A great week for Body Clock Research in MCT RCSI

Last week was another superb week for circadian research in the Molecular and Cellular Therapeutics Department. The Curtis Laboratory published our first big paper on the immune body clock in Nature Communications. This study originated back in 2013. I was still a postdoc in Prof. Luke O’Neills laboratory at Trinity College and was intrigued by some of the studies that showed that multiple sclerosis (MS) was affected by the circadian disruption. A key study showed that teenagers who work shift work before the age of 18 are more susceptible to multiple sclerosis in later life. I wondered if we would see any differences in multiple sclerosis if we disturbed the immune body clock. I approached Prof. Kingston Mills also at Trinity College, who is one of the world leaders of multiple sclerosis and has a key mouse model that recapitulates certain features of MS, called experimental autoimmune encephalomyelitis (EAE). The first experiment we conducted was to see if a mouse which does not have the molecular clock in macrophages was more susceptible to disease, and low and behold it was! This project was driven by one of the most talented researchers that I have ever had the pleasure of working with, Dr. Caroline Sutton, who is a senior postdoctoral fellow in Prof. Mills lab. This project is a great example of collaboration between multiple labs, Mills, O’Neill and my own new group here at RCSI.

And if that wasn’t enough! We also hosted the circadian expert Prof. Qing-jun Meng for our second institutional seminar series on Thursday. Prof. Meng is a world expert on clocks in the musculoskeletal system at University of Manchester. I met Qing-jun in 2013, and have followed his research intensely. He has made seminal discoveries on the impact of the clock on cartilage and invertebral disk function and how this leads to diseases of ageing, such as osteoarthritis and lower back pain. He had the audience enthralled for an hour with his rhythmic images of cells glowing with 24-hour rhythms, and his use of Google searches. It was an absolute pleasure to have Qing-jun with us for the day, and I hope that we can have him back again in the near future.

 

Some news features on the article can be found here:

Siliconrepablic.com

EurekAlert

RTE

Written by Annie Curtis

MCT Research Talks November 27th 2017

Dr Justyna Surowka, Medical University of Lublin, Lublin, Poland
(Current Erasmus Post-doc with the O’Connor group) presented “Assessment of chosen immune cell populations in patients with ovarian cancer”
Despite the decades of studies on developing new therapeutic strategies, ovarian cancer remains one of the malignancies with the highest mortality rate. Therefore, new therapies, among them immunotherapy, are in demand. Recently, Kurman and Shih proposed a new classification of ovarian cancer. It is based on molecular and histopathological differences between tumors and divides them into two subtypes: type I and type II ovarian cancer. However, there are no studies exploring functions of an immune system in those types of ovarian cancer. We demonstrated that each type of ovarian cancer can induce a unique phenotype of dendritic cells and differentiation of Tregs, both associated with immunosuppressive function, which may be an obstacle while developing effective anticancer dendritic cell vaccination.

Dr Sudipto Das presented “Dissecting the epigenome of metastatic colorectal cancer”
The talk highlighted the experimental and analytical pipelines that have been established in the lab in order to develop single-base pair resolution DNA methylation maps derived from difficult-to-handle FFPE (Formalin Fixed Paraffin Embedded) tissue. We next applied these optimized approaches to primary tumour samples derived from 58 metastatic colorectal cancer (mCRC) patients and 10 matched normal samples, with an aim to unravel the methylation alterations across both conventional gene regulatory regions such as promoters as well as alternative regulatory elements such as enhancers of protein-coding and non-coding genes. Intriguingly, we have now identified a DNA methylation specific signature consisting of 377 differentially methylated loci that differentiates tumour and normal and in parallel provides us with three distinctive clinical clusters, which show a significant overlap with prognostically relevant consensus molecular sub-types of CRC. However, further work is warranted to ascertain the precise function of the signature as well as their role in predicting patient response to treatment.
The second part of the talk detailed about the ongoing genomics focused on “n-of-1” genomic studies which essentially involves atypical cancer presentation in patients, with the idea of understanding the biology of such unusual clinical phenotypes and moreover to identify any potential therapeutic targets.