Murine Experimental Model of Original Tumor Development and Peritoneal Metastasis via Orthotopic Inoculation with Ovarian Carcinoma Cells

Podsumowanie

To clarify the multistep process of peritoneal dissemination of ovarian carcinoma, the current study presents a murine experimental model of original tumor development and peritoneal metastasis via orthotopic inoculation with these tumor cells.

Streszczenie

Epithelial ovarian carcinoma (EOC) is associated with a poor prognosis because it shows peritoneal dissemination. To improve the prognosis, it is important to control peritoneal dissemination. However, it is still unclear how tumor cells detach from primary lesions and attach to the mesothelium. The establishment of an appropriate animal model is needed to gain an understanding of the mechanism of peritoneal dissemination in vivo. In the current study, we introduce the process from the local injection of EOC cells into the murine ovarian surface to the development of metastasis, including the peritoneum and distant organs. Female nude mice (BALB/c nu/nu) at 8 weeks of age were used. Under a microscopic field of view, EOC cells (1 x 10⁵ cells/µl of medium-extracellular matrix (ECM)-based hydrogel/unilateral ovary/mouse) were injected into murine ovaries through a retroperitoneal approach from the dorsal flank. This proposed method is a less invasive procedure for the mouse and minimizes damage to the ovary. Here, we describe the methodological steps in the development of the original and metastatic tumor formation of EOC.

Wprowadzenie

Epithelial ovarian carcinoma (EOC) accounts for the highest rate of cancer-related mortality among gynecological malignancies¹. EOC is associated with a poor prognosis, primarily due to its late symptomatology, and is often associated with multiple intraperitoneal disseminations and distant metastases^2-4. Peritoneal dissemination is a multi-step process. Firstly, tumor cells detach from the primary lesions, and migrate into the abdominal cavity. When the tumor cells attach to the peritoneal mesothelium, they start to invade tissues through the mesothelium^5,6. In order to better understand the tumor biology (e.g., cancer progression and therapeutic response), mouse models provide a wealth of information. A xenograft with human cancer cells is widely used for mouse models in which human cancer cells are inoculated subcutaneously, intraperitoneally, intravenously, and orthotopically. An animal model with an orthotopically grafted tumor can more efficiently and accurately generate results that reflect the tumor environment in humans in comparison with an animal model with a heterotopically grafted tumor. Therefore, for many human tumors, orthotopic transplantation models have been established^7-11.

Here, we describe the orthotopic inoculation of human EOC cells through a retroperitoneal approach from the dorsal flank, which has limited invasiveness compared to ventral inoculation. This technique can provide a variety of useful information on EOC, especially the mechanism of intraperitoneal dissemination.

Protokół

The treatment protocol follows the guidelines for animal experimentation adopted by Nagoya University.

1. Preparation of Cell Suspensions

1. Human ovarian clear cell carcinoma cell line.
   1. Maintain ES-2 cells¹² in RPMI-1640 medium with 10% fetal bovine serum (FBS) and penicillin/streptomycin (penicillin: 100 units/ml, streptomycin: 0.1 mg/ml). Culture cells at 37 °C in a 5% CO₂ humidified incubator.
   2. Collect cells in the logarithmic growth phase in 0.05% trypsin/0.02% EDTA solution (trypsin/EDTA).
      1. First, remove the old media from the cell culture vessel, then wash the cells once with PBS (PBS without Ca²⁺/Mg²⁺, 3 - 4 ml per 25 cm²).
      2. Next, add 1 ml per 25 cm² of trypsin/EDTA. Rotate the cell culture vessel to cover the cell monolayer with trypsin/EDTA. After removing and discarding trypsin/EDTA, return the cell culture vessel to the incubator for 3 - 5 min or until cells are detached.
      3. Examine the cells under a microscope to ensure the cells are detached from the surface of the cell culture vessel and floating.
      4. Add fresh serum containing growth medium to inactivate the trypsin (5 ml per 25 cm²), and re-suspend the cells. Transfer re-suspended cells to a 15 ml conical tube.
      5. Centrifuge at 300 x g for 5 min. Perform centrifugation either at 4 °C or room temperature. Carefully remove supernatant and re-suspend cells with growth medium (5 ml per 25 cm²).
   3. Count cells (e.g., by trypan-blue exclusion) then re-suspend in growth medium at a density of 2 x 10⁸ cell/ml. Put the suspended cells on ice.
2. Thaw frozen extracellular matrix (ECM)-based hydrogel aliquots in an ice bath.
3. Add the cell suspension to ECM-based hydrogel aliquots at a ratio of 1:1 (final cell concentration: 1 x 10⁵ cells/µl of medium-ECM-based hydrogel) and mix thoroughly. Place the prepared cell suspensions in an ice bath until use.

2. Orthotopic Inoculation with Cell Suspensions

NOTE: Surgery does not require a dedicated suite. Surgery can be performed on a laboratory benchtop in an area of the room that is separate and has minimal activity. A laminar hood also may be used. Sterile surgical instruments must be used and scissors should not be used to make skin incisions.

1. Use female nude mice (BALB/c nu/nu) at 8 weeks of age for this orthotopic inoculation model.
2. First, anesthetize the mouse using inhalation with isoflurane (2 - 4%). Check anesthetic depth by verifying lack of withdrawal upon firm toe pinch. After the mouse is anesthetized, apply a bland sterile ophthalmic ointment to the eyes to prevent drying as necessary.
3. Place the anesthetized mouse on an operating stage belly-side down. Disinfect the surgical area several times with both alcohol and an iodine-based or chlorhexidine-based scrub.
4. Make a ~ 2-cm incision vertically near the spine between the right costal arch and femur. Use a sterile surgical drape around the incision site. Fix the incised skin surfaces with clamps to maintain the opening.
   Note: Retractors can be used instead of clamps.
5. Next, make a second incision (approximately 1 cm) at the parietal peritoneum under the first incision to open the abdominal cavity. Clamp the incised abdominal surfaces. Clip the fat tissue that surrounds the ipsilateral ovary and fallopian tube with a clamp to remove the ovary from the abdominal cavity. Carefully place the ovary and fallopian tube on gauze. Then, place the mouse belly-side down under the dissecting microscope.
6. Place the cell suspension in an insulin syringe (1/2 cc, 29 G) just before injection. Carefully inject the prepared cell suspension (1 - 2 µl) into the ovary. For several sec, retain the needle within the ovary to ensure gelation of the ECM-based hydrogel. After gelation, the injected tumor cells remain inside the ovary.
7. Carefully return the ovary into the body. Suture the second incision with sterile medical silk, and then seal the skin with wound clips.
8. After surgery, the mice will be administered an analgesia (e.g., meloxicam, intramuscular (i.m.) or subcutaneous (s.c.), 0.2 mg/kg) for initial 24 hr period.

3. Post-surgical Treatment

1. Place each mouse in a separate cage on clean paper with a hot pack to keep the mouse warm until it has regained sufficient consciousness to maintain sternal recumbency. Then, return the animals to their cages for rearing and monitoring. Monitor the mice daily for 3 - 7 days following surgical treatment.
2. Monitoring of postoperative mice
   1. In case of signs of pain, administer analgesics daily (e.g., meloxicam, i.m. or s.c., 0.2 mg/kg).
   2. If mice have signs of infection (e.g., redness, swelling, discharge), administer daily injection with an anti-infective reagent (e.g., penicillin, i.m., 100,000 IU/kg).
3. Remove skin closure materials 10 - 14 days after post-surgical treatment.

4. Analysis of Tumors and Metastases

NOTE: The tumor will be formed at the injected ovary 2 - 3 weeks after inoculation.

1. Sacrifice the mice by carbon dioxide, and then collect the samples (e.g., tumors, metastases, organs)^13-15 for further analysis^14,16-20.
   NOTE: If an in vivo imaging system is available, cells bearing enzymes that produce bioluminescence (e.g., luciferase) or fluorescent protein (e.g., GFP) can be used in this protocol. This modified protocol will provide useful information for the dynamics of the spread of cancer cells from the primary tumor.

Wyniki

Six nude mice had their ovaries inoculated with the human clear cell carcinoma cell line ES-2, as described in this protocol. As shown in Figure 1A, after 2 weeks, 5 of the 6 mice had a tumor in the ovary inoculated with ES-2 cells, but there was no tumor in the contralateral ovary without inoculation (used as a control). Moreover, 2 of the 5 mice showed multiple peritoneal disseminations with ascites. Cells metastasize to the liver (Figure 1B). The ovari...

Dyskusje

Animal models are essential to analyze the mechanisms of tumor development, progression, metastasis, and drug efficacy against cancer cells. Mice bearing human ovarian cancer cells also have been used as an animal model. Here, we describe a less invasive procedure for the administration of ovarian tumor cells at an orthotopic site. Using this procedure, inoculation into the ovary through a retroperitoneal approach from the dorsal flank offers significant advantages over other commonly used techniques. Firstly, orthotopic...

Materiały

Name	Company	Catalog Number	Comments
Matrigel matrix	BD	354234	ECM-based hydrogel
Insulin syringe	TERUMO	SS-05M2913	1/2 cc, 29 G x 1/2"
Suturing needle with suture			11 mm, 3/8, Nylon6-0
Reflex 7 mm Wound Clip Applier	CellPoint Scientific	204-1000
Reflex 7 mm wound clips	CellPoint Scientific	203-1000