In vivo T-cell depletion with pretransplant low-dose antithymocyte globulin is associated with reduced transplant-related mortality and improved clinical outcome in patients receiving allogeneic hematopoietic stem cell transplantation from unrelated and partially matched related donors.

Graft versus host disease (GVHD) represents one of the major limiting factors to the successful applicability of hematopoietic stem cells transplantation (HSCT). In particular, allogeneic HSCT from alternative donors with unmanipulated graft results in an increased risk of both acute and chronic GVHD compared with matched sibling donor transplants [1]. At the present, none of the GVHD prophylactic strategies currently in use, including calcineurin inhibitors [2], T-lymphocyte depletion, and monoclonal antibodies [3,4], have been proven to be of superior efficacy over another.

Expression and functional regulation of myoglobin in epithelial cancers.

Myoglobin is a multifunctional heme protein that is thought to be expressed exclusively in myocytes. Its importance in both oxygen transport and free radical scavenging has been extensively characterized. We hypothesized that solid tumors could take advantage of proteins such as myoglobin to cope with hypoxic conditions and to control the metabolism of reactive oxygen and nitrogen species. We therefore sought to establish whether myoglobin might be expressed and functionally regulated in epithelial tumors that are known to face hypoxia and oxidative stress during disease progression. We analyzed the expression of myoglobin in human epithelial cancers at both transcriptional and protein levels; moreover, we investigated the expression levels of myoglobin in cancer cell lines subjected to different conditions, including hypoxia, oxidative stress, and mitogenic stimuli. We provide evidence that human epithelial tumors, including breast, lung, ovary, and colon carcinomas, express high levels of myoglobin from the earliest stages of disease development. In human cancer cells, myoglobin is induced by a variety of signals associated with tumor progression, including mitogenic stimuli, oxidative stress, and hypoxia. This study provides evidence that myoglobin, previously thought to be restricted to myocytes, is expressed at high levels by human carcinoma cells. We suggest that myoglobin expression is part of a cellular program aimed at coping with changed metabolic and environmental conditions associated with neoplastic growth.

Replacement of normal with mutant alleles in the genome of normal human cells unveils mutation-specific drug responses.

Mutations in oncogenes and tumor suppressor genes are responsible for tumorigenesis and represent favored therapeutic targets in oncology. We exploited homologous recombination to knock-in individual cancer mutations in the genome of nontransformed human cells. Sequential introduction of multiple mutations was also achieved, demonstrating the potential of this strategy to construct tumor progression models. Knock-in cells displayed allele-specific activation of signaling pathways and mutation-specific phenotypes different from those obtainable by ectopic oncogene expression. Profiling of a library of pharmacological agents on the mutated cells showed striking sensitivity or resistance phenotypes to pathway-targeted drugs, often matching those of tumor cells carrying equivalent cancer mutations. Thus, knock-in of single or multiple cancer alleles provides a pharmacogenomic platform for the rational design of targeted therapies.