The present invention refers to the use of gene sequences or portions thereof characterized in that the same belong to the classes of in vitro and ex vivo induced, repressed or conserved genes in Mycobacterium tuberculosis currently infected human macrophages and to corresponding peptides or consensus peptides or proteins for the preparation of specific bio-markers for the diagnosis and prevention of active or latent disease.

The application relates to methods of treating chronic viral infection by modulating Tim-3 activity. In addition, the present application relates to methods of diagnosing or monitoring immune system activity or function, chronic viral infection and inflammatory disease using Tim-3 expression.

Means that enables monitoring of an anticancer effect of an anti-CD4 antibody or an anticancer drug targeting an immune checkpoint is disclosed. The method for testing a therapeutic effect of a cancer therapy of the present invention is a method for testing a therapeutic effect of an anticancer drug comprising as an effective ingredient an anti-CD4 antibody or an anticancer drug targeting an immune checkpoint, which method comprises investigation of expression of (1) at least one immune checkpoint receptor, (2) CD8, and (3) at least one cell surface molecule selected from the group consisting of CD44 and CD45RO, on T cells using a sample derived from a patient who received the anticancer drug. Induction of a T cell population which is positive for the immune checkpoint molecule (1) and positive for CD8, and which shows high expression of CD44 and/or high expression of CD45RO, indicates that said anticancer drug is producing a therapeutic effect in said patient.

A method for predicting whether a patient will be a long-term survivor on treatment of a disease by adoptive cell transfer (ACT), is disclosed comprising: (i) analysing a blood-derived sample obtained from the patient for one or more prognostic markers of long-term survival on treatment of a disease by ACT, and; (ii) based on the analysis of step (i), predicting whether the patient will be a long-term survivor on treatment of the disease by ACT. Also disclosed are methods for treating a patient by ACT, methods for selecting a patient for treatment by ACT, and methods for selecting a patient for treatment of a disease by ACT.

The invention provides methods and compositions for the diagnosis, prognosis, and/or treatment response characterization of individuals suffering from systemic lupus erythematosus (SLE) using single cell network profiling.

The invention relates to panels of biomarkers for diagnosing and/or monitoring the progression of an active mycobacterial infection or for diagnosing the absence of a mycobacterial infection, particularly tuberculosis. Such diagnosis and/or monitoring may be differential diagnosis between active tuberculosis patients and patients with latent, non-progressing tuberculosis or healthy or sick patients, irrespective of whether the patients have been characterised as being sputum smear positive or sputum smear negative, and/or irrespective of whether they have been characterised as being HIV positive or HIV negative. The above pertain in all aspects both to pulmonary and extra pulmonary Mycobacterium tuberculosis infections, with Mycobacterium tuberculosis being the causative organism in tuberculosis.

The present invention relates to combination therapies useful for the treatment of cancer. In particular, the invention relates to a therapeutic combination which comprises a PD-1 antagonist, an ATR inhibitor and a platinating agent.

The present invention concerns a composition comprising at least three peptides derived from Mycobacterium tuberculosis antigen Rv2626c, its use in the diagnostic of latently infected Mycobacterium tuberculosis (LTBI) subjects, corresponding methods of use and kits.

The present invention relates to Mycobacterium tuberculosis (M tuberculosis) proteins and immunologically active fragments (peptides or mimotope peptides) thereof. In particular, the invention relates to a group of M. tuberculosis proteins and peptides thereof that are both highly antigenic and characteristic of clinical strains of M. tuberculosis. Accordingly, the further relates to the use of these M. tuberculosis proteins or peptides in diagnosing, treating or preventing M. tuberculosis complex infection.

The present invention provides a method for enhancing immune cell function by activating various immune cells ex vivo and provides immune cells with enhanced function. The invention further provides an immune-related cell multifunctionality evaluation method. A biguanide antidiabetic drug selected from metformin, phenformin, and buformin is capable of enhancing immune cell multifunctionality by increasing CD8+T cells having a high ability to produce IL-2, INFα, and IFNγ. The immune-related cell multifunctionality may be evaluated by comparing immune cells treated with a biguanide antidiabetic drug selected from metformin, phenformin, and buformin, with control immune cells untreated with the biguanide antidiabetic drug. When the multifunctionality of immune cells treated with the biguanide antidiabetic drug selected from metformin, phenformin, and buformin is determined to be significantly increased compared with the control, it can be evaluated that the sensitivity of the immune cells to the therapeutic agent is improved.