Cancer mucosa antigens as a novel immunotherapeutic class of tumor-associated antigen

Colorectal cancer is a leading cause of cancer-related mortality worldwide. Surgery and chemoradiation exhibit incomplete efficacy and, ultimately, 50% of patients die of metastatic disease. In the context of that unmet clinical need, immunotherapeutic approaches have enjoyed limited success, partly because of a paucity of suitable antigen targets. However, exploitation of immune compartmentalization, employing antigens with expression restricted to normal intestinal mucosa and derivative colorectal tumors--cancer mucosa antigens (CMAs)--may represent a previously unrecognized class of immune targets supporting efficacious antitumor immunotherapy. Guanylyl cyclase C (GCC) is an intestine/colorectal cancer-restricted protein ideally suited as the first CMA for clinical evaluation.

Quantitative analysis of adenovirus-specific CD4+ T-cell responses from healthy adults

Although nearly all adults are seropositive for adenoviruses, little is known about the cellular immune responses to these ubiquitous pathogens. We have previously identified adenovirus-specific proliferative T-cell responses in peripheral blood mononuclear cells (PBMC) from healthy adults. In this study, memory T-cell responses to adenovirus were further evaluated in healthy adult donors using a short term, quantitative enzyme-linked immunospot assay (ELISPOT) assay. Adenovirus antigen induced specific secretion of interferon-gamma (IFN-gamma) from PBMC within 12 hours of incubation. PBMC from 20 of 22 healthy donors (90.9%) expressed IFN-y in response to adenovirus. Responder cells were identified as CD4+ T cells by immunomagnetic depletion methods. Interleukin-4 (IL-4) secretion was not detected, consistent with a TH1 response. There was a 10-fold variation in the frequencies of adenovirus-specific CD4+ T cells between donors (range, 34 to 294; median, 122 per million PBMC). Adenovirus-specific T cell frequencies remained stable over periods up to 2 years among individual donors, but there was an inverse correlation between frequency and donor age. These quantitative data suggest that most adults retain adenovirus-specific cellular memory after childhood exposure. This assay may be useful for the evaluation of adenovirus-specific CD4+ T-cell responses in patients treated with adenovirus gene therapy vectors and the identification of major T-cell epitopes.

The HA-2 minor histocompatibility antigen is derived from a diallelic gene encoding a novel human class I myosin protein

Human minor histocompatibility Ags (mHag) present significant barriers to successful bone marrow transplantation. However, the structure of human mHag and the basis for antigenic disparities are still largely unknown. Here we report the identification of the gene encoding the human mHag HA-2 as a previously unknown member of the class I myosin family, which we have designated MYO1G. The gene is located on the short arm of chromosome 7. Expression of this gene is limited to cells of hemopoietic origin, in keeping with the previously defined tissue expression of the HA-2 Ag. RT-PCR amplification of MYO1G from different individuals led to the identification of two genetic variants, designated MYO1G(V) and MYO1G(M). The former encodes the peptide sequence previously shown to be the HA-2 epitope (YIGEVLVSV), whereas the latter shows a single amino acid change in this peptide (YIGEVLVSM). This change has only a modest effect on peptide binding to the class I MHC-restricted element HLA-A*0201, and a minimal impact on recognition by T cells when added exogenously to target cells. Nonetheless, as detected using either T cells or mass spectrometry, this amino acid change results in a failure of the latter peptide to be presented at the surface of cells that express MYO1G(M) endogenously. These studies have thus identified a new mHag-encoding gene, and thereby provide additional information about both the genetic origins of human mHag as well as the underlying basis of an Ag-positive vs Ag-negative state.

B-Myb overexpression results in activation and increased Fas/Fas ligand-mediated cytotoxicity of T and NK cells

The human B-myb gene encodes a transcriptional regulator that plays an important role in cell cycle progression, differentiation, and survival. To assess the in vivo role of B-myb, we investigated the phenotype of mouse transgenic lines in which B-Myb expression in lymphoid tissues was driven by the LCK proximal promoter. Overexpression of B-Myb had no measurable effect on the subsets of splenic and thymic lymphocytes, but was associated with increased expression of Fas ligand in NK and T cells. B-Myb-overexpressing splenocytes expressed higher IFN-gamma levels and contained higher percentages of cytokine-producing cells than wild-type (wt) splenocytes, as detected by Western blot analysis and ELISPOT assays, respectively. Ex vivo-cultured transgenic thymocytes and splenocytes had decreased survival compared with the corresponding cells from wt mice, possibly dependent on increased expression of Fas ligand. In addition, Fas ligand-dependent cytotoxicity of transgenic T and NK cells was significantly higher than that mediated by their wt counterparts. Together, these results indicate that B-Myb overexpression results in T and NK cell activation and increased cytotoxicity. Therefore, in addition to its well-established role in proliferation and differentiation, B-myb also appears to be involved in activation of NK and T cells and in their regulation of Fas/Fas ligand-mediated cytotoxicity

Differential role of p38 and c-Jun N-terminal kinase 1 mitogen-activated protein kinases in NK cell cytotoxicity

The serine-threonine mitogen-activated protein kinase (MAPK) family includes extracellular signal-regulated kinases (ERK), c-Jun N-terminal kinases (JNK), and p38 kinases. In NK cells, spontaneous or Ab-mediated recognition of target cells leads to activation of an ERK-2 MAPK-dependent biochemical pathway(s) involved in the regulation of NK cell effector functions. Here we assessed the roles of p38 and JNK MAPK in NK cell-mediated cytotoxicity. Our data indicate that p38 is activated in primary human NK cells upon stimulation with immune complexes and interaction with NK-sensitive target cells. FcgammaRIIIA-induced granule exocytosis and both spontaneous and Ab-dependent cytotoxicity were reduced in a dose-dependent manner in cells pretreated with either of two specific inhibitors of this kinase. Target cell-induced IFN-gamma and FcgammaRIIIA-induced TNF-alpha mRNA accumulation was similarly affected under the same conditions. Lack of inhibition of NK cell cytotoxicity in cells overexpressing an inactive form of JNK1 indicates that this kinase, activated only upon FcgammaRIIIA ligation, does not play a significant role in cytotoxicity. These data underscore the involvement of p38, but not JNK1, in the molecular mechanisms regulating NK cell cytotoxicity.

Impaired assembly yet normal trafficking of MHC class I molecules in Tapasin mutant mice

Loading of peptides onto major histocompatibility complex class I molecules involves a multifactorial complex that includes tapasin (TPN), a membrane protein that tethers empty class I glycoproteins to the transporter associated with antigen processing. To evaluate the in vivo role of TPN, we have generated Tpn mutant mice. In these animals, most class I molecules exit the endoplasmic reticulum (ER) in the absence of stably bound peptides. Consequently, mutant animals have defects in class I cell surface expression, antigen presentation, CD8+ T cell development, and immune responses. These findings reveal a critical role of TPN for ER retention of empty class I molecules. Tpn mutant animals should prove useful for studies on alternative antigen-processing pathways that involve post-ER peptide loading.

The induction of virus-specific CTL as a function of increasing epitope expression: responses rise steadily until excessively high levels of epitope are attained

The role of epitope expression levels in CD8+ T cell priming has been controversial. Yet this parameter is of great importance in the design of rational approaches to optimize CTL responses to a variety of pathogens. In this paper we examine the influence of epitope production on CD8+ T cell priming by exploiting a system that allows a 200-fold range of cell surface epitope expression in vitro with a fixed dose of vaccinia virus. Our results demonstrate that, with the exception of a notable decline at the highest level of epitope, the magnitude of the responding CTL population generated in vivo following equivalent viral infections is essentially proportional to epitope density.

Intratumoral recombinant GM-CSF-encoding virus as gene therapy in patients with cutaneous melanoma

Seven immunocompetent, revaccinated patients with surgically incurable cutaneous melanoma underwent treatment of dermal and/or subcutaneous metastases with twice-weekly intratumoral injections of escalating doses (10(4)-2 x 10(7) plaque-forming units (PFU)/lesion; 10(4)-8 x 10(7) PFU/session) of a vaccinia/GM-CSF recombinant virus for 6 weeks. Patients with stable or responding disease were maintained on treatment until tumor resolution or progression. Systemic toxicity was infrequent, dose-related, and limited to mild flu-like symptoms that resolved within 24 hours. Local inflammation, at times with pustule formation, was consistently seen with doses of > or =10(7) PFU/lesion. Chronically treated lesions showed a dense infiltration, with CD4+ and CD8+ lymphocytes, histiocytes, and eosinophils. All seven patients developed an antivaccinia humoral immune response 14-21 days following revaccination. Despite the presence of these antivaccinia antibodies, the reporter gene was expressed, as judged by the development of anti-beta-galactosidase antibodies in all patients. Passenger cytokine gene function was evidenced by the presence of virally encoded GM-CSF mRNA at injection sites both early (weeks 1 and 5) and late (week 31) in the course of treatment. Eosinophilia at treatment sites indicated that physiologically significant levels of functional cytokine were generated. However, there were no changes in the total number of peripheral white blood cells or in the numbers or percentages of polymorphonuclear leukocytes, monocytes, or eosinophils. GM-CSF was not detected in the sera. The two patients with the largest tumor burdens failed to respond even at treatment sites. Three patients had mixed responses, with regression of treated and untreated dermal metastases and progression of disease elsewhere. One patient had a partial response, with regression of injected and uninjected regional dermal metastases. Residual melanoma was excised, rendering the patient disease free. One patient with only dermal metastases confined to the scalp achieved a complete remission. Sequential administration of escalating doses of a GM-CSF recombinant vaccinia virus is safe, effective at maintaining passenger gene function, and can induce tumor regression.

Dependence of both spontaneous and antibody-dependent, granule exocytosis-mediated NK cell cytotoxicity on extracellular signal-regulated kinases

Extracellular signal-regulated kinases (ERK, also known as mitogen-activated protein kinases) are serine-threonine kinases transducing signals elicited upon ligand binding to several tyrosine kinase-associated receptors. We have reported that ERK2 phosphorylation and activation follows engagement of the low affinity receptor for the Fc portion of IgG (CD16) on NK cells, and is necessary for CD16-induced TNF-alpha mRNA expression. Here, we analyzed the involvement of ERK in NK cell-mediated cytotoxicity and IFN-gamma expression induced upon stimulation with targets cells, coated or not with Abs. Our data indicate that, as with immune complexes, ERK2 phosphorylation occurs in human primary NK cells upon interaction with target cells sensitive to granule exocytosis-mediated spontaneous cytotoxicity, and that this regulates both target cell- and immune complex-induced cytotoxicity and IFN-gamma mRNA expression. A specific inhibitor of mitogen-activated protein kinase kinase reduced both spontaneous and Ab-dependent cytotoxicity in a dose-dependent manner involving, at least in part, inhibition of granule exocytosis without affecting effector/target cell interaction and rearrangement of the cytoskeleton proteins actin and tubulin. Involvement of ERK in the regulation of Ca2+-dependent cell-mediated cytotoxicity was confirmed, using a genetic approach, in primary NK cells infected with a recombinant vaccinia virus encoding an ERK inactive mutant. These data indicate that the biochemical pathways elicited in NK cells upon engagement of receptors responsible for either spontaneous or Ab-dependent recognition of target cells, although distinct, utilize ERK as one of their downstream molecules to regulate effector functions.

Antigen processing of two H2-IEd-restricted epitopes is differentially influenced by the structural changes in a viral glycoprotein

The factors that influence the intracellular location(s) of MHC class II-restricted epitope loading remain poorly understood. We present evidence that two I-Ed-restricted epitopes of the influenza hemagglutinin (HA) molecule, termed site 1 (S1; encompassing amino acid residues 107-119) and site 3 (S3; encompassing amino acid residues 302-313), are generated in distinct endocytic compartments. By means of an epitope-specific mAb, we show that S1 becomes detectable in late endocytic/lysosomal vesicles; using a mutant cell line, we also show that the presentation of S1 is dependent upon H2-DM expression. In contrast, S3; presentation is H2-DM-independent and appears in early endosomes as a result of acid-induced structural changes in HA. Presentation of both epitopes can be made H2-DM-independent by denaturing HA and made H2-DM-dependent by preventing the acid-induced conformational changes from occurring. These findings indicate that the structural context of a given epitope can determine where it is processed.

Dinitrophenyl-modified autologous melanoma vaccine induces a T cell response to hapten-modified, melanoma peptides

Active specific immunotherapy with dinitrophenyl (DNP)-modified autologous melanoma vaccine elicits inflammatory responses in metastatic tumor sites. Postsurgical adjuvant immunotherapy with this vaccine prolongs survival in stage III melanoma patients. We have reported that, after administration of DNP-modified melanoma vaccine, T cell responses to DNP-modified autologous tumor cells are demonstrable in vivo and in vitro. These responses are hapten specific and MHC restricted. To elucidate this phenomenon, we investigated the immune response to DNP-modified peptides eluted from autologous cells. Short peptides were extracted from DNP-modified and unmodified autologous melanoma cells by an acid elution technique and HPLC fractionation. Peptides were also extracted from DNP-modified and unmodified, EB virus-transformed, autologous B lymphoblasts. These various peptide fractions were loaded onto autologous B lymphoblasts and tested for ability to elicit a response by a DNP-specific T cell line as measured by IFN-gamma production. Unexpectedly, stimulatory activity of peptides from DNP-modified melanoma cells was confined to a single HPLC fraction. Spectrometric analysis of this fraction confirmed modification of peptides with DNP. A weaker T cell response was observed to a single HPLC fraction of DNP-modified peptides from the patient's B lymphoblasts. No T cell response was elicited by corresponding fractions of peptides eluted from unmodified melanoma cells or B lymphoblasts. These findings demonstrate the human T cell response to DNP-modified autologous melanoma cells is mediated by hapten-modified, MHC-associated peptides. Further investigation of these peptides could lead to a new strategy for peptide-based cancer immunotherapy.

Murine transporter associated with antigen presentation (TAP) preferences influence class I-restricted T cell responses

The transporter associated with antigen presentation (TAP) complex shuttles cytosolic peptides into the exocytic compartment for association with nascent major histocompatibility complex class I molecules. Biochemical studies of murine and human TAP have established that substrate length and COOH-terminal residue identity are strong determinants of transport efficiency. However, the existence of these specificities in the intact cell and their influences on T cell responses have not been demonstrated. We have devised a method for studying TAP- mediated transport in intact cells, using T cell activation as a readout. The approach makes use of a panel of recombinant vaccinia viruses expressing peptides containing the Kd-restricted nonamer influenza nucleoprotein residues 147-155. The COOH terminus of each construct was appended with a dipeptide composed of an internal threonine residue followed by a varying amino acid. Synthetic peptide versions of these 11-mers exhibit vastly different transport capabilities in streptolysin O-permeabilized cells, in accordance with the predicted influence of the COOH-terminal residues. Presentation of the endogenously expressed version of each construct requires TAP-mediated transport and cooexpression with a vac-encoded exocytic COOH-terminal dipeptidase, angiotensin converting enzyme, to allow liberation of the minimal epitope. Recognition by epitope-specific CTLs therefore signifies TAP-mediated transport of a complete 11-mer within the target cell. Under normal assay conditions no influences of the COOH-terminal residue were revealed. However, when T cell recognition was limited, either by blocking CD8 coreceptor interactions or by decreasing the amount of transport substrate synthesized, significant COOH-terminal effects were revealed. Under such conditions, those peptides that transported poorly in biochemical assays were less efficiently presented. Therefore, TAP specificity operates in the intact cell, appears to reflect previously defined rules with regard to the influence of the COOH-terminal residue, and can strongly influence T cell responses.

Initiation codon scanthrough versus termination codon readthrough demonstrates strong potential for major histocompatibility complex class I-restricted cryptic epitope expression

Accumulating evidence shows that the repertoire of major histocompatibility complex class I-restricted epitopes extends beyond conventional translation reading frames. Previously, we reported that scanthrough translation, where the initiating AUG of a primary open reading frame is bypassed, is most likely to account for the presentation of cryptic epitopes from alternative reading frames within the influenza A PR/8/34 nucleoprotein gene. Here, we confirm and extend these findings using an epitope cassette construct that features two well-defined CD8(+) T cell (TCD8+) epitopes in alternative reading frames, each preceded by a single start codon. Expression of one epitope depends on scanning of the ribosome over the first AUG with translation initiation occurring at the second AUG. We find that scanthrough translation has great potency in our system, with its impact being modulated, as predicted, by the base composition surrounding the first initiation codon, the number of start codons preceding the point of alternate reading frame initiation, and the efficiency with which the epitope itself is generated. Additionally, we investigated the efficiency of eukaryotic translation termination codons, to assess codon readthrough as a mechanism for cryptic epitope expression from 3' untranslated regions. In contrast with initiation codons, eukaryotic stop codons appear to be highly efficient at preventing expression of epitopes encoded in 3' untranslated regions, suggesting that 3' untranslated regions are not a common source of cryptic epitope substrate. We conclude that scanthrough is a powerful mechanism for the expression of epitopes encoded in upstream alternative open reading frames that may contribute significantly to TCD8+ responses and to tolerance induction.

Point mutation flanking a CTL epitope ablates in vitro and in vivo recognition of a full-length viral protein

CD8+ T cells (T(CD8+)) recognize viral Ags as short peptides (epitopes) displayed at the cell surface by MHC class I molecules. Using a panel of recombinant vaccinia viruses, we show that single-point mutations flanking either side of an H-2Kd-restricted epitope, residues 147-155, within full-length influenza nucleoprotein (NP) can impact, even ablate, presentation of that epitope, while having no effect on presentation of distal epitopes. The most severe blocking mutation (Ala to Pro at position 146) did not inhibit NP(147-155) presentation in the context of a truncated minigene, implying that this peptide is not a functional processing intermediate. An amino-terminal proline replacement also significantly reduced presentation of NP(50-57) (H-2Kk restricted), while the same mutation did not affect a third NP epitope. Thus, while trends in processing specificity may exist, the epitope itself contributes to flanking sequence effects. These findings were paralleled by in vivo priming experiments in which, depending on viral dose, subtle in vitro blocking effects were absolute. Proteasome/synthetic peptide coincubation studies support a role for enhanced epitope destruction in preventing presentation, as did the effect of the peptide aldehyde, LLnL, which restored presentation of NP(147-155) from the mutated constructs. This reagent did not inhibit epitope presentation, even from wild-type NP, suggesting that its production may be proteasome independent. These results support the notion that point mutation of epitope flanking sequence can serve as a mechanism for viral immune evasion, shed light on the mechanisms involved, and suggest that in vitro assays may not be sensitive indicators of flanking sequence effects.

Point mutation flanking a CTL epitope ablates in vitro and in vivo recognition of a full-length viral protein

CD8+ T cells (T(CD8+)) recognize viral Ags as short peptides (epitopes) displayed at the cell surface by MHC class I molecules. Using a panel of recombinant vaccinia viruses, we show that single-point mutations flanking either side of an H-2Kd-restricted epitope, residues 147-155, within full-length influenza nucleoprotein (NP) can impact, even ablate, presentation of that epitope, while having no effect on presentation of distal epitopes. The most severe blocking mutation (Ala to Pro at position 146) did not inhibit NP(147-155) presentation in the context of a truncated minigene, implying that this peptide is not a functional processing intermediate. An amino-terminal proline replacement also significantly reduced presentation of NP(50-57) (H-2Kk restricted), while the same mutation did not affect a third NP epitope. Thus, while trends in processing specificity may exist, the epitope itself contributes to flanking sequence effects. These findings were paralleled by in vivo priming experiments in which, depending on viral dose, subtle in vitro blocking effects were absolute. Proteasome/synthetic peptide coincubation studies support a role for enhanced epitope destruction in preventing presentation, as did the effect of the peptide aldehyde, LLnL, which restored presentation of NP(147-155) from the mutated constructs. This reagent did not inhibit epitope presentation, even from wild-type NP, suggesting that its production may be proteasome independent. These results support the notion that point mutation of epitope flanking sequence can serve as a mechanism for viral immune evasion, shed light on the mechanisms involved, and suggest that in vitro assays may not be sensitive indicators of flanking sequence effects.

MHC affinity, peptide liberation, T cell repertoire, and immunodominance all contribute to the paucity of MHC class I-restricted peptides recognized by antiviral CTL

MHC class I-restricted T cell responses to viral proteins focus on a limited set of peptides. To better understand this phenomenon, we examined all of the 26 nonameric peptides encoded by the influenza virus A/Puerto Rico/8/34 (PR8) conforming to the canonical Kd binding motif. Ten peptides bound strongly to Kd as assessed by a cell surface stabilization assay. Five of these 10 induced in vitro secondary CD8+ T cell responses from splenocytes derived from PR8-immunized mice. The strongest responses were induced by the two previously defined antigenic peptides, which ranked only second and fifth in relative binding affinity. To examine the limiting factors in the immunogenicity of Kd-binding peptides, we produced recombinant vaccinia viruses (rVVs) expressing cytosolic or endoplasmic reticulum (ER)-targeted peptides. rVVs expressing ER-targeted versions of the 7 peptides with the highest relative affinities for Kd rescued Kd cell surface expression in T2 cells, while those expressing the 3 lowest affinity peptides did not. The immunogenicity of several, but not all, of the highest affinity peptides was greatly enhanced when expressed as VV-encoded cytosolic or ER-targeted peptides as compared with full length proteins. We conclude that limitations in the immunogenicity of class I binding peptides reflects, in order of decreasing importance, peptide liberation by cellular proteases, T cell repertoire, and TAP-mediated peptide transport. We also observed an additional important contributing factor: suppression of T cell responses to nondominant peptides by an immunodominant peptide located in the same protein.

Regulation of class I-restricted epitope processing by local or distal flanking sequence

Influenza A/Puerto Rico/8/34 nucleoprotein (NP) contains an H-2Kd-restricted CD8+ T cell (T CD8+) epitope spanning amino acid residues 147-155. It was previously demonstrated that expression of NP147-155 and NP147-158 in isolation via "minigene"/recombinant vaccinia virus (vac) technology leads to sensitization of target cells for NP-specific killing while expression of 147-158 lacking the arginine at position 156 (termed here as 147-155TG) does not. The presentation block was overcome by placing this fragment into the context of full length NP. We show that addition of a single amino acid, Met159, to the C terminus of the blocked peptide (creating 147-155TGM) restores presentation. Presentation of 147-155TGM was not due to trimming in the exocytic compartment, consistent with severe limitations on C-terminal trimming activity in this location. Rescued presentation was also achieved when the blocked construct was extended in the N-terminal direction only, but in this case more than 55 amino acids of flanking sequence were required. The transition to presentation was abrupt, with 91-155TG and shorter constructs showing little or no detectable presentation and 90-155TG showing full level presentation. Presentation could not be attributed to acquisition of conventional targets for ubiquitination since mutation of all Lys residues, to which the ubiquitin moiety is conjugated, does not abrogate presentation. Rescued presentation was not inhibited by the peptide aldehyde N-acetyl-L-leucinyl-L-leucinal-L-norleucinal, suggesting that the added elements may be recruiting nonproteasomal activity. We have therefore identified and begun to characterize protease targeting of regulatory elements, both local and distal to an epitope, which strongly influence the ability of the epitope to be excised.

MHC affinity, peptide liberation, T cell repertoire, and immunodominance all contribute to the paucity of MHC class I-restricted peptides recognized by antiviral CTL

MHC class I-restricted T cell responses to viral proteins focus on a limited set of peptides. To better understand this phenomenon, we examined all of the 26 nonameric peptides encoded by the influenza virus A/Puerto Rico/8/34 (PR8) conforming to the canonical Kd binding motif. Ten peptides bound strongly to Kd as assessed by a cell surface stabilization assay. Five of these 10 induced in vitro secondary CD8+ T cell responses from splenocytes derived from PR8-immunized mice. The strongest responses were induced by the two previously defined antigenic peptides, which ranked only second and fifth in relative binding affinity. To examine the limiting factors in the immunogenicity of Kd-binding peptides, we produced recombinant vaccinia viruses (rVVs) expressing cytosolic or endoplasmic reticulum (ER)-targeted peptides. rVVs expressing ER-targeted versions of the 7 peptides with the highest relative affinities for Kd rescued Kd cell surface expression in T2 cells, while those expressing the 3 lowest affinity peptides did not. The immunogenicity of several, but not all, of the highest affinity peptides was greatly enhanced when expressed as VV-encoded cytosolic or ER-targeted peptides as compared with full length proteins. We conclude that limitations in the immunogenicity of class I binding peptides reflects, in order of decreasing importance, peptide liberation by cellular proteases, T cell repertoire, and TAP-mediated peptide transport. We also observed an additional important contributing factor: suppression of T cell responses to nondominant peptides by an immunodominant peptide located in the same protein.

Regulation of class I-restricted epitope processing by local or distal flanking sequence

Influenza A/Puerto Rico/8/34 nucleoprotein (NP) contains an H-2Kd-restricted CD8+ T cell (T CD8+) epitope spanning amino acid residues 147-155. It was previously demonstrated that expression of NP147-155 and NP147-158 in isolation via "minigene"/recombinant vaccinia virus (vac) technology leads to sensitization of target cells for NP-specific killing while expression of 147-158 lacking the arginine at position 156 (termed here as 147-155TG) does not. The presentation block was overcome by placing this fragment into the context of full length NP. We show that addition of a single amino acid, Met159, to the C terminus of the blocked peptide (creating 147-155TGM) restores presentation. Presentation of 147-155TGM was not due to trimming in the exocytic compartment, consistent with severe limitations on C-terminal trimming activity in this location. Rescued presentation was also achieved when the blocked construct was extended in the N-terminal direction only, but in this case more than 55 amino acids of flanking sequence were required. The transition to presentation was abrupt, with 91-155TG and shorter constructs showing little or no detectable presentation and 90-155TG showing full level presentation. Presentation could not be attributed to acquisition of conventional targets for ubiquitination since mutation of all Lys residues, to which the ubiquitin moiety is conjugated, does not abrogate presentation. Rescued presentation was not inhibited by the peptide aldehyde N-acetyl-L-leucinyl-L-leucinal-L-norleucinal, suggesting that the added elements may be recruiting nonproteasomal activity. We have therefore identified and begun to characterize protease targeting of regulatory elements, both local and distal to an epitope, which strongly influence the ability of the epitope to be excised.

Ribosomal scanning past the primary initiation codon as a mechanism for expression of CTL epitopes encoded in alternative reading frames

An increasing amount of evidence has shown that epitopes restricted to MHC class I molecules and recognized by CTL need not be encoded in a primary open reading frame (ORF). Such epitopes have been demonstrated after stop codons, in alternative reading frames (RF) and within introns. We have used a series of frameshifts (FS) introduced into the Influenza A/PR/8 /34 nucleoprotein (NP) gene to confirm the previous in vitro observations of cryptic epitope expression, and show that they are sufficiently expressed to prime immune responses in vivo. This presentation is not due to sub-dominant epitopes, transcription from cryptic promoters beyond the point of the FS, or internal initiation of translation. By introducing additional mutations to the construct exhibiting the most potent presentation, we have identified initiation codon readthrough (termed scanthrough here, where the scanning ribosome bypasses the conventional initiation codon, initiating translation further downstream) as the likely mechanism of epitope production. Further mutational analysis demonstrated that, while it should operate during the expression of wild-type (WT) protein, scanthrough does not provide a major source of processing substrate in our system. These findings suggest (i) that the full array of self- and pathogen-derived epitopes available during thymic selection and infection has not been fully appreciated and (ii) that cryptic epitope expression should be considered when the specificity of a CTL response cannot be identified or in therapeutic situations when conventional CTL targets are limited, as may be the case with latent viral infections and transformed cells. Finally, initiation codon readthrough provides a plausible explanation for the presentation of exocytic proteins by MHC class I molecules.

In situ cytokine gene transfection using vaccinia virus vectors

Studies by a number of investigators have focused on inducing tumor-specific immunity as a therapeutic approach to cancer. Successful immunotherapeutic strategies have involved localized treatment with immune-active adjuvants, systemic administration using cytokines such as interleukin-2, and the use of whole tumor cells or tumor cell fragments as vaccines. With an increasing understanding of the requirements for the development of an immune response, immunotherapeutic strategies have focused on providing mechanistic requirements, such as tumor or accessory antigen expression and cytokine-based "immune help." Recent preclinical studies have shown that ex vivo cytokine gene transfection of tumor cells and their use as vaccines result in the enhanced development of antitumor immunity and in some cases can be used to successfully treat pre-existing tumors. Studies from our laboratory have explored the use of vaccinia virus recombinants to directly transfect tumor cells in situ with cytokine genes as a strategy for enhancing the development of antitumor immunity. We have demonstrated that vaccinia virus recombinants are highly efficient in transfecting a wide range of murine and human tumors in vitro and can be used with similar effects in in vivo murine models. In addition, we have found that vaccinia virus productively infects human melanoma cells following intratumoral injection in patients with accessible lesions. In situ transfection is highly efficient, and therapy with increasing doses of virus is safe with only minor side effects. The results of our studies support the use of cytokine-encoding recombinant vaccinia virus vectors for in situ transfection in patients with cancer.

Antigen processing in vivo and the elicitation of primary CTL responses

CD8+ T lymphocytes (TCD8+) play an important role in cellular immune responses. TCD8+ recognize MHC class I molecules complexed to peptides of 8 to 10 residues derived largely from cytosolic proteins. Proteins are generally thought to be fragmented in the cytoplasm and delivered to nascent class I molecules in the endoplasmic reticulum (ER) by a peptide transporter encoded by the MHC. To explore the extent to which TCD8+ induction in vivo is limited by proteolysis or peptide transport into the ER, mice were immunized with recombinant vaccinia viruses containing mini-genes encoding antigenic peptides (bypassing the need for proteolysis), or these peptides with a NH2-terminal ER insertion sequence (bypassing the requirements for both proteolysis and transport). Additionally, mice were immunized with recombinant vaccinia viruses encoding rapidly degraded fragments of proteins. We report that limitations in induction of TCD8+ responses vary among Ags: for some, full length proteins are as immunogenic as other forms tested; for others, maximal responses are induced by peptides or by peptides targeted to the ER. Most importantly, in every circumstance examined, targeting peptides to the ER never diminished, and in some cases greatly enhanced, the TCD8+ immune response and provide an important alternative strategy in the design of live viral or naked DNA vaccines for the treatment of cancer and infectious diseases.

Antigen processing in vivo and the elicitation of primary CTL responses

CD8+ T lymphocytes (TCD8+) play an important role in cellular immune responses. TCD8+ recognize MHC class I molecules complexed to peptides of 8 to 10 residues derived largely from cytosolic proteins. Proteins are generally thought to be fragmented in the cytoplasm and delivered to nascent class I molecules in the endoplasmic reticulum (ER) by a peptide transporter encoded by the MHC. To explore the extent to which TCD8+ induction in vivo is limited by proteolysis or peptide transport into the ER, mice were immunized with recombinant vaccinia viruses containing mini-genes encoding antigenic peptides (bypassing the need for proteolysis), or these peptides with a NH2-terminal ER insertion sequence (bypassing the requirements for both proteolysis and transport). Additionally, mice were immunized with recombinant vaccinia viruses encoding rapidly degraded fragments of proteins. We report that limitations in induction of TCD8+ responses vary among Ags: for some, full length proteins are as immunogenic as other forms tested; for others, maximal responses are induced by peptides or by peptides targeted to the ER. Most importantly, in every circumstance examined, targeting peptides to the ER never diminished, and in some cases greatly enhanced, the TCD8+ immune response and provide an important alternative strategy in the design of live viral or naked DNA vaccines for the treatment of cancer and infectious diseases.

Intravesical gene therapy: in vivo gene transfer using recombinant vaccinia virus vectors

Intratumoral gene transfer may be a significant tool in active immunotherapy. The ability to insert functional genes into a tumor in vitro and in vivo using recombinant vaccinia vectors was examined in the murine bladder tumor model. Vaccinia recombinants expressing the influenza hemagglutinin or nucleoprotein antigens infected/transfected murine (MB-49 and MBT-2) and human (T24) bladder tumor cell lines in vitro. Systemic vaccinia immunity was induced with as few as 10 plaque-forming units of recombinant vaccinia instilled intravesically, and the encoded protein was expressed in vivo in tumor and urothelium. However, preimmunity to vaccinia did not inhibit intravesical tumor transfection. Thus, recombinant vaccinia virus is effective in introducing foreign antigens locally into tumor in vivo, supporting its use in clinical immunotherapy.

Identification of overlapping class I and class II H-2d-restricted T cell determinants of influenza virus N1 neuraminidase that require infectious virus for presentation

The requirement for endogenous viral protein synthesis in helper and cytotoxic T cell (CTL) recognition of influenza virus was studied at the level of individual epitopes. The viral envelope glycoprotein neuraminidase (NA) contains class I and class II major histocompatibility complex (MHC)-restricted T cell determinants that are presented by virus-infected antigen-presenting cells (APC). We had previously shown that recognition of NA by class II I-Ed-restricted T cells required either active viral infection of APC or introduction of uv-inactivated virus to the cytosol, similar to the well-established requirements for class I-restricted responses. Detailed mapping of T cell epitopes was undertaken using vaccinia virus vectors encoding truncated segments of the influenza NA molecule and by synthetic peptides. Class I MHC-restricted CTL were found to recognize two regions of NA: residues 69-89 in the context of Dd and 191-201 presented by Kd. Analyses of T cell proliferation and T hybridoma clones revealed that class II-restricted responses recognized the same two regions as the CTL, presented by I-Ed and I-Ad, respectively. Interestingly, both class I and class II MHC-restricted T cells showed similar requirements for endogenously synthesized antigen, responding poorly or not at all to endocytosed uv-inactivated virus. This extends previous observations that specific epitopes can be preferentially presented by class II molecules from endogenously synthesized antigens and shows that the same antigenic determinants can have access to both class I and class II antigen presentation pathways.

Presentation of numerous viral peptides to mouse major histocompatibility complex (MHC) class I-restricted T lymphocytes is mediated by the human MHC-encoded transporter or by a hybrid mouse-human transporter

The major histocompatibility complex-encoded transporter associated with antigen processing (TAP) is required for the efficient presentation of cytosolic antigens to class I-restricted T cells. TAP is thought to be formed by the interaction of two gene products, termed TAP1 and TAP2. We find that TAPs consisting either of human subunits, or mouse TAP1 and human TAP2, facilitate the presentation of numerous defined viral peptides to mouse class I-restricted T cells. As human and mouse TAP2 and TAP1 differ in 23 and 28% of their residues, respectively, this indicates that TAP1 and TAP2 can form a functional complex with partners considerably different from those they coevolved with. Moreover, these findings indicate that widely disparate TAPs facilitate delivery of the same peptides to class I molecules. These findings suggest that TAP polymorphism does not greatly influence the types of peptides presented to the immune system.

Expression of a membrane protease enhances presentation of endogenous antigens to MHC class I-restricted T lymphocytes

We find that expression of the membrane dipeptidyl carboxypeptidase angiotensin-converting enzyme (ACE) enhances presentation of certain endogenously synthesized peptides to major histocompatibility complex (MHC) class I-restricted cytotoxic T lymphocytes. ACE appears to function only in an intracellular secretory compartment of antigen-presenting cells. ACE-enhanced antigen presentation requires the expression of the putative antigenic peptide transporters, TAP1 and TAP2. These findings demonstrate that a protease can influence the processing of endogenously synthesized antigens and strongly suggest that longer peptides can be transported from the cytosol to a secretory compartment where trimming of antigenic peptides to the lengths preferred by MHC class I molecules can occur if the appropriate protease is present.

A transient transfection system for identifying biosynthesized proteins processed and presented to class I MHC restricted T lymphocytes

CD8+ cytotoxic T lymphocytes (CTL) constitute a major portion of immune responses to foreign and self antigens. CTL recognize class I major histocompatibility complex molecules complexed to peptides of 8-10 residues derived from cytosolic proteins. To understand CTL responses to these antigens and to manipulate CTL responses optimally, it is necessary to identify the specific peptides recognized by CTL. The methods currently used for this purpose have significant drawbacks. We describe a plasmid transfection method that results in significant lysis of histocompatible target cells. Influenza virus-specific CTLs specifically lysed target cells that were transfected with plasmids bearing cDNAs encoding full length gene products, fragments containing the region that encodes the CTL epitope, or even a ten residue peptide. This significantly lessens the time and effort required to define genes, and gene segments that contain CTL epitopes.

Flanking sequences influence the presentation of an endogenously synthesized peptide to cytotoxic T lymphocytes

Cytotoxic T lymphocytes (CTL) recognize class I major histocompatibility complex molecules complexed to peptides of eight to nine residues generated from cytosolic proteins. We find that CTL recognize, in vitro and in vivo, cells synthesizing a 10-residue peptide consisting of an initiating methionine followed by nine residues corresponding to a naturally processed determinant from influenza virus nucleoprotein (NP) (residues 147-155). Addition of two COOH-terminal residues corresponding to NP residues 157 and 158 severely reduced presentation of the endogenously produced peptide to CTL in vitro and in vivo. Extension of NH2 and COOH terminal flanking residues to include residues corresponding to NP residues 137-146 and 159-168 failed to increase the antigenicity of this peptide. Its presentation was greatly enhanced, however, by further extending the NH2 and COOH termini to include all of the additional residues of NP. These findings indicate first, that a naturally processed viral ligand (with an NH2-terminal Met) of a class I molecule contains sufficient information to access intracellular class I molecules, and second, that flanking residues can influence the processing and presentation of antigens to CTL.

Immunogenic peptides of influenza virus subtype N1 neuraminidase identify a T-cell determinant used in class II major histocompatibility complex-restricted responses to infectious virus

Six nonoverlapping peptides of the neuraminidase (NA) glycoprotein of influenza virus A/Puerto Rico/8/34 (H1N1) (PR8 virus) were found to be immunogenic for proliferating T cells when injected into BALB/c mice in Freund adjuvant. T cells elicited by peptide immunization could recognize PR8 virus in vitro. However, only one of these peptides, corresponding to residues 79 to 93 of NA (NA 79-93), was able to restimulate T cells of mice immunized with infectious virus. T cells that recognized this peptide were uniformly I-Ed restricted, yet infectious influenza virus was required for responses. NA 79-93-specific T-hybridoma clones raised by immunization either with whole virus or with the synthetic peptide alone each responded to replicative virus and not to UV-inactivated virions. These data suggest that the NA 79-93 T-cell determinant which is commonly presented during an encounter with influenza virus in vivo is processed preferentially from NA synthesized within antigen-presenting cells.

Virus entry and antigen biosynthesis in the processing and presentation of class-II MHC-restricted T-cell determinants of influenza virus

Receptor-mediated uptake of influenza virus is responsible for efficient introduction of virus particles to APC. This leads to the effective presentation to T-cells of very small concentrations of proteins entering on the intact virus. Endocytosed virus transits rapidly to the endosome compartment. Entry into this environment appears to greatly affect the fate of T-cell determinants. While promoting the presentation of determinants which require extensive antigen processing, the intracellular environment appears also to lead to destruction of labile determinants, such as those of NA. The same NA determinants are efficiently presented by actively infected cells, indicating that newly biosynthesized viral proteins need not be subjected to the same handling as internalized viral particles. In a similar way, site 3 of HA, which, in a single pulse of noninfectious virus or isolated HA protein is expressed with a relatively short half-life, has greatly improved levels of duration and expression on actively infected APC. Since certain T(H) determinants are unavailable or poorly expressed when introduced on nonreplicative influenza virus, vaccination with inactivated virus might have limitations in stimulating T(H) as well as class-I responses. Finally, individual T-cell determinants of the same protein can exhibit distinct patterns of expression and persistence on APC surfaces. These different half-lives of T(H) determinants may be influential in determining immuno-dominance of T-cell sites. Determinants that are longer-lived on APC may have a greater probability of interacting with appropriate T(H) precursors, which could lead to an enhanced T-cell response to that region of the viral protein.

Antigen presentation requires transport of MHC class I molecules from the endoplasmic reticulum

The role of exocytosis of major histocompatibility complex (MHC) class I molecules in the presentation of antigens to mouse cytotoxic T lymphocytes (CTLs) was examined by use of a recombinant vaccinia virus that expresses the E19 glycoprotein from adenovirus. E19 blocked the presentation of vaccinia and influenza virus proteins to CTLs in a MHC class I allele-specific manner identical to its inhibition of MHC class I transport from the endoplasmic reticulum. This finding indicates that (i) the relevant parameter for antigen presentation is the rate of MHC class I molecule exocytosis, not the level of class I cell surface expression, and (ii) association of class I molecules with antigen is likely to occur within the endoplasmic reticulum.

Murine cell lines stably expressing the influenza virus hemagglutinin gene introduced by a recombinant retrovirus vector are constitutive targets for MHC class I- and class II-restricted T lymphocytes

A retrovirus vector containing the hemagglutinin (HA) gene of influenza virus was constructed and used to infect murine cell lines of fibroblast, mastocytoma and B cell lineages which are able to present antigens to MHC-restricted T cells. Stable cell lines were selected in which the retrovirus vector integrated as a single copy in almost all of the individual cell clones examined. The HA mRNA was shown to be of the expected length by Northern blot analysis, but the levels varied among the cell clones. Although the HA transcript was difficult to detect in any of the retrovirus-infected cell clones derived from fibroblasts, HA Ag was easily detected on the cell surface by cytofluorographic analysis. Significantly, retrovirus-infected clones derived from each cell type were recognized by HA-specific class I and class II MHC-restricted T lymphocytes. HA produced in these cells was able to be acquired, processed, and presented to class II-restricted T cells by additional, non-HA-expressing APC. This indicates that HA endogenously synthesized within these cell lines is available for Ag processing by an exogenous route.

Murine cell lines stably expressing the influenza virus hemagglutinin gene introduced by a recombinant retrovirus vector are constitutive targets for MHC class I- and class II-restricted T lymphocytes

A retrovirus vector containing the hemagglutinin (HA) gene of influenza virus was constructed and used to infect murine cell lines of fibroblast, mastocytoma and B cell lineages which are able to present antigens to MHC-restricted T cells. Stable cell lines were selected in which the retrovirus vector integrated as a single copy in almost all of the individual cell clones examined. The HA mRNA was shown to be of the expected length by Northern blot analysis, but the levels varied among the cell clones. Although the HA transcript was difficult to detect in any of the retrovirus-infected cell clones derived from fibroblasts, HA Ag was easily detected on the cell surface by cytofluorographic analysis. Significantly, retrovirus-infected clones derived from each cell type were recognized by HA-specific class I and class II MHC-restricted T lymphocytes. HA produced in these cells was able to be acquired, processed, and presented to class II-restricted T cells by additional, non-HA-expressing APC. This indicates that HA endogenously synthesized within these cell lines is available for Ag processing by an exogenous route.

Class II major histocompatibility complex-restricted T cells specific for a virion structural protein that do not recognize exogenous influenza virus. Evidence that presentation of labile T cell determinants is favored by endogenous antigen synthesis

The contribution of viral infectivity to the expression of MHC class II-restricted T cell determinants was studied. A murine I-Ed-restricted T cell hybridoma recognizing the neuraminidase (NA) glycoprotein of influenza PR8 virus was stimulated strongly by infectious virus but failed to recognize antigen introduced on noninfectious virions. Recognition correlated with the de novo synthesis of viral NA within infected APC. The effectiveness of infectious virus did not depend strictly upon the amount of NA present in cultures, since high NA concentrations could be achieved by addition of nonreplicative virus without being stimulatory for NA-specific T cells. Recognition of a determinant generated only when synthesized in murine host cells was ruled out, since, in high concentration, NA isolated from purified egg-grown virions, even if reduced and alkylated, was recognized by the T hybridoma clone. Isolated NA was recognized when added to pre-fixed APC, suggesting that this form of antigen was able to bypass the usual processing pathway of exogenous proteins. Data suggest that endogenously synthesized antigen may contribute most significantly to presentation of labile T cell determinants. In addition to NA, recognition of an I-Ed-restricted determinant of the influenza hemagglutinin (HA) molecule, shown previously to have a relatively short half-life on APC surfaces, was enhanced greatly by infectious virus. In contrast, T cell recognition of a more stably expressed I-Ed-restricted site of the same HA polypeptide was only marginally improved on infected APC.

Individual class II-restricted antigenic determinants of the same protein exhibit distinct kinetics of appearance and persistence on antigen-presenting cells

The kinetics of presentation of class II-restricted T cell determinants of influenza virus hemagglutinin (HA) was investigated over a 48-h time course after pulsing of A20 B lymphoma APC with non-replicative virus or isolated HA. At intervals after Ag pulse, APC were fixed with paraformaldehyde to arrest Ag processing and to preserve the expression levels of the presented determinants. Expression of T cell sites at each time point was probed by a panel of BALC/c T hybridomas specific for the HA of influenza A/Puerto Rico/8/34 virus, recognizing either site 1 (residues 111 to 119), site 2 (126 to 138), or site 3 (302 to 313). Characteristic patterns of presentation were observed for each site: sites 2 and 3 achieved maximal expression by 8 h post pulse, but declined thereafter, whereas site 1 presentation continued to increase over time. The quantitative expression of each T cell site was affected by the proteolysis inhibitor leupeptin, resulting in partial inhibition of site 1, complete blocking of site 2, but enhancement of site 3. However, the expression kinetics of sites 1 and 3, which could be observed in the presence of the inhibitor, remained qualitatively unchanged. These observations indicate that some T cell determinants (e.g., HA site 1) may exhibit a greater longevity of expression on APC than other antigenic sites of the same protein. Differences in the persistence of surface expression of distinct T cell sites may be a factor in their relative immunodominance.

Individual class II-restricted antigenic determinants of the same protein exhibit distinct kinetics of appearance and persistence on antigen-presenting cells

The kinetics of presentation of class II-restricted T cell determinants of influenza virus hemagglutinin (HA) was investigated over a 48-h time course after pulsing of A20 B lymphoma APC with non-replicative virus or isolated HA. At intervals after Ag pulse, APC were fixed with paraformaldehyde to arrest Ag processing and to preserve the expression levels of the presented determinants. Expression of T cell sites at each time point was probed by a panel of BALC/c T hybridomas specific for the HA of influenza A/Puerto Rico/8/34 virus, recognizing either site 1 (residues 111 to 119), site 2 (126 to 138), or site 3 (302 to 313). Characteristic patterns of presentation were observed for each site: sites 2 and 3 achieved maximal expression by 8 h post pulse, but declined thereafter, whereas site 1 presentation continued to increase over time. The quantitative expression of each T cell site was affected by the proteolysis inhibitor leupeptin, resulting in partial inhibition of site 1, complete blocking of site 2, but enhancement of site 3. However, the expression kinetics of sites 1 and 3, which could be observed in the presence of the inhibitor, remained qualitatively unchanged. These observations indicate that some T cell determinants (e.g., HA site 1) may exhibit a greater longevity of expression on APC than other antigenic sites of the same protein. Differences in the persistence of surface expression of distinct T cell sites may be a factor in their relative immunodominance.

Acid-induced conformational modification of the hemagglutinin molecule alters interaction of influenza virus with antigen-presenting cells

Brief exposure of influenza virus to pH 5 was found to have extensive effects upon presentation of viral Th cell antigenic determinants. This acidity, comparable to that encountered in host cell endosomes, was known to effect conformational changes in the viral hemagglutinin (HA) which alter the molecule's fusion activity, antigenicity, and susceptibility to enzymes. Three major effects of low pH upon presentation of viral T cell determinants were observed: first, acid pretreatment permitted presentation by pre-fixed APC of two of three linear T cell sites of the HA molecule, bypassing the APC activity required to present untreated virus; second, the two determinants presented in this manner disappeared rapidly from APC surfaces; third, acid-pretreated virus was not efficiently utilized by active APC in the normal pathway of viral antigen presentation. These observations suggest that the pH-induced conformational transition of HA may constitute sufficient processing for certain linear determinants of the molecule and additionally influences the processes involved in the general formation and presentation of viral T cell sites.

Acid-induced conformational modification of the hemagglutinin molecule alters interaction of influenza virus with antigen-presenting cells

Brief exposure of influenza virus to pH 5 was found to have extensive effects upon presentation of viral Th cell antigenic determinants. This acidity, comparable to that encountered in host cell endosomes, was known to effect conformational changes in the viral hemagglutinin (HA) which alter the molecule's fusion activity, antigenicity, and susceptibility to enzymes. Three major effects of low pH upon presentation of viral T cell determinants were observed: first, acid pretreatment permitted presentation by pre-fixed APC of two of three linear T cell sites of the HA molecule, bypassing the APC activity required to present untreated virus; second, the two determinants presented in this manner disappeared rapidly from APC surfaces; third, acid-pretreated virus was not efficiently utilized by active APC in the normal pathway of viral antigen presentation. These observations suggest that the pH-induced conformational transition of HA may constitute sufficient processing for certain linear determinants of the molecule and additionally influences the processes involved in the general formation and presentation of viral T cell sites.

Role of receptor-binding activity of the viral hemagglutinin molecule in the presentation of influenza virus antigens to helper T cells

The concentration of antigen required to stimulate influenza virus-specific helper T cells was observed to be dependent upon the antigenic form bearing the relevant determinant: intact, nonreplicative virus was needed only in picomolar amounts, while denatured proteins, protein fragments, or synthetic peptides were required in micromolar concentrations for a threshold level of stimulation. Antigenic efficiency of intact virus was found to result from the attachment of virus to sialic acid residues on the surface of the antigen-presenting cell since spikeless viral particles lacking the hemagglutinin molecule were much less efficient antigens for helper T cells and continuous presence of hemagglutination-inhibiting antihemagglutinin antibodies reduced efficiency of stimulation by intact virus approximately 100-fold for both hemagglutinin and internal virion proteins. Influenza virus associated rapidly with antigen-presenting cells; less than 10 min at 20 degrees C was sufficient to introduce virus for a maximal level of T-cell stimulation. This rapid attachment was blocked by antibodies to the hemagglutinin or by pretreatment of the antigen-presenting cells with neuraminidase to remove the cellular virus receptor. Following viral adsorption by antigen-presenting cells, a lag period of 30 min at 37 degrees C was required for the expression of helper T-cell determinants. One early event identified was the movement of the virus to a neuraminidase-insensitive compartment, which can occur at 10 degrees C, but which was not equivalent to expression of helper T-cell determinants. Preincubation of cells with virus at 10 degrees C for 4 h reduced the lag period of helper T-cell determinant expression to 15 min when these cells were shifted to 37 degrees C, suggesting that transition of the virus to a neuraminidase-resistant state is a required step in presentation of T-cell antigenic determinants.

Physarum myosin light chain binds calcium

Myosin from the slime mold Physarum polycephalum contains three sizes of polypeptides: a heavy chain and two light chains, LC-1 and LC-2. Using a simple qualitative test for calcium binding by comparing electrophoretic migration of the polypeptides in sodium dodecyl sulfate (SDS) acrylamide gels in the presence and absence of calcium, we have found that Physarum myosin light chain LC-2 migrates with an apparent molecular weight of 16,900 daltons in the presence of the metal ion chelator ethylene glycol bis (B-aminoethyl ether) N,N'-tetraacetic acid (EGTA). However, if calcium chloride is added to the sample prior to electrophoresis, the apparent molecular weight decreases to 16,100. Lanthanide and cadmium ions, but not magnesium, can substitute for calcium. Because the ionic radii of Ca2+, La3+, and Cd2+ are almost identical, we conclude that Physarum myosin LC-2 possesses a very size-specific binding site for calcium. Physarum myosin LC-1 and the heavy chain give no evidence for binding calcium by this test. Since cytoplasmic streaming in the plasmodium of Physarum requires calcium, our evidence indicates that the calcium-binding property of Physarum myosin LC-2 may be important in regulating the production of force by actomyosin in the ectoplasm. Unexpectedly, the myosin light chain in Physarum capable of binding calcium, LC-2, is the essential light chain, while LC-1 is a member of the regulatory class of myosin light chains [V. T. Nachmias, personal communication]. Until now, essential myosin light chains have not been shown to have high affinity divalent cation binding sites. This means a new version of the myosin-based model for actomyosin regulation by calcium may be required to explain cytoplasmic movement in Physarum, and perhaps in other motile systems involving cytoplasmic myosins as well.