Dependence of human cell survival and proliferation on the CASP3 prodomain.

Mechanisms that regulate cell survival and proliferation are important for both the development and homeostasis of normal tissue, and as well as for the emergence and expansion of malignant cell populations. Caspase-3 (CASP3) has long been recognized for its proteolytic role in orchestrating cell death-initiated pathways and related processes; however, whether CASP3 has other functions in mammalian cells that do not depend on its known catalytic activity have remained unknown. To investigate this possibility, we examined the biological and molecular consequences of reducing CASP3 levels in normal and transformed human cells using lentiviral-mediated short hairpin-based knockdown experiments in combination with approaches designed to test the potential rescue capability of different components of the CASP3 protein. The results showed that a ≥50% reduction in CASP3 levels rapidly and consistently arrested cell cycle progression and survival in all cell types tested. Mass spectrometry-based proteomic analyses and more specific flow cytometric measurements strongly implicated CASP3 as playing an essential role in regulating intracellular protein aggregate clearance. Intriguingly, the rescue experiments utilizing different forms of the CASP3 protein showed its prosurvival function and effective removal of protein aggregates did not require its well-known catalytic capability, and pinpointed the N-terminal prodomain of CASP3 as the exclusive component needed in a diversity of human cell types. These findings identify a new mechanism that regulates human cell survival and proliferation and thus expands the complexity of how these processes can be controlled. The graphical abstract illustrates the critical role of CASP3 for sustained proliferation and survival of human cells through the clearance of protein aggregates.

Aging alters the cell cycle control and mitogenic signaling responses of human hematopoietic stem cells.

Human hematopoietic stem cells (HSCs), like their counterparts in mice, comprise a functionally and molecularly heterogeneous population of cells throughout life that collectively maintain required outputs of mature blood cells under homeostatic conditions. In both species, an early developmental change in the HSC population involves a postnatal switch from a state in which most of these cells exist in a rapidly cycling state and maintain a high self-renewal potential to a state in which the majority of cells are in a quiescent state with an overall reduced self-renewal potential. However, despite the well-established growth factor dependence of HSC proliferation, whether and how this mechanism of HSC regulation might be affected by aging has remained poorly understood. To address this knowledge gap, we isolated highly HSC-enriched CD34+CD38-CD45RA-CD90+CD49f+ (CD49f+) cells from cord blood, adult bone marrow, and mobilized peripheral blood samples obtained from normal humans spanning 7 decades of age and then measured their functional and molecular responses to growth factor stimulation in vitro and their regenerative activity in vivo in mice that had undergone transplantation. Initial experiments revealed that advancing donor age was accompanied by a significant and progressively delayed proliferative response but not the altered mature cell outputs seen in normal older individuals. Importantly, subsequent dose-response analyses revealed an age-associated reduction in the growth factor-stimulated proliferation of CD49f+ cells mediated by reduced activation of AKT and altered cell cycle entry and progression. These findings identify a new intrinsic, pervasive, and progressive aging-related alteration in the biological and signaling mechanisms required to drive the proliferation of very primitive, normal human hematopoietic cells.

Transduction of the central nervous system after intracerebroventricular injection of adeno-associated viral vectors in neonatal and juvenile mice.

Several neurodevelopmental and neurodegenerative disorders affecting the central nervous system are potentially treatable via viral vector-mediated gene transfer. Adeno-associated viral (AAV) vectors have been used in clinical trials because of their desirable properties including a high degree of safety, efficacy, and stability. Major factors affecting tropism, expression level, and cell type specificity of AAV-mediated transgenes include encapsidation of different AAV serotypes, promoter selection, and the timing of vector administration. In this study, we evaluated the ability of single-stranded AAV2 vectors pseudotyped with viral capsids from serotype 9 (AAV2/9) to transduce the brain and target gene expression to specific cell types after intracerebroventricular injection into mice. Titer-matched AAV2/9 vectors encoding the enhanced green fluorescent protein (eGFP) reporter, driven by the cytomegalovirus (CMV) promoter, or the neuron-specific synapsin-1 promoter, were injected bilaterally into the lateral ventricles of C57/BL6 mice on postnatal day 5 (neonatal) or 21 (juvenile). Brain sections were analyzed 25 days after injection, using immunocytochemistry and confocal microscopy. eGFP immunohistochemistry after neonatal and juvenile administration of viral vectors revealed transduction throughout the brain including the striatum, hippocampus, cerebral cortex, and cerebellum, but with different patterns of cell-specific gene expression. eGFP expression was seen in astrocytes after treatment on postnatal day 5 with vectors carrying the CMV promoter, expanding the usefulness of AAVs for modeling and treating diseases involving glial cell pathology. In contrast, injection of AAV2/9-CMV-eGFP on postnatal day 21 resulted in preferential transduction of neurons. Administration of AAV2/9-eGFP with the synapsin-1 promoter on either postnatal day 5 or 21 resulted in widespread neuronal transduction. These results outline efficient methods and tools for gene delivery to the nervous system by direct, early postnatal administration of AAV vectors. Our findings highlight the importance of promoter selection and age of administration on the intensity, distribution, and cell type specificity of AAV transduction in the brain.