(PQB5) Does the timing of Pten and Rb1 mutation affect prostate cancer phenotypes

(PQB5) Pten 和 Rb1 突变的时间是否影响前列腺癌表型

• 批准号: 8708795
• 负责人: DAVID W. GOODRICH
• 金额: $ 17.91万
• 依托单位: ROSWELL PARK CANCER INSTITUTE CORP
• 依托单位国家: 美国
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-08-01 至 2016-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8708795
• 关键词: Address; Affect; Alleles; Androgens; Behavior; Binding; Breeding; Cancer Model; Cancer Patient; Cancer Prognosis; Cells; Chimeric Proteins; Data; Disease; Ensure; Epigenetic Process; Estrogen Receptors; Future; Gene Mutation; Genes; Genetic; Genetic Engineering; Genetic Predisposition to Disease; Genetic Recombination; Genetic Transcription; Genetically Engineered Mouse; Goals; Histologic; Human; LoxP-flanked allele; Malignant - descriptor; Malignant Neoplasms; Malignant neoplasm of prostate; Mediating; Methodology; Mus; Mutation; Nature; PTEN gene; Pattern; Performance; Phenotype; Process; RB1 gene; Recurrence; Retinoblastoma; Site; Staging; System; Tamoxifen; Testing; Time; Tissues; Transgenes; Transgenic Mice; Translations; Variant; base; cancer cell; cancer initiation; cancer therapy; deprivation; design; expectation; human disease; in vivo; interest; lung small cell carcinoma; mouse model; novel; prostate cancer model; public health relevance; recombinase; response; tumor progression

DESCRIPTION (provided by applicant): Cancer progression is driven by an evolutionary process of genetic mutation, phenotypic variation, and selection. The genetic background of cancer cells is thus continuously changing. Genetic background will dictate the nature of future mutations that can be tolerated and selected for. The effects of specific new mutations will depend on the genetic background in which they occur. Thus the temporal order of mutations is expected to influence cancer phenotype. How the timing of mutation affects cancer phenotypes remains a largely unanswered question, however. Answering this provocative question (PQB5) is significant because cancer prognosis and effective personalized cancer treatment will depend not only on the nature of mutations present within a particular cancer, but also on the order in which they are acquired. Genetically engineered mouse cancer models have been vital in elucidating the genetic etiology of cancer, but have rarely been used to address PQB5. This is due to limitations inherent in commonly used genetic engineering methodology; when multiple mutations are created, the order of mutations is either unknown, is not controllable, or is not restricted to incipient cancer cells. A current barrier to progress is the availability of mouse cancer models that allow precise control over the timing and order of multiple genetic mutations. We propose to overcome this barrier by developing a novel mouse cancer model based on a lox-neo/stop-lox FlpO-ERT2 transgene. This transgene encodes an FlpO recombinase, ERT2 estrogen receptor fusion protein whose activity is tamoxifen inducible. The transgene is combined with tissue specific Cre transgenes, floxed alleles of the cancer initiating mutation, and frted alleles of the secondary mutation. Cre expression creates the cancer initiating mutation and removes the neo/stop cassette from lox-neo/stop-lox FlpO-ERT2, restricting its expression to initiated cancer cells. FlpO-ERT2 activity can then be induced at experimentally controlled times by tamoxifen administration, creating a secondary mutation by deleting frted gene alleles. This mouse model can be used to determine how 2 mutations occurring in a defined and controllable temporal order affect cancer phenotypes in vivo. We will use this mouse model to test whether the timing of Pten and Rb1 mutation alters prostate cancer phenotype. PTEN and RB1 mutation are common in human prostate cancer, with PTEN loss occurring early and RB1 loss occurring late. The late loss of RB1 is puzzling as its early loss is known to initiate other human cancers. It is unknown whether PTEN and RB1 loss cooperate to drive prostate cancer progression or whether the temporal pattern of mutation influences prostate cancer phenotype. We postulate that the timing of Pten and Rb1 mutation will alter prostate cancer phenotypes in vivo because the effects of these mutations are dependent on genetic background. Two specific aims are proposed to create the lox-neo/stop-lox FlpO-ERT2 allele, to use it to alter the timing of Pten and Rb1 mutation in the mouse prostate cancer model, and to characterize the effects of these mutations on prostate cancer phenotypes in vivo.

描述（由申请人提供）：癌症进展是由基因突变，表型变异和选择的进化过程驱动的。 因此，癌细胞的遗传背景正在不断变化。 遗传背景将决定可以耐受和选择的未来突变的性质。 特定新突变的影响将取决于它们发生的遗传背景。 因此，预计突变的时间顺序会影响癌症表型。 然而，突变的时间如何影响癌症表型仍然是一个很大程度上没有回答的问题。 回答这个挑衅性问题（PQB5）是重要的，因为癌症的预后和有效的个性化癌症治疗将不仅取决于特定癌症中存在的突变的性质，而且还取决于获得它们的顺序。 基因工程的小鼠癌模型对于阐明癌症的遗传病因至关重要，但很少用于解决PQB5。 这是由于常用的基因工程方法固有的局限性。当产生多个突变时，突变的顺序是未知的，不可控制，或不限于初期的癌细胞。 当前进步的障碍是小鼠癌模型的可用性，可以精确控制多个遗传突变的时间和顺序。 我们建议通过开发基于Lox-Neo/stop-lox flpo-ert2转基因的新型小鼠癌模型来克服这一障碍。 该转基因编码一种活性是他莫昔芬诱导的FLPO重组酶ERT2雌激素受体融合蛋白。 转基因与组织特异性CRE转基因，癌症引发突变的flox菌等位基因以及次级突变的fr骨等位基因结合。 CRE表达会产生癌症，从而从Lox-Neo/stop-lox flpo-ert2中去除NEO/Stop Cassette，从而将其表达限制为启动的癌细胞。 然后，他可以通过他莫昔芬给药在实验控制的时间诱导FLPO-ERT2活性，从而通过删除FRTED基因等位基因产生二次突变。 该小鼠模型可用于确定在定义和可控制的时间顺序中发生的2个突变如何影响体内的癌症表型。 我们将使用该小鼠模型来测试PTEN和RB1突变的时间是否改变了前列腺癌的表型。 PTEN和RB1突变在人类前列腺癌中很常见，PTEN损失发生早期，RB1损失迟到。 RB1的后期损失令人困惑，因为它的早期损失是 已知会引发其他人类癌症。 尚不清楚PTEN和RB1损失是否合作以驱动前列腺癌的进展，还是突变的时间模式是否影响前列腺癌表型。 我们假设PTEN和RB1突变的时机会在体内改变前列腺癌表型，因为这些突变的作用取决于遗传背景。 提出了两个具体的目的来创建LOX-NEO/stop-lox flpo-ert2等位基因，以使用它来改变小鼠前列腺癌模型中PTEN和RB1突变的时间，并表征这些突变对VIVO中前列腺癌表型的影响。