{"id":835,"date":"2015-04-02T08:32:53","date_gmt":"2015-04-02T08:32:53","guid":{"rendered":"http:\/\/blogs.kent.ac.uk\/biosciences\/?p=835"},"modified":"2015-04-02T08:32:53","modified_gmt":"2015-04-02T08:32:53","slug":"research-seminar-from-its-origins-to-the-modern-metabolic-network","status":"publish","type":"post","link":"https:\/\/blogs.kent.ac.uk\/biosciences\/2015\/04\/02\/research-seminar-from-its-origins-to-the-modern-metabolic-network\/","title":{"rendered":"Research Seminar: From its origins to the modern metabolic network"},"content":{"rendered":"

Dr. Markus Rasler, Department of Biochemistry, University of Cambridge<\/strong><\/p>\n

Wednesday 8th April, 4.00 p.m., Stacey Lecture Theatre 1<\/strong><\/p>\n

Every cell depends on a conserved core set of conserved metabolic reactions, and necessitates flexibility in the flux through the reactions in order to adopt to changes in physiology. We combine quantitative mass spectrometry with genetic tools to study how metabolic networks react upon changes in environment and during ageing. In this talk I\u2019ll present novel results that indicate origins of this network date back to the prebiotic world. In chemical simulations of Archean ocean, we detect the enzyme-free interconversion of metabolites constituting glycolysis and the pentose phosphate pathway, indicating a pre-enzymatic origin of these reaction sequences.<\/p>\n

In the modern metabolic network however, additional constraints arise from the limited number of catalysts over the high complexity of chemical molecules present in the metabolic network. Cells can overcome this by compartmentalisation of the networks over time and space. In the second part of the presentation and show examples how modern cells adjust their metabolic flux in order to adjust to rapid growth of a cells and during and stress conditions.<\/p>\n