Defining cutaneous molecular pathobiology of arsenicals using phenylarsine oxide as a prototype.

Arsenicals are painful, inflammatory and blistering causing agents developed as chemical weapons in World War I/II. However, their large stockpiles still exist posing threat to public health. Phenylarsine oxide (PAO), a strong oxidant and a prototype arsenical is tested for its suitability to defining molecular mechanisms underlying arsenicals-mediated tissue injury. Topically applied PAO induces cutaneous erythema, edema and micro-blisters. These gross inflammatory responses were accompanied by the enhanced production of pro-inflammatory cytokines, ROS and unfolded protein response (UPR) signaling activation. To demonstrate the involvement of UPR in the pathobiology of these lesions, we employed chemical chaperone, 4-phenylbutyric acid (4-PBA) which attenuates UPR. 4-PBA significantly reduced PAO-induced inflammation and blistering. Similar to its effects in murine epidermis, a dose- and time-dependent upregulation of ROS, cytokines, UPR proteins (GRP78, p-PERK, p-eIF2α, ATF4 and CHOP) and apoptosis were observed in PAO-treated human skin keratinocytes NHEK and HaCaT. In addition, 4-PBA significantly restored these molecular alterations in these cells. Employing RNA interference (RNAi)-based approaches, CHOP was found to be a key regulator of these responses. These effects are similar to those manifested by lewisite suggesting that PAO could be used as a prototype of arsenicals to define the molecular pathogenesis of chemical injury.

On the limited recognition of inorganic surfaces by short peptides compared with antibodies.

The vast potential applications of biomolecules that bind inorganic surfaces led mostly to the isolation of short peptides that target selectively specific materials. The demonstrated differential affinity toward certain surfaces created the impression that the recognition capacity of short peptides may match that of rigid biomolecules. In the following, we challenge this view by comparing the capacity of antibody molecules to discriminate between the (100) and (111A) facets of a gallium arsenide semiconductor crystal with the capacity of short peptides to do the same. Applying selection from several peptide and single chain phage display libraries, we find a number of antibody molecules that bind preferentially a given crystal facet but fail to isolate, in dozens of attempts, a single peptide capable of such recognition. The experiments underscore the importance of rigidity to the recognition of inorganic flat targets and therefore set limitations on potential applications of short peptides in biomimetics.

Awakening dormant haematopoietic stem cells.

Haematopoietic stem cells (HSCs) in mouse bone marrow are located in specialized niches as single cells. During homeostasis, signals from this environment keep some HSCs dormant, which preserves long-term self-renewal potential, while other HSCs actively self renew to maintain haematopoiesis. In response to haematopoietic stress, dormant HSCs become activated and rapidly replenish the haematopoietic system. Interestingly, three factors - granulocyte colony-stimulating factor, interferon-alpha and arsenic trioxide - have been shown to efficiently activate dormant stem cells and thereby could break their resistance to anti-proliferative chemotherapeutics. Thus, we propose that two-step strategies could target resistant leukaemic stem cells by priming tumours with activators of dormancy followed by chemotherapy or targeted therapies.

Primary development and participation in a foreign antigen-driven immune response of a chromatin-reactive B cell clonotype are not influenced by TLR9 or other MyD88-dependent TLRs.

Recent findings support a central role for TLRs in both foreign Ag-driven immune responses and systemic autoimmune diseases mediated by B lymphocytes. In vitro studies have shown that the Ag receptors (BCRs) on B cells specific for nuclear autoantigens can facilitate the delivery of these autoantigens to the endocytic compartment, resulting in activation of the nucleic acid-specific TLRs present in this subcellular locale. If this pathway is operative in vivo it might promote the development, survival, or activation of such autoreactive B cells. To test this idea, we evaluated the influence of a deficiency in the CpG DNA-specific TLR, TLR9, or all MyD88-dependent TLRs on the primary development and foreign Ag-driven immune response of B cells in a line of V(H) knockin mice that contains a high frequency of "dual reactive" B cells specific for DNA-based autoantigens such as chromatin, as well as the hapten arsonate. We found that although development and activation of these B cells in vitro are clearly influenced by DNA-based autoantigens, TLR9 or MyD88 deficiencies had no apparent effect on the primary development and participation in the anti-arsonate response of these B cells in vivo. We discuss these results in the context of previous models for the role of TLR9 and other TLRs in the regulation of antinuclear Ag B cell development and activity.

The primary antibody repertoire represents a linked network of degenerate antigen specificities.

In this study, germline Abs were used to select clones from a random dodecapeptide phage-display library. This revealed a much greater heterogeneity of binders than could be obtained with mutated daughter Abs that presumably had been selected in vivo by nominal Ag during active immune responses. We demonstrate that the pluripotency of germline Abs can subsequently be optimized by binding interactions that correlate with thermodynamic changes indicative of structural adaptations at the interface. This singular feature confers on each Ab a distinct window of Ag specificities, where the entropic space explored constitutes a thermodynamic signature of that particular Ab. Combining site plasticity may facilitate overlaps in such windows, with independent Abs converging onto common determinants with near identical binding affinities. In addition to providing for an amplified recognition potential, this networking of individual spectra of Ag specificities simultaneously facilitates the rapid recognition of Ag. Importantly, it also ensures that the primary response is composed of Abs with a high degree of "evolvability."

Evidence of an immunologic mechanism behind the therapeutical effects of arsenic trioxide (As(2)O(3)) on myeloma cells.

Exposure of RPMI 8226, Karpas 707 and U266 human myeloma-like lines to low doses of As(2)O(3) was followed by a marked increase in lymphokine activated killers (LAK)-mediated killing and up- modulation of CD38 and CD54, two molecules involved in cell-cell interactions. Moreover, simultaneous exposure of effectors and targets to As(2)O(3) yielded the most effective condition for lysis. The expression of CD31 (CD38 ligand) and CD11a (CD54 ligand) was also up-regulated by LAK, suggesting that increased adhesion was responsible for the improved killing. Similar results were obtained using freshly isolated myeloma cells. These findings indicate that As(2)O(3) may be useful to boost the immune system against myelomas.

Repertoire analysis in human immunoglobulin heavy chain minilocus transgenic, muMT/muMT mice.

Mice transgenic for the human immunoglobulin heavy chain minilocus pHCl were developed several years ago to help better understand the mechanisms of VDJ recombination and antibody response. Interestingly, these minilocus transgenic mice develop a polyclonal, extremely diverse mu human immunoglobulin heavy chain repertoire, but when immunized, they exclusively use murine immunoglobulin heavy chains. Here, the data shows that when the minilocus is transferred by cross-breeding onto the muMT background, the resulting mice (HCl-muMT/muMT mice) develop polyclonal, extremely diverse mu and gamma1 human immunoglobulin heavy chain repertoires. Our data indicates that if no antigen specific antibodies are detected in pHCl transgenic mice, it is essentially due to competition with endogenous immunoglobulin heavy chain gene segments. Moreover, the data shows that despite the presence of only one functional V(H) gene segment and despite mu and gamma1 repertoires similar to the early pre-immune human repertoire, HCl-muMT/muMT mice, can develop immune responses against proteins and haptens. Finally, the data shows that in aged HC1-muMT/muMT mice, the generation of new B-cells may be impaired and old mice may mainly rely on B-cell generated earlier in life to mount immune responses.

Contrasting the in situ behavior of a memory B cell clone during primary and secondary immune responses.

Whether memory B cells possess altered differentiative potentials and respond in a qualitatively distinct fashion to extrinsic signals as compared with their naive precursors is a current subject of debate. We have investigated this issue by examining the participation of a predominant anti-arsonate clonotype in the primary and secondary responses in the spleens of A/J mice. While this clonotype gives rise to few Ab-forming cells (AFC) in the primary response, shortly after secondary immunization its memory cell progeny produce a massive splenic IgG AFC response, largely in the red pulp. Extensive clonal expansion and migration take place during the secondary AFC response but Ab V region somatic hypermutation is not reinduced. The primary and secondary germinal center (GC) responses of this clonotype are both characterized by ongoing V gene hypermutation and phenotypic selection, little or no inter-GC migration, and derivation of multiple, spatially distinct GCs from a single progenitor. However, the kinetics of these responses differ, with V genes containing a high frequency of total as well as affinity-enhancing mutations appearing rapidly in secondary GCs, suggesting either recruitment of memory cells into this response, or accelerated rates of hypermutation and selection. In contrast, the frequency of mutation observed per V gene does not increase monotonically during the primary GC response of this clonotype, suggesting ongoing emigration of B cells that have sustained affinity- and specificity-enhancing mutations.

Molecular and cellular basis of the altered immune response against arsonate in irradiated A/J mice autologously reconstituted.

The humoral immune response to arsonate (Ars) in normal A/J mice is dominated in the late primary and particularly in the secondary response by a recurrent and dominant idiotype (CRIA) which is encoded by a single canonical combination of the variable gene segments: VHidcr11-DFL16.1-JH2 and Vkappa10-Jkappa1. Accumulation of somatic mutations within cells expressing this canonical combination or some less frequent Ig rearrangements results in the generation of high-affinity antibodies. By contrast, in partially shielded and irradiated A/J mice (autologous reconstitution) immunized with Ars-keyhole limpet hemocyanin (KLH), both the dominance of the CRIA idiotype and the affinity maturation are lost, whereas the anti-Ars antibody titer is not affected. To understand these alterations, we have analyzed a collection of 27 different anti-Ars hybridomas from nine partially shielded and irradiated A/J mice that had been immunized twice with Ars-KLH. Sequence analysis of the productively rearranged heavy chain variable region genes from those hybridomas revealed that (i) the canonical V(D)J combination was rare, (ii) the pattern of V(D)J gene usage rather corresponded to a primary repertoire with multiple gene combinations and (iii) the frequency of somatic mutations was low when compared to a normal secondary response to Ars. In addition, immunohistological analysis has shown a delay of 2 weeks in the appearance of full blown splenic germinal centers in autoreconstituting mice, as compared to controls. Such a model could be useful to understand the immunological defects found in patients transplanted with bone marrow.

Structural requirements for a specificity switch and for maintenance of affinity using mutational analysis of a phage-displayed anti-arsonate antibody of Fab heavy chain first complementarity-determining region.

We previously showed that a single mutation at heavy (H) position 35 of Abs specific for p-azophenylarsonate (Ars) resulted in acquisition of binding to the structurally related hapten p-azophenylsulfonate (Sulf). To explore the sequence and structural diversity of the H chain first complementarity-determining region (HCDR1) in modulating affinity and specificity, positions 30-36 in Ab 36-65 were randomly mutated and expressed as Fab in a bacteriophage display vector. Ab 36-65 is germline encoded, lacking somatic mutations. Following affinity selection on Sulf resins, 55 mutant Fab were isolated, revealing seven unique HCDR1 sequences containing different amino acids at position H:35. All Fab bound Sulf, but not Ars. Site-directed mutagenesis in a variety of HCDR1 sequence contexts indicates that H:35 is critical for hapten specificity, independent of the sequence of the remainder of HCDR1. At H:35, Asn is required for Ars specificity, consistent with the x-ray crystal structure of the somatically mutated anti-Ars Ab 36-71, while Sulf binding occurs with at least seven different H:35 residues. All Sulf-binding clones selected following phage display contained H:Gly33, observed previously for Ars-binding Abs that use the same germline V(H) sequence. Site-directed mutagenesis at H:33 indicates that Gly plays an essential structural role in HCDR1 for both Sulf- and Ars-specific Abs.

In vivo and in vitro assessment of B-B cell interactions: inhibition of proliferation and antibody production of the CRIA B cells mediated by the surface immunoglobulins of anti-CRIA B cells.

In this work we have assessed the effect of cell surface anti-immunoglobulin (Ig) of anti-idiotypic B cells on their idiotypic counterparts in vivo and in vitro, as a surrogate for soluble anti-surface Ig, using the well-characterized anti-arsonate system. The response of A/J mice against the hapten arsonate coupled to keyhole limpet hemocyanin (ARS-KLH) is dominated by a closely related family of antibodies sharing the same determinant, named the CRIA idiotype. We show herein that a massive induction of anti-CRIA B cells, subsequent to immunization with the mAb 3665 (CRIA+, arsonate binding) coupled to KLH, mediated a strong and long-lasting inhibition of this dominant oligoclonal response to arsonate. The titer of anti-arsonate antibodies remained, however, unchanged. Adoptive transfers to x-irradiated syngeneic mice showed that anti-CRIA-producing B cells have a direct effect on induction of inhibition. This was supported by the in vitro data where irradiated anti-CRIA B cells could induce inhibition of both antibody production and mitogenesis of their counterparts, CRIA B cells. This inhibitory effect could be decreased when the surface anti-surface Ig were hidden by the 3665 Fab fragments but not by anti-MHC class II antibodies. These interactions between CRIA and anti-CRIA B cells were solely Igh restricted and the inhibition was likely initiated by hyperaggregation of surface Ig. The presence of ARS-KLH-primed T cells in vitro could prevent the growth inhibition but not the suppression of antibody production. A similar profile was noticed in vitro for soluble polyclonal rabbit anti-CRIA Ab. All together, our data suggest that a negative signaling in B cells may be initiated by surface Ig of their idiotypic partners subsequent to a strong cross-linking of their surface Ig receptors.

Acute oral gallium arsenide exposure and changes in certain hematological, hepatic, renal and immunological indices at different time intervals in male Wistar rats.

Male albino rats were given a single oral dose of gallium arsenide (GaAs) (100, 200 or 500 mg/kg). Erythrocyte delta-aminolevulinic acid dehydratase (ALAD) activity was inhibited in all the three GaAs-exposed groups accompanied by elevated urinary excretion of ALA. A significant increase in serum aspartate aminotransferase (AST) activity, and gamma-glutamyltranspeptidase (gamma-GT) was observed. A significant increase in hepatic malondialdehyde (MDA) and a decrease in hepatic glutathione contents were also noted. Renal alkaline phosphatase activity, urinary ALA and protein excretion increased significantly on GaAs exposure. These changes were accompanied by significant alterations in almost all the immunological variables, with an increase in gallium and arsenic concentration in blood and soft tissues. While most of the above biochemical alterations were prominent at day 7 following single exposure to 200 and 500 mg/kg GaAs, most of the immunological indices altered with all the three doses and remained high even at day 21. The results suggest only a moderate effect of GaAs on renal and hepatic tissues. By contrast, immunological and haematological systems are the most vulnerable to the toxic effects of GaAs.

Differences in sequence-specific expression of two anti-arsonate Fabs in E. coli.

Monoclonal antibodies are potentially useful therapeutic agents and can now be produced in hosts such as bacteria. However, it has been found that bacterial expression of some antibody-combining site fragments is greatly diminished. We compared two homologous anti-arsonate antibodies, 36-65 and 36-71, to address the question of why the former but not the latter expresses well as Fab in E. coli. These antibodies are both derived from the same variable region germline genes but differ in affinity due to somatic mutations present in 36-71. To investigate the poor expression of 36-71 Fab, we examined several factors, such as cellular toxicity, induction with isopropylthio-beta-D-galactoside, and growth of transformed bacteria at lower temperatures (30 degrees C), as well as the possibility of E. coli strain-related expression of Fab. However, none of these factors made a significant difference to Fab expression. We next localized a significant portion of the defect in Fab expression to the heavy chain by swapping the heavy and light chains from the two antibodies to construct hybrid Fabs. We used site-directed mutagenesis to engineer amino acids into the variable regions of antibody 36-71, to reproduce those found in 36-65 which is expressed well in E. coli. The defect in expression is due to residues located in the complementarity-determining regions, as mutations of heavy chain framework residues to those present in 36-65 do not enhance expression of 36-71 Fab in E. coli.

Random mutagenesis of two complementarity determining region amino acids yields an unexpectedly high frequency of antibodies with increased affinity for both cognate antigen and autoantigen.

To gain insight into the mechanism and limitations of antibody affinity maturation leading to memory B cell formation, we generated a phage display library of random mutants at heavy chain variable (V) complementarity determining region 2 positions 58 and 59 of an anti-p-azophenylarsonate (Ars) Fab. Single amino acid substitutions at these positions resulting from somatic hypermutation are recurrent products of affinity maturation in vivo. Most of the ex vivo mutants retained specificity for Ars. Among the many mutants displaying high Ars-binding activity, only one contained a position 58 and 59 amino acid combination that has been previously observed among the monoclonal antibodies (mAbs) derived from Ars-immunized mice. Affinity measurements on 14 of the ex vivo mutants with high Ars-binding activity showed that 11 had higher intrinsic affinities for Ars that the wild-type V region. However, nine of these Fabs also bound strongly to denatured DNA, a property neither displayed by the wild-type V region nor observed among the mutants characteristic of in vivo affinity maturation. These data suggest that ex vivo enhancement of mAb affinity via site-directed and random mutagenesis approaches may often lead to a reduction in antibody specificity that could complicate the use of the resulting mAbs for diagnostic and therapeutic applications. Moreover, the data are compatible with a hypothesis proposing that increased specificity for antigen, rather than affinity per se, is the driving force for formation of the memory B cell compartment.

Simultaneous involvement of all six predicted antigen binding loops of the T cell receptor in recognition of the MHC/antigenic peptide complex.

The TCR is predicted to resemble the Fab fragment of an Ig molecule and by analogy to possess six Ag binding loops that contact MHC proteins bound with antigenic peptides. We have identified residues in the predicted Ag binding loops (beta 1, beta 2, and beta 3) on a TCR beta-chain that are important in the recognition of the MHC/antigenic peptide complex. Using site-directed mutagenesis, we altered the residues forming the predicted Ag binding site on the beta-chain expressed by the T lymphocyte clone D5, which specifically recognizes p-azobenzenearsonate-conjugated peptides presented by the class II MHC molecule I-Ad. Amino acid substitution of individual residues in each loop affected Ag recognition, demonstrating that all three putative Ag binding loops of the D5 TCR beta-chain are important in interaction with I-Ad/arsonate-conjugated Ag. Taken together with our previous work on the D5 TCR alpha-chain (Nalefski et al., J. Exp. Med. 175:1553), these results suggest that all six Ag binding loops of the D5 TCR alpha- and beta-chains interact simultaneously with the MHC/peptide complex. Consequently, the area of interaction between the TCR and the MHC/antigenic peptide complex is predicted to be extensive.

Verification of a model of a F(ab) complex with phenylarsonate by oligonucleotide-directed mutagenesis.

A model of the combining site of a mouse antibody specific for p-azophenylarsonate was tested by oligonucleotide-directed mutagenesis of the proposed hapten-contacting residues, Arg96 in the L chain, and Asn35, Trp47, Tyr50, Ser95, and Tyr100b in the H chain. The affinity and relative affinity for p-azophenylarsonate-N-acetyl-L-tyrosine of mutant antibodies expressed in transfectomas were determined by fluorescence quenching and by inhibition ELISA, respectively. The results show that alteration of the proposed contacting residues has drastic effects on hapten binding, and that the hydroxyl groups of Tyr50 and Tyr100b appear to orient the phenyl rings for optimal aromatic-aromatic interactions with the phenyl ring of the hapten. They further indicate a tight packing of the contacting residues around the hapten, which cannot accommodate changes in the positions of the functional groups of Asn35 and Ser95.

Crystal structure of the antigen-binding fragment of the murine anti-arsonate monoclonal antibody 36-71 at 2.9-A resolution.

The structure of the antigen-binding fragment (Fab) of an anti-phenylarsonate monoclonal antibody (36-71) bearing a major crossreacting idiotype of A/J mice has been solved and refined to an R factor of 19.3% at a resolution of 2.9 A. An initial electron density map was obtained with phase information from a total of six isomorphous heavy-atom derivatives (from two different compounds) and a molecular replacement solution using the HED10 Fab crystal structure as a model. The structure of the McPC603 Fab was used to provide an initial set of atomic coordinates. The electron density maps are clear and easily interpretable for the entire sequence except for sections from two of the heavy-chain complementarity-determining regions totaling 21 residues. These residues have been left out of the refinement and are not represented in our current model. The antigen-combining site was located by means of a difference Fourier synthesis with one of the heavy-atom derivatives, which contained arsanilic acid. It lies in a small pocket formed by residues from the hypervariable regions of both the heavy and the light chains. Interactions with the hapten from framework residues are also possible.

The influence of V kappa gene polymorphism on the induction of silent idiotypes in the arsonate system.

It has been previously shown that it is possible to modify the expressed repertoire of a given individual using idiotypic manipulation. For example, A/J mice respond to arsonate challenge by synthesizing a dominant idiotype, CRIA, whereas BALB/c mice do not. However, after treatment with rabbit polyclonal anti-CRIA antibodies (Ab2 or anti-idiotypic antibodies) and arsonate, BALB/c mice are able to synthesize a CRIA-like idiotype. To determine whether this modification of repertoire is dependent on the immunoglobulin loci (Ig-h, kappa), we have analyzed the anti-arsonate response after anti-idiotypic treatment of three strains of mice (C58, C.C58, AKR), chosen because they are among a small group of strains which express Kappa V regions not seen in other strains. There are also L chains lacking in these strains which are expressed in other mice. The C58 and C.C58 strains share the same Ig-h locus (Ig-ha) with BALB/c mice but C.C58 are congenic mice, that express the kappa loci on a BALB/c genetic background. AKR mice express the Ig-hd haplotype. AKR, C58 and C.C58 do not produce CRIA positive antibodies in response to arsonate; a defect which has been previously mapped to the kappa locus. These three strains of mice (C58, C.C58 and AKR) were treated with rabbit anti-CRIA and boosted with Ars-KLH. The results show that after such treatment, the C.C58 mice were able to express CRIA-like antibodies which are serologically identical to those of BALB/c.