High frequency of antitumor T cells in the blood of melanoma patients before and after vaccination with tumor antigens

After vaccination of melanoma patients with MAGE antigens, we observed that even in the few patients showing tumor regression, the frequency of anti-vaccine T cells in the blood was often either undetectable or <10−5 of CD8 T cells. This frequency being arguably too low for these cells to be sole effectors of rejection, we reexamined the contribution of T cells recognizing other tumor antigens. The presence of such antitumor T cells in melanoma patients has been widely reported. To begin assessing their contribution to vaccine-induced rejection, we evaluated their blood frequency in five vaccinated patients. The antitumor cytotoxic T lymphocyte (CTL) precursors ranged from 10−4 to 3 × 10−3, which is 10–10,000 times higher than the anti-vaccine CTL in the same patient. High frequencies were also observed before vaccination. In a patient showing nearly complete regression after vaccination with a MAGE-3 antigen, we observed a remarkably focused antitumoral response. A majority of CTL precursors (CTLp's) recognized antigens encoded by MAGE-C2, another cancer-germline gene. Others recognized gp100 antigens. CTLp's recognizing MAGE-C2 and gp100 antigens were already present before vaccination, but new clonotypes appeared afterwards. These results suggest that a spontaneous antitumor T cell response, which has become ineffective, can be reawakened by vaccination and contribute to tumor rejection. This notion is reinforced by the frequencies of anti-vaccine and antitumor CTLs observed inside metastases, as presented by Lurquin et al. (Lurquin, C., B. Lethé, V. Corbière, I. Théate, N. van Baren, P.G. Coulie, and T. Boon. 2004. J. Exp. Med. 201:249–257)

MAGE-C2 antigenic peptides and uses thereof

This invention relates to isolated peptides derived from MAGE-C2, nucleic acid molecules that encode MAGE-C2 and the isolated peptides derived from MAGE-C2, expression vectors comprising the nucleic acid molecules, host cells transformed or transfected with the nucleic acid molecules or the expression vectors, and to tetramers comprising the peptides, HLA molecules, [exist]2 microglobulin and a first and second binding partner. This invention also relates to methods for using the peptides, nucleic acid molecules, expression vectors, tetramers and complexes of this invention as well as to cytolytic T cells which recognize the peptides in complex with an HLA molecule

MAGE-C2 antigenic peptides and uses thereof

This invention relates to isolated peptides derived from MAGE-C2, nucleic acid molecules that encode MAGE-C2 and the isolated peptides derived from MAGE-C2, expression vectors comprising the nucleic acid molecules, host cells transformed or transfected with the nucleic acid molecules or the expression vectors, and to tetramers comprising the peptides, HLA molecules, beta2 microglobulin and a first and second biding partner. This invention also relates to methods for using the peptides, nucleic acid molecules, expression vectors, tetramers and complexes of this invention as well as to cytolytic T cells which recognize the peptides in complex with an HLA molecule

A MAGE-C2 antigenic peptide processed by the immunoproteasome is recognized by cytolytic T cells isolated from a melanoma patient after successful immunotherapy

We have pursued our analysis of a melanoma patient who showed almost complete tumor regression following vaccination with MAGE-A1 and MAGE-A3 antigens. We previously described high frequencies of tumor-specific CTL precursors in blood samples collected after but also before vaccination. A set of CTL clones were derived that recognized antigens different from those of the vaccine. Two of these antigens were peptides encoded by another MAGE gene, MAGE-C2. Here we describe the antigen recognized by another tumor-specific CTL clone. It proved to be a third antigenic peptide encoded by gene MAGE-C2, ASSTLYLVF. It is presented by HLA-B57 molecules and proteasome-dependent. Tumor cells exposed to interferon-gamma (IFN-γ) were better recognized by the anti-MAGE-C2(42-50) CTL clone. This mainly resulted from a better processing of the peptide by the immunoproteasome as compared to the standard proteasome. Mass spectrometric analyses showed that the latter destroyed the antigenic peptide by cleaving between two internal hydrophobic residues. Despite its higher "chymotryptic-like" (posthydrophobic) activity, the immunoproteasome did not cleave at this position, in line with the suggestion that hydrophobic residues immediately downstream from a cleavage site impair cleavage by the immunoproteasome. We previously reported that one of the other MAGE-C2 peptides recognized by CTL from this patient was also better processed by the immunoproteasome. Together, these results support the notion that the tumor regression of this patient was mediated by an antitumor response shaped by IFN-γ and dominated by CTL directed against peptides that are better produced by the immunoproteasome, such as the MAGE-C2 peptides

Elevated right ventricular pressures are not a contraindication to liver transplantation in Alagille syndrome.

BACKGROUND: Elevated right ventricle pressure resulting from pulmonary artery stenoses may affect outcome and survival after liver transplantation in patients with Alagille syndrome. METHODS AND RESULTS: Between 1984 and 1997, among 444 pediatric liver transplant recipients, 17 had liver transplantation for Alagille syndrome (mean age 3.5 years, range 1.2-13 years), mainly because of poor quality of life with intractable pruritus, and failure to thrive. All patients had pulmonary artery stenosis. In 10 patients considered to have elevated RV pressure on ECG and/or Doppler-echocardiography, a cardiac catheterization was performed before liver transplantation. Mean RV systolic pressure was 55 mmHg (median 49.5 mmHg, range 35-98 mm Hg), mean RV to left ventricular systolic pressure ratio 0.53 (median 0.53, range 0.29-0.78) with a ratio above 0.5 in 6 patients (median 0.66, range 0.5-0.8). All patients underwent successful liver transplantation. Five patients died 1 to 9 months after transplantation from noncardiac causes. In two of them, cardiac catheterization before transplantation showed a RV to left ventricular pressure ratio of 0.51 in one and 0.37 in the second. In the three others, echocardiography before transplantation estimated RV pressures below 0.5 systemic pressures. At follow-up (median 6 years, range 1.5-15 years), liver tests were normal in all, none complained of pruritus and body weight was normalized in 70%. None of the patients presented cardiac symptoms, arrhythmias, or worsening of their cardiac status. CONCLUSIONS: Liver transplantation can be performed safely in children with Alagille syndrome, even in the presence of elevated right ventricular pressure