Lysis of ovarian cancer cells by human lymphocytes redirected with a chimeric gene composed of an antibody variable region and the Fc receptor gamma chain.

To expand the spectrum of recognition of effector lymphocytes and to redirect them towards predefined targets, we have altered the specificity of human tumor-infiltrating lymphocytes (TIL) through stable modification with chimeric receptor genes consisting of single-chain antibody variable regions linked to the gamma subunit common to the immunoglobulin (Ig)G and IgE Fc receptors. Using either hapten or ovarian carcinoma-specific monoclonal antibodies, we constructed chimeric receptor genes and retrovirally introduced them into CD8+ TIL. Redirected TIL specifically lysed trinitrophenyl-labeled Daudi or a human ovarian carcinoma cell line (IGROV-1), and secreted granulocyte/macrophage colony-stimulating factor upon stimulation with the appropriate antigen. This strategy may allow new approaches towards the adoptive immunotherapy of cancer in humans.

Mitochondrial polyriboadenylate polymerase: relative lack of activity in hepatomas.

An enzyme that polymerizes adenylate residues from adenosine triphosphate was prepared from rat liver mitochondria and compared to similar preparations from the mitochondria of three hepatomas. Enzyme activity in the hepatomas was only 1 to 2 percent of that in normal liver.

A complete mapping of the proteins in the small ribosomal subunit of Escherichia coli.

The relative positions of the centers of mass of the 21 proteins of the 30S ribosomal subunit from Escherichia coli have been determined by triangulation using neutron scattering data. The resulting map of the quaternary structure of the small ribosomal subunit is presented, and comparisons are made with structural data from other sources.

Structural convergence in the active sites of a family of catalytic antibodies.

The x-ray structures of three esterase-like catalytic antibodies identified by screening for catalytic activity the entire hybridoma repertoire, elicited in response to a phosphonate transition state analog (TSA) hapten, were analyzed. The high resolution structures account for catalysis by transition state stabilization, and in all three antibodies a tyrosine residue participates in the oxyanion hole. Despite significant conformational differences in their combining sites, the three antibodies, which are the most efficient among those elicited, achieve catalysis in essentially the same mode, suggesting that evolution for binding to a single TSA followed by screening for catalysis lead to antibodies with structural convergence.

WISH-PC2: a unique xenograft model of human prostatic small cell carcinoma.

Prostatic small cell carcinoma is an aggressive subtype of prostate cancer that usually appears as a progression of the original adenocarcinoma. We describe here the WISH-PC2, a novel neuroendocrine xenograft of small cell carcinoma of the prostate. This xenograft was established from a poorly differentiated prostate adenocarcinoma and is serially transplanted in immune-compromised mice where it grows within the prostate, liver, and bone, inducing osteolytic lesions with foci of osteoblastic activity. It secretes to the mouse Chromogranin A and expresses prostate plasma carcinoma tumor antigen-1, six-transmembrane epithelial antigen of the prostate, and members of the Erb-B receptor family. It does not express prostate-specific antigen, prostate stem cell antigen, prostate-specific membrane antigen, and androgen receptor, and it grows independently of androgen. Altogether, WISH-PC2 provides an unlimited source in which to study the involvement of neuroendocrine cells in the progression of prostatic adenocarcinoma and can serve as a novel model for the testing of new therapeutic strategies for prostatic small cell carcinoma.

Differences in the biochemical properties of esterolytic antibodies correlate with structural diversity.

A prerequisite to the design and engineering of catalytic antibodies is the knowledge of their structure and in particular which residues are involved in binding and catalysis. We compared the structure and catalytic properties of a series of six monoclonal antibodies which were all raised against a p-nitrophenyl (PNP) phosphonate and which catalyze the hydrolysis of p-nitrophenyl esters. Three of the antibodies (Group I) have similar light and heavy chain variable regions. The other three antibodies have similar VL regions of which two (Group II) have VH regions from the MOPC21 gene family and the remaining one (Group III) a VH from the MC101 gene family making a total of three different groups based on their V region sequences. The structural division into groups is paralleled by the differences in binding constants to hapten analogs, substrate specificity and the susceptibility of the catalytic activity of the antibodies to chemical modification of tryptophan and arginine residues. The relative binding of a transition state analog to the binding of substrate is much higher for the Group I antibodies than for the other groups. Only the Group I antibodies can catalyze the hydrolysis of a carbonate substrate. However all of the antibodies lose catalytic activity upon specific tyrosine modification which highlights the importance of tyrosine in the active site of the antibodies. Thus, antibodies raised against a single hapten can give antibodies with different structures, and correspondingly different specificities and catalytic properties.

Expression and characterization of recombinant single-chain Fv and Fv fragments derived from a set of catalytic antibodies.

The generation of catalytic antibodies should enable the catalysis of reactions for which no enzymatic or chemical catalyst is currently available. In previous studies, we established a series of catalytic antibodies capable of hydrolysing p-nitrobenzyl (pNB) and p-nitrophenyl (pNP) esters. A group of these catalytic antibodies exhibited high reactivity and substrate specificity, yet each individual antibody demonstrated different kinetic parameters. In order to study the molecular basis for these differences, we have cloned, sequenced and expressed the variable regions of this group of antibodies as functional scFv and Fv in bacteria. The variable region of the heavy chain is derived from a novel germline gene of the J558 family whereas the light chain comes from a germline gene previously found in our catalytic antibodies catalysing the hydrolysis of only nitrophenyl esters, demonstrating that the heavy chain determines the specificity for the nitrobenzyl esters. Several different expression systems were examined for their ability to produce catalytically active antibodies. When expressed as an scFv, both refolded and secreted scFvs exhibited catalytic activity although yields of expressed protein were low. The secreted scFvs had higher specific activity. On the other hand, Fv fragments were expressed in sufficient quantities to allow kinetic analysis. Levels of expression were dependent on the sequence of VL used. Using this expression system, the relative contributions of the individual light and heavy chains to catalysis and binding could be evaluated. Both original VH and VL regions are required for hapten binding, although the VH is more crucial for catalysis. By replacing the CDR3 of the heavy chain with a random sequence, it was shown to be essential for both binding and catalysis. This expression system together with site-directed mutagenesis should enable a more detailed study of the catalytic mechanism of this set of antibodies.

Transfer of chimeric receptor gene made of variable regions of tumor-specific antibody confers anticarbohydrate specificity on T cells.

The antitumor specificity of T cells can be induced by gene transfer using a recently developed therapeutic approach (T body). In this work, we genetically conferred anticarbohydrate specificity onto T cells using the variable regions of monoclonal antibody MLuC1, which binds the Lewis(Y) (LeY) tumor-associated antigen that is overexpressed on several human carcinomas. The variable regions of MLuC1, which are in a single-chain Fv (ScFv) configuration, were cloned and spliced in a eukaryotic expression vector with both the gene encoding the signal-transducing gamma-chain of the human Fcgamma receptor and a flexible hinge domain. The chimeric ScFv-gamma gene was expressed in a murine cytotoxic T-cell hybridoma. Transfectants receiving vector only served as a negative control (mock). Screening for functional transfectants was carried out using a tumor growth inhibition assay. The soluble form of MLuC1 ScFv was recovered from bacteria periplasm and tested for binding to LeY-expressing cells by the fluorescence-activated cell sorter analysis. Despite the low binding ability of the soluble MLuC1 ScFv, 7 of 13 genetically engineered cytotoxic T lymphocyte clones inhibited the growth of LeY-positive cells and did not affect growth of LeY-negative cells. None of the mock clones tested specifically inhibited tumor growth. These data indicate that, by chimeric MLuC1 ScFv-gamma gene transfer, it is possible to confer anticarbohydrate specificity onto T cells and extend the applicability of the T-body approach to tumor-associated antigens that are naturally not recognized by T cells.

Functional expression of chimeric receptor genes in human T cells.

Tumor immunotherapy has been limited to date by the poor antigenicity of most tumors, the immunocompromised state of many cancer patients, and the slow tumor penetration and short half-life of exogenously-introduced anti-tumor antibodies. Our group has developed a model immunotherapy system using a chimeric construct containing an antibody V region fused to a T cell activation molecule (T body) introduced by transfection into cytotoxic T cell lines, or populations of activated primary T or natural killer (NK) cells. In this study we have optimized the conditions needed for efficient transduction of human peripheral lymphocytes (PBL) using retroviral vectors pseudotyped with the gibbon ape leukemia virus (GaLV) envelope. Selection of packaging cells producing high virus titers was performed following transfection with constructs containing the green fluorescent protein (GFP), and FACS sorting. As a model chimeric receptor gene we used a tripartite construct consisting of a single-chain anti-TNP antibody variable region linked to part of the extracellular domain and the membrane spanning regions of the CD28 coreceptor molecule and joined at its 5' end to a gene fragment encoding the intracellular moiety of the gamma activation molecule common to the Fcepsilon and Fcgamma receptors. Enriched preparations of retrovectors containing this chimeric receptor and the GFP gene could stably and efficiently transduce human PBL co-activated by anti-CD3 and anti-CD28 antibodies. In routine experiments, the transgene was expressed in 35-70% of the human T cells. Such lymphocytes express the chimeric receptors on their surface and upon stimulation with hapten immobilized on plastic they can produce IL-2. Transfectomas activated in this manner also undergo specific proliferation in the absence of exogenous IL-2. Moreover, the transduced lymphocytes could effectively lyse target cells expressing the TNP hapten on their surface. These studies establish the conditions for the optimal transfection of effector lymphocytes to redirect them against a variety of tumor targets.

Specific cleavage of ribosomal RNA caused by alpha sarcin.

Alpha sarcin causes the specific cleavage of RNA from 80S ribosomes and 60S subunits of yeast, but not from the 40S subunits to produce a small RNA fragment. The fragment was also produced on treatment of the 60S subunits of wheat germ ribosomes. The fragment has a molecular weight of 100,000 and is a cleavage product of the large RNA species in the 60S subunits. The fragment is not derived from the 5'end of the yeast 25S RNA nor does it bind to 5.8S RNA and we propose that the fragment represents the 3' terminal 320 nucleotides of 25S rRNA. The ability to produce fragment could not be separated from the ability of alpha sarcin to inhibit protein synthesis. Alpha sarcin also causes the specific cleavage of the 23S RNA of the E. coli subunit to produce a smaller fragment of RNA than that produced from eukaryote ribosomes.

Specific activation and targeting of cytotoxic lymphocytes through chimeric single chains consisting of antibody-binding domains and the gamma or zeta subunits of the immunoglobulin and T-cell receptors.

The generation of tumor-specific lymphocytes and their use in adoptive immunotherapy is limited to a few malignancies because most spontaneous tumors are very weak or not at all immunogenic. On the other hand, many anti-tumor antibodies have been described which bind tumor-associated antigens shared among tumors of the same histology. Combining the variable regions (Fv) of an antibody with the constant regions of the T-cell receptor (TCR) chains results in chimeric genes endowing T lymphocytes with antibody-type specificity, potentially allowing cellular adoptive immunotherapy against types of tumors not previously possible. To generalize and extend this approach to additional lymphocyte-activating molecules, we designed and constructed chimeric genes composed of a single-chain Fv domain (scFv) of an antibody linked with gamma or zeta chains, the common signal-transducing subunits of the immunoglobulin receptor and the TCR. Such chimeric genes containing the Fv region of an anti-trinitophenyl antibody could be expressed as functional surface receptors in a cytolytic T-cell hybridoma. They triggered interleukin 2 secretion upon encountering antigen and mediated non-major-histocompatibility-complex-restricted hapten-specific target cell lysis. Such chimeric receptors can be exploited to provide T cells and other effector lymphocytes, such as natural killer cells, with antibody-type recognition directly coupled to cellular activation.

Functional expression in mast cells of chimeric receptors with antibody specificity.

Chimeric genes composed of a single-chain Fv domain (scFv) of an antibody linked with receptor chains normally present in cells of hematopoietic origin were constructed. Such genes could be expressed as functional surface receptors in the RBL-2H3 (rat basophilic leukemia) mast cell line. The chimeric receptors exhibited binding properties of an antibody molecule and triggered degranulation of transfected mast cells on stimulation with antigen. Genetically engineered designer cells (e.g., T-lymphocytes, mast cells, or natural killer cells), equipped with built-in antibody-type recognition, can be now exploited for immunotherapy.

Targeting of T lymphocytes to Neu/HER2-expressing cells using chimeric single chain Fv receptors.

Cell surface molecules essential for the transformed phenotype or growth of malignant cells are attractive targets for anticancer immunotherapy. Antibodies specific to Neu/HER2, a human adenocarcinoma-associated growth factor receptor, were demonstrated to have tumor-inhibitory capacity. Yet, the inefficient accessibility of antibodies to solid tumors limits their clinical use. To redirect effector lymphocytes to adenocarcinomas, we constructed and functionally expressed in T cells chimeric single chain receptor genes incorporating both the Ag-binding domain of anti-Neu/HER2 antibodies and the zeta-signal-transducing subunit of the TCR/CD3 complex or the gamma-signal-transducing subunit of the Ig Fc receptor complex. Surface expression of the anti-Neu/HER2 chimeric genes in cytotoxic T cell hybridomas endowed them with specific Neu/HER2 recognition enabling their activation for IL-2 production and lysis of transformed cells overexpressing Neu/HER2. These chimeric genes hold promise for the immunotherapy of cancer.

Direct T cell activation by chimeric single chain Fv-Syk promotes Syk-Cbl association and Cbl phosphorylation.

The protein tyrosine kinase Syk is activated upon engagement of immune recognition receptors. We have focused on the identification of signaling elements immediately downstream to Syk in the pathway leading to T cell activation. To circumvent T cell receptor (TCR). CD3 activation of Src family kinases, we constructed a signaling molecule with an extracellular single chain Fv of an anti-TNP antibody, attached via a transmembrane region to Syk (scFv-Syk). In a murine T cell hybridoma, direct aggregation of chimeric Syk with antigen culminates in interleukin-2 production and target cell lysis. Initially, it causes an increase in the association between scFv-Syk and the cytosolic protein Cbl and subsequently promotes tyrosine phosphorylation of Cbl. Interestingly, although both Cbl and phospholipase C-gamma (PLC-gamma) are phosphorylated in this hybridoma upon TCR.CD3 cross-linking, these two events are uncoupled in scFv-Syk-transfected cells, in which we were unable to detect antigen-driven PLC-gamma phosphorylation. These results support a model in which Syk can initiate and directly activate the T cell's signaling machinery and position Cbl as a primary tyrosine kinase substrate in this pathway. Furthermore, for efficient PLC-gamma phosphorylation to occur in these cells, the combined actions of different tyrosine kinase families may be required.

Harnessing Syk family tyrosine kinases as signaling domains for chimeric single chain of the variable domain receptors: optimal design for T cell activation.

T cells of tumor bearers often show defective TCR-mediated signaling events and, therefore, exhibit impaired immune responses. As such, patients with heavy tumor burden are often not amenable to adoptive T cell therapy. To overcome this limitation, we have developed a chimeric receptor that joins an extracellular single chain Fv (scFv) of a specific Ab for Ag recognition to an intracellular protein tyrosine kinase (PTK) for signal propagation. Stimulation through the scFv-PTK receptor should bypass defective TCR-proximal events and directly access the T cell's effector mechanisms. In this study we describe the optimization of a scFv-PTK configuration, leading to complete T cell activation. The cytosolic PTK Syk is superior to its family member, Zap-70, for intracellular signaling. As a transmembrane (TM) domain, CD4 performs better than CD8 when plastic-immobilized Ag serves as a stimulator. However, when APC are used to trigger chimeric receptors, the need for a flexible spacer between the scFv and TM domains becomes apparent. The CD8alpha-derived hinge successfully performs this task in chimeric scFv-Syk receptors regardless of its cysteine content. A cytotoxic T cell hybridoma expressing chimeric receptor genes composed of scFv-CD8(hinge)-CD8(TM)-Syk or scFv-CD8(hinge)-CD4(TM)-Syk is efficiently stimulated to produce IL-2 upon interaction with APC and specifically lyses appropriate target cells in a non-MHC-restricted manner.

Mapping of murine IgE epitopes involved in IgE-Fc epsilon receptor interactions.

The generation of anti-IgE monoclonal antibodies has permitted the identification of various serological epitopes on the IgE molecule. The relationship of the sites on IgE recognized by such antibodies to the Fc epsilon receptor (Fc epsilon R) interaction site has been determined using cross-inhibition studies. However, interpretation of this type of experiment is limited by problems of steric hindrance. Thus, to accomplish precise mapping on the IgE molecule of the Fc epsilon R interaction site and the binding sites of various anti-IgE mAb, we employed site-directed mutagenesis of the IgE heavy chain gene. To this end we have constructed and expressed a recombinant murine constant epsilon heavy chain (C epsilon) gene bearing a (4-hydroxy-3-nitrophenyl)acetic acid (NP)-binding VH region. Several site-specific mutants in the C epsilon 3 and C epsilon 4 domains of this recombinant C epsilon gene were prepared and expressed by transfection into the light chain-producing J558L myeloma cell line. The resulting IgE antibodies were tested for binding to mast cells and to various anti-IgE mAb. The mutants produced include a proline to histidine point mutant at amino acid residue 404 in the C epsilon 3 domain, a mutant with a truncated C epsilon 4 domain, a mutant with a 45 amino acid deletion in the carboxy end of C epsilon 3, and a chimeric human C epsilon in which the human C epsilon 3 was replaced by the homologous mouse C epsilon 3 domain. These mutants have permitted the localization, to the C epsilon 3 domain, of the epitopes recognized by the 84.1C and 95.3 anti-IgE mAb. The 84.1C mAb recognizes a site on IgE which is identical or very close to the Fc epsilon R binding site, and 95.3 recognizes a site on IgE which is related, but not identical to the Fc epsilon R binding site. The antigenic determinant recognized by the 51.3 mAb, which is inefficient at blocking the IgE-Fc epsilon R interaction, has been mapped to the C epsilon 4 domain. When tested for binding to the Fc epsilon R on RBL-2H3 cells, the point mutant bound to the Fc epsilon R with twofold reduced affinity, while the C epsilon 3 deletion mutant and the mutant truncated in C epsilon 4 lost all receptor binding activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Tyrosine phosphorylation of insulin receptor substrate-1 in vivo depends upon the presence of its pleckstrin homology region.

To characterize the structural basis for the interactions between the insulin receptor (IR) and its major substrate, insulin receptor substrate-1 (IRS-1), a segment of the NH2-terminal region of IRS-1 (Pro5-Pro65) was deleted. This region contains the first four conserved boxes of a pleckstrin homology (PH) domain, located at the NH2-terminal part of IRS-1. COS-7 cells were then cotransfected with the genes coding for IR and a wild-type (WT) or a mutated form of IRS-1. IRS-1 delta PH underwent significantly reduced insulin-dependent tyrosine phosphorylation compared with WT IRS-1. The reduced in vivo tyrosine phosphorylation of IRS-1 delta PH was accompanied by reduced association between IRS-1 delta PH and its downstream effector p85 regulatory subunit of phosphatidylinositol-3 kinase. In contrast, both WT IRS-1 and IRS-1 delta PH underwent comparable insulin-dependent tyrosine phosphorylation in vitro when incubated with partially purified insulin receptor kinase. These findings suggest that the overall structure of IRS-1 is not altered by deletion of its PH domain and that the PH domain is not the main site for protein-protein interactions between the insulin receptor and IRS-1, at least in vitro. In conclusion, the PH region might facilitate in vivo binding of IRS-1 to membrane phospholipids or other cellular constituents in close proximity to the IR, whereas the actual interactions with the IR are presumably mediated through other domains of the IRS-1 molecule. This could account for the fact that partial deletion of the PH domain selectively impairs the in vivo interactions between the insulin receptor and IRS-1, whereas their in vitro interactions remain unaffected.