国际学生入学条件
Applicants must have completed or are nearing the completion of a Master of Science degree. Applicants must have distinguished themselves during their M.Sc. to be considered for our Ph.D. program. Applicants who have never been enrolled in an M.Sc. program but have an average of A- or higher in all relevant courses from their B.Sc. may be consideration for direct entry into our Ph.D. program.. IELTS: Minimum required score: 7.0 (Academic)with at least 6.5 for each component.TOEFL paper-based Test(Pbt) Overall Score: 580 and Internet-based format (IBT) Overall Score: 93.
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IDP—雅思考试联合主办方
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雅思考试总分
7.0
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雅思考试指南
- 雅思总分:7
- 托福网考总分:93
- 托福笔试总分:580
- 其他语言考试:The Certificate of Proficiency in English (COPE) Required score: 76 (with at least 22 in each component and 32 in the writing component). MELAB: 85
CRICOS代码:
申请截止日期: 请与IDP顾问联系以获取详细信息。
课程简介
分子遗传学系由医学大楼管理,有近100名教职员工,其实验室位于医学大楼,最佳研究所,唐纳利细胞和生物分子研究中心,菲茨杰拉德大楼,病童医院,西奈山医院,安大略省癌症研究所和玛格丽特公主医院。分子遗传学的理学硕士和哲学博士课程为从细菌,病毒到人类的广泛遗传系统提供研究培训。研究项目包括DNA修复,重组和分离,转录,RNA剪接和催化,基因表达调控,信号转导,宿主细胞与细菌和病毒的相互作用,简单生物(蠕虫和果蝇)以及复杂生物的发育遗传学(小鼠),分子神经生物学,分子免疫学,癌症生物学和病毒学,结构生物学以及人类
MoGen researchers studying Genetic Models of Development and Disease aim to understand how the instructions required to produce a complex multicellular organism are encoded in the genome, interpreted during embryonic development, and how errors in their implementation underlie diverse implementations pathologies, including many types of cancer. How a single cell, the fertilized egg, develops into an individual that may comprise trillions of cells has fascinated observers since its discovery. Over the past 40 years, phenomenal advances with genetic analysis and molecular biology have revealed many of the mechanisms that lay out plans of the developing body, specify the identities of different cell types, and pattern tissues and organs throughout the body. One of the striking lessons to emerge from such studies is that a small number of well-conserved regulatory pathways repeatedly act during development, in different contexts, and in organisms ranging from simple invertebrates to humans, to control decisions about cell fate, tissue growth, pattern formation, and morphogenesis. Consequently, discoveries about the workings of these pathways in simple, highly tractable organisms can readily be applied to investigate the development and genetic disease in more complex ones, including humans.
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