Attenuation of cytomegalovirus-induced endothelial intercellular adhesion molecule-1 mRNA/protein expression and T lymphocyte adhesion by a 2'-O-methoxyethyl antisense oligonucleotide.

BACKGROUND: Intercellular adhesion molecule-1 (ICAM-1) is strongly induced under inflammatory conditions associated with allograft rejection, thereby promoting leukocyte recruitment and activation at the site of inflammation. Enhancement of ICAM-1 expression can also be the result of viral infection, in particular human cytomegalovirus (CMV), a frequent source of complications in the transplant recipient. In vitro studies have shown that CMV infection of endothelial cells (EC) results in the direct enhancement of ICAM-1 expression and consequent leukocyte adhesion/activation suggesting mechanisms by which CMV exacerbates graft vascular disease. Although treatment of EC with ICAM-1-specific antisense oligonucleotides has been shown to attenuate ICAM-1 induction under simulated inflammatory conditions (i.e., TNF-alpha), no studies have addressed their effectiveness on virally-induced ICAM-1 expression. RESULTS: In the current investigation, we show that the progressive increase in endothelial ICAM-1 protein expression that follows inoculation with CMV correlates with a progressive accumulation of ICAM-1 mRNA. Furthermore, we demonstrate that treatment of EC with a partially 2'-O-methoxyethyl modified ICAM-1-specific antisense oligonucleotide before viral inoculation significantly reduces CMV-associated induction of ICAM-1 protein and mRNA expression. Finally, we show that antisense-mediated attenuation in ICAM-1 expression results in a significant reduction of T lymphocyte adhesion to CMV-infected EC monolayers, an interaction that has been implicated in allogeneic T lymphocyte activation, in viral transmission to transiently adherent leukocytes and subsequent hematogenous dissemination. CONCLUSIONS: These findings demonstrate for the first time that antisense oligonucleotides can effectively reverse virally-induced host cellular protein expression, specifically ICAM-1, as well as consequent T lymphocytes adhesion, thus broadening the potential clinical utility of antisense oligonucleotides.

Suppression of src-induced transformed phenotype by expression of tropomyosin-1.

Suppression of high M(r) tropomyosins (TMs) is a common feature of transformed cells. Previous work from this laboratory has demonstrated that the isoform 1 of TM, TM1, acts as an anti-oncogene in ras-transformed murine fibroblasts. In this study, we have investigated whether TM1 is a ras-specific suppressor, or a general suppressor protein of the cellular transformation. V-src transformed fibroblasts, which express decreased TM1, were transduced with a full-length cDNA to overexpress TM1. Both the control and the transduced cells expressed v-src kinase at comparable levels. TM1 expressing (src-T1) cells grew at a lower rate in monolayer, exhibited well spread, flat morphology than the control cells. Enhanced expression of TM1 resulted in improved microfilamental architecture. More significantly, src-T1 cells completely failed to grow under anchorage independent conditions. These data demonstrate that TM1 is as an anti-oncogene of functionally diverse oncogenes, and it is a class II tumor suppressor protein.

The human elk-1 gene family: the functional gene and two processed pseudogenes embedded in the IgH locus.

Elk-1 is a transcription factor whose activation by several mitogen-activated protein kinases (MAPKs) mediates the immediate early responses of the c-fos promoter to growth factors and other stimuli. Here, we report the structure of the human elk-1 gene, which we have localized about 6.5kb upstream of the properdin gene on the X chromosome. The coding sequence is interrupted by four introns; two additional introns lie within the 5' untranslated region. We have also found two elk-1-related processed pseudogenes in the human immunoglobulin heavy chain (IgH) locus, accounting for 'elk-2' previously visualized by in-situ hybridization at 14q32. A processed pseudogene evidently inserted downstream of a primordial immunoglobulin Calpha gene and was duplicated along with part of the IgH locus. Gene/pseudogene sequence comparisons and Southern blots of primate DNAs suggest that both the pseudogene insertion and the locus duplication occurred between about 30 and 60 million years ago.

CD40 ligand and appropriate cytokines induce switching to IgG, IgA, and IgE and coordinated germinal center and plasmacytoid phenotypic differentiation in a human monoclonal IgM+IgD+ B cell line.

B lymphocytes are induced to undergo Ig class switching and a complex phenotypic differentiation by the milieu of the germinal center. Partly as a result of the lack of a suitable in vitro B cell model, the relationship between these processes in the humans has never been formally established in vitro. We have identified a human monoclonal B cell line, CL-01, that expresses surface IgM and IgD and, upon induction with CD40 ligand, IL-4, and IL-10, switches to all seven downstream isotypes, showing typical DNA switch recombination preceded by germline transcription of targeted CH regions. In CL-01 cells, switch-inducing stimuli trigger concomitant changes in expression of surface IgD, CD23, CD38, and CD77 that parallel those reported in ex vivo isolated tonsillar centroblasts, centrocytes, and memory B cells. Eventually, in the presence of IL-6, CL-01 cells express CD56 and accumulate cytoplasmic IgG and IgA, both traits of plasmacytoid differentiation. Analysis of transcription and recombination of the Ig H locus in sorted CL-01 cells suggest that Ig class switching begins in centroblasts, it extends to all isotypes in centrocytes, and it is extinct in memory B cells. Thus, we have induced coordinated Ig class switching, progression through germinal center phenotypic stages, and differentiation to memory B cells and plasma cells at the level of a single B clonotype. Our data suggest that these processes are likely regulated by a common maturation program, the activation of which may require CD40 ligand, IL-4, IL-10, and IL-6 only.

Enhancer complexes located downstream of both human immunoglobulin Calpha genes.

To investigate regulation of human immunoglobulin heavy chain expression, we have cloned DNA downstream from the two human Calpha genes, corresponding to the position in the mouse IgH cluster of a locus control region (LCR) that includes an enhancer which regulates isotype switching. Within 25 kb downstream of both the human immunoglobulin Calpha1 and Calpha2 genes we identified several segments of DNA which display B lymphoid-specific DNase I hypersensitivity as well as enhancer activity in transient transfections. The corresponding sequences downstream from each of the two human Calpha genes are nearly identical to each other. These enhancers are also homologous to three regions which lie in similar positions downstream from the murine Calpha gene and form the murine LCR. The strongest enhancers in both mouse and human have been designated HS12. Within a 135-bp core homology region, the human HS12 enhancers are approximately 90% identical to the murine homolog and include several motifs previously demonstrated to be important for function of the murine enhancer; additional segments of high sequence conservation suggest the possibility of previously unrecognized functional motifs. On the other hand, certain functional elements in the murine enhancer, including a B cell-specific activator protein site, do not appear to be conserved in human HS12. The human homologs of the murine enhancers designated HS3 and HS4 show lower overall sequence conservation, but for at least two of the functional motifs in the murine HS4 (a kappaB site and an octamer motif ) the human HS4 homologs are exactly conserved. An additional hypersensitivity site between human HS3 and HS12 in each human locus displays no enhancer activity on its own, but includes a region of high sequence conservation with mouse, suggesting the possibility of another novel functional element.

Cleavage of oligodeoxyribonucleotides from controlled-pore glass supports and their rapid deprotection by gaseous amines.

A novel method for the deprotection of oligodeoxyribonucleotides has been developed. Gaseous amines such as ammonia or methylamine were employed under pressure to achieve mild and rapid deprotection conditions. For example, oligodeoxyribonucleotides having a (tert-butyl)phenoxyacetyl group for the protection of the exocyclic amino function of cytosine, adenine and guanine were released from controlled-pore glass supports and fully deprotected by ammonia or methylamine under gas phase conditions, at room temperature, within 35 or 2 min respectively.

Interleukin-10 induces immunoglobulin G isotype switch recombination in human CD40-activated naive B lymphocytes.

Upon activation, B lymphocytes can change the isotype of the antibody they express by immunoglobulin (Ig) isotype switch recombination. In previous studies on the regulation of human IgG expression, we demonstrated that interleukin 10 (IL-10) could stimulate IgG1 and IgG3 secretion by human CD40-activated naive (sIgD+) tonsillar B cells. To assess whether IL-10 actually promotes the DNA recombination underlying switching to these isotypes, we examined the effect of IL-10 on the generation of reciprocal products that form DNA circles as by-products of switch recombination. The content of reciprocal products characteristic of mu-gamma recombination was elevated after culture of CD40-activated tonsillar sIgD+ B cells with either IL-4 or IL-10, although high levels of IgG secretion were observed only with IL-10. Unlike IL-4, IL-10 did not induce reciprocal products of mu-epsilon and gamma-epsilon switch recombination. These results demonstrate that IL-10 promotes both switching to gamma and IgG secretion.

Human Ig S gamma regions and their participation in sequential switching to IgE.

The Ig isotype switch from IgM to IgE is accompanied by a DNA recombination that joins S mu, the highly repetitive "switch" region upstream of the C mu gene, to the S epsilon region upstream of C epsilon, thereby creating a composite S mu-S epsilon region. In human B cells cultured in vitro with IL-4 to promote the switch to IgE, we previously described evidence for S mu-S gamma-S epsilon structures, suggesting that some B cells can switch sequentially from mu to gamma and then to epsilon; similar sequential switching to epsilon occurs routinely in the mouse. To identify which of the four human gamma genes might be involved in this mu-gamma-epsilon switching pathway, we cloned and analyzed nine S mu-S gamma-S epsilon composite switch regions and studied S epsilon-S gamma junctions from reciprocal deletion circles. Since only the S gamma 4 sequence had previously been described, our investigation required determination of the germline S gamma 1, S gamma 2, and S gamma 3 sequences. This analysis showed that S gamma 1 is the longest and most highly repetitive switch region, including nearly identical 79-bp repeats partially homologous to the 49-bp repeat of murine S gamma sequences. Of nine cloned chromosomal S mu-S gamma-S epsilon junctions, seven were derived from S gamma 1, and one each from S gamma 3 and S gamma 4 (both of which were in inverted orientation). Analysis of reciprocal S epsilon-S gamma junctions demonstrated contributions of S gamma 1, S gamma 2, and S gamma 4. Thus, all four of the human gamma loci can participate in sequential switching to IgE, arguing against a model of directed switching from a specific subtype, such as was proposed in the murine system.

Human polyreactive and monoreactive antibodies: effect of glycosylation on antigen binding.

The present experiments were initiated to determine whether the carbohydrate portions of antibody molecules contribute to polyreactivity. Cell lines making human monoclonal polyreactive or monoreactive antibodies of the immunoglobulin (Ig) M, IgG and IgA isotypes were treated with tunicamycin to block N-linked glycosylation of the proteins. Analysis of the secreted native and non-glycosylated proteins revealed a > 95% inhibition of [3H]mannose incorporation. Electrophoresis on sodium dodecyl sulphate-polyacrylamide gels of the proteins from tunicamycin-treated cells showed increased mobility and the absence of [3H]mannose incorporation of the immunoglobulin heavy chains, consistent with the lack of glycosylation. The native and non-glycosylated antibodies were then tested for their ability to bind different antigens. Despite the lack of glycosylation, both polyreactive and monoreactive antibodies bound to antigens with little if any loss of reactivity or specificity. It is concluded that the carbohydrate moieties do not contribute significantly to polyreactivity.

Half-life of polyreactive antibodies.

Monoclonal polyreactive antibodies bind to a variety of self and foreign antigens. In contrast, monoclonal monoreactive antibodies bind to a single or restricted number of known antigens. The rate at which polyreactive antibodies are removed from the circulation compared to monoreactive antibodies has not been determined. In the present experiments, human monoclonal polyreactive and monoreactive antibodies of different isotypes were injected intravenously into mice and the clearance from the circulation was determined. The half-life of polyreactive IgM, IgA, and IgG antibodies was 8.0, 8.2, and 9.8 hr, respectively, compared to 35.4, 26.6, and 280 hr for monoreactive IgM, IgA, and IgG antibodies, respectively. Examination of tissue sections from animals given intravenous antibody showed substantial deposition of polyreactive, but not monoreactive, antibodies in several organs, the liver being the principal site of deposition. It is concluded that polyreactive antibodies are cleared from the circulation substantially faster than monoreactive antibodies.

Structure of the VH and VL segments of polyreactive and monoreactive human natural antibodies to HIV-1 and Escherichia coli beta-galactosidase.

B lymphocytes committed to the production of antibodies binding to antigens on pathogenic bacteria and viruses (natural antibodies) are common components of the normal human B cell repertoire. A major proportion of natural antibodies is capable of binding multiple antigens (polyreactive antibodies). Using B cells from three HIV-1 seronegative healthy subjects, and purified HIV-1 and beta-galactosidase from Escherichia coli as selecting antigen, we generated three natural IgM mAb to HIV-1 and a natural IgM mAb to beta-galactosidase. The three HIV-1-selected antibodies (mAb102, mAb103, and mAb104) were polyreactive. They bound with different affinities (Kd = 10(-6) to 10(-8) M) to the HIV-1 envelope gp160, the p24 core protein, and the p66 reverse transcriptase, but not to the 120 glycosylated env protein. They also bound to beta-galactosidase (Kd approximately 10(-7) M), tetanus toxoid, and various various self antigens. In contrast, the natural mAb selected for binding to beta-galactosidase (mAb207.F1) was monoreactive, in that it bound with a high affinity (Kd < 10(-8) M) to this antigen, but to none of the other antigens tested, including HIV-1. Structural analysis of the VH and VL segments revealed that the natural mAb utilized three segments of the VHIV gene family and one of the VHIII family, in conjunction with VL segments of the V lambda I, V lambda II, V lambda III, or V kappa IV subgroups. In addition, the natural mAb VH and VL segments were in unmutated or virtually unmutated (germline) configuration, including those of the monoreactive mAb207.F1 to beta-galactosidase, and were identical or closely related to those utilized by specific autoantibodies or specific antibodies to viral and/or bacterial pathogens. Thus, the present data show that both polyreactive and monoreactive natural antibodies to foreign antigen can be isolated from the normal human B cell repertoire. They also suggest that the VH and VL segments of not only polyreactive but also monoreactive natural antibodies can be encoded in unmutated or minimally mutated genes, and possibly provide the templates for the specific high affinity antibodies elicited by self or foreign antigens.

Recombination activating genes-1 and -2 of the rabbit: cloning and characterization of germline and expressed genes.

The recombination activating genes RAG-1 and RAG-2 appear to be necessary components of the machinery needed for the Ig or TCR gene rearrangements that occur in developing B and T lymphocytes. In addition RAG-2 has been implicated in the process of V-gene diversification by somatic gene conversion in the chicken. Because gene conversion may be an important mechanism for V-gene diversification in the rabbit, we cloned the rabbit RAG locus and characterized the coding regions of the genomic RAG-1 and RAG-2. In addition, we sequenced cDNAs encompassing the RAG-2 coding region, part of the RAG-2 5' untranslated region and a 967 bp fragment of cDNA from the RAG-1 coding region. Northern analysis revealed a RAG-1 mRNA of 6.6 kb which is similar in size to the RAG-1 mRNA reported previously for other species, and a major species of RAG-2 mRNA of 4.4 kb, which is larger than that from the mouse (2.2 kb). Analysis of the genomic clones showed that, as in other species, the RAG-1 and RAG-2 genes are oriented so as to be convergently transcribed. The DNA sequence analysis showed that the rabbit RAG-1 coding region is 91, 85 and 72% identical to human, mouse and chicken, respectively. The deduced RAG-1 protein sequence for rabbit is 93, 90 and 78% identical to human, mouse and chicken. Comparison of the rabbit RAG-2 coding region revealed 90, 87 and 71% identity to human, mouse and chicken, respectively, at the nucleotide level, and 91, 90 and 72% at the protein level. Although there is considerable conservation of sequence between species, we obtained evidence for allelic forms of the rabbit RAG locus both by Southern analyses and by sequencing. A remarkable degree of polymorphism was found in our rabbit colonies, particularly in the region 3' of the rabbit RAG-2 coding region. A 5' cDNA probe hybridized with one or more additional fragments that are not detected with the coding region probes, suggesting that the 5' cDNA sequence results from splicing of one or more upstream exons.

Clonal analysis of a human antibody response. II. Sequences of the VH genes of human IgM, IgG, and IgA to rabies virus reveal preferential utilization of VHIII segments and somatic hypermutation.

The construction of mAb-producing cell lines has been instrumental in dissecting the fine specificities and genetic makeup of murine antibodies to exogenous and self Ag. The analysis of the genetic composition of human antibody responses has been hampered by the difficulty in generating human mAb of predetermined class and specificity. Using B lymphocytes from three healthy subjects vaccinated with inactivated rabies virus vaccine, we generated nine human mAb binding to rabies virus and analyzed the genes encoding their VH regions. Six mAb (five IgG1 and one IgA1) were monoreactive and displayed high affinities for rabies virus Ag. The remaining three mAb (IgM) were polyreactive and displayed lower affinities for rabies virus Ag. Seven mAb (3 IgG1, the IgA1, and the three IgM) utilized VH gene segments of the VHIII family. The remaining two IgG1 mAb utilized gene segments of the VHI and VHIV families. Of the seven expressed VHIII family genes, three were similar to the germline VH26c gene, two to the germline 22-2B gene, one to the germline H11 gene, and one to the germline 8-1B gene. The expressed VHI and VHIV genes displayed sequences similar to those of the germline hv1263 and V71-4 genes, respectively. The VH genes of all but one mAb (mAb55) resembled those that are predominantly expressed by C mu + clones in human fetal liver libraries. When compared with known germline sequences, the VH genes of the rabies virus-binding mAb displayed variable numbers of nucleotide differences. That such differences resulted from a process of somatic hypermutation was formally demonstrated (by analyzing DNA from polymorphonuclear neutrophil of the same subject whose B lymphocytes were used for the mAb generation) in the case of the VH gene of the high affinity (anti-rabies virus glycoprotein) IgG1 mAb57 that has been shown to efficiently neutralize the virus in vitro and in vivo. The distribution, mainly within the complementarity determining regions, and the high replacement-to-silent ratio of the mutations, were consistent with the hypothesis that the mAb57-producing cell clone underwent a process of Ag-driven affinity maturation through clonal selection. The D gene segments of the rabies virus-selected mAb were heterogeneous and, in most cases, flanked by significant N segment additions. The JH segment utilization was unbalanced and reminiscent of those of the adult and fetus. Four mAb utilized JH4, two JH6, two JH3, and one JH5; no mAb utilized JH1 or JH2 genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Complete sequence of the genes encoding the VH and VL regions of low- and high-affinity monoclonal IgM and IgA1 rheumatoid factors produced by CD5+ B cells from a rheumatoid arthritis patient.

We have characterized the VH and VL genes of three low-affinity polyreactive and two high-affinity monoreactive IgM and IgA1 rheumatoid factor (RF) mAb generated using circulating CD5+ B cells from a single rheumatoid arthritis patient. We found that four and one RF mAb utilized genes of the VHIV and VHIII families, respectively. The VHIV gene usage by these RF mAb differs from the preferential VHIII, VHI, and, to a lesser extent, VHII gene usage by the IgM with RF activity found in patients with mixed cryoglobulinemia, Waldenstrom's macroglobulinemia, and other monoclonal gammopathies. In addition, in contrast to the preponderant kappa L chain usage by the RF in these patients, a lambda L chain was utilized by all RF mAb from our rheumatoid arthritis patient. Two RF mAbs utilized V lambda I, two V lambda IV, and one V lambda III L chains. The VH genes of the two low-affinity polyreactive IgM RF mAb were in germline configuration. When compared with the deduced amino acid sequence of the putatively corresponding genomic segment, the VH gene of the high-affinity monoreactive IgM RF mAb displayed five amino acid differences, all of which are in the complementarity determining regions (CDR), possibly the result of a process of somatic point mutation and clonal selection driven by Ag. The unavailability of the corresponding genomic VH segment sequences made it impossible to infer whether the VH genes utilized by the two IgA1 RF were in a germline or somatically mutated configuration. Sequencing of the genes encoding the H chain CDR3 (D segments) revealed that all three low-affinity polyreactive RF mAb displayed a much longer D segment (36-45 bases) than their high-affinity monoreactive counterparts (15-24 bases), raising the possibility that a long D segment may be one of the factors involved in antibody polyreactivity.

Evolutionarily conserved organization and sequences of germline diversity and joining regions of the rabbit T-cell receptor beta 2 chain.

We previously reported that there are three different copies of T-cell receptor beta chain constant region (C beta) genes in some rabbits, two of which are present on an approximately 16-kb and one on an approximately 6-kb Eco RI fragment. We also reported that one of the C beta genes on the approximately 16-kb fragment was chimeric, with a 5' cluster of J beta 2 segments and a 3' untranslated region of beta 1 type. Here we report the complete genomic sequences of the D beta 2 and J beta 2 segments associated with the chimeric C beta gene. The rabbit D beta 2 gene segment has very strong similarity to both its human and mouse counterparts. The sequence similarity also extends rather far from the coding region in both 5' and 3' directions. The content and organization of rabbit J beta 2 gene segments is similar to those found in both human and mouse. The rabbit J beta 2 cluster has six functional segments and one pseudogene, as well as a remnant of another pseudogene between J beta 2.2 and J beta 2.3 equivalent to the one found in man in the same location. The J beta 2.5 gene segment of rabbit has lost the splice signal and is a pseudogene unlike its counterparts in man and mouse. Overall analysis of the rabbit D beta 2-J beta 2 region reveals a closer similarity to human than mouse. However, the general organization of the gene segments in the D beta 2-J beta 2 regions of all three species is remarkably conserved over long stretches of DNA sequence.

Identification of enhancer sequences 3' of the rabbit Ig kappa L chain loci.

The rabbit is useful for studies of Ig L chain gene expression because of a great disparity in expression of two isotypic forms of the kappa L chain. Normally, K1 is expressed at high levels and K2 is almost silent; expression of K2 increases in mutant or experimentally allotype-suppressed animals. The reasons for the preferential utilization of the K1 isotype have not been fully elucidated. We were interested in looking for second enhancers 3' of the C kappa genes because the absence of a 3' enhancer in the K2 locus could explain the preferential utilization of the K1 isotype. However, we found a strong region of enhancer activity about 7 kb downstream of the C kappa 2 gene. Sequences in this region are highly conserved between rabbit, man, and mouse. There also appears to be a homologous 3' enhancer region in the rabbit K1 locus. We also confirmed earlier reports that the rabbit K1 intron enhancer is inactive in transient transfections into mouse B cells but find that the same construct has low but significant activity in a human B cell line. In a comparable construct the K2 intron enhancer is without activity suggesting possible differential activity of the intronic enhancers.

Clonal analysis of a human antibody response. Quantitation of precursors of antibody-producing cells and generation and characterization of monoclonal IgM, IgG, and IgA to rabies virus.

We quantitated and characterized the changes in the human B cell repertoire, at the clonal level, before and after immunization with rabies virus. Moreover, we generated 10 monoclonal cell lines producing IgM, IgG, and IgA antibodies to the virus. We found that in healthy subjects, not previously exposed to the virus, nearly 2% of the circulating B lymphocytes were committed to the production of antibodies that bound the virus. These B cells expressed the surface CD5 molecule. The antibodies they produced were polyreactive IgM that displayed a relatively low affinity for the virus components (Kd, 1.0-2.4 x 10(-6) g/microliters). After immunization, different anti-virus (IgG and IgA) antibody-producing cells consistently appeared in the circulation and increased from less than 0.005% to greater than 10% of the total B cells committed to the production of IgG and IgA, respectively. Most of such B cells do not express CD5 and produce monoreactive antibodies of high affinity for rabies virus (Kd, 6.5 x 10(-9) to 1.2 x 10(-10) g/microliters). One of these IgG mAbs efficiently neutralized rabies virus in vitro and in vivo, as detailed elsewhere (Dietzschold, B., P. Casali, Y. Ueki, M. Gore, C. E. Rupprecht, A. L. Notkins, and H. Koprowski, manuscript submitted for publication). Hybridization experiments using probes specific for the different human V gene segment families revealed that cell precursors producing low affinity IgM binding to rabies virus utilized a restricted number of VH gene segments (i.e., only members of the VHIIIb subfamily), whereas cell precursors producing high affinity IgG and IgA to rabies virus utilized an assortment of different VH gene segments (i.e., members of the VHI, VHIII, VHIV, and VHVI families and VHIIIb subfamily). In conclusion, our studies show that EBV transformation in conjunction with limiting dilution technology and somatic cell hybridization techniques are useful methods for quantitating, at the B cell clonal level, the human antibody response to foreign Ags and for generating human mAbs of predetermined specificity and high affinity.