Close-up of an the ICR logo on a research centre

Centre for In Vivo Modelling

The Centre for In Vivo Modelling is a newly established research centre within the Division of Cancer Biology at the ICR. Our scientists and clinical researchers use state-of-the-art in vivo models to address fundamental questions in cancer biology, with the ultimate aim of identifying curative treatments. We also serve as a collaborative hub across the ICR and The Royal Marsden, providing cutting-edge expertise in advanced mouse genetics and humanised in vivo models of cancer.

Professor Kamil R Kranc, Chair of Haemato-Oncology, serves as the Centre's Director, while Fabiana Muzzonigro is the Centre Administrator.

 

How we conduct research at this centre

Solid tumours and blood cancers are highly complex ecosystems, with many composed of varying cell types including rare cancer stem cells at the apex of a hierarchical organisation, more differentiated malignant progeny, and a dynamic microenvironment that nurtures tumour growth and survival. At our Centre, we seek to elucidate the fundamental principles that govern this malignant ecosystem. We employ advanced mouse genetics (including barcoding and lineage tracing) and PDX models to dissect how tumour cells function, evolve under selective pressures, evade therapy, and engage with their microenvironment to sustain disease progression. By decoding these intricate cellular and molecular interactions, we aim to identify transformative therapeutic strategies capable of eradicating cancer at its origin - achieving durable remission while preserving normal tissue integrity.

A particular strength of our Centre lies in the generation and application of in vivo models, which are essential for uncovering novel aspects of cancer biology and evaluating emerging therapies. We work in close collaboration with ICR researchers and clinicians at The Royal Marsden to develop patient-derived xenograft (PDX) models of leukaemias and solid tumours by transplanting human cancer tissue into immunocompromised mice. In parallel, we generate and utilise genetically engineered mouse models (GEMMs) to interrogate cancer biology in a physiologically relevant context. By leveraging these sophisticated in vivo systems, the Centre aims to:

  • Uncover new facets of cancer biology in a complex in vivo ecosystem
  • Discover and validate novel therapeutic targets allowing for elimination of cancer stem cells and their malignant progeny in blood cancers and solid tumours
  • Collaborate closely with drug discovery teams at the ICR to develop inhibitors of these targets
  • Evaluate new anti-cancer drugs in pre-clinical in vivo models, paving the way for clinical trials.

In addition to our academic focus, CIVM serves as a collaborative hub across the ICR and The Royal Marsden, providing the ICR community with cutting-edge expertise in advanced mouse genetics and humanised mouse models of cancer.

Join us

We are recruiting two exceptional Group Leaders to join the Division of Cancer Biology and the Centre for In Vivo Modelling (CIVM). This is a unique opportunity to shape the future of cancer biology research, lead innovative programmes, and make discoveries that transform patient outcomes.

These new Group Leaders will investigate fundamental mechanisms of tumour initiation, progression, and treatment resistance, and develop cutting-edge preclinical models to advance understanding of cancer biology. Working in close collaboration across the ICR and The Royal Marsden Hospital, the postholders will translate discovery science into new therapeutic opportunities, contributing to the ICR’s mission to make the discoveries that defeat cancer.

Find out more about the vacancies

Members of this Centre

Headshot of Professor Kamil Kranc

Professor Kamil R Kranc

Director of the Centre for In Vivo Modelling & Group Leader

Haemato-Oncology Group
Professor Kristian Helin, head and shoulders in frame, stood in front of the ICR's Centre for Cancer Drug Discovery

Professor Kristian Helin

Group Leader

Epigenetics and Cancer
axel-behrens 300x300

Professor Axel Behrens

Group Leader

Cancer Stem Cell
Headshot of Cathrin Brisken

Professor Cathrin Brisken

Group Leader

Endocrine Control Mechanisms
Professor Louis Chesler (Profile pic)

Professor Louis Chesler

Clinical Senior Lecturer/Group Leader

Paediatric Solid Tumour Biology and Therapeutics
AmandaSwain, head of the Tumour Profiling Unit

Dr Amanda Swain

Group Leader

Development and Cancer
Marco Bezzi photo

Dr Marco Bezzi

Group Leader

Tumour Functional Heterogeneity
Professor Chris Jones

Professor Chris Jones

Head of Division

Glioma
anguraj sandanandam

Professor Anguraj Sadanandam

Group Leader

Systems and Precision Cancer Medicine Clinical Pharmacology & Trials
Dr Olivia Rossanese in the lab

Dr Olivia Rossanese

Director of the Centre for Cancer Drug Discovery & Head of Division

Tumour Microenvironment and Pharmacology Target Evaluation and Molecular Therapeutics
Pipettes and well plates

In Vivo Modelling core

We provide cutting-edge expertise in advanced mouse genetics and humanized mouse models of cancer.
Find out more

CIVM Service Core

Dr Francisca Nunes de Almeida, PhD

Dr Francisca Nunes de Almeida

Staff Scientist

Dr Chenxin Liu, PhD

Dr Chenxin Liu

Technician

Dr Kallayanee Chawengsaksophak

Dr Kallayanee Chawengsaksophak

Senior Staff Scientist

Other staff:

Email: [email protected]

Driving discovery through collaboration 

At CIVM, our collaborative spirit drives our mission to advance cancer cures. We actively partner with basic science, translational, and clinical research groups across the ICR and The Royal Marsden. Our collaborations also extend beyond, working closely with distinguished academic teams at the Universities of Oxford, Cambridge, Edinburgh, Cardiff, London, Glasgow, and the Francis Crick Institute.

 

News from the Centre

We are recruiting a Group Leader in In Vivo Cancer Modelling. We welcome applications at both the Career Development Faculty and Career Faculty levels. Competitive start up package is available. For further particulars please contact [email protected].

 

 

Current vacancies

Group Leader in In Vivo Cancer Modelling

  • Sutton
  • Cancer Biology
  • From £66,092 per annum
  • Fixed term

The Institute of Cancer Research (ICR) in London seeks to appoint a Group Leader in In Vivo Cancer Modelling to play a pivotal role in advancing our cutting-edge cancer research. The position is based at the newly established Centre for In Vivo Modelling (CIVM), part of the Division of Cancer Biology. We welcome applications at both the Career Development Faculty and Career Faculty levels. Key Requirements The successful candidate will generate and employ state-of-the-art genetic and humanised mouse models of cancer to tackle fundamental and translational questions in haemato-oncology and/or solid tumour oncology. In addition to leading a successful research group, they will expand the CIVM's research capabilities and foster productive collaborations with other groups and centres at the ICR, thus promoting in vivo modelling by integrating it into multidisciplinary projects and initiatives. Applicants must have an internationally recognised track record of leading research in in vivo modelling and advanced mouse genetics, demonstrated by high-quality publications and significant funding success. For more junior candidates, an outstanding track record in cancer research, coupled with a compelling research vision leveraging advanced genetic mouse models and clear potential to secure competitive external funding, is essential. As part of your online application you will be required to upload your full CV which will pre-populate your application form, you will also be asked to attach the following documents and failure to do so will mean your application cannot be considered on this occasion: Lists of major publications, achievements, research grants, distinctions. Research plan (five to six pages outlining your current research interests and research programme for the next 5 years) A PDF of a maximum of five key publications, or other research outputs (e.g. patents) that best demonstrate previous productivity You must also complete the personal statement section of the application form in the format of a covering letter including the names and contact details of three academic referees Department/Directorate Information: Cancer Biology Division Information The ICR is one of the world’s most influential cancer research institutions, with an outstanding track record of achievement dating back more than 100 years. In addition to being one of the UK’s leading higher education institutions for research quality and impact, the ICR is consistently ranked among the world’s most successful for industry collaboration. As a member institution of the University of London, we also provide postgraduate higher education of international distinction. One of the ICR’s key research strategies is to defeat cancer by viewing it as a dynamic ecosystem. We aim to solidify our expertise in state-of-the-art in vivo cancer models to probe these complex cancer ecosystems, discover their underlying biology, and identify new therapeutic targets. The postholder will significantly contribute to driving these strategic priorities. We encourage all applicants to access the job pack attached for more detailed information regarding this role. If you would like to informally discuss this position, please contact Professor Kamil R. Kranc ([email protected]), Director of the Centre for In Vivo Modelling, or Professor Chris Jones ([email protected]), Head of the Division of Cancer Biology at the ICR.

More info

Group Leader in Cancer Stem Cell Biology

  • Sutton
  • Cancer Biology
  • Competitive
  • Permanent

Key Requirements As part of your online application you will be required to upload your full CV which will pre-populate your application form, you will also be asked to attach the following documents and failure to do so will mean your application cannot be considered on this occasion: Lists of major publications, achievements, research grants, distinctions. Research plan (five to six pages outlining your current research interests and research programme for the next 5 years) A PDF of a maximum of five key publications, or other research outputs (e.g. patents) that best demonstrate previous productivity You must also complete the personal statement section of the application form in the format of a covering letter including the names and contact details of three academic referees Department/Directorate Information: Cancer Biology Information The Institute of Cancer Research (ICR) in London seeks to appoint a Group Leader in Cancer Stem Cell Biology to play a pivotal role in advancing our cutting-edge cancer research. The position will be based in newly-refurbished laboratory and office space at our Sutton campus within the Division of Cancer Biology. We welcome applications at both the Career Development Faculty and Career Faculty levels. The ICR is one of the world’s most influential cancer research institutions, with an outstanding track record of achievement dating back more than 100 years. In addition to being one of the UK’s leading higher education institutions for research quality and impact, the ICR is consistently ranked among the world’s most successful for industry collaboration. As a member institution of the University of London, we also provide postgraduate higher education of international distinction. One of the ICR’s key research strategies is to defeat cancer by viewing it as a dynamic ecosystem. We aim to solidify our expertise in the biology of cancer stem cellsaq. The postholder will significantly contribute to understanding the underlying biology of cancer stem cells and how this may be exploited to address key questions in tumour relapse, disease progression and metastasis. The successful candidate will have a compelling research programme focused on cancer stem cell biology in an area which complements existing disease-specific expertise at the ICR / Royal Marsden NHS trust. Possible areas of research include (but are not restricted to) basic mechanisms of self-renewal and pluripotency, regulation of cancer stem cell fate / differentiation, how they remodel the tumour microenvironment into a supportive niche, targeting treatment resistance of cancer stem cells, and the role of CSCs in driving the metastatic cascade. Applicants must have an internationally recognised track record of leading research in cancer stem cell biology, demonstrated by high-quality publications and significant funding success. For more junior candidates, an outstanding postdoctoral track record in cancer research, coupled with a compelling research vision in a strategic area of cancer stem cell biology and clear potential to secure competitive external funding, is essential. If you would like to informally discuss this position, please contact Professor Chris Jones ([email protected]), Head of the Division of Cancer Biology at the ICR.

More info

News from the ICR

08/01/26

A major advance in cell biology has revealed how our cells safeguard their genetic material during one of the most vulnerable moments in their life cycle. The study identifies a specific protein complex as a central coordinator of DNA repair during cell division.

Every time a cell divides, it must copy its entire DNA and distribute it evenly between two daughter cells. This process, called mitosis, is usually tightly regulated. However, if cells enter mitosis with unfinished or damaged DNA, chromosomes can break apart, leading to genetic instability – a hallmark of many diseases, including cancer. Until now, scientists did not fully understand how cells manage DNA damage during mitosis, when most conventional repair systems are switched off.

Now, researchers have shown that the protein complex CIP2A–TOPBP1 plays a key part in managing DNA repair processes during mitosis. This discovery provides crucial insight into how cells maintain genome stability and offers promising new directions for cancer treatment.

Scientists from The Institute of Cancer Research, London, led the study, the findings of which were published in the journal Nature Communications. The work was funded by the Medical Research Council, the Biotechnology and Biological Sciences Research Council, Cancer Research UK, the Wellcome Trust, the Royal Society and The Institute of Cancer Research (ICR), which is both a research institute and a charity.

The challenge of DNA repair in mitosis

DNA repair during mitosis is uniquely challenging. The usual repair pathways, which operate during earlier phases of the cell cycle, are largely inactive. Instead, cells rely on emergency mechanisms to prevent catastrophic chromosome breakage. Two such backup systems – mitotic DNA synthesis (MiDAS) and microhomology-mediated end joining (MMEJ) – step in to resolve replication stress and repair DNA breaks. The new study demonstrates that these processes are not random but precisely orchestrated by the CIP2A–TOPBP1 axis.

The CIP2A-TOPBP1 protein duo acts as a molecular coordinator, ensuring that MiDAS and MMEJ occur at the right time and place. The choreography is remarkably precise: a single amino acid change in one of the repair proteins this complex controls, SLX4, can disrupt the localisation of repair machinery specifically in mitosis, destabilising chromosomes and slowing cell growth. These findings underscore the complexity of mitotic DNA repair and highlight potential vulnerabilities that could be exploited in cancer therapy.

A collaborative scientific approach

The research represents a highly collaborative, multidisciplinary effort. The team used a combination of innovative techniques – including advanced light microscopy, flow cytometry, proteomics, gene editing and biochemical analysis – to unravel the intricate processes that protect chromosomes during division.

This integration of cutting-edge technologies was essential to observe DNA repair events in real time and map the molecular interactions that maintain genome stability.

Implications for cancer research

The clinical significance of this discovery is profound. Cancer cells often endure high levels of replication stress and DNA damage, but they survive by hijacking backup repair pathways. The study reveals that tumours deficient in BRCA1 or BRCA2 – genes essential for homologous recombination repair – or exposed to drugs that induce DNA damage are particularly dependent on the CIP2A–TOPBP1 axis. Disrupting this dependency could render such cancers unable to repair their DNA, leading to cell death.

The findings challenge previous assumptions about CIP2A. Earlier studies suggested that CIP2A primarily acted as a structural tether in mitosis, holding broken chromosomes together during cell division. These new data reveal that CIP2A actively regulates MiDAS and MMEJ, underlining another critical function of this complex.

This previously unknown role highlights the dynamic nature of mitotic repair and suggests opportunities for highly selective interventions that disrupt cancer-specific vulnerabilities without harming normal cells.

Future directions

Building on these findings, the researchers plan to chart the mechanisms that maintain genome stability during mitosis, which remain relatively undefined. Through this, their ultimate goal is to identify novel therapeutic targets that exploit cell-cycle-specific weaknesses, improving outcomes for patients with cancers that currently lack effective treatment options.

First author Dr Peter Martin, Senior Scientific Officer in the Division of Cell and Molecular Biology at the ICR, said:

“The significant role that CIP2A has in maintaining genome stability through DNA repair was unexpected, but it opens the door to new therapeutic possibilities, with CIP2A, TOPBP1 and SLX4 among the proteins emerging as promising drug targets.

“The next step is to define biomarkers of DNA damage tolerance in mitosis, so clinicians can select patients that may benefit the most from therapies that target these processes. Over time, we hope to reshape treatment paradigms for cancers that are driven by replication stress or resistant to conventional chemotherapies, improving patient outcomes especially for those with unmet clinical needs.”

Senior author Professor Wojciech Niedzwiedz, Group Leader of the Cancer and Genome Instability Group at the ICR, said:

“By focusing on mitosis – a critical yet underexplored phase – this research opens a new frontier in cancer biology and therapeutic innovation. Deepening our understanding of mitotic DNA repair is key for developing strategies that synergise with existing treatments and overcome resistance to first-line therapies.

“Our longer-term aim is to significantly improve treatment outcomes for patients, giving more people extra time to enjoy in better health.”

Image credit: Mahmoud Ahmed from Pixabay

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