Immunohistochemical studies of the local immune system in the reproductive tract of the sow

Immune responses in the uterine mucosa: clues for vaccine development in pigs

The immune system in the upper reproductive tract (URT) protects against sexually transmitted pathogens, while at the same time providing immune tolerance responses against allogenic sperm and the developing fetus. The uterine environment is also responsive to hormonal variations during the estrus cycle, although the most likely timing of exposure to pathogens is during estrus and breeding when the cervix is semi-permissive. The goal for intrauterine immunization would be to induce local or systemic immunity and/or to promote colostral/lactogenic immunity that will passively protect suckling offspring. The developing fetus is not the vaccine target. This minireview article focuses on the immune response induced in the pig uterus (uterine body and uterine horns) with some comparative references to other livestock species, mice, and humans.

Tissue distribution of some immune cells in bovine reproductive tract during follicular and luteal phase

More recent studies indicate that immune cells which secrete their secretory products or cytokines play an important role in reproductive system. In our study, immune cell populations (CD8⁺ T lymphocytes, CD68⁺ macrophages, plasma cells, siderophages, eosinophils) and expression of major histocompatibility complex (MHC) class I and class II were examined in female reproductive tract during follicular (n = 13) and luteal phase (n = 10). Plasma cells and eosinophil granulocytes are present in few numbers in luminal epithelium, but abundant in longitudinal muscle layer of uterus, whereas siderophages are the dominant cell type in stroma. Moreover, MHC-I and -II⁺ cells are expressed by individual cells in organ layers, while CD8⁺ T cells and CD68⁺ macrophages are dominant in epithelium and muscle layer, respectively. In conclusion, we did not found significant changes in immune cells according to follicular and luteal phases, but localization and numbers in each organ have changed according to both organ and layers. These results indicate that these factors may play a crucial role not only to generate an immune response but also to have a role in regulation of physiological functions in female reproductive organs.

A review of the human vs. porcine female genital tract and associated immune system in the perspective of using minipigs as a model of human genital Chlamydia infection

Sexually transmitted diseases constitute major health issues and their prevention and treatment continue to challenge the health care systems worldwide. Animal models are essential for a deeper understanding of the diseases and the development of safe and protective vaccines. Currently a good predictive non-rodent model is needed for the study of genital chlamydia in women. The pig has become an increasingly popular model for human diseases due to its close similarities to humans. The aim of this review is to compare the porcine and human female genital tract and associated immune system in the perspective of genital Chlamydia infection. The comparison of women and sows has shown that despite some gross anatomical differences, the structures and proportion of layers undergoing cyclic alterations are very similar. Reproductive hormonal cycles are closely related, only showing a slight difference in cycle length and source of luteolysing hormone. The epithelium and functional layers of the endometrium show similar cyclic changes. The immune system in pigs is very similar to that of humans, even though pigs have a higher percentage of CD4(+)/CD8(+) double positive T cells. The genital immune system is also very similar in terms of the cyclic fluctuations in the mucosal antibody levels, but differs slightly regarding immune cell infiltration in the genital mucosa - predominantly due to the influx of neutrophils in the porcine endometrium during estrus. The vaginal flora in Göttingen Minipigs is not dominated by lactobacilli as in humans. The vaginal pH is around 7 in Göttingen Minipigs, compared to the more acidic vaginal pH around 3.5-5 in women. This review reveals important similarities between the human and porcine female reproductive tracts and proposes the pig as an advantageous supplementary model of human genital Chlamydia infection.

Efficacy of oral vaccination against swine erysipelas in growing-finishing pigs in a clinically infected Slovakian pig herd

In a large Slovakian growing-finishing pig production unit, the effects of oral vaccination against swine erysipelas (SE) were investigated in three groups of pigs of 10 weeks of age. In group 1, the pigs were vaccinated intramuscularly at 1 and 3 weeks after arrival in the growing-finishing barn using an Erysipelothrix rhusiopathiae bacterin. Group 2 pigs were vaccinated at the same time as group 1 using an oral avirulent live SE vaccine administered through drinking water; the pigs in the third group were placebo treated. Clinical signs of acute SE, arthritic changes, average daily weight gain (ADG), feed conversion ratio, and mortality were evaluated. None of the pigs in groups 1 and 2 but 31.7% of the control animals (group 3) showed typical clinical signs of acute SE. More (P<0.01) non-vaccinated pigs had chronic arthritic changes compared with groups 1 and 2. No significant differences in mortality were recorded between the groups. Groups 1 and 2 had higher (P<0.05) ADG and lower feed conversion ratios compared with group 3 pigs. The results demonstrated that the oral avirulent live culture was efficacious in significantly reducing the clinical symptoms caused by E. rhusiopathiae infection, so enhancing the pigs' performance.

The sow endosalpinx at different stages of the oestrous cycle and at anoestrus: studies on morphological changes and infiltration by cells of the immune system

The aim of this study was to investigate the morphological changes of the sow endosalpinx and the distribution of leukocytes throughout the oestrous cycle and at anoestrus. Nineteen crossbred sows (Swedish Landrace x Swedish Yorkshire) at late dioestrus (three), prooestrus (three), oestrus (three), early dioestrus (three), dioestrus (three) and anoestrus (four) were used. Oviductal samples from three different parts (isthmus, ampulla and infundibulum), taken immediately after slaughter, were fixed, embedded in plastic resin and stained with toluidine blue or stored in a freezer at -70 degrees C until analysed by immunohistochemistry (prooestrus and anoestrus) with an avidin-biotin peroxidase method. Quantitative and qualitative examinations of oviductal epithelium and subepithelial connective tissue were performed by light microscopy. During all stages, a lower degree of morphological changes (pseudostratification, mitosis and secretory granules) was found in the isthmus compared with ampulla and infundibulum. In ampulla and infundibulum, pseudostratification, mitotic activity and secretory granules of the epithelium were high at prooestrus/oestrus. Cytoplasmic protrusions of epithelial cells with some extruded nuclei were prominent in ampulla and infundibulum at all stages except for oestrus and early dioestrus. Lymphocytes as well as CD2- and CD3-positive cells were the predominant immune cells in the epithelial layer. The numbers of lymphocytes and CD3-positive cells did not differ among segments and stages. Numbers of CD2-positive cells did not differ between prooestrus and anoestrus while the numbers were significantly higher in the infundibulum than in ampulla and isthmus. Neutrophils were only occasionally found and mainly in the infundibulum. In the subepithelial connective tissue layer, the two most commonly observed immune cell types were lymphocytes and plasma cells. The numbers of lymphocytes as well as CD2- and CD3-positive cells was lower in isthmus than in the other segments (p < or = 0.001). Higher numbers of plasma cells (p < or = 0.001) were found in infundibulum than in ampulla and isthmus. The numbers of lymphocytes and plasma cells were not significantly different between stages of the oestrous cycle. However, the number of neutrophils differed and were highest at prooestrus in ampulla and infundibulum. The numbers of CD2-, CD3- and CD79-positive cells did not differ between prooestrus and anoestrus whereas for CD14- and SWC3-positive cells, the numbers were higher at prooestrus (p < or = 0.05) than at anoestrus. In the oviduct, the morphology differed in ampulla and infundibulum with oestrous cycle stages, which indicates an effect by ovarian steroid hormones. The immune cell infiltration was less influenced by cyclic changes. However, the immune cell infiltration (in the connective tissue) in the upper part, especially infundibulum, differed significantly from the one in the lower part, isthmus, indicating different immune functions within various parts of the oviduct.

Seminal plasma regulates endometrial cytokine expression, leukocyte recruitment and embryo development in the pig

In pigs, uterine exposure to the constituents of semen is known to increase litter size but the underlying physiological mechanisms remain undefined. Studies in rodents and humans implicate immune modulating moieties in seminal plasma as likely candidates, acting through enhancing the receptivity of the female tract. In this study, the acute and longer term effects of seminal plasma on cytokine expression and leukocyte abundance in the pig endometrium during early pregnancy have been characterised. The reproductive tracts of gonadotrophin-primed pre-pubertal gilts treated with intrauterine infusions of either pooled seminal plasma or phosphate-buffered saline (PBS) were retrieved at 34 h, or on day 5 and day 9 after treatment. Seminal plasma elicited an endometrial inflammatory infiltrate comprised of predominantly macrophages and major histocompatibility complex class II+-activated macrophages and dendritic cells. The abundance of these cells was greatest at the pre-ovulatory (34 h) time-point and their increase relative to PBS-treated tissues was maintained until day 9 after seminal plasma treatment. Seminal plasma induced the expression of the cytokines, granulocyte macrophage colony-stimulating factor, interleukin-6 and monocyte chemoattractant protein-1, and the eicosanoid-synthesising enzyme cyclo-oxygenase-2. Expression was maximal 34 h after treatment but altered expression patterns as a consequence of seminal plasma induction persisted through early pregnancy. These changes were accompanied by altered dynamics in pre-implantation embryo development with an increase in the number of embryos and in their viability after seminal plasma treatment. Together, these findings implicate factors in seminal plasma in programming the trajectory of uterine cytokine expression and leukocyte trafficking during early pregnancy and in regulating pre-implantation embryo development in the pig.

Influence of pre-ovulatory insemination and early pregnancy on the infiltration by cells of the immune system in the sow endometrium

The aim of this study was to investigate the distribution of leukocytes in the sow endometrium following insemination and during early pregnancy. Cross-bred multiparous sows (Swedish Landrace x Swedish Yorkshire) were artificially inseminated (AI) once at 20-15 h before ovulation. Blood samples were collected from the jugular vein 1 h before slaughter for analyses of oestradiol-17beta and progesterone levels. The sows were slaughtered at 5-6 h (group I, n = 4) after AI or at different times after ovulation: 20-25 h (group II, n = 4), 70 h (group III, n = 4), day 11 (group IV, n = 3; first day of standing oestrus = day 1) and day 19 (group V, n = 3). Uterine horns were flushed to control for the presence of spermatozoa and neutrophils (groups I-IV) and/or for recovery of oocytes and/or embryos (groups II-IV, control of pregnancy). Mesometrial uterine samples were fixed, embedded in plastic resin and stained with toluidine blue. The surface and glandular epithelia as well as subepithelial and glandular connective tissue layers were examined by light microscopy. A marked number of neutrophils and spermatozoa were observed in the flushings from the uterine horns of sows slaughtered at 5-6 h after insemination. All animals slaughtered after ovulation were pregnant but no morphological effect of pregnancy was observed until day 11. In the surface epithelium, the largest numbers of intraepithelial lymphocytes were found in groups II and III, the smallest number was found in group V. The largest number of lymphocytes within the glandular epithelium was found in group III. The largest number of macrophages within the surface and glandular epithelia were found in group I. Neutrophils were found within the surface epithelium only in groups I and II. In the subepithelial connective tissue layer, a high infiltration of neutrophils was found in groups I and II while the largest number of eosinophils was found in group IV. The largest number of lymphocytes was observed in group V. In conclusion, this study showed a variation in the infiltration and distribution of neutrophils, lymphocytes, macrophages, eosinophils and plasma cells in the endometrium following insemination and during different stages of early pregnancy. Particularly, the pattern of lymphocyte presence on day 19 of pregnancy, indicate that the lymphocyte function may play a role during embryonic attachment in the pig.

Corrigendum to "The sow endometrium at different stages of the oestrus cycle: studies on morphological changes and infiltration by cells of the immune system." [Anim. Reprod. Sci. 65 (2001) 95-114]

The aim of this study was to investigate the distribution of leukocytes and the morphological changes of the sow endometrium throughout the oestrous cycle. Fifteen crossbred multiparous sows (Swedish Landrace x Swedish Yorkshire), with an average parity number of 3.4+/-0.7 (mean+/-S.D.) were used. Blood samples were collected from the jugular vein 1 h before slaughter for analyses of oestradiol-17beta and progesterone levels. Uterine samples from the mesometrial side of both horns, taken immediately after slaughter at late dioestrus, prooestrus, oestrus, early dioestrus and dioestrus, were fixed, embedded in plastic resin and stained with toluidine blue. The surface and glandular epithelium as well as subepithelial and glandular connective tissue layers were examined by light microscopy (LM). The significantly highest surface and the glandular epithelium were observed at oestrus and dioestrus, respectively. The largest number of capillaries (underneath the surface epithelium) was found at oestrus. In the surface epithelium, the largest number of intraepithelial lymphocytes (IELs, round nucleus) was found at early dioestrus. The largest number of lymphocytes and macrophages within the glandular epithelium were found at early dioestrus and oestrus, respectively. In the subepithelial connective tissue layer, the most common type of leukocytes during all stages was the lymphocyte. The largest numbers of lymphocytes and neutrophils were found at oestrus while the largest number of eosinophils was found at dioestrus. The dominating cells of the immune system in the connective tissue of the glandular layer were lymphocytes and macrophages. The significantly largest numbers of lymphocytes and plasma cells were found at early dioestrus and dioestrus, respectively. The number of lymphocytes in the connective tissue of the glandular layer and the number of plasma cells in the subepithelial layer were positively correlated with the plasma level of progesterone (P < or = 0.05). The numbers of capillaries and neutrophils in the subepithelial layer underneath the surface epithelium as well as the number of macrophages in both surface and glandular epithelium were positively correlated with the plasma level of oestradiol-17beta (P < or = 0.05). In conclusion, the present study showed a variation om the infiltration and distrobution of lymphocytes, neutrophils, eosinophils, macrophages, mast cells, and plasma cells in the sow endometrium during different stages of the oestrous cycle. Also morphological parameters (e.g. height of surface and glandular epithelium, capillaries density and degree of oedema) varied throughout the oestrous cycle.

Lymphocytes and T lymphocyte subsets are regionally distributed in the female goat reproductive tract: influence of the stage of the oestrous cycle

The reproductive tract of the female is a part of the mucosal system which protects from pathogens invasion. We have analysed the presence and distribution of total lymphocytes, plasma cells (antibody secreting B cells) and T lymphocytes subsets in the reproductive tract of the female goat. The influence of the oestrous cycle on the densities of lymphocytes and plasma cells of the cervix and uterus horn was evaluated in sections prepared for conventional histology. Immunocytochemistry was used for the study of lymphocyte subsets by confocal microscopy and immunoperoxidase techniques. Present results show that the reproductive tract of the goat is a site rich in lymphocytes. These cells were found mingled with the epithelial cells of the endometrium and distributed throughout the stroma. Lymphocyte aggregates were observed in the stroma. Lymphocyte but not plasma cell number changed depending on the reproductive stage of the goats. The impact of the hormonal environment was different for the cervix and uterine horn. Immunocytochemistry studies evidenced the presence of cells displaying immunoreactivity for both CD 4+ and CD 8+ antibodies in the epithelial layer and stroma of the cervix and uterine horn. These cells were more numerous in the cervix and were also found infiltrating the luminal epithelia of endometrial glands. Overall, our results indicate that lymphocyte distribution is different in the cervix and the horn, and is influenced by the stage of the reproductive cycle. In summary, CD 4+ and CD 8+ T lymphocytes subsets could be found in the endometrium of both the cervix and uterine horn of the goat reproductive tract.

The sow endometrium at different stages of the oestrous cycle: studies on morphological changes and infiltration by cells of the immune system

The aim of this study was to investigate the distribution of leukocytes and the morphological changes of the sow endometrium throughout the oestrous cycle. Fifteen crossbred multiparous sows (Swedish Landrace x Swedish Yorkshire), with an average parity number of 3.4 +/- 0.7 (mean +/- S.D.) were used. Blood samples were collected from the jugular vein 1h before slaughter for analyses of oestradiol-17beta and progesterone levels. Uterine samples from the mesometrial side of both horns, taken immediately after slaughter at late dioestrus, prooestrus, oestrus, early dioestrus and dioestrus, were fixed, embedded in plastic resin and stained with toluidine blue. The surface and glandular epithelium as well as subepithelial and glandular connective tissue layers were examined by light microscopy. The significantly highest surface and the glandular epithelium were observed at oestrus and dioestrus, respectively. The largest number of capillaries (underneath the surface epithelium) was found at oestrus. In the surface epithelium, the largest number of intraepithelial lymphocytes (IELs, round nucleus) was found at early dioestrus. The largest number of lymphocytes and macrophages within the glandular epithelium were found at early dioestrus and oestrus, respectively. In the subepithelial connective tissue layer, the most common type of leukocytes during all stages was the lymphocyte. The largest numbers of lymphocytes and neutrophils were found at oestrus while the largest number of eosinophils was found at dioestrus. The dominating cells of the immune system in the connective tissue of the glandular layer were lymphocytes and macrophages. The significantly largest numbers of lymphocytes and plasma cells were found at early dioestrus and dioestrus, respectively. The number of lymphocytes in the connective tissue of the glandular layer and the number of plasma cells in the subepithelial layer were positively correlated with the plasma level of progesterone (P < or = 0.05). The numbers of capillaries and neutrophils in the subepithelial layer underneath the surface epithelium as well as the number of macrophages in both surface and glandular epithelium were positively correlated with the plasma level of oestradiol-17beta (P < or = 0.05). In conclusion, the present study showed a variation in the infiltration and distribution of lymphocytes, neutrophils, eosinophils, macrophages, mast cells and plasma cells in the sow endometrium during different stages of the oestrous cycle. Also morphological parameters (e.g. height of surface and glandular epithelium, capillaries density and degree of oedema) varied throughout the oestrous cycle.

Post-mortem examination of genital organs from sows with reproductive disturbances in a sow-pool

Over a period of approx. 15 months, post-mortem (PM) examinations were made on genital organs (34 gilts and 81 sows) from a sow-pool with reproductive disturbances. Anamnestic data on the animals included information about parity number, date of farrowing, dates of weaning, oestrus and service, and cause of culling. At the PM examination, the macroscopic appearance of the ovaries (follicles, corpora lutea, cysts) and uterus (content, endometrium) were studied. Specimens from the endometrium was examined histologically. The most common reason for culling was repeat breeding (67%), in most cases at irregular intervals. The non-productive period averaged 82 days in sows (weaning to slaughter) and 151 days in gilts (from 1st day of mating until slaughter). In 49.6% of the sows no pathological changes were found. Macroscopic examination of the ovaries in 108 animals showed that 69% were cycling normally, 17% were anoestral and 14% had multiple follicular cysts (7 animals were not included due to ovo-testis [1 case], pregnancy [3 cases] and with signs of recent abortion [3 cases]). As judged from the histological examination, 27% of the animals had endometritis, which was classified as mild in 50% of them. Anoestral animals had a higher incidence of endometritis (61%) than animals showing cyclic ovarian activity (19%). This indicates that ovarian inactivity is of importance for the development of endometritis. It was concluded that post-mortem examination of genital organs from animals with reproductive problems is a valuable diagnostic tool. The anamnestic data together with the PM results indicated that management routines (oestrous detection, insemination, grouping at early pregnancy) needed to be changed.

The immunoglobulins and immunoglobulin genes of swine

The historical works describing the characterization of swine immunoglobulins are reviewed. The three major isotypes, IgM, IgA and IgG, have been recognized for 25 years and their concentrations in various body fluids, the location of the plasma cells throughout the body which synthesize them and their transport into lacteal secretions and absorption by the gut of the newborn piglet, have been studied by many investigators. Swine like humans, have both kappa and lambda light chains and their frequency of expression is similar to that of humans. Various investigators have provided immunochemical evidence for IgG subclass and allotype diversity, although until the recent advent of molecular biology, the complete sequence of any swine immunoglobulin was unknown. Molecular genetic studies reveal single copies of C alpha and C epsilon but as many as eight copies of C gamma. The sequences of five IgG subclasses, IgG1, IgG2a, IgG2b, IgG3 and IgG4, are now available as well as the sequence and genomic organization of C alpha and the sequence of C mu. Swine CH genes all appear to belong to a single small family very similar to human VHIII. Especially interesting is the high degree of similarity among human and swine Ig genes despite the distinct phylogenetic relationship of these species. The rapid expansion of knowledge and technology in the field of molecular biology, together with the attractiveness of the swine as a model for immunoontogeny, in which the influences of both maternal regulatory factors and intestinal gut flora can be experimentally controlled, promises the beginning of an exciting area in swine immunology.

Studies on the distribution of immune cells in the uteri of prepubertal and cycling gilts

To establish the cellular basis for the local immune response in the porcine uterus, immunohistochemical studies using a panel of monoclonal antibodies to pig leukocytes were conducted on uterine tissues from prepubertal and cycling gilts. In prepubertal uteri, neutrophils were the most predominant cell type, while MHC class II+ cells and CD2+ T lymphocytes were also common. At the early-stage of the oestrous cycle, CD2+ T cells were numerous in the endometrium, particularly in the uterine epithelium and subepithelial regions. However, by the mid-stage of the cycle there was a significant and dramatic fall in CD2+ T cells and other lymphocytes expressing the CD4, CD8 and CD1 phenotypes, MHC class II+ cells were predominant throughout the endometrium. During late oestrus there was a dramatic infiltration of neutrophils into the subepithelial stroma. A distinct increase in the CD2+ intraepithelial T lymphocyte population was also observed at this stage of the cycle. It was concluded that in the healthy, non-pregnant pig uterus T lymphocytes, macrophages and neutrophils were the prominent leukocyte cell types and their migration and distribution in the uterus was strongly influenced by the oestrous cycle. These immune cells may play an important interactive role in the cyclic cellular changes in both the structure and function of the endometrium. Furthermore, the leukocyte phenotypes found in the porcine endometrium indicate that a local cellular immune response could be elicited.

Immunostimulatory factor(s) in the porcine uterine fluids

The effects of porcine uterine fluid filtrate (PUF) on lymphocyte activity were examined. PUF was added to porcine lymphocyte cultures in the presence or absence of phytohemagglutinin (PHA), concanavalin A (Con A), or pokeweed mitogen (PWM). Lymphocyte response was determined by 3H-thymidine incorporation. Results indicated that PUF enhanced PHA-, Con A-, and PWM-induced lymphocyte mitogenesis by 222%, 207%, and 261%, respectively, as compared to control. The stimulatory effect of PUF was unlikely to be due to the presence of interleukin-2 in PUF, by evidence that PUF alone did not support cytotoxic T-lymphocyte proliferation, nor was the stimulatory effect due to microbial contamination, because treatment of PUF through PyroBind columns to remove endotoxin did not affect its activity. Incubation of PUF at 56C for 40 min did not alter the enhancement effect. Treatment of PUF with trypsin or pronase for up to 24 hr did not change its activity. In mixed lymphocytes reaction, PUF augmented 3H-thymidine uptake by 242%. The molecular (mol) mass of the immunostimulatory activity in PUF was examined by size-exclusion HPLC, Sephadex G-50, and G-15 gel filtration, and it was found to be 0.8 kDa and < 0.5 kDa. Extracts of porcine endometrium also enhanced PHA-induced lymphocyte mitogenesis, suggesting that the factor(s) may be of uterine origin. In conclusion, we have identified an factor(s) in PUF capable of stimulating lymphocyte mitogenesis and mixed lymphocyte reaction.

Plasma cell numbers in uteri of mares with persistent endometritis and in ovariectomised mares treated with ovarian steroids

Immunoglobulins A, G and M were localised by immunoperoxidase staining of endometrial sections from ovariectomised mares. Treatment with progesterone or oestradiol-17 beta did not significantly affect numbers of cells secreting any of the isotypes. Mares with persistent endometritis did not have significantly greater numbers of endometrial plasma cells than genitally-normal mares.

Expression of IgA and secretory component in the normal and in adenocarcinomas of Fallopian tube, endometrium and endocervix

The occurrence and localization of IgA and secretory components (SC) were examined in the normal and in adenocarcinomas of Fallopian tube, endometrium and endocervix. IgA-containing immunocytes were identified in the stroma of 90% of normal Fallopian tubes. It is suggested that the Fallopian tube may have an immunological function and may, together with the endocervix, constitute the local secretory immune system of the female genital tract. IgA and SC were frequently demonstrated in the cytoplasm and luminal secretion of adenocarcinomas of the endocervix, endometrium and Fallopian tube. This study has shown a decrease in immunoreactivity of SC among poorly differentiated adenocarcinomas but has failed to demonstrate any correlation between the expression of IgA and the degree of differentiation of the tumours. Secretory component appears, therefore, to be more useful than IgA as an indicator of secretory activity and differentiation of adenocarcinomas of the female genital tract.

Immunohistochemical evaluation of the equine endometrium during the oestrous cycle

Endometrial biopsies were obtained from four mares during consecutive oestrous cycles on the first day of oestrus, on the day when ovulation was detected, and four and eight days after ovulation. Cycle stages were confirmed by means of rectal palpation, ultrasonography and plasma progesterone determination. Immunohistochemical evaluation of the formalin fixed biopsy specimens was performed using a peroxidase anti-peroxidase technique. Immunoglobulin (Ig)A-, IgM-, IgG(Fc)- and IgG(T)-containing cells were detected in all biopsies; with IgA- and IgG(Fc)-containing cells generally predominating. There was no cyclical trend of Ig-containing cell numbers for any isotype. Free immunoglobulins of the four classes evaluated were frequently seen in luminal epithelium, glandular epithelium and secretions, and interstitium. This study of endometrial biopsies from a limited number of cycling mares suggests the presence in the equine endometrium of free and intracellular immunoglobulins of the classes A, M, G(Fc) and G(T) without any apparent cyclical trend.

Uptake of immunoglobulins and other proteins from serum into epithelial cells of the mouse uterus and oviduct

The transport of immunoglobulins into the lumen of the female reproductive tract is not well understood, especially in the case of IgG. In mice, there are conflicting reports concerning the presence of immunoglobulins in uterine luminal and glandular epithelial cells, and immunoglobulins have not been detected in the luminal epithelial cells of the oviduct. In the present study we detected both IgA and IgG in uterine luminal and glandular epithelial cells on day 1 of pregnancy by immunolabeling. Also, we observed that fluorescein-conjugated mouse and bovine IgG and other proteins were taken up into vesicles in uterine luminal and glandular epithelial cells after intravenous administration. These observations indicate that both kinds of epithelial cells take up immunoglobulins from the interstitial fluid on day 1 of pregnancy, and that the cells may therefore be involved in the transport of immunoglobulins and other proteins to the uterine lumen at that time. In the oviduct, we detected IgA and IgG in vesicles in the luminal epithelial cells of the preampulla by immunolabeling, and we observed fluorescein-conjugated IgA and IgG in similar vesicles after intravenous administration. The presence of IgA and IgG in vesicles in the epithelial cells of the preampulla, together with the previous demonstration of plasma cells of both isotypes and large amounts of interstitial immunoglobulins in the lamina propria of this segment, suggests that the preampulla of the oviduct may be an important site for the local immune system in the mouse female genital tract.

Localization of immunoglobulins in the mouse uterus, embryo, and placenta during the second half of pregnancy

Throughout the second half of pregnancy in mice there were many plasma cells containing immunoglobulins A (IgA) and G (IgG) in the uterine endometrium. There was intense staining of IgA in uterine glands at all stages, but little staining of IgG. The staining of both immunoglobulins (Igs) in the luminal epithelium was moderate to dark on day 11, slight on day 14, and increased from day 16 to term. From day 14 to term the endometrium exhibited folds or villi around each placenta. The cores of the villi contained many plasma cells of both isotypes, and the staining of extracellular Igs in the villous cores was darker than in nonvillous endometrium. Both Igs were detected in the uterine lumen, and in visceral and parietal yolk sac endoderm cells at all stages. Near term, the staining of Igs in the visceral yolk sac was darkest in the peripheral villous portion adjacent to the endometrial villi. From day 14 to term IgG was present in the visceral yolk sac mesenchyme and embryo, consistent with its transfer from the uterine lumen to the embryo via the vitelline circulation. In contrast, IgA was not detected in yolk sac mesenchyme until day 19, when only slight staining was observed, and IgA was never detected in the embryo. Most trophoblast giant cells contained both Igs on day 11. During the remainder of pregnancy, there was staining of both Igs in labyrinthine trophoblast and in a few giant cells adjacent to the parietal yolk sac on the placenta, but there was negligible staining in the spongiotrophoblast region. Our observations suggest that the local immune system in the mouse uterus may protect the embryo during the second half of pregnancy by secreting anti-microbial immunoglobulins A and G into the uterine lumen surrounding the visceral yolk sac, and may at the same time contribute to the transfer of maternal IgG to the embryo via the yolk sac and vitelline circulation.

Secretory immunoglobulin binding to bacteria in the mouse uterus after mating

Bacteria of several species were present in the mouse uterus on the morning after mating, as demonstrated by bacterial cultures and microscopic examination of Gram-stained uterine luminal contents. The similarity between bacteria cultured from the vagina before mating and from the uterus after mating suggested that bacteria were introduced into the uterus from the vagina, possibly by coitus. The bacteria were cleared from the uterus about two days after mating. Immunohistochemical labeling of smears of the luminal contents on the morning after mating demonstrated IgA, IgG, and possibly IgM bound to many of the bacteria. The bacteria were often agglutinated, and there was a correlation between the intensity of immunoglobulin labeling on bacteria and the extent of agglutination. The amount of antibody bound to bacteria in multiparous mice was about the same as in mice that had not been mated previously. We observed both IgG and IgA on bacteria when organisms from vaginal cultures were incubated for 60 min in the uteri of estrogen-primed, virgin, female mice. This indicated that the uterus was the source of at least part of the immunoglobulins bound to bacteria. We did not demonstrate that the immunoglobulins bound to bacteria were specific anti-bacterial antibodies, but the binding persisted through three washing steps and there was no immunoglobulin binding to sperm in the same preparations. Neutrophils in the uterine lumen on the day after mating contained phagocytosed bacteria. These results suggest that the secretory immune system in the female mouse reproductive tract may play a role in returning the uterus to an aseptic state after mating by at least three mechanisms: direct blocking of attachment sites involved in bacterial binding to mucosal epithelium, agglutination of bacteria and thus reduction in the number of organisms available for binding to the epithelium, and opsonization of bacteria for phagocytosis by neutrophils.