Centre for In Vivo Modelling Service Core

At the Centre for In Vivo Modelling (CIVM), we combine advanced animal genetics and cutting-edge technologies to drive cancer research. Our multidisciplinary team specialises in the generation and maintenance of genetically engineered mouse models (GEMMs), humanised mouse strains, and patient-derived models (xenografts and organoids), using innovations such as CRISPR gene editing, embryo manipulation, and in vivo genetic screening. We develop and cryopreserve new cancer models that closely replicate human disease, supporting translational studies that inform effective therapies. Our approach integrates rigorous scientific standards, ethical oversight, and collaborative expertise, aiming to accelerate progress in understanding cancer biology and developing better treatments for patients.

Our Centre is dedicated to driving innovation and excellence in cancer research through advanced in vivo modelling. We work in close collaboration with the ICR researchers and clinicians at The Royal Marsden to generate genetically engineered mouse models (GEMMs) and patient-derived models, such as patient-derived xenografts (PDXs) and patient-derived organoids (PDOs) to interrogate cancer biology in its own ecosystem. By leveraging these sophisticated in vivo systems, the Centre aims to:

  • Develop innovative cancer models in collaboration with ICR researchers to advance cancer research and drug discovery.
  • Work in partnership with The Royal Marsden Hospital to obtain patient samples and generate new patient-derived cancer models for translational studies.
  • Foster close interdisciplinary collaboration with drug discovery teams to leverage these in vivo models in the creation and testing of next-generation anti-cancer therapies.
  • Continuously improve the sophistication and relevance of our cancer models, ensuring they more faithfully recapitulate the complexity of human disease and enhance the translational impact of our research.

 

Our services

Advantages of cryopreserving your strains:

  • Allows you to save space, by getting the mice you need, when you need;
  • Reduces your animal costs;
  • Reduces animal use;
  • Reduces risk from disasters (e.g. disease outbreaks, breeding cessation, equipment failures, genetic contamination, natural disasters, etc…).

 What can be cryopreserved?

  • Mouse Sperm
  • Mouse Embryos
  • Mouse Embryonic Stem Cells
  • Mouse Oocytes

 Sperm Cryopreservation:

Description: Sperm is retrieved from the epididymal tissues of 3 male mice and is cryopreserved in 20 to 30 straws that are stored in liquid-phase, liquid nitrogen across two tanks in two separate locations (SRD and CCDD), to ensure sample safety and mitigate risks associated to unexpected or uncontrollable events.

Material needed: 3 males, reproductively active, 12-25 weeks old

Timeline: 2-6 weeks (dependant on QC method of choice)

Considerations: this method of cryopreservation is rapid and cheap; however, it only preserves half of the genome. This method is only recommended for single mutations on a common inbred background.

Quality Control: we provide different levels of Quality Control (QC) for different price ranges.

  1. Test thaw QC: we will thaw 1 straw the day after cryopreservation and visually assess motility and viability of the recovered sperm
  2. IVF and culture to blastocyst QC: we highly recommend this QC step. In addition to test thaw, we will also perform IVF and culture embryos up to blastocyst stage. We will provide the investigator with a fertility rate (%) for the recovered sperm. We will charge an extra cost to cover the IVF procedure.
  3. IVF and embryo transfer QC: In addition to test thaw, we will perform IVF and transfer 2-cell embryos into up to 3 pseudopregnant females to generate viable embryos/live pups. We will charge an extra cost to cover the IVF and embryo transfer procedures.

    Please note that we require you to provide your genotyping protocol, as well as full detail of the genetic content of each strain that you submit for cryopreservation.

Diagram of Sperm Cryopreservation

Embryo Cryopreservation:

Description: Female mice are hormonally superovulated and oocytes are retrieved for in vitro fertilisation (IVF) with sperm from donor male. Resulting embryos are placed in cryoprotectant and loaded into multiple straws, which are gradually cooled and stored in liquid-phase liquid nitrogen in two separate tanks.

Material needed: Donor male and 8-10 donor females

Timeline: 12-15 weeks

Diagram of Embryo Cryopreservation

Embryonic Stem Cells Cryopreservation:

Not available, yet.

Oocyte Cryopreservation:

Not available, yet.

Cryostorage:

If you have cryopreserved mouse sperm/embryo/oocytes at another institution, we can cryostorage your samples for an annual fee. We do require that the investigator takes charge of shipping costs into our facility, and that thawing and genotyping protocols are submitted to the CIVM.

The CIVM stores all samples in liquid-phase liquid nitrogen tanks (CryoPlus1, ThermoFisher Scientific). Material retrieved from each strain is split between 2 tanks, a main and a backup tank, for redundancy. For additional safety, these 2 tanks are located in two separate buildings at ICR Sutton. Both tanks are continuously monitored by T-scan alarm systems and undergo annual service, as well as daily visual inspections.

 

Sperm Cryorecovery:

Description: Frozen sperm is cryorecovered by IVF, followed by embryo transfer. We can purchase wild-type female oocyte donors of the same genetic background, or alternatively the investigator can provide homozygous oocyte donors of the same strain.

Material needed: straw with frozen sperm and 8 to 12 females for IVF, 7-16 weeks old.

Timeline: 12-15 weeks

Diagram of Sperm Cryorecovery

 

Embryo Cryorecovery:

Description: Frozen 2-cell embryos are thawed and transferred into pseudopregnant females.

Material needed: straw(s) with frozen 2-cell embryos

Timeline: 8-10 week


Oocyte Cryorecovery:

Not available, yet.

 

Mouse rederivation

Description: Mouse rederivation is a process used to produce pathogen-free mouse colonies by removing microbial contaminants from existing lines. The procedure can be performed either through natural mating or in vitro fertilization (IVF):

  • In natural mating, embryos are obtained from donor mice and transferred into pathogen-free recipient females.
  • In IVF-based rederivation, fertilized embryos are created in vitro using gametes from donor mice and then implanted into clean recipient females.

Both methods effectively eliminate pathogens, allowing safe importation of mouse strains from lower health-status facilities into the ICR BSU. Samples from both litter and recipient mother will be sent for Health Screening and the associated costs will be charged separately to the Investigator.

Material needed: For IVF-based rederivation we require the investigator to provide 2 males, reproductively active, 12-25 weeks old, and the CIVM will purchase wild-type female egg-donors. Alternatively, if maintaining homozygosity is essential, the investigator will need to provide additional 6-10 females, 7-16 weeks old.

Timeline: 12-15 week

Mouse Rederivation Mating Diagram

Mouse Rederivation IVF diagram

We are currently setting up CRISPR/Cas9-based gene editing protocols. Soon, you’ll be able to apply for projects that involve developing new alleles based on:

  • Knockout by indel formation
  • Knockout by precise deletion
  • Conditional knockout
  • Knock-in of point mutations
  • Knock-in of small tags
  • Large knock-in
  • Exon replacement

These alleles will be developed based on Electroporation of Microinjection of CRISPR/Cas9 system reagents.

We will collaborate with you to design the best strategy and help you generate the genetically engineered mice you need for your project. 

We also provide:

  • Development of humanised mouse strains
  • Development of Patient-derived xenografts (PDX) and organoid models

Latest ICR News

05/03/26

Researchers have uncovered a previously unknown mechanism that allows breast cancer to exploit day-to-day gene activity to fuel its growth. This finding reveals how hormone-driven breast cancers develop and adapt to treatment.

The study, led by scientists at The Institute of Cancer Research, London, and predominantly funded by Cancer Research UK, but also in collaboration with colleagues in China, uncovers how an enzyme known for generating mutations in cancer, APOBEC3B (A3B), plays a direct role in promoting the growth and survival of a common type of breast cancer by regulating certain gene activities in oestrogen receptor-positive (ER-positive) breast cancer.

The findings, published in Nature Communications, have reshaped the research community’s understanding of how the instability and regulation of the genetic environment and cancer evolution are linked to cancers driven by hormones.

A new role for APOBEC3B

Oestrogen is the key hormone that regulates normal breast development by activating oestrogen receptors to switch specific genes on and off to control cell growth and survival.

Un-regulated oestrogen activity promotes the proliferation of new breast cells, which can lead to the accumulation of abnormal mutations that increase the likelihood of breast cancer developing. When breast cancer cells express oestrogen receptors, the disease is classified as oestrogen receptor-positive (ER-positive). ER-positive breast cancer accounts for 80 per cent of breast cancer cases, and is commonly treated with hormone therapies, yet many eventually become resistant to treatment.

The activation of oestrogen receptors in cancer cells is known to be accompanied by extensive DNA damage – referred to as DNA breaks – but how this damage arises and why it is closely tied to gene activation has remained unclear.

A3B – a DNA editing enzyme in the body's natural defence system – is widely recognised as a source of mutation in cancer. Yet its precise role in hormone-driven DNA damage was difficult to pinpoint in experimental models because most A3B-induced damage is rapidly repaired by the cell, leaving only a small fraction visible.

To overcome this hurdle, the research team developed a breast cancer cell model where DNA repair was temporarily blocked, allowing them for the first time to capture A3B’s activity in unprecedented detail

Targeting gene control regions

Using a combination of advanced gene sequencing techniques, the team found that A3B does not primarily target protein-coding genes in DNA, as originally thought. Instead, it targets specific regions in DNA – known as promoters and enhancers – that control when genes are switched on and how strongly they are expressed.

These promoter and enhancer regions of DNA become exposed during transcription, the first step in gene expression. When DNA coding for protein is copied into messenger RNA, which is then used to synthesise new proteins essential for cell structure, function, and repair. To start this process short stretches of DNA become exposed around the promoter and enhancers that regulate oestrogen-responsive gene expression. These regions of DNA become substrates for A3B that modifies the DNA in a way that influences how the damage is subsequently repaired.

Rather than being accidental or purely harmful, the DNA breaks that result from A3B editing DNA can enable the activation of oestrogen-responsive genes and remodel chromatin – the DNA, RNA and proteins that carry genetic information. In effect, the A3B-initiated DNA damage is integrated and coordinated into normal gene-regulation pathways, which cancer cells exploit to their advantage.

By reframing A3B as an active regulator of gene expression, rather than simply a mutational driver of cancer, this research marks a major shift in the understanding of how cancer-linked enzymes influence genetic regulation in hormone-driven cancers.

New findings, new context

The findings also provide new context for why ER-positive breast cancers often show high levels of genomic instability. Cancers that stop responding to hormone therapies frequently exhibit elevated A3B activity, suggesting that tumours may rely on this enzyme to adapt and survive under therapeutic pressure from treatment.

By better understanding A3B’s mutational activity and its relationship with hormone-driven gene activation, The Institute of Cancer Research (ICR) provides new context for the high genomic instability observed in ER-positive breast cancers. Further research could open up new strategies to interfere with this dysregulation, potentially by targeting the DNA-repair pathways that process A3B-induced damage, without directly disrupting essential oestrogen signalling.

Mapping future roles

Senior author Dr Paul Clarke, Leader of the RNA Biology and Molecular Therapeutics Group in the Centre for Cancer Drug Discovery at The Institute of Cancer Research, said: “A3B has long been viewed as a source of harmful mutations in cancer. What we were able to show here is that it also plays a far more active and organised role in controlling gene expression in oestrogen-driven breast cancer than we previously realised.”

Future research from the team will explore whether A3B plays similar regulatory roles in other hormone-driven cancers and whether interfering with the DNA repair pathways that process A3B-induced damage could unearth new therapeutic opportunities, especially for people whose cancer has become resistant to treatment.

Dr Clarke added: “While our findings do not immediately translate into the clinic, our new understanding will influence how the ICR identifies new ways to disrupt these complicated pathways to, hopefully, develop more efficient treatment for patients.”