A subscription to JoVE is required to view this content. Sign in or start your free trial.

In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This protocol describes a pregnancy and feeding management technique for embryo-transferred and genetically modified rabbits, aimed at reducing newborn rabbit mortality and enhancing the preparation efficiency of gene-edited rabbits.

Abstract

With the advancement of scientific research, the demand for gene-edited rabbit models is increasing. However, there are limited pregnancy and feeding management systems for gene-edited rabbits, leading to low survival rates among gene-edited rabbits prepared by many inexperienced researchers. Therefore, proper guidance is essential. This article summarizes the pregnancy and feeding practices for genetically modified rabbits developed in the author's laboratory and outlines a set of fundamental processes. These include pregnancy diagnosis, antenatal care, midwifery, assisted breastfeeding, weaning, and other procedures, along with the rescue and care of weak newborn rabbits. Compared to the traditional natural childbirth and nurturing methods used in rabbit farms, this approach involves more refined management, requiring additional time and effort but significantly increasing the survival rate of suckling rabbits. The methods described in this article are suitable for most laboratory breeding scenarios involving gene-edited or embryo-transferred rabbits and provide a straightforward and effective reference for other researchers.

Introduction

Rabbits are a classic animal model for biomedical research and are increasingly becoming the preferred translational model to bridge the gap between rodent models and large animal models1,2. Compared with large animals, rabbits have moderate body size, small feeding space, low feeding cost, and convenient blood collection, which are conducive to repeated collection of research data and surgical operations. Rabbits are characterized by good reproductive ability, a short gestation period (28-32 days for New Zealand white rabbits), a large number of births, and fast growth3,4. Compared with rodents, rabbits are closer to humans in phylogenesis5. It is a cost-effective and practical experimental substitute for pigs and non-human primates6. Compared with other large and medium-sized gene editing animals (pigs, cattle, sheep, cats, dogs, monkeys), the preparation cost of gene editing rabbits is low, and the cycle is short. With the development of gene therapy7,8,9, stem cell therapy10,11,12,13, brain science research14, and other scientific fields1,15,16,17,18, the demand for nonrodent species in gene editing is increasing.

Gene editing rabbits were once considered to be one of the middle-sized gene editing animals that could realize industrial applications6. However, until today, gene-editing rabbits have not been able to achieve large-scale production. One of the main reasons is that the production and breeding of gene-editing rabbits are challenging, and the difficulty is much greater than that of gene-editing mice or rats. There are not many laboratories that can efficiently cultivate gene-editing rabbits. It is often difficult for beginners to successfully prepare gene editing rabbits, and they often encounter such unpleasant problems as low pregnancy rate19, abortion20, dystocia21, refusal of lactation by female rabbits22, and death of suckling rabbits23. However, there are few systematic data or literature guidelines on the pregnancy and feeding of gene-editing rabbits or embryo-transferred rabbits. Most of them are based on the experience of ordinary rabbit farms.

Therefore, this article summarizes the mature experience of pregnancy and nursing management of genetically modified rabbits from author's laboratory, and introduces a set of basic processes of embryo-transferred rabbits and genetically modified rabbits, including pregnancy diagnosis, antenatal care, midwifery, artificial assisted feeding, ablactation, as well as the rescue and nursing of weak baby rabbits. This process is specially established for breeding gene-editing rabbits or embryo-transferred rabbits. Compared with the traditional natural childbirth and nurturing method of rabbit farms, the pregnancy and nursing management model takes more time and energy, but it can greatly reduce the mortality of baby rabbits, and the effort is worth it.

Protocol

All experimental protocols were approved by the Ethics Committee for Animal Experiments of the Guangdong Medical Laboratory Animal Center. The ethical review number for the MKRN3 gene-modified rabbit breeding involved in this study is B202210-6. The study adheres to procedures in compliance with ethical standards outlined in the Helsinki Declaration of 1975 (revised 1983). The New Zealand rabbits used in this study were obtained from the Guangdong Medical Laboratory Animal Center in China. The pregnancy and feeding process of genetically modified rabbits described in this article is a summary of the daily animal breeding practices in the author's laboratory. Details on the reagents and the equipment used are listed in the Table of Materials.

1. Pregnancy diagnosis

  1. On the 12th to 14th day after embryo transfer (choose one of the time points), confirm pregnancy through direct palpation.
    NOTE: This step can be skipped. If palpation is too rough and forceful, it can lead to miscarriage in pregnant rabbits.
    1. Hold the neck skin behind the rabbit's ears with one hand, let the rabbit's buttocks shrink forward, close to the abdominal cavity of the rabbit's buttocks, and then use the other hand to open the palm and gently touch the back end of the abdomen.
    2. Press the abdomen to a certain degree. If a continuous string of smooth and elastic flesh balls, similar in size to fava beans, is touched, it is considered pregnancy24.
  2. If conditions permit, use ultrasound on the 15th day after embryo transfer to determine if the rabbit is pregnant. The pregnancy diagnosis of rabbits is based on the presence of small, strong echogenic points (gestational sacs) in the liquid dark zone.
  3. During the period of the 16th-18th days after embryo transfer, observe the rabbit twice a day in the morning and evening, for approximately 15 min each time. If the rabbit is observed to exhibit behaviors such as restlessness, rapid breathing, plucking hair to build nests, etc., during labor or estrus, it indicates that the female rabbit is pseudopregnant and has not truly conceived.
    NOTE: If embryo transfer fails, female rabbits will have pseudopregnancy similar to parturient or oestrus on the 16th-18th days due to the decrease of luteal hormone.

2. Antenatal care

  1. Allow pregnant rabbits to eat freely during pregnancy and add fresh green feed once a week.
  2. On the morning or evening of the 25th day after embryo transfer, transfer the pregnant rabbits to the delivery cage.
    1. Disinfect the delivery cage, animal incubator, paper scraps, or shavings in advance.
      NOTE: Choose a rabbit delivery cage that meets international criteria in size. Ensure that the delivery cage has sufficient space for the mother rabbit to move. Choose an incubator that can resist mother rabbit nibble. Choose thick paper scraps with good water absorption. According to the requirements and suggestions of local animal facility management, select appropriate disinfection methods.
    2. Fix the incubator on one side of the delivery cage, and put towels, shavings, or paper scraps into the animal incubator for the pregnant rabbits to make a nest.
    3. Provide adequate feed and drinking water.
    4. Gently move the pregnant rabbits to the delivery cage.
    5. Pay attention to whether the pregnant rabbits have made a nest in the incubator every day. If not, add some paper scraps and towels outside the incubator on the morning of the 28th day of pregnancy.
      NOTE: If the pregnant rabbits do not nest in the incubator, it will likely not give birth in the incubator. Put some towels and paper scraps outside the incubator to prevent newborn rabbits from losing temperature and dying outside the box.

3. Parturition

NOTE: Day 0 refers to shortly after fertilization and prokaryotic formation. Rabbits are ovulation-stimulating animals that ovulate 10-12 h after mating. The single-cell stage embryos obtained on the day after mating are considered to be on the 0.5th day. If single-cell stage embryos are cultured in vitro for only 2-3 h and then transferred to surrogate rabbits, it is also considered to be the 0.5th day of pregnancy.

  1. Prenatal monitoring
    NOTE: The gestation period of rabbits is 28-32 days. If a rabbit gives birth before the 30th day of pregnancy, the size of the fetus is usually relatively small, and there are rare cases of difficult labor. No excessive intervention is needed before the 30th day.
    1. On the morning of the 30th day of pregnancy in rabbits, perform abdominal palpation to roughly determine the number, size, and activity of the fetus.
      1. Hold the neck skin behind the rabbit's ears with one hand, let the rabbit's buttocks shrink forward, close to the abdominal cavity of the rabbit's buttocks, and then use the other hand to open the palm and gently touch the back end of the abdomen. The force must be light.
        NOTE: Pressing into the abdomen to a certain extent will touch several egg-sized ellipsoids, which can feel the movement of the fetus.
    2. If it is found that the number of fetuses conceived by pregnant rabbits is only 1-2, on the 30th day of pregnancy, inject 0.02 mg of cloprostenol intramuscularly at 5 p.m. to induce the rabbits' delivery the next day.
      NOTE: Pregnant rabbits have only 1-2 fetuses, which are prone to dystocia or delivery failure when mature.
  2. Hasten parturition
    NOTE: If the pregnant rabbit does not give birth on the morning of the 31st day of pregnancy, it can consider whether it needs to hasten parturition according to the following conditions.
    1. If the pregnant rabbit is only pregnant with 1-2 fetuses and has been injected with cloprostenol the day before, on the morning of the 31st day of pregnancy, inject 10 units of oxytocin into the muscles to induce labor.
    2. If the pregnant rabbit has signs of delivery (such as restlessness, rapid breathing, ear vascular dilation, plucking and making a nest, planning the ground, etc.), inject 10 units of oxytocin into the muscles to induce labor.
    3. If the pregnant rabbit has no signs of delivery and fetal movement is normal, continue to observe. If there is no delivery in the morning of the 32nd day of pregnancy, inject 10 units of oxytocin into the muscles to induce labor.
      NOTE: Usually, the use of oxytocin can solve difficult labor. Generally, 5-10 min after oxytocin injection, the pregnant rabbits will start delivery. Oxytocin is effective for about half an hour and can be administered again after half an hour. It is not recommended to induce labor with oxytocin more than 3 times. If oxytocin is ineffective, have a veterinarian perform a cesarean section. Otherwise, the fetus will die in the uterus, soften, and be discharged from the vagina.

4. Midwifery

  1. Arrange and prepare the incubators (Figure 1).
    NOTE: Prepare in advance before the rabbit gives birth. The size of the incubator used in this study is 45 cm × 30 cm × 15 cm in length × width × height.
    1. Add sterile absorbent padding. Corncob granules are recommended.
    2. Spread a towel as a mat covered with artificial down cotton.
      NOTE: The material of artificial down cotton is baby-grade polyester fiber, which is non-toxic. Artificial down cotton is very suitable for newborn rabbits keeping warm. However, it cannot be used to make a nest for the mother rabbit, or it may be eaten into the stomach.
  2. Quickly wipe the mucus on the newborn rabbits with a towel. Ensure they breathe smoothly, and then put them into the incubator.
    NOTE: If the breathing of newborn rabbits stops, immediately press the chest for auxiliary breathing (25-35 times/min) to reduce the chest diameter by 25%-30% until spontaneous breathing is restored.
  3. After the delivery of pregnant rabbits, count the number of fetuses born. Stick information cards on the incubator: modified genes, number of newborn rabbits, date of birth, etc.
    NOTE: The suitable environmental temperature for newborn rabbits is 30-32 °C. Placing an appropriate amount of rabbit hair or artificial down cotton inside the incubator can achieve a good insulation effect. Rabbit house should be maintained at 16-25 °C. Female rabbits usually have 6-8 nipples. If there are too many babies, some babies can be fed by other mother rabbits.

5. Postpartum care

  1. Baby rabbit care (Figure 2)
    NOTE: After giving birth, let the mother rabbit rest for about 1 h before breastfeeding. Rabbits usually breastfeed 1-3 times a day.
    1. Clean all nipples of the mother rabbit with alcohol cotton before the first feeding.
    2. Gently massage each nipple and gently squeeze out the first drop of milk.
    3. Feeding of 1-2-day-old baby rabbits: Each time, place the mother rabbit on the mat in a lateral position or a prone position and place the sucking rabbits one by one to their nipples to suck milk (Figure 2A). 1-2 day-old rabbits need to be fed 2-3 times a day.
      NOTE: Premature rabbits or low birth weight baby rabbits are prone to hypoglycemia. Feed 1 mL of 5% glucose and consume breast milk as soon as possible. If the baby rabbit is too weak to drink, then directly inject 1 mL of 5% glucose into the abdominal cavity.
    4. On the second day after birth, use a marker pen to number the back of each baby rabbit. Trim a small amount of tail tissue for genotyping.
    5. Feeding baby rabbits over 2 days old: When feeding, place the mother rabbit in an incubator and let it breastfeed on its own (Figure 2B). 2-9-day-old rabbits need to be fed 1-2 times a day, and over 9-day-old rabbits need to be fed once a day until weaning. Make sure the baby rabbits are full (Figure 2C).
      NOTE: If the mother rabbit is unwilling to breastfeed, it can be fed some fresh vegetables to make it more willing to cooperate. If necessary, mother rabbits can be breastfed after being placed in a stable position. Gently squeeze out the first drop of milk from each nipple of the mother rabbit to alleviate breast swelling and pain, which is beneficial for the baby rabbits to suckle on the milk. If the above methods are ineffective, other lactating mother rabbits should be used for breastfeeding.
    6. During the first 4 days after birth, clean the perineum of the baby rabbit twice a day with wet cotton balls to stimulate the excretion of meconium and urine (Figure 2D).
    7. As the hair of the baby rabbit grows, remove some down cotton from the incubator every day.
    8. Change the towel once a day until the baby rabbit grows to the point where its entire body is covered in hair.
      NOTE: Generally, the towel is no longer needed on the 8th day after birth.
    9. If baby rabbits (1-2 weeks old) experience diarrhea, immediately feed 3 drops of animal-grade gentamicin (concentration is 0.04 g/mL) twice a day for 5 consecutive days.
      NOTE: Diarrhea in baby rabbits is usually caused by sucking milk from mother rabbits with mastitis, or by the high temperature and humidity of the environment. The mortality rate of baby rabbits with diarrhea is very high.
    10. After the young rabbit opens its eyes (about 2 weeks old), move it to a nursing cage with a towel. Add some green feed.
      NOTE: The suitable temperature for baby rabbits (2-3 weeks old) is 23-30 °C.
    11. Separate the mother rabbit from the baby rabbits and only open the baffle once a day for breastfeeding.
      NOTE: This can prevent the baby rabbits from biting the mother rabbit's nipple.
  2. Postpartum care of the mother rabbit
    1. During lactation, allow mother rabbits to drink and eat freely and feed them with appropriate green feed to ensure adequate nutrition.
    2. If the mother rabbit suffers from mastitis, stop breastfeeding immediately and administer appropriate veterinary antibiotics for treatment (cephalosporins are recommended). Feed the young rabbits to other lactating mother rabbits with similar delivery times.

6. Ablactation

  1. Ensure that most young rabbits are weaned at 35 days of age. Weak rabbits are weaned at 40 days of age.
    NOTE: The suitable temperature for young rabbits (3 weeks to 3 months old) is 20-25 °C. The suitable temperature for young rabbits (3-6 months old) and adult rabbits is also 15-25 °C.
  2. Consider whether to vaccinate conventional vaccines according to the experimental requirements after weaning.

Results

This article describes a pregnancy and feeding management procedure for embryo-transferred and genetically modified rabbits. At the end of 2022, the author's laboratory initiated the development of a preparation platform for gene-modified rabbits. During this period, several common issues were encountered, including abortion, failure to deliver at term, dystocia, failure to pluck hair for nest preparation before delivery, the unwillingness of mother rabbits to breastfeed or incidents of cannibalism, insufficient brea...

Discussion

The main steps in the pregnancy and nursing management of embryo-transferred and genetically modified rabbits include midwifery and early assisted breastfeeding. Difficult childbirth is a common issue in rabbits19. Prolonged delivery times often result in fetal ischemia, hypoxia, and death25. The appropriate use of oxytocin can effectively shorten delivery times and reduce instances of fetal dystocia26. Many primiparous mother rabbits fail to pluck h...

Disclosures

The authors have nothing to disclose.

Acknowledgements

This research was supported by the National Natural Science Foundation of China (Grant No. 82101937), the Guangdong Medical Science and Technology Research Fund Project, China (Grant No. B2024069), and the Guangzhou Science and Technology Plan Project, China (Grant No. SL2023A04J02229, Assignment No. 2024A04J4923).

Materials

NameCompanyCatalog NumberComments
Artificial down cottonYangzhou Anguang Textile Co., Ltd, China5490-Jinyu
Cloprostenol Sodium InjectionShanghai Quanyu Biotechnology (Zhumadian) Animal Pharmaceutical Co., Ltd, China163232207
Corncob granulesGuangdong Provincial Medical Laboratory Animal Center, ChinaYUMIXIN
Electronic platform scaleYongkang Runjin weighing instrument Co., Ltd, Chinarj-09
GentamicinShanxi Jinfukang Biological Pharmaceutical Co., Ltd, China041531504
Glucose injectionHenan Kelun Pharmaceutical Co., Ltd, ChinaH41022251
IncubatorFoshan Chancheng Hualong Plastic Factory, ChinaAAA-2For newborn rabbits
Incubator box Hebei mabao wire mesh products Co., Ltd., Chinahttps://qr.1688.com/s/AJ1K7O3pAs a nest for the mother rabbits
Inslin SyringeBecton,Dickinson and Company, USAUltra-Fine,328421
Oxytocin injectionGuangzhou Baiyunshan Mingxing Pharmaceutical Co., LtdH44025245
Penicillin injectionGuangdong Kangtaiyuan Animal Husbandry Co., Ltd, China300012430
Rabbit delivery cageSuzhou Suhang Technology Equipment Co., Ltd., Suzhou, ChinaRB42-8G
TowelZhejiang Jieliya Co., Ltd, ChinaW3290

References

  1. Xu, J., et al. Gene editing in rabbits: Unique opportunities for translational biomedical research. Front Genet. 12, 642444 (2021).
  2. Esteves, P. J., et al. The wide utility of rabbits as models of human diseases. Exp Mol Med. 50 (5), 1-10 (2018).
  3. Song, J., et al. Genome engineering technologies in rabbits. J Biomed Res. 35 (2), 135-147 (2020).
  4. Brewer, N. R. Biology of the rabbit. J Am Assoc Lab Anim Sci. 45 (1), 8-24 (2006).
  5. Inazu, A., et al. Increased high-density lipoprotein levels caused by a common cholesteryl-ester transfer protein gene mutation. N Engl J Med. 323 (18), 1234-1238 (1990).
  6. Han, Y., et al. Genome-edited rabbits: Unleashing the potential of a promising experimental animal model across diverse diseases. Zool Res. 45 (2), 253-262 (2024).
  7. Ebrahimi, P., et al. In vivo and ex vivo gene therapy for neurodegenerative diseases: A promise for disease modification. Naunyn Schmiedebergs Arch Pharmacol. 397 (10), 7501-7530 (2024).
  8. Carter, J. E., Schuchman, E. H. Gene therapy for neurodegenerative diseases: Fact or fiction. Br J Psychiatry. 178, 392-394 (2001).
  9. Zha, Y., et al. CRISPR/Cas9-mediated knockout of APOC3 stabilizes plasma lipids and inhibits atherosclerosis in rabbits. Lipids Health Dis. 20 (1), 180 (2021).
  10. Khandpur, S., Gupta, S., Gunaabalaji, D. R. Stem cell therapy in dermatology. Indian J Dermatol Venereol Leprol. 87 (6), 753-767 (2021).
  11. Gao, L., et al. Stem cell therapy: A promising therapeutic method for intracerebral hemorrhage. Cell Transplant. 27 (12), 1809-1824 (2018).
  12. Alessandrini, M., Preynat-Seauve, O., De Bruin, K., Pepper, M. S. Stem cell therapy for neurological disorders. S Afr Med J. 109 (8b), 70-77 (2019).
  13. Song, J., et al. Development of the nude rabbit model. Stem Cell Reports. 16 (3), 656-665 (2021).
  14. Liu, X., et al. YIPF5 (p.W218R) mutation induced primary microcephaly in rabbits. Neurobiol Dis. 182, 106135 (2023).
  15. Bhaskar, S. M. M. Incidental findings in brain imaging research: spotlight on ethical considerations. Eur Radiol. 32 (10), 6977-6978 (2022).
  16. Sá, K. N., Venas, G. Brazilian research on noninvasive brain stimulation applied to health conditions. Arq Neuropsiquiatr. 79 (11), 974-981 (2021).
  17. Fan, J., Wang, Y., Chen, Y. E. Genetically modified rabbits for cardiovascular research. Front Genet. 12, 614379 (2021).
  18. Mu, Y., et al. GTKO Rabbit: A novel animal model for preclinical assessment of decellularized xenogeneic grafts via in situ implantation. Mater Today Bio. 18, 100505 (2023).
  19. Castellini, C., et al. The main factors affecting the reproductive performance of rabbit does: A review. Anim Reprod Sci. 122 (3-4), 174-182 (2010).
  20. Rosell, J. M., Fuente, L. F. Reproductive diseases in farmed rabbit does. Animals (Basel). 10 (10), (2020).
  21. Dickie, E. Dystocia in a rabbit (Oryctolagus cuniculus). Can Vet J. 52 (1), 80-83 (2011).
  22. Jiménez, A., González-Mariscal, G. Maternal responsiveness to suckling is modulated by time post-nursing: A behavioral and c-Fos/oxytocin immunocytochemistry study in rabbits. J Neuroendocrinol. 31 (9), e12788 (2019).
  23. Whitney, J. C., et al. Rabbit mortality survey. Lab Anim. 10 (3), 203-207 (1976).
  24. Varga, M. Rabbit Basic Science. Textbook of Rabbit Medicine. , 3-108 (2014).
  25. Hudson, R., Müller, A., Kennedy, G. A. Parturition in the rabbit is compromised by daytime nursing: the role of oxytocin. Biol Reprod. 53 (3), 519-524 (1995).
  26. Morgan, D. R. Routine birth induction in rabbits using oxytocin. Lab Anim. 8 (2), 127-130 (1974).
  27. Hamilton, H. H., Lukefahr, S. D., McNitt, J. I. Maternal nest quality and its influence on litter survival and weaning performance in commercial rabbits. J Anim Sci. 75 (4), 926-933 (1997).
  28. Benedek, I., Altbӓcker, V., Molnár, T. Stress reactivity near birth affects nest building timing and offspring number and survival in the European rabbit (Oryctolagus cuniculus). PLoS One. 16 (1), e0246258 (2021).
  29. González-Mariscal, G., Gallegos, J. A. The maintenance and termination of maternal behavior in rabbits: involvement of suckling and progesterone. Physiol Behav. 124, 72-76 (2014).
  30. Saxmose Nielsen, S., et al. Health and welfare of rabbits farmed in different production systems. Efsa j. 18 (1), e05944 (2020).
  31. Pinto-Pinho, P., Pinto, M. L., Monteiro, J., Fardilha, M. Pregnancy Complications and feto-maternal monitoring in rabbits. Vet Sci. 10 (10), 622 (2023).
  32. Abel, M., Smith, G. W., Nathanielsz, P. W. Prostaglandin-induced parturition in the rabbit; quantitative aspects of the route and duration of administration. J Endocrinol. 58 (1), xvi (1973).
  33. Sui, T., et al. A novel rabbit model of Duchenne muscular dystrophy generated by CRISPR/Cas9. Dis Model Mech. 11 (6), 032201 (2018).
  34. Deng, J., et al. The disrupted balance between hair follicles and sebaceous glands in Hoxc13-ablated rabbits. Faseb j. 33 (1), 1226-1234 (2019).

Reprints and Permissions

Request permission to reuse the text or figures of this JoVE article

Request Permission

Explore More Articles

Pregnancy ManagementNursing ManagementGenetically Modified RabbitsGene edited ModelsFeeding PracticesAntenatal CareMidwiferyAssisted BreastfeedingWeaning ProceduresSurvival RatesLaboratory BreedingEmbryo transferred RabbitsWeak Newborn Care

This article has been published

Video Coming Soon

JoVE Logo

Privacy

Terms of Use

Policies

Contact Us

Recommend to library

JoVE NEWSLETTERS

Research

Education

Authors

Librarians

ABOUT JoVE

Copyright © 2025 MyJoVE Corporation. All rights reserved