Leisa Johnson scite author profile

About 30% of human tumours carry ras gene mutations. Of the three genes in this family (composed of K-ras, N-ras and H-ras), K-ras is the most frequently mutated member in human tumours, including adenocarcinomas of the pancreas ( approximately 70-90% incidence), colon ( approximately 50%) and lung ( approximately 25-50%). To construct mouse tumour models involving K-ras, we used a new gene targeting procedure to create mouse strains carrying oncogenic alleles of K-ras that can be activated only on a spontaneous recombination event in the whole animal. Here we show that mice carrying these mutations were highly predisposed to a range of tumour types, predominantly early onset lung cancer. This model was further characterized by examining the effects of germline mutations in the tumour suppressor gene p53, which is known to be mutated along with K-ras in human tumours. This approach has several advantages over traditional transgenic strategies, including that it more closely recapitulates spontaneous oncogene activation as seen in human cancers.

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Distinct Thresholds Govern Myc's Biological Output In Vivo

Murphy

et al. 2008

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SUMMARY Deregulated Myc triggers a variety of intrinsic tumor suppressor programs that serve to restrain Myc’s oncogenic potential. Since Myc activity is also required for normal cell proliferation, activation of intrinsic tumor suppression must be triggered only when Myc signaling is oncogenic. However, how cells discriminate between normal and oncogenic Myc is unknown. Here we show that distinct threshold levels of Myc govern its output in vivo: low levels of deregulated Myc are competent to drive ectopic proliferation of somatic cells and oncogenesis but activation of the apoptotic and ARF/p53 intrinsic tumor surveillance pathways requires Myc over-expression. The requirement to keep activated oncogenes at low level to avoid engaging tumor suppression is likely an important selective pressure governing the early stages of tumor microevolution. SIGNIFICANCE Cancers are prevented by the activation of intrinsic tumor suppression programs that either fix the damage in cells or ensure that the damaged cells cannot propagate. Cancers can only arise once these tumor suppressor pathways are abrogated. Importantly, activation of such tumor suppressor pathways must be restricted only by oncogenic, not normal, growth signals. Using a novel in vivo model of Myc-induced tumorigenesis in which Myc function is deregulated without concomitant over-expression, we show that tumor surveillance programs are triggered specifically by Myc over-expression, not deregulation. Nonetheless, low-level deregulated Myc remains potently oncogenic. These observations identify a novel mechanism by which the tumor suppressor defense mechanisms can be circumvented, with implications for our understanding of early stage neoplasia.

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K-ras is an essential gene in the mouse with partial functional overlap with N-ras

Johnson¹,

Greenbaum²,

Cichowski³

et al. 1997

Genes Dev.

496

394

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Mammalian ras genes are thought to be critical in the regulation of cellular proliferation and differentiation and are mutated in ∼30% of all human tumors. However, N-ras and H-ras are nonessential for mouse development. To characterize the normal role of K-ras in growth and development, we have mutated it by gene targeting in the mouse. On an inbred genetic background, embryos homozygous for this mutation die between 12 and 14 days of gestation, with fetal liver defects and evidence of anemia. Thus, K-ras is the only member of the ras gene family essential for mouse embryogenesis. We have also investigated the effect of multiple mutations within the ras gene family. Most animals lacking N-ras function and heterozygous for the K-ras mutation exhibit abnormal hematopoietic development and die between days 10 and 12 of embryogenesis. Thus, partial functional overlap appears to occur within the ras gene family, but K-ras provides a unique and essential function.

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An adenovirus E1A mutant that demonstrates potent and selective systemic anti-tumoral efficacy

Heise¹,

Hermiston²,

Johnson³

et al. 2000

Nat Med

513

394

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Replication-selective oncolytic viruses constitute a rapidly evolving and new treatment platform for cancer. Gene-deleted viruses have been engineered for tumor selectivity, but these gene deletions also reduce the anti-cancer potency of the viruses. We have identified an E1A mutant adenovirus, dl922-947, that replicates in and lyses a broad range of cancer cells with abnormalities in cell-cycle checkpoints. This mutant demonstrated reduced S-phase induction and replication in non-proliferating normal cells, and superior in vivo potency relative to other gene-deleted adenoviruses. In some cancers, its potency was superior to even wild-type adenovirus. Intravenous administration reduced the incidence of metastases in a breast tumor xenograft model. dl922-947 holds promise as a potent, replication-selective virus for the local and systemic treatment of cancer.

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Generation of a prostate from a single adult stem cell

Leong¹,

Wang²,

Johnson³

et al. 2008

Nature

385

368

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The existence of prostate stem cells (PSCs) was first postulated from the observation that normal prostate regeneration can occur after repeated cycles of androgen deprivation and replacement in rodents. Given the critical role of PSCs in maintaining prostate tissue integrity and their potential involvement in prostate tumorigenesis, it is important to define specific markers for normal PSCs. Several cell-surface markers have been reported to identify candidate PSCs, including stem cell antigen-1 (Sca-1, also known as Ly6a), CD133 (Prom1) and CD44 (refs 3-10). However, many non-PSCs in the mouse prostate also express these markers and thus identification of a more defined PSC population remains elusive. Here we identify CD117 (c-kit, stem cell factor receptor) as a new marker of a rare adult mouse PSC population, and demonstrate that a single stem cell defined by the phenotype Lin(-)Sca-1(+)CD133(+)CD44(+)CD117(+) can generate a prostate after transplantation in vivo. CD117 expression is predominantly localized to the region of the mouse prostate proximal to the urethra and is upregulated after castration-induced prostate involution-two characteristics consistent with that of a PSC marker. CD117(+) PSCs can generate functional, secretion-producing prostates when transplanted in vivo. Moreover, CD117(+) PSCs have long-term self-renewal capacity, as evidenced by serial isolation and transplantation in vivo. Our data establish that single cells in the adult mouse prostate with multipotent, self-renewal capacity are defined by a Lin(-)Sca-1(+)CD133(+)CD44(+)CD117(+) phenotype.

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Leisa Johnson

Somatic activation of the K-ras oncogene causes early onset lung cancer in mice

Distinct Thresholds Govern Myc's Biological Output In Vivo

K-ras is an essential gene in the mouse with partial functional overlap with N-ras

An adenovirus E1A mutant that demonstrates potent and selective systemic anti-tumoral efficacy

Generation of a prostate from a single adult stem cell

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