This protocol describes a newly established method for virus delivery to the murine prostate. Using either CRISPR/Cas9 technology, gene overexpression, or Cre recombinase delivery, the technique allows orthotopic alteration of gene expression and implements a novel mouse model for prostate cancer.
With an increasing incidence of prostate cancer, identification of new tumor drivers or modulators is crucial. Genetically engineered mouse models (GEMM) for prostate cancer are hampered by tumor heterogeneity and its complex microevolution dynamics. Traditional prostate cancer mouse models include, amongst others, germline and conditional knockouts, transgenic expression of oncogenes, and xenograft models. Generation of de novo mutations in these models is complex, time-consuming, and costly. In addition, most of traditional models target the majority of the prostate epithelium, whereas human prostate cancer is well known to evolve as an isolated event in only a small subset of cells. Valuable models need to simulate not only prostate cancer initiation, but also progression to advanced disease.
Here we describe a method to target a few cells in the prostate epithelium by transducing cells by viral particles. The delivery of an engineered virus to the murine prostate allows alteration of gene expression in the prostate epithelia. Virus type and quantity will hereby define the number of targeted cells for gene alteration by transducing a few cells for cancer initiation and many cells for gene therapy. Through surgery-based injection in the anterior lobe, distal from the urinary track, the tumor in this model can expand without impairing the urinary function of the animal. Furthermore, by targeting only a subset of prostate epithelial cells the technique enables clonal expansion of the tumor, and therefore mimics human tumor initiation, progression, as well as invasion through the basal membrane.
This novel technique provides a powerful prostate cancer model with improved physiological relevance. Animal suffering is limited, and since no additional breeding is required, overall animal count is reduced. At the same time, analysis of new candidate genes and pathways is accelerated, which in turn is more cost efficient.
Detection and treatment of prostate cancer have significantly improved over the last decade. Still, the incidence of prostate cancer is increasing, following life expectancy. With an estimated 1.1 million new cases worldwide, it is among the most common causes of cancer-related death in men 1. Prostate cancer is slow in its development, but when the cancer has progressed to an advanced metastatic state, prognosis is poor due to limited treatment options. So far, only a few genes have been identified as common drivers in this cancer, and its heterogeneity and multifocality impedes detection of biomarkers and targetable disease drivers2,3.
Classical techniques of generating GEMMs are often impaired by their complexity, timely expenses, and costs. Conditional knockout models have been widely used to study prostate cancer candidate genes, that result in embryonic lethality when inactivated in the germline4. Most common models involve a prostate-specific Cre recombinase driven by either a modified Probasin5 or a PSA6 promoter integrated in the GEMM by additional cross-breeding. In these models, the gene of interest will be targeted in the majority of prostate epithelial cells, generating hyperplasia in the entire organ, which may impair the animal's urinary tract function7.
Viral delivery of the Cre protein by injection into the anterior lobe of the murine prostate can resolve this problem by only targeting a few cells8. Taking laboratories technical prerequisites, expertise, and objectives into account, the method benefits from a broad range of possible variations. Successful approaches utilizing Adenovirus targeting JunB and Pten9 or Lentivirus targeting Pten and Trp5310 have been shown amongst others. Adding transgenes, such as luciferase, to the viral construct or to the GEMM will furthermore enable non-invasive monitoring of disease progression via bioluminescence imaging11.
Genome editing based on the CRISPR/Cas9 technology reveals a new and rapid opportunity to study cancer through rapid generation of somatic knockouts12. Viral delivery of single guide RNAs (sgRNAs) directed to the anterior lobe of the murine prostate establishes a physiologically more relevant model of prostate cancer. By this means, single cells carrying chosen mutations can form clones that are capable of expansion and invasion. Furthermore, use of guide RNAs for multiple target genes will generate cell clones with alterations in different genes. This will allow tumor heterogeneity and a natural selection pressure on cancer progression, which can reveal the importance of each gene alteration or epistatic mechanisms.
Here we present a method to deliver viral particles to the murine prostate for alteration of gene expression. By a small abdominal incision, the murine anterior prostate lobe is exposed and viral particles are injected into the lobe. Five days post-surgery, surgical clips can be removed from the skin and the prostatic cancer can be analyzed from 8 weeks after. Overall, this is a rapid and cost-efficient procedure, which has little impact on the mouse and allows larger tumor to develop without compromising the mouse.
This protocol involves a surgical procedure in laboratory mice. All animal experiments must be individually reviewed and approved by an Institutional Animal Care and Use Committee (IACUC). As the approach is based on animal recovery and survival, ensure appropriate anesthesia, pain management, and an aseptic surgical environment at all time. Use a heating pad to prevent hypothermia during surgery and until recovery from anesthesia.
1. Starting Considerations
2. Virus-delivery to the Murine Prostate
3. Post-surgery Procedures
To assess virus delivery to the murine prostate, samples were analyzed three months after the surgery. The Rosa26-LSL-Cas9-EGFP mice12 express GFP in cells that have been exposed to Cre protein expressed by the virus. The prostate samples were examined with a fluorescence microscopy to identify areas with GFP signal (Figure 2A). The GFP signal indicates Cre activity in the prostate epithelium but not whether gene editing has been induced by the CRISPR guide. Immunohistochemical sections showed focal areas of cells with high expression of pAKT (Figure 2B), indicating loss of Pten13. An immunofluorescence co-staining of pAKT and GFP identified double positive cells (Figure 2C). This confirmed the transformation of prostatic cells by the Adeno-associated virus. Overall, these results show that in vivo CRISPR/Cas9 gene editing can be performed in the prostate epithelium by using the Adeno-associated virus and Rosa26-LSL-Cas9-EGFP mouse.
Figure 1: Illustration of the procedure. The procedure is carried out in the Rosa26-LSL-Cas9-EGFP mouse generated by Platt et al.12 The anterior prostate (AP) is attached to the seminal vesicle (SV). Virus particles expressing guide RNA and a Cre protein are injected into the anterior prostate to alter gene expression. Please click here to view a larger version of this figure.
Figure 2: Gene alteration in the murine prostate through orthotopic virus delivery. 7-week-old male Rosa26-LSL-Cas9-EGFP mice were injected with Adeno-associated virus containing a guide RNA for Pten and coding for a Cre protein. Samples were analyzed 3 months after virus injection. (A) GFP fluorescence imaging of the anterior prostate. (B) Histological section (4 µm) stained for pAKT (brown) marks the clonal area with loss of Pten expression. The dashed box marks the high magnification filed. (C) Immunofluorescence staining for GFP (green) and pAKT (red). Nuclear acids were stained with DAPI. Left: staining of the non-injected anterior lobe showing no signal for GFP or pAKT. Right: staining of the injected lobe showing co-localization of GFP (cytoplasmic staining) and pAKT (cell membrane localization). (D) Ptenflox/flox mice injected with Cre-expressing Adenovirus. H&E staining of a histological section (4 µm) of the anterior lobe 6 months after virus delivery. Dotted ellipse marks the area of high grade prostatic intraepithelial neoplasia. For details see reference 9. Please click here to view a larger version of this figure.
In this protocol, we describe a method to alter gene expression in the anterior lobe of the murine prostate by virus injection, creating a powerful new mouse model for prostate cancer (Figure 2). The successful administration of an Adenovirus was first described by Leow et al. in 20058. We have previously shown how an Adenovirus coding for a Cre recombinase protein can replace time-consuming cross-breeding of a Cre allele for tissue-specific deletion 9 (Figure 2D). Since the virus infects a few cells9, this model mimics the human scenario of clonal expansion14,15 and is optimal for cancer studies (Figure 2B).
The discovery of CRISPR/Cas9 technology has opened new opportunities for in vivo gene editing. It is now possible to alter multiple genes simultaneously, providing a highly valuable technique for this heterogenic cancer in a both cost-saving and time-efficient manner. Research using animal models benefits from the advantage of generating gene alterations not only in the germline, but also in adult tissues. Furthermore, the development of Cas9 expressing mice allows viral delivery of both the Cre and sgRNAs (Figure 1). As the guides have no impact on the genome without Cas9 expression, the work with this virus is non-hazardous.
Adeno-associated viruses induce very low immune responses, and even though present for up to a year, the virus does not integrate into the host genome, which makes it preferable for in vivo knockout studies16. In this context, it must be noted that different serotypes may impact transduction efficiency in distinct tissue types. Therefore, optimization for the targeted tissue is crucial to achieve high efficiency. Using genome-integrating Lentivirus can on the other hand allow long-term oncogene expression10.
The human prostate is not separated in distinct lobes and it has been discussed which of the murine prostate lobes best represents the human prostate. While the lateral lobe was proposed, no significant difference has been shown between the different lobes with respect to tumor initiation9,17,18,19. Another critical aspect of the virus delivery is the possible infection of other cells in the body. We have observed prostate stroma cells that have been transduced. The risk can be minimized during the orthotopic delivery procedure, avoiding blood vessels and preventing leakage while injecting. Further virus design including a prostate specific promoter, such as the Probasin promoter and serotype, could increase cell-specificity.
The authors have nothing to disclose.
MR was funded by a fellowship from the Danish cancer society (R146-A9394-16-S2). MFB and MKT were funded by AUFF NOVA (AUFF-E-2015-FLS-9-8). MR and MFB were co-funded by Graduate School, HEALTH, AU. The E.F.W. laboratory is supported by grants from the Spanish Ministry of Economy (SAF2015-70857, co-funded by the ERDF-EU) and an ERC advanced grant (741888 – CSI-Fun).
We want to thank Liliana Fajardo Mellor (Genes, Development and Disease; National Cancer Research Center) for critical reading of the manuscript.
Equipment | |||
B6J.129(B6N)-Gt(ROSA)26Sortm1(CAG-cas9*,-EGFP)Fezh/J mice | The Jackson Laboratory | 26175 | |
0,5 ml U-100 insulin syringe | BD | 324825 | for virus injection |
1 ml syringe | BD | 300013 | for anesthesia injection |
30 G 1/2'' needle | BD | 304000 | for anesthesia injection |
6-0 Polysorb Suture | Medtronic | GL889 | to close the peritoneum |
Disposable sterilized surgery drape | multiple suppliers | ||
Heating pad | multiple suppliers | ||
Povidone-Iodine Prep Pad | Fisher Scientific | 06-669-70 | |
Trimming machine | Aesculap | GT415 | to shave the abdomen |
Dumont Forceps | F.S.T | 11252-00 | |
Halsey Micro Needle Holder | F.S.T | 12500-12 | |
Iris Scissors | F.S.T | 14094-11 | |
Narrow Pattern Forceps | F.S.T | 11002-12 | |
Ring Forceps | F.S.T | 11106-09 | |
Wound Clip System Handle incl. Clips | F.S.T | 12030-01 | to close the skin |
Wound Clip System Remover | F.S.T | 12030-04 | |
Microscope | Leica | different models have been used | |
Reagents | |||
1x PBS | Gibco | 10010-023 | |
Antisedan | obtained from the animal facility | ||
Butorphanol | obtained from the animal facility | ||
Medetomidinhydrochlorid | obtained from the animal facility | ||
Midazolam | obtained from the animal facility | ||
100% Ethanol | Fisher Scientific | 22-032-103 | |
Eye ointment | Takeda | 7242 | |
Virus (AAV, AV) | multiple suppliers | virus used in this protocol is an in-house production | |
pAKT antibody | CST | 4060 | used 1:200 dillution |
GFP anitbody | CST | 2956 | used 1:100 dillution |