A recent paper published in the scientific journal Cell gives an unprecedented insight into the metabolic interactions that occur throughout the body over 24 hours. As part of a large-scale study, the authors constructed 24-hour metabolic profiles of mouse tissues and organs under conditions of energy balance and high-fat diet. Their findings provide an overview of how the various metabolic pathways in the body are interconnected and also reveal suitable time frames for anti-obesity therapies. The study was conducted under the aegis of the Helmholtz Zentrum München and the University of California Irvine in collaboration with the German Center for Diabetes Research (DZD).
Squamous cell carcinomas of the head and neck (HNSCC) are usually only diagnosed at an advanced stage and thus have a relatively poor prognosis. One cause may be human papillomavirus (HPV), but the main cause is tobacco smoking and excessive consumption of high-percentage alcohol.
“While the virally induced tumors can be treated relatively well, the other head and neck tumors have a rather poor prognosis,” said Professor Claus Belka, MD, head of the Clinical Cooperation Group (CCG) Personalized Radiotherapy in Head and Neck Cancer. The CCG comprises scientists from Helmholtz Zentrum München and LMU and is closely associated with the DKTK. “In this study, we investigated how molecular markers can be used to define subgroups that undergo a different course of disease after radiation chemotherapy,” Belka said. This could offer an opportunity for personalized treatment. “The Research Unit Radiation Cytogenetics at Helmholtz Zentrum München, headed by Professor Horst Zitzelsberger, offers optimal detection methods and expertise for the identification of such molecular markers, which allow the stratification of patients.”
Patient data provide an approach to personalized therapy
To investigate this question, the researchers examined cancer tissues from two independent tissue sample collections: Specifically, it was a multicenter patient collective of the DKTK Radiation Oncology Group (DKTK-ROG; coordination of the miRNA study Prof. Michael Henke) and a monocentric patient collective from the LMU Clinic for Radiotherapy and Radiation Oncology (head: Prof. Belka). In the analysis, the researchers focused on miRNAs: tiny molecules that influence the expression of numerous (in part cancer-relevant) genes. “Working with our colleagues enabled us to study a total of 162 samples from patients with HPV-negative head and neck cancer,” said Dr. Julia Hess. She shares the first authorship with Dr. Kristian Unger. Both are heading a working group in the Research Unit Radiation Cytogenetics. Out of all of the miRNAs, the researchers were able to identify five miRNAs whose expression predicted the course of the disease and the risk of recurrence. “In combination with other clinical data, this five miRNA signature allows the definition of four groups with different prognoses,” Unger added.
Source: Read Full Article