犬骨肉瘤全基因组扫描风险建模显示，具有孟德尔水平多基因风险的个体很常见。

Risk-modeling of dog osteosarcoma genome scans shows individuals with Mendelian-level polygenic risk are common.

机构信息

Department of Veterinary Clinical Sciences, The Ohio State University College of Veterinary Medicine, Columbus, OH, USA.

Department of Animal Sciences, The Ohio State University College of Food, Agricultural and Environmental Sciences, Columbus, OH, USA.

出版信息

BMC Genomics. 2019 Mar 19;20(1):226. doi: 10.1186/s12864-019-5531-6.

DOI:10.1186/s12864-019-5531-6

PMID:30890123

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6425649/

Abstract

BACKGROUND

Despite the tremendous therapeutic advances that have stemmed from somatic oncogenetics, survival of some cancers has not improved in 50 years. Osteosarcoma still has a 5-year survival rate of 66%. We propose the natural canine osteosarcoma model can change that: it is extremely similar to the human condition, except for being highly heritable and having a dramatically higher incidence. Here we reanalyze published genome scans of osteosarcoma in three frequently-affected dog breeds and report entirely new understandings with immediate translational indications.

RESULTS

First, meta-analysis revealed association near FGF9, which has strong biological and therapeutic relevance. Secondly, risk-modeling by multiple logistic regression shows 22 of the 34 associated loci contribute to risk and eight have large effect sizes. We validated the Greyhound stepwise model in our own, independent, case-control cohort. Lastly, we updated the gene annotation from approximately 50 genes to 175, and prioritized those using cross-species genomics data. Mostly positional evidence suggests 13 genes are likely to be associated with mapped risk (including MTMR9, EWSR1 retrogene, TANGO2 and FGF9). Previous annotation included seven of those 13 and prioritized four by pathway enrichment. Ten of our 13 priority genes are in loci that contribute to risk modeling and thus can be studied epidemiologically and translationally in pet dogs. Other new candidates include MYCN, SVIL and MIR100HG.

CONCLUSIONS

Polygenic osteosarcoma-risk commonly rises to Mendelian-levels in some dog breeds. This justifies caninized animal models and targeted clinical trials in pet dogs (e.g., using CDK4/6 and FGFR1/2 inhibitors).

摘要

背景

尽管体细胞肿瘤遗传学带来了巨大的治疗进展，但有些癌症的存活率在 50 年内并没有提高。骨肉瘤的 5 年生存率仍为 66%。我们提出，天然犬骨肉瘤模型可以改变这种状况：它与人类的情况极其相似，只是遗传性更高，发病率也高得多。在这里，我们重新分析了三种常见受影响犬种的骨肉瘤发表的全基因组扫描，并报告了具有直接转化意义的全新认识。

结果

首先，荟萃分析显示 FGF9 附近存在关联，该基因具有很强的生物学和治疗相关性。其次，多因素逻辑回归风险模型显示 34 个相关位点中有 22 个与风险相关，其中 8 个具有较大的效应大小。我们在自己独立的病例对照队列中验证了灰狗逐步模型。最后，我们将基因注释从大约 50 个基因更新为 175 个，并使用跨物种基因组学数据对其进行了优先级排序。大多数位置证据表明，有 13 个基因可能与映射风险相关（包括 MTMR9、EWSR1 反转基因、TANGO2 和 FGF9）。以前的注释包括这 13 个基因中的 7 个，并通过途径富集对其中 4 个进行了优先级排序。我们的 13 个优先基因中有 10 个位于与风险建模相关的基因座中，因此可以在宠物狗中进行流行病学和转化研究。其他新的候选基因包括 MYCN、SVIL 和 MIR100HG。

结论

在某些犬种中，多基因骨肉瘤风险通常上升到孟德尔水平。这证明了犬类动物模型的合理性，并为宠物犬的靶向临床试验提供了依据（例如，使用 CDK4/6 和 FGFR1/2 抑制剂）。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d1f3/6425649/46f196689dda/12864_2019_5531_Fig1_HTML.jpg

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犬骨肉瘤全基因组扫描风险建模显示，具有孟德尔水平多基因风险的个体很常见。

Risk-modeling of dog osteosarcoma genome scans shows individuals with Mendelian-level polygenic risk are common.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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