Steven C. Pruitt

Neural stem cell detection, characterization, and age-related changes in the subventricular zone of mice.

The mammalian brain contains neural stem cells (NSCs) that allow continued neurogenesis throughout the life of the animal. However, neurogenesis is known to decline during aging and, to the extent that neurogenesis is required for normal CNS function, this may contribute to neurodegenerative disease. Decreased neurogenesis could result from loss of NSCs or dysfunction at some later step, and distinguishing these possibilities is important for understanding the cause of the decline. However, because of the inability to distinguish NSCs from their rapidly dividing progeny in situ, it has not been possible to quantitatively assess the NSC populations in young and old animals. In this report we show that the G1 phase-specific expression of the replication factor Mcm2 is a useful marker for detecting slowly cycling putative NSCs in situ and confirm the identity of these cells using both cytosine β-d-arabinofuranoside (Ara-C) treatment and a double nucleoside analog-labeling technique. The ability to distinguish NSCs from proliferative progenitors has allowed characterization of the expression of several markers including Nestin, Musashi, and GFAP in these different cell types. Furthermore, comparison of the NSC populations in the subventricular zones of young (2-4 months) and old (24-26 months) mice demonstrates an approximately twofold reduction in the older mice. A similar twofold reduction is also observed in the number of neurospheres recovered in culture from old relative to young animals. The reduction in the neural stem cell population documented here is sufficient to account for the reduced level of neurogenesis in old animals.

Reduced Mcm2 expression results in severe stem/progenitor cell deficiency and cancer.

Mcm2 is a component of the DNA replication licensing complex that marks DNA replication origins during G1 of the cell cycle for use in the subsequent S‐phase. It is expressed in stem/progenitor cells in a variety of regenerative tissues in mammals. Here, we have used the Mcm2 gene to develop a transgenic mouse in which somatic stem/progenitor cells can be genetically modified in the adult. In these mice, a tamoxifen‐inducible form of Cre recombinase is integrated 3′ to the Mcm2 coding sequence and expressed via an internal ribosome entry site (IRES). Heterozygous Mcm2IRES‐CreERT2/wild‐type (wt) mice are phenotypically indistinguishable from wild‐type at least through 1 year of age. In bigenic Mcm2IRES‐CreERT2/wt; Z/EG reporter mice, tamoxifen‐dependent enhanced green fluorescence protein expression is inducible in a wide variety of somatic stem cells and their progeny. However, in Mcm2IRES‐CreERT2/IRES‐CreERT2 homozygous embryos or mouse embryonic fibroblasts, Mcm2 is reduced to approximately one‐third of wild‐type levels. Despite the fact that these mice develop normally and are asymptomatic as young adults, life span is greatly reduced, with most surviving to only ∼10–12 weeks of age. They demonstrate severe deficiencies in the proliferative cell compartments of a variety of tissues, including the subventricular zone of the brain, muscle, and intestinal crypts. However, the immediate cause of death in most of these animals is cancer, where the majority develop lymphomas. These studies directly demonstrate that deficiencies in the function of the core DNA replication machinery that are compatible with development and survival nonetheless result in a chronic phenotype leading to stem cell deficiency in multiple tissues and cancer.

DNA Damage Response and Tumorigenesis in Mcm2 Deficient Mice

Minichromosome maintenance proteins (Mcms) are components of the DNA replication licensing complex. In vivo, reduced expression or activity of Mcms has been shown to result in highly penetrant early onset cancers (Shima et al., 2007; Pruitt et al., 2007) and stem cell deficiencies (Pruitt et al., 2007). Here we use mouse embryonic fibroblasts from an Mcm2-deficient strain of mice to show by DNA fiber analysis that origin usage is decreased in Mcm2-deficient cells under conditions of hydroxyurea (HU)-mediated replication stress. DNA damage responses (DDRs) resulting from HU and additional replication-dependent and replication-independent genotoxic agents were also examined and shown to function at wild-type (wt) levels. Further, basal levels of many components of the DDR were expressed at wt levels, showing that there is no acute replicative stress under normal growth conditions. Only very modest, 1.5- to 2-fold increases in the basal levels of γ-H2AX, p21cip1 and 53bp foci were found, consistent with a slight chronic elevation in DDR pathways. The one condition in which a larger difference between wt- and Mcm2-deficient cells was found occurred after ultraviolet irradiation and may reflect the role of Chk1-mediated suppression of dormant origins. In vivo, abrogating p53-mediated DDR in Mcm2-deficient mice results in increased embryonic lethality and accelerated cancer formation in surviving mice. Further, p53 mutation rescues the negative effect of Mcm2 deficiency on the survival of neural stem cells in vitro; however, the enhanced survival correlates with increased genetic damage relative to Mcm2 wt cells carrying the p53 mutation. Together these results show that even relatively minor perturbations to primary or dormant replication origin usage contribute to accelerated genetic damage in vivo. In addition, these studies show that tumor types resulting from Mcm2 deficiency are strongly affected by interaction with both genetic background and p53.

Whole-genome sequencing identifies genomic heterogeneity at a nucleotide and chromosomal level in bladder cancer

Significance Genetic alterations are frequently observed in bladder cancer. In this study, we demonstrate that bladder tumors can be classified into two different types based on the spectrum of genetic diversity they confer. In one class of tumors, we observed tumor protein p53 mutations and a large number of single-nucleotide and structural variants. Another characteristic of this group was chromosome shattering, known as chromothripsis, and mutational heterogeneity. The other two bladder tumors did not show these profound genetic aberrations, but we found a novel translocation and amplification of the gene glutamate receptor ionotropic N-methyl D-aspertate, a potentially druggable target. Advancements in bladder cancer treatment have been slow. Understanding the genetic landscape of bladder cancer may therefore help to identify new therapeutic targets and bolster management of this disease. Using complete genome analysis, we sequenced five bladder tumors accrued from patients with muscle-invasive transitional cell carcinoma of the urinary bladder (TCC-UB) and identified a spectrum of genomic aberrations. In three tumors, complex genotype changes were noted. All three had tumor protein p53 mutations and a relatively large number of single-nucleotide variants (SNVs; average of 11.2 per megabase), structural variants (SVs; average of 46), or both. This group was best characterized by chromothripsis and the presence of subclonal populations of neoplastic cells or intratumoral mutational heterogeneity. Here, we provide evidence that the process of chromothripsis in TCC-UB is mediated by nonhomologous end-joining using kilobase, rather than megabase, fragments of DNA, which we refer to as “stitchers,” to repair this process. We postulate that a potential unifying theme among tumors with the more complex genotype group is a defective replication–licensing complex. A second group (two bladder tumors) had no chromothripsis, and a simpler genotype, WT tumor protein p53, had relatively few SNVs (average of 5.9 per megabase) and only a single SV. There was no evidence of a subclonal population of neoplastic cells. In this group, we used a preclinical model of bladder carcinoma cell lines to study a unique SV (translocation and amplification) of the gene glutamate receptor ionotropic N-methyl D-aspertate as a potential new therapeutic target in bladder cancer.

Accumulation of mutations and somatic selection in aging neural stem/progenitor cells

Genomic instability within somatic stem cells may lead to the accumulation of mutations and contribute to cancer or other age‐related phenotypes. However, determining the frequency of mutations that differ among individual stem cells is difficult from whole tissue samples because each event is diluted in the total population of both stem cells and differentiated tissue. Here the ability to expand neural stem/progenitor cells clonally permitted measurement of genomic alterations derived from a single initial cell. C57Bl/6 × DBA/2 hybrid mice were used and PCR analysis with strain‐specific primers was performed to detect loss of heterozygosity on nine different chromosomes for each neurosphere. The frequency with which changes occurred in neurospheres derived from 2‐month‐ and 2‐year‐old mice was compared. In 15 neurospheres derived from young animals both parental chromosomes were present for all nine chromosome pairs. In contrast, 16/17 neurospheres from old animals demonstrated loss of heterozygosity (LOH) on one or more chromosomes and seven exhibited a complete deletion of at least one chromosomal region. For chromosomes 9 and 19 there is a significant bias in the allele that is lost where in each case the C57Bl/6 allele is retained in 6/6 neurospheres exhibiting LOH. These data suggest that aging leads to a substantial mutational load within the neural stem cell compartment which can be expected to affect the normal function of these cells. Furthermore, the retention of specific alleles for chromosomes 9 and 19 suggests that a subset of mutational events lead to an allele‐specific survival advantage within the neural stem cell compartment.

Mcm2 deficiency results in short deletions allowing high resolution identification of genes contributing to lymphoblastic lymphoma

Mini-chromosome maintenance (Mcm) proteins are part of the replication-licensing complex that is loaded onto chromatin during the G1-phase of the cell cycle and required for initiation of DNA replication in the subsequent S-phase. Mcm proteins are typically loaded in excess of the number of locations that are used during S-phase. Nonetheless, partial depletion of Mcm proteins leads to cancers and stem cell deficiencies. Mcm2 deficient mice, on a 129Sv genetic background, display a high rate of thymic lymphoblastic lymphoma. Here array comparative genomic hybridization is used to characterize the genetic damage accruing in these tumors. The predominant events are deletions averaging less than 0.5 Mbp, considerably shorter than observed in prior studies using alternative mouse lymphoma models or human tumors. Such deletions facilitate identification of specific genes and pathways responsible for the tumors. Mutations in many genes that have been implicated in human lymphomas are recapitulated in this mouse model. These features, and the fact that the mutation underlying the accelerated genetic damage does not target a specific gene or pathway a priori, are valuable features of this mouse model for identification of tumor suppressor genes. Genes affected in all tumors include Pten, Tcfe2a, Mbd3 and Setd1b. Notch1 and additional genes are affected in subsets of tumors. The high frequency of relatively short deletions is consistent with elevated recombination between nearby stalled replication forks in Mcm2-deficient mice.

Effect of minichromosome maintenance protein 2 deficiency on the locations of DNA replication origins

Minichromosome maintenance (MCM) proteins are loaded onto chromatin during G1-phase and define potential locations of DNA replication initiation. MCM protein deficiency results in genome instability and high rates of cancer in mouse models. Here we develop a method of nascent strand capture and release and show that MCM2 deficiency reduces DNA replication initiation in gene-rich regions of the genome. DNA structural properties are shown to correlate with sequence motifs associated with replication origins and with locations that are preferentially affected by MCM2 deficiency. Reduced nascent strand density correlates with sites of recurrent focal CNVs in tumors arising in MCM2-deficient mice, consistent with a direct relationship between sites of reduced DNA replication initiation and genetic damage. Between 10% and 90% of human tumors, depending on type, carry heterozygous loss or mutation of one or more MCM2-7 genes, which is expected to compromise DNA replication origin licensing and result in elevated rates of genome damage at a subset of gene-rich locations.

Cell Cycle Heterogeneity in the Small Intestinal Crypt and Maintenance of Genome Integrity

Stem cell quiescence has been hypothesized to suppress the rate at which genetic mutations accumulate within tissues by reducing the number of divisions a cell undergoes. However, recent studies have suggested that stem cells in the small intestine are rapidly dividing. This observation raises the issue of whether replication related errors are an important contributor to the accumulation of genetic damage and, if so, how genomic integrity is maintained within the small intestine. Here, reporter‐marked small intestinal epithelial cells, resulting from mini‐chromosome maintenance protein 2 (Mcm2) gene driven Cre‐mediated recombination, are shown to be retained at the +1 position within the crypt and to contribute to the intestinal epithelia over long periods. Additionally, we show that the rate of cycling of +1 position Mcm2‐expressing stem cells is heterogeneous with cycling times ranging between 1 and 4 days. Further, this heterogeneity depends on the p53 signaling pathway and could provide the basis for retention and expansion, through niche succession and crypt fission, of genetically intact stem cells. This somatic selection process would require active cellular replication. STEM CELLS 2010;28:1250–1259

Yeast two-hybrid interaction partner screening through in vivo Cre-mediated Binary Interaction Tag generation

Yeast two-hybrid (Y2H) has been successfully used for genome-wide screens to identify protein–protein interactions for several model organisms. Nonetheless, the logistics of pair-wise screening has resulted in a cumbersome and incomplete application of this method to complex genomes. Here, we develop a modification of Y2H that eliminates the requirement for pair-wise screening. This is accomplished by incorporating lox sequences into Y2H vectors such that cDNAs encoding interacting partners become physically linked in the presence of Cre recombinase in vivo. Once linked, DNA from complex pools of clones can be processed without losing the identity of the interacting partners. Short linked sequence tags from each pair of interacting partner (binary interaction Tags or BI-Tags) are then recovered and sequenced. To validate the approach, comparisons between interactions found using traditional Y2H and the BI-Tag method were made, which demonstrate that the BI-Tag technology accurately represents the complexity of the interaction partners found in the screens. The technology described here sufficiently improves the throughput of the Y2H approach to make feasible the generation of near comprehensive interaction maps for complex organisms.

Cdkn1b overexpression in adult mice alters the balance between genome and tissue ageing

Insufficient cell proliferation has been suggested as a potential cause of age related tissue dysgenesis in mammals. However, genetic manipulation of cell cycle regulators in the germ lines of mice results in changes in animal size but not progeroid phenotypes. Here we increase levels of the cyclin dependent kinase inhibitor Cdkn1b (p27kip1) in adult mice through doxycycline inducible expression and show this results in reduced cell proliferation in multiple tissues. The mice undergo changes resembling aging even in the absence of an elevated DNA damage response or evidence of senescent cells suggesting an altered balance between genetic and tissue aging. In contrast, suppressing cell proliferation by doxycycline treatment of neonates retards growth, but the onset of degenerative changes is delayed during the period of reduced body mass. These results support the hypothesis that many of the most recognizable features of mammalian aging can result from an imbalance between cell production and the mass of tissue that must be maintained.