First-in-Human Case Study: Multipotent Adult Progenitor Cells for Immunomodulation After Liver Transplantation.

Mesenchymal stem cells and multipotent adult progenitor cells (MAPCs) have been proposed as novel therapeutics for solid organ transplant recipients with the aim of reducing exposure to pharmacological immunosuppression and its side effects. In the present study, we describe the clinical course of the first patient of the phase I, dose-escalation safety and feasibility study, MiSOT-I (Mesenchymal Stem Cells in Solid Organ Transplantation Phase I). After receiving a living-related liver graft, the patient was given one intraportal injection and one intravenous infusion of third-party MAPC in a low-dose pharmacological immunosuppressive background.

Autologous cell therapies: the importance of regulatory oversight.

Promising new medical technologies and approaches to treatment offer the potential to substantially improve the lives of patients who need help, and in some cases transform the way medicine is practiced. In recent years, the biotechnology industry has generated many examples of new approaches that are having a profound impact on medical care, including protein and peptide therapeutics, monoclonal antibodies and molecular diagnostics.

Company profile: Athersys.

Athersys (Nasdaq: ATHX) is a biopharmaceutical company engaged in the discovery and development of novel therapies designed to treat significant unmet medical needs. The company is heavily focused on the regenerative medicine area, with multiple clinical and preclinical stage programs. The most advanced programs at the company are focused on the development of MultiStem®, a clinical stage allogeneic stem cell therapy that has demonstrated potential for treating a range of conditions and is believed to have widespread application in the field of regenerative medicine.

Efficient assembly of de novo human artificial chromosomes from large genomic loci.

Background: Human artificial chromosomes (HACs) are potentially useful vectors for gene transfer studies and for functional annotation of the genome because of their suitability for cloning, manipulating and transferring large segments of the genome. However, development of HACs for the transfer of large genomic loci into mammalian cells has been limited by difficulties in manipulating high-molecular weight DNA, as well as by the low overall frequencies of de novo HAC formation. Indeed, to date, only a small number of large (>100 kb) genomic loci have been reported to be successfully packaged into de novo HACs.

Rapid creation of BAC-based human artificial chromosome vectors by transposition with synthetic alpha-satellite arrays.

Efficient construction of BAC-based human artificial chromosomes (HACs) requires optimization of each key functional unit as well as development of techniques for the rapid and reliable manipulation of high-molecular weight BAC vectors. Here, we have created synthetic chromosome 17-derived alpha-satellite arrays, based on the 16-monomer repeat length typical of natural D17Z1 arrays, in which the consensus CENP-B box elements are either completely absent (0/16 monomers) or increased in density (16/16 monomers) compared to D17Z1 alpha-satellite (5/16 monomers). Using these vectors, we show that the presence of CENP-B box elements is a requirement for efficient de novo centromere formation and that increasing the density of CENP-B box elements may enhance the efficiency of de novo centromere formation.