Scholarship for Nigerians and Africans
This service provides information on Scholarships, Grants, Fellowships opportunities at the undergraduate and postgraduate levels including Research Institutions for Nigerians and Africans
Laboratory of Cell Signaling and Metabolic Disorders is currently recruiting Postdoctoral Associate to undertake a project: “Molecular Mechanisms of Insulin Resistance and Beta-cell Failure in Type 2 Diabetes”.
Applicants should hold a PhD degree in the fields of life sciences no more than four years of post-doctoral training and have extensive experience in molecular biology, cell biology and/or biochemistry.
Scholarship Application Deadline: 10 April 2011
Academically accomplished domestic and international students are invited to apply for funded positions in the M.Sc. and Ph.D. programs of the Department of Oncology at the University of Alberta, an institution that ranks among the top 100 in the world. Graduate applications are now being accepted for September 2011. Please visit our website for complete information.
Research Environment
The Department of Oncology at the University of Alberta is located within the Cross Cancer Institute, the major cancer treatment centre in Central/Northern Alberta, Canada.
Thesis-based M.Sc. and Ph.D. research topics include but are not limited to:
• genetic and epigenetic control of nuclear organization
• regulatory mechanisms in neural development, retinoblastoma and brain tumours
• metabolism of cachexia and wasting diseases
• mechanisms of cell-cycle control
• molecular events in ovarian cancer
• novel gene therapeutics
• nutrient-gene interactions in cancer
• tumor imaging and positron emission tomography
• molecular basis of DNA-repair
• molecular events in multiple myeloma
• computer based modeling and drug discovery
• molecular mechanisms of melanoma pathogenesis
The Medical Physics Program, accredited by the Commission on Accreditation of Medical Physics Education Programs (CAMPEP), prepares students for a career as a Medical Physicist in North America.
Graduate students in Oncology enjoy many benefits, including:
• dedicated trainee-oriented staff
• an interdisciplinary research environment
• a centrally managed state-of-the art imaging facility
• world-class computational facilities for molecular modeling
• state-of-the-art animal and tumor imaging facilities
• real-time image-guided adaptive radiotherapy
• accredited training and research opportunities in Medical Physics
• a modern city with ready access to Canada’s most spectacular National Parks.
Please visit our website for more information about the Oncology graduate program, or about the specialized streams of Experimental Oncology or Medical Physics.
Funding and Awards
In 2011-12, graduate students will be funded to a minimum level of $25,000 – $27,000 CAD. Support comes from sources such as:
• departmental/university scholarships
• competitive provincial and national awards
• tuition scholarships
• travel and conference awards
• supervisor-funded stipends.
Exceptional new candidates are also be eligible for recruitment awards including:
• Vanier Canada Graduate Scholarships: prestigious national award valued at $50,000 CAD/year
• Cathy & Harold Roozen Endowment Entrance Award
• Antoine Noujaim Graduate Entrance Scholarship
Our funding website contains more detailed information about scholarships and awards.
Candidate Requirements
The Oncology program welcomes academically accomplished domestic and international students with a baccalaureate degree (or its academic equivalent) and an appropriate research background. Specific requirements regarding English Language Proficiency, GRE scores, and minimum GPA, can be found on our website.
Scholarship Application Deadline: Contact Employer
Further Scholarship Information and Application
The ability to migrate is an essential feature of most animal cells. During development, motion of cells is required for morphogenesis (e.g. gastrulation, organogenesis). In adult animals, cell motilityplays an important role in normal physiology (e.g. to combat infection) and disease (e.g. cancer metastasis). Although cell motility has been intensely studied, the overwhelming majority of the research effort has so far focused on just one mechanism of locomotion, prevalent when cells are cultured on glass substrates: lamellipodial-based migration. However, when migrating in 3D environments, cells can utilise other modes of motility in addition to lamellipodial motility. An increasing number of studies point to the importance of blebbing motility which is based on the formation of blebs at the leading edge. Blebs are quasi-spherical membrane protrusions that grow and disappear in minutes. They are initially devoid of F-actin but after bleb growth stops, an actin-rich cortex regrows under the membrane. Blebbing motility is essential for some embryonic cells during development. White blood cells can migrate using bleb-like protrusions when placed in 3D matrices. Some metastatic cancer cells can use blebbing motility to escape anti-tumour treatments, which block lamellipodial motility by targeting protease activity. Other tumour cells use blebs to cross the endothelium to invade tissues.
For blebbing to be translated into movement, cells need to exert forces on the extracellular environment and translocate their mass. During lamellipodial motility, cell-body translocation is achieved by contraction of the cell rear coupled to adhesion of the lamellipodium
to the substrate and forward protrusion.. In contrast, hardly anything is known about the sequence of events leading to motion in blebbing motility. Whether or not blebs actually adhere to the substrate is unknown. However, since blebbing motility is much more efficient when
cells are sandwiched between two surfaces, this suggests that pushing forces against the substrate, in addition to pulling on adhesions, could be involved. Little is known about F-actin cortex dynamics and its regulation during blebbing motility.
In summary, our understanding of blebbing motility lags far behindthat of lamellipodial motility. This proposal aims to explore the cellular and molecular mechanisms underlying bleb-based migration, an important yet understudied mode of cellular motility. Using a cell line that uses bleb to locomote (Walker carcinosarcoma cells), we will focus on two main objectives:
1) Understanding cell body translocation during blebbing motility in confined environments
2) Investigating the molecular mechanisms of movement in blebbing motility
Candidates should have a strong academic record: Bachelor’s degree or equivalent in Molecular Cell Biology with a first or an upper class second. This project involves a significant experimental component and previous experimental research experience is desirable. Research
experience in cell culture, molecular biology, and fluorescence microscopy is a plus. The stipend is of the order of £15k per year and
tuition fees will be covered. Funding is available to UK and EEA candidates. Interviews will occur on a rolling basis until the
position is filled.
Suitably qualified candidates interested in performing cutting edge research in a multidisciplinary scientific environment in order to understand blebbing motility should send their CV to Dr Guillaume Charras (g.charras-at-ucl.ac.uk,
Scholarship Application Deadline:Contact Employer
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