Abstract

The immune system is mainly responsible for protecting the organism against agents that may interfere in its homeostasis. Thus, understand how this system develops and operates is very important, for create new therapies to assist this system in its operation, such as its failure. In domestic dogs, few studies show how actually occurs the development, maturation and functioning of the immune system. Therefore, this study demonstrates the development and possible activation of it on dog fetus from late gestational period by in situ and microscopic analyzes.

Keywords:
Development; organs; neonate; lymphocytes

Introduction

Embryonic development is the study of early life and its changes through the prenatal period (Moore and Persaud, 2008Moore KL, Persaud V. 2008. Embriologia Clínica, 8th ed. Rio de Janeiro: Elsevier, 536pp.). The study of development can be divided according to the changes that occur during this period, such as the embryonic stage when most organs and systems are established and the fetal period, which is the growth and improvement of organs (Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.; Martins et al., 2011Martins DS, Ambrósio CE, Saraiva NZ, Wenceslau CV, Morini AC, Kerkis I, Garcia JM, Miglino MA. 2011. Early development and putative primordial germ cells characterization in dogs. Reprod Domest Anim, 46:62-66.), thus, the characterization of the embryonic and fetal development is divided according to the changes that occurred during that period (Miglino et al., 2006Miglino MA, Ambrosio CE, Martins DS, Wenceslau CV, Pfarrer C, Leiser R. 2006. The carnivore pregnancy: the develop- ment of the embryo and fetal membranes. Theriogenology, 66:1699-1702.; Pretzer, 2008Pretzer SD. 2008. Canine embryonic and fetal development: a review. Theriogenology, 70:300-303.).

Dog’s immune system still not well described, but in general, it consists of an intricate network of molecules, cells and organs that are responsible for protecting the body against mostly microorganisms, tumors, and traumas (Miglino et al., 2006Miglino MA, Ambrosio CE, Martins DS, Wenceslau CV, Pfarrer C, Leiser R. 2006. The carnivore pregnancy: the develop- ment of the embryo and fetal membranes. Theriogenology, 66:1699-1702.; Tizard, 2014Tizard IR. 2014. Veterinary Immunology. 9th ed. Philadelphia: Saunders, Elsevier, 568p.). Furthermore, specialized cells such as macrophages, neutrophils, dendritic cells, natural killer cells, lymphocytes, and components produced by them are part of this system, which is divide in innate and acquire immunity (Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.; Abbas et al., 2014Abbas AK, Lichtman AH, Pillai S. 2014. Cellular and Molecular Immunology. 8th ed. Philadelphia: Saunders, Elsevier. 544p.).

Innate immunity is formed during embryo and fetus development, in contrast the acquire immunity is only complete at postnatal, due to the evolution of the lymphocyte cell linage and improvement of the antigen recognition after birth (Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.). The thymus, bone marrow and Peyer’s patch are primary lymphoid organs regulating the initial development and maturation of the immune cells (Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.).

The canine development happens during approximately 65 days, but the organogenesis starts at 21days (Pieri et al., 2015Pieri NC, Souza AF, Casals JB, Roballo KCS, Ambrósio CE, Martins DS. 2015. Comparative Development of Embryonic Age by Organogenesis in Domestic Dogs and Cats. Reprod Domest Anim, 50:625-631.). The immune system begins with the formation of thymus from the third pair of pharyngeal pouches and subsequent formation of secondary lymphoid organs, continuing in the postnatal period (Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.).

The lymphatic and cardiovascular systems are critical to the immune system, once they lead antigens and antigen presenting cells to the lymph nodes and initiate the immune response, then, entire immune action depends of them (Alitalo and Carmeliet, 2002Alitalo K, Carmeliet P. 2002. Molecular mechanisms of lymphangiogenesis in health and disease. Cancer Cell, 1:219-227.). In canines, as in cats, around 17 days, the cardiovascular system is formed (Abreu et al., 2011Abreu DK, Rodrigues EAF, Monteiro JM, Franciolli AL, Costola-Souza C, Roballo KCS, Ambrósio CE, Miglino MA. 2011. Estudo microscópico e macroscópico, com enfoque radiográfico e de alizarina, no desenvolvimento embrionário e fetal de gatos domésticos (Felis catus) em diferentes idades gestacionais. Pesq Vet Bras, 31(Suppl. 1):57-66.; Roballo et al., 2013Roballo KC, Ercolin AC, Casals JB, Pieri NC, Barreto RS, Illera MJ, Martins DS, Miglino MA, Ambrósio CE. 2013. Domestic carnivore’s development: detec- tion of Oct-4, a pluripotency marker, in pharyngeal arches. Reprod Domest Anim, 48:41-43.). In addition, the fetal liver represents the initial hematopoietic tissue in early gestation and is responsible for the rapid expansion of restricted progenitor cells lineage from the immune system (Holsapple et al., 2003Holsapple MP, West LJ, Landreth KS. 2003. Species comparison of anatomical and functional immune system development. Birth Defects Res B Dev Reprod Toxicol, 68:321-334.), which can be visualized at around 26 to 27 days of gestation (Pieri et al., 2015Pieri NC, Souza AF, Casals JB, Roballo KCS, Ambrósio CE, Martins DS. 2015. Comparative Development of Embryonic Age by Organogenesis in Domestic Dogs and Cats. Reprod Domest Anim, 50:625-631.).

In dogs, the immune system development still unclear and deeper researches are necessary. Consequently, in this study, we analyzed the anatomy and histology of the main immune system organs at late gestation period in domestic dogs (45 to 50 days of pregnancy), to a better understanding of it and future contributions to the immunology studies.

Materials and Methods

The protocols and procedures involving animals were conducted in accordance with the Committee of Ethics of the Faculty of Veterinary Medicine and Animal Science, University of Sao Paulo, Brazil. Fetus at 45 to 50 days of pregnancy (N = 5, 13.5-15 cm of crown-rump), were obtained from dog population control campaign in Pirassununga, SP, Brazil. In order to define the gestational ages more accurately, we used the methodologies already described by Evans and Sack (1973)Evans HE, Sack WO. 1973. Prenatal development of domestic and laboratory mammals: growth curves, external features and selected references. Zentralbl Veterinarmed C, 2:11-45., Yeager and Concannon (1995)Yeager AE, Concannon PW. 1995. Ultrasonography of the reproductive tract of the female dog and cat. In: Bonagura, JD, Kirk RW. (Ed.). Kirk’s current veterinary therapy: XII small animal practice. 12 ed. Philadelphia: Saunders, p.1040-1051., with the aid of a caliper measuring CR length, morphogenesis and organogenesis as well as microscopic techniques. The fetus’s organs were prepared for macroscopy and microscopy analyzes, following Pieri et al. (2015)Pieri NC, Souza AF, Casals JB, Roballo KCS, Ambrósio CE, Martins DS. 2015. Comparative Development of Embryonic Age by Organogenesis in Domestic Dogs and Cats. Reprod Domest Anim, 50:625-631.’s protocol. In summary, they were analyzed in situ, and following by fixation for 24h, dehydrated, embedded in paraffin, and serial sections were stained with haematoxylin and eosin, then the slides were analyzed using a Zeiss KS400 (Oberkochen, Germany), and images were captured with AXIVISION 4.6 software (Carl Zeiss, Gottingen, Germany).

Results

The thymus was below the neck, cranial to the heart, close to the aorta artery, in front of the trachea, connected with the main vein and artery from the circulatory system, lobulated and proximally 1.3 mm of length (Fig. 1A and B). In the thymus the medullar and cortical region was not well delimited, the Hassal corpuscles was not evident at this period, and there was apparently reticular cells (important for the lymphocyte’s maturation) (Fig. 2AB).

Figure 1
Immune system development in dogs (macroscopy): Trachea (T); Thymus (Th); Heart (H); Lymphocytes (Ly); Liver (Li); Intestine (In) Spleen (Sp).

Figure 2
Immune system development in dogs (microscopy): Afferent lymph vessels (AV); subcapsular sinus (SS); Endothelial cells (EC); Lymphocytes (Ly). Central vein (CV); simple squamous epithelium (EP); Hepatocytes (H); Sinusoids (Si). Blood vessels (BV).

The lymph node was connected and close to the thymus with less than 0.4 mm of length with afferent lymph vessels, subcapsular sinus, endothelial cells, and lymphocytes, there was no evidence of cortex and medullar region at this fetal period (Fig. 1CD). Moreover, it was possible to analyze this regional lymph node just at this period.

The fetal liver was lobulated, with gallbladder, and occupying about half of the intestinal cavity (Fig. 1CD), and there was apparent central vein formed with blood cells inside with the vein epithelium around and hepatocytes in contact (Fig. 2GH).

The fetal spleen was connected to the circulatory and intestinal systems located at the left side, caudal to the stomach (Fig. 1D), and with lymphocytes, there was not the delimitation of write and red pulp at this period, but the capsule was formed with the simple epithelium (Fig. 2EF).

In this study, the lymphocytes were present at all main immune system organs at late pregnancy (Fig. 3).

Figure 3
Scheme of the immune system development: In dogs after embryogenesis the cardiovascular system becomes functional allowing the immune system organs maturation (middle third of gestation), and activation (final third of gestation).

Discussion

The thymus cellularity in the canine fetal happens at days 45- 55 according to Felsburg (2002)Felsburg PJ. 2002. Overview of immune system development in the dog: comparison with humans. Hum Exp Toxicol, 21, 487-492. and in accordance with ours findings.

According to Abreu et al. (2011)Abreu DK, Rodrigues EAF, Monteiro JM, Franciolli AL, Costola-Souza C, Roballo KCS, Ambrósio CE, Miglino MA. 2011. Estudo microscópico e macroscópico, com enfoque radiográfico e de alizarina, no desenvolvimento embrionário e fetal de gatos domésticos (Felis catus) em diferentes idades gestacionais. Pesq Vet Bras, 31(Suppl. 1):57-66., in embryos of cats with approximately 52 days of gestation, the liver occupies a large part of the abdominal cavity and is slightly lobed, with presence of bile duct entering the hepatic parenchyma near the lobular center veins.

Our findings at late gestational period showed the fetal liver without lymphocytes, proving their migration to the immune system organs, in accordance with the following authors’ researches. Solomon (1970)Solomon JB. 1970. Unification of foetal and neonatal immunology. Nature, 29:895-897. affirms that at early pregnancy periods the appearance of dog lymphocytes occurs much earlier than in cats; in addition, this system become immunocompetent approximately the same physiological period in rabbit, rat, chicken, and possibly dog at early periods. In humans and mice studies the lymphocyte progenitor cells appears in the fetal liver at early pregnancy and migrate (Holsapple et al., 2003Holsapple MP, West LJ, Landreth KS. 2003. Species comparison of anatomical and functional immune system development. Birth Defects Res B Dev Reprod Toxicol, 68:321-334.).

The rudimentary spleen development starts at 27-28 days, being popularized by immune cells after 52 days (Felsburg, 2002Felsburg PJ. 2002. Overview of immune system development in the dog: comparison with humans. Hum Exp Toxicol, 21, 487-492.), in accordance with the finds of this research.

It knows that lymphocytes derived from bone marrow migrate to the thymus on day 35 to 46, the lymph nodes and spleen around day 50-55 of pregnancy in canines; however, the fetus will be capable of an immune response only in the final third of gestation (Bryant et al., 1973Bryant BJ, Shifrine M, McNeil C. 1973. Cell mediated immune response in the developing dog. Int Arch Allergy Immunol, 45:937-942.; Hyttel et al., 2010Hyttel P, Sinowatz F, Vejlsted M. 2010. Domestic Animal Embryology. 11th ed. Philadelphia: Saunders, Elsevier, 208-215.).

In conclusion, according to our findings, the main immune organs were at this gestational period formed, and there were lymphocyte cells in the canine main organs at late development in dogs (45 to 50 days of pregnancy), proving the immune system functionality, but not proving its total activation. In addition, these results open a new field for other domestic animals immune system researchers.

Acknowledgment

This research was supported by the Sao Paulo Research Foundation (FAPESP) grant number 2015/17897-9 and to CNPq, Process 431508/2018-6.

References

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