Efficacy and Safety of Daratumumab in Intermediate/High-risk Smoldering Multiple Myeloma: Final Analysis of CENTAURUS.

Early intervention of smoldering multiple myeloma (SMM) may delay progression to multiple myeloma. Here, we present the final analysis of the phase 2 CENTAURUS study (NCT02316106). In total, 123 patients with intermediate/high-risk SMM were randomized to intravenous daratumumab 16 mg/kg following a Long intense (n = 41), Intermediate (n = 41), or Short intense (n = 41) dosing schedule.

Daratumumab, Bortezomib, Lenalidomide, and Dexamethasone for Multiple Myeloma.

Background: Daratumumab, a monoclonal antibody targeting CD38, has been approved for use with standard myeloma regimens. An evaluation of subcutaneous daratumumab combined with bortezomib, lenalidomide, and dexamethasone (VRd) for the treatment of transplantation-eligible patients with newly diagnosed multiple myeloma is needed.

Methods: In this phase 3 trial, we randomly assigned 709 transplantation-eligible patients with newly diagnosed multiple myeloma to receive either subcutaneous daratumumab combined with VRd induction and consolidation therapy and with lenalidomide maintenance therapy (D-VRd group) or VRd induction and consolidation therapy and lenalidomide maintenance therapy alone (VRd group).

Identification and characterization of side population cells in embryonic stem cell cultures.

Marker and functional heterogeneity has been described for embryonic stem cells (ESCs). This property has been correlated with the presence of ESC subpopulations resembling pluripotent cell lineages of the embryo. The ability to efflux Hoechst (Ho) displayed by side population (SP) cells has proven valuable as a marker to identify multipotent stem cells from a variety of tissues.

Pluripotentiality and conditional transgene regulation in human embryonic stem cells expressing insulated tetracycline-ON transactivator.

Conditional manipulation of gene expression by using tetracycline (TET)-ON based approaches has proven invaluable to study fundamental aspects of biology; however, the functionality of these systems in human embryonic stem cells (hESC) has not been established. Given the sensitivity of these cells to both genetic manipulation and variations of culture conditions, constitutive expression of TET transactivators might not only be toxic for hESC but might also impair their ability to self-renew or differentiate into multiple tissues. Therefore, the effect of these transactivators on the biology and pluripotentiality of hESC must first be evaluated before broad use of TET-ON methodologies is applied in these cells.

Plasticity and tissue regenerative potential of bone marrow-derived cells.

Diverse in vivo studies have suggested that adult stem cells might have the ability to differentiate into cell types other than those of the tissues in which they reside or derive during embryonic development. This idea of stem cell "plasticity" has led investigators to hypothesize that, similar to embryonic stem cells, adult stem cells might have unlimited tissue regenerative potential in vivo, and therefore, broad and novel therapeutic applications. Since the beginning of these observations, our group has critically examined these exciting possibilities for mouse bone marrow-derived cells by taking advantage of well-characterized models of tissue regeneration, Cre/lox technology, and novel stem cell isolation protocols.

Altered subcellular localization and low frequency of mutations of ING1 in human brain tumors.

Purpose: Clinical and experimental evidence suggest that the p33ING1b candidate tumor suppressor functionally cooperates with p53 in controlling biochemical and biological functions. Because p53 is frequently mutated in brain tumors and the ING1 locus maps to a site of which the loss is associated with gliomas, we analyzed the mutation and expression profiles of ING1B in human brain tumors. Here we present the first report of ING1 expression and mutation analyses in human brain tumor samples and malignant glioma cell lines.

ING1 represses transcription by direct DNA binding and through effects on p53.

The ING family of proteins is involved in the regulation of diverse processes ranging from cell cycle and cellular senescence to apoptosis. These effects are most likely through activation of acetylation-dependent pathways that ultimately alter gene expression. Despite reports linking ING to p53 activation, the molecular basis of how ING activates p53 function has not been elucidated.

ING1 isoforms differentially affect apoptosis in a cell age-dependent manner.

Recently, several novel human ING1 isoforms have been cloned. However,the biochemical functions and the involvement of these proteins in apoptosis remain uncharacterized. We have examined the apoptotic effects and biochemical functions of the two major human ING1 isoforms p47(ING1a) and p33(ING1b) in young and senescent human diploid fibroblasts induced to enter into apoptosis by diverse treatments.

Human ING1 proteins differentially regulate histone acetylation.

ING1 proteins are nuclear, growth inhibitory, and regulate apoptosis in different experimental systems. Here we show that similar to their yeast homologs, human ING1 proteins interact with proteins associated with histone acetyltransferase (HAT) activity, such as TRRAP, PCAF, CBP, and p300. Human ING1 immunocomplexes contain HAT activity, and overexpression of p33(ING1b), but not of p47(ING1a), induces hyperacetylation of histones H3 and H4, in vitro and in vivo at the single cell level.