragment. They should be arranged in opposite polarity to JKCK since reciprocal recombination products derived from them are known to exist; such recombination products must have been formed by inversion of oppositely oriented gene segments.

N segment insertion and region-directed somatic hypermutation in a kappa gene of a t(2;8) chromosomal translocation

A detailed molecular analysis of both reciprocal recombination products of the variant t(2;8) chromosomal translocation of the Burkitt lymphoma derived cell line JI and their germline counterparts was carried out. The breakpoint on chromosome 8 is localized 28 kb to the 3' side of the c-myc protooncogene, the breakpoint on chromosome 2 was found to be within an aberrantly rearranged VK gene (abbreviations ref. 1). Novel features of the immunoglobulin moiety involved in this process include insertion of extra nucleotides in the V-J junction which have the characteristics of a N segment as it has been found up to now only in heavy chain and T cell receptor genes; the occurrence of somatic mutations in 8q+ and not in 2p-. These data allow a reconstruction of the course of events in the cell line JI; remarkable sequence regularities at the chromosomal breakpoints consisting of symmetrically placed dinucleotides and elements related to the hepta- and nonanucleotide recombinase recognition sequences are discussed in the context of the translocation mechanism.

T cell receptor beta gene sequences in the circular DNA of thymocyte nuclei: direct evidence for intramolecular DNA deletion in V-D-J joining

We have identified circular DNA containing T cell receptor (TCR) beta gene sequences in mouse thymocytes, thereby providing direct evidence for the intramolecular DNA deletion model of V-D-J joining in TCR beta genes. Two types of excision products of V-D-J joining have been identified. Type I, a circular reciprocal recombinant of normal V-D or D-J joining, contains a 7mer-7mer head-to-head structure expected from an excised product of normal V-D or D-J joining. Type II contains a D beta 2-J beta 1 structure on the circular DNA; the recombination event producing this molecule occurs between an upstream J and a downstream D segment, probably leaving the reciprocal 7mer-7mer structure on the chromosome. Some type I molecules seem to represent excision products of secondary joining after formation of the first D-J or V-D-J structure. The recombination mechanism that generates the circular DNA is discussed.