Oral vitamin A supplementation of porcine epidemic diarrhea virus infected gilts enhances IgA and lactogenic immune protection of nursing piglets
Vitamin A (VA) has pleiotropic effects on the immune system and is critical for mucosal immune function and intestinal lymphocyte trafficking. We hypothesized that oral VA supplementation of porcine epidemic diarrhea virus (PEDV)-infected pregnant gilts would enhance the gut-mammary gland-secretory IgA axis to boost lactogenic immunity and passive protection of nursing piglets against PEDV challenge. Gilts received daily oral retinyl acetate (30 000 IU) starting at gestation day 76 throughout lactation. At 3–4 weeks pre-partum, VA-supplemented (PEDV + VA) and non-supplemented (PEDV) gilts were PEDV or mock inoculated (mock + VA and mock, respectively). PEDV + VA gilts had decreased mean PEDV RNA shedding titers and diarrhea scores. To determine if lactogenic immunity correlated with protection, all piglets were PEDV-challenged at 3–5 days post-partum. The survival rate of PEDV + VA litters was 74.2% compared with 55.9% in PEDV litters. Mock and mock + VA litter survival rates were 5.7% and 8.3%, respectively. PEDV + VA gilts had increased PEDV IgA antibody secreting cells and PEDV IgA antibodies in serum pre-partum and IgA+β7+ (gut homing) cells in milk post piglet challenge compared with PEDV gilts. Our findings suggest that oral VA supplementation may act as an adjuvant during pregnancy, enhancing maternal IgA and lactogenic immune protection in nursing piglets.
porcine epidemic diarrhea virus
antibody secreting cell
vitamin A deficient
mesenteric lymph node
immunoglobulin secreting cell
transmissible gastroenteritis virus
- RT qPCR
real-time quantitative polymerase chain reaction
tumor necrosis factor
transforming growth factor
geometric mean titer
Enzyme-Linked Immunosorbent Spot
Diarrheal disease represents a major global health burden and is the leading cause of morbidity and mortality in young humans and animals alike [1, 2]. In young animals, diarrheal disease accounts for an estimated multi-million dollar loss annually to the livestock industry due to mortality, reduced weight gain, treatment costs and trade sanctions on exporting animal products from infected countries [3, 4]. Passive lactogenic immunity that provides protective IgG in colostrum and a continuous supply of secretory IgA (sIgA) in milk plays a significant role in conferring protection against enteric pathogens in neonates . For example higher pathogen-specific IgA antibody (Ab) titers in milk are associated with lower incidence of enteric disease in pigs and children [6, 7, 8, 9]. Additionally, boosting the maternal immune response may have beneficial consequences for the mother, providing protection against disease during pregnancy and lactation. Enhancing immunity by maternal vaccination has the potential to provide a dual benefit in immune protection for the mother–neonatal dyad.
Porcine epidemic diarrhea virus (PEDV) is an alphacoronavirus that causes acute diarrhea, dehydration and 80–100% mortality in neonatal piglets [2, 10]. In adult pigs, PEDV causes watery diarrhea, depression and anorexia as well as agalactia and reduced reproductive performance [2, 11]. Due to the high virulence of PEDV and the naïve, immature immune system of neonatal piglets, passive lactogenic immunity to PEDV induced via the gut-mammary gland (MG)-sIgA axis during pregnancy and lactation remains the most promising and effective way to protect nursing piglets against PEDV-induced disease [8, 12, 13, 14, 15]. Providing sufficient PEDV-specific lactogenic immunity is dependent on trafficking of IgA antibody secreting cells (ASCs) from the intestine to the MG and accumulation of sIgA Abs in milk [7, 8, 13, 14, 16]. However, little is known regarding the anti-viral humoral immune response during pregnancy and the level of lactogenic immune protection generated after induction of the gut-MG-sIgA axis is variable. Indeed, our lab demonstrated that third trimester PEDV-infected gilts provided insufficient passive lactogenic immune protection to PEDV-challenged nursing piglets compared with second or first trimester PEDV-infected gilts . Therefore, identifying cost effective strategies to stimulate and enhance trafficking of PEDV IgA ASCs to the MG and accumulation of PEDV sIgA Abs in milk in a pregnant swine model is critical for development of maternal vaccines and therapeutics that improve maternal and lactogenic immunity and neonatal health.
Retinoic acid (RA) is a vitamin A (VA) metabolite with pleiotropic effects on the immune system [17, 18]. For example, VA deficient (VAD) individuals with serum retinol levels at 0.70 µmol/L or below are more susceptible to some enteric and respiratory diseases, with young children at the highest risk [19, 20]. Specifically, VA is required for the enhancement and regulation of immune responses and cellular trafficking in the gut. Lamina propria (LP) CD103+ dendritic cells (DCs) synthesize RA through expression of retinal dehydrogenases (i.e. Aldh1a1/2) . Synergistically with locally produced cytokines, CD103+ LP DCs upregulate mucosal trafficking adhesion molecules, integrin α4β7 and chemokine CC receptor (CCR)9 expression on B and T lymphocytes after interaction in the Peyer’s Patches or mesenteric lymph node (MLN) [22, 23, 24]. For example, VAD mice had significantly decreased α4β7+ memory T cells in lymphoid organs and T cells in the LP . Additionally, VAD alters cytokine responses during infection by skewing towards an increased T-helper cell type-1 (Th1) cytokine response in infants and mice [25, 26]. Treatment of T cells with 10 nM RA in vitro resulted in a shift toward Th2 cytokine responses  promoting an immunoregulatory environment. Therefore, even subclinical deficiencies in VA may negatively impact mucosal lymphocyte trafficking and gut homeostasis during pregnancy.
Also relevant to mucosal immune responses is the role of RA in B cell differentiation and IgA production. Using a gnotobiotic pig model, our lab demonstrated that subclinical VAD piglets had decreased frequencies of CD103+ LP DCs, resulting in decreased adaptive immune responses to human rotavirus (HRV) and prolonged diarrhea [27, 28]. VAD gnotobiotic piglets vaccinated with attenuated HRV demonstrated higher diarrhea severity post HRV challenge compared with vaccinated VA sufficient piglets. This coincided with lower serum IgA HRV Ab titers and significantly decreased intestinal IgA ASCs post-challenge suggesting a compromised anamnestic immune response [28, 29]. However, these parameters and the impact of VA supplementation during pregnancy on the gut-MG-sIgA axis and passive neonatal immunity are largely undefined. Therefore, we hypothesized that oral VA supplementation of PEDV-infected pregnant gilts would enhance trafficking of IgA ASCs from the gut to the MG leading to increased accumulation of sIgA Abs in milk and passive lactogenic protection of PEDV-challenged nursing piglets.
The risk of subclinical and clinical VAD increases with gestational age due to accelerated growth of the fetus and the physiological increase of blood volume in swine and humans [27, 30]. Dietary VA recommendations given for swine  are represented by physiologically-based mathematical models developed for relatively disease-free environments. Therefore, it is likely that the dietary VA required during pregnancy to efficiently stimulate the gut-MG-sIgA axis and provide sufficient lactogenic immune protection to neonates during an enteric viral infection is higher than current dietary recommendations. To investigate the impact of daily oral VA supplementation during gestation and lactation, we supplemented gilts with non-teratogenic, yet physiologically relevant levels of oral retinyl acetate [30 000 international units (IU)] daily starting at the beginning of the third trimester and lasting throughout lactation. We demonstrated that daily oral VA supplementation in PEDV-infected gilts decreased diarrhea, increased the numbers of PEDV IgA ASCs and PEDV IgA Abs in serum pre-partum and IgA immunoglobulin secreting cells (IgSCs) and IgA+β7+ cells in milk post piglet challenge, providing greater lactogenic immune protection to neonatal nursing piglets.
Materials and methods
The wild-type PC22A strain of PEDV was used for gilt infection and piglet challenge at a dose of 1 × 105 plaque forming units diluted in Minimal Essential Media [MEM (Life Technologies, Carlsbad, CA, USA)]. Briefly, PC22A was isolated and cultured in Vero cells as described previously [32, 33]. Cells were grown in growth medium containing Dulbecco’s Modified Eagle’s Medium [DMEM (Life Technologies, Carlsbad, CA, USA)] supplemented with 5% fetal bovine serum (Life Technologies, Carlsbad, CA, USA) and 1% antibiotic–antimycotic (Life Technologies, Carlsbad, CA, USA). Virus was grown in Vero cells in maintenance medium containing DMEM supplemented with 10 μg/mL trypsin (Life Technologies, Carlsbad, CA), 0.3% tryptose phosphate broth (Sigma Aldrich, St. Louis, MO, USA), and 1% antibiotic–antimycotic. Cells were kept in a humidified incubator at 37 °C and 5% CO2. PC22A was passaged three times in Vero cells before passaging once for generation of inoculum in a gnotobiotic pig. The virulence of pig passaged PC22A was confirmed in adult and neonatal pigs as described previously [13, 34, 35]. Cell-culture adapted PC22A was used as a positive control in the virus neutralization (VN) Ab assay.
Serum VA concentrations
Serum samples were collected as reported previously  and submitted to the Diagnostic Center for Population and Animal Health (Michigan State University, Lansing, MI, USA) for quantitative VA concentrations by HPLC.
PEDV RNA quantification by real-time quantitative polymerase chain reaction (RT-qPCR)
To determine PEDV RNA shedding titers, two rectal swabs were suspended in 4 mL MEM as described previously . Viral RNA was extracted from 50 μL of fecal supernatants following centrifugation (2000 × g for 30 min at 4 °C) using the MagMAX Viral RNA Isolation Kit (Applied Biosystems, Foster City, CA, USA) according to the manufacturer’s instructions. Titers of viral RNA shed in feces were determined by TaqMan RT-qPCR using the Onestep RT-PCR Kit (QIAGEN, Valencia, CA, USA) as described previously . The detection limit was 10 copies per 20 µL of reaction, corresponding to 4.8 log10 copies/mL of original fecal samples.
Isolation of MNCs from blood, spleen, MG, MLN and ileum
Blood, spleen, MG, MLN and ileum were collected aseptically at euthanasia and processed for MNC isolation as described previously [16, 39]. The isolated cells were resuspended in enriched RPMI [E-RPMI (Roswell Park Memorial Institute)] medium containing 8% fetal bovine serum, 2 mM l-glutamine, 1 mM sodium pyruvate, 0.1 mM nonessential amino acids, 20 mM HEPES (N-2-hydroxy-ethylpiperazine-N-2-ethanesulfonic acid), and 1% antibiotic–antimycotic (Life Technologies, Carlsbad, CA, USA) and used for assays. The viability of MNCs was determined by trypan blue exclusion. Briefly, MNCs were diluted twofold in 0.4% trypan blue before visualizing using an automated cell counter (Cellometer, Nexcelom, Lawrence, MA, USA). The viability (%) was calculated as [1.00 − (number of blue cells/number of total cells)] × 100.
Detection of cytokines in serum by ELISA
Serum samples from PEDV and PEDV + VA gilts were processed and analyzed for proinflammatory [tumor necrosis factor (TNF)-α, interleukin (IL)-6], innate [interferon (IFN)-α] and Th1 (IL-12, IFN-γ), Th2 (IL-4), Th17 (IL-22) and T regulatory/anti-inflammatory [IL-10 and transforming growth factor (TGF)-β] cytokines as described previously .
Colostrum/milk processing for whey and isolation of MNCs
Colostrum/milk was collected aseptically after gilts were given 2 cc oxytocin (VetOne, Boise, ID, USA) IM to facilitate collection of mammary secretions. Samples were filtered through a 70 μm pore filter and centrifuged at 1800 × g for 30 min at 4 °C to separate fat, skim milk and cell pellet portions. Fat was removed utilizing sterile plain-tipped applicators (Fisher Scientific, Hampton, NH, USA). Skim milk was collected and centrifuged at 28 000 × g for 1 h at 4 °C to separate the whey that was then stored at −20 °C until tested. Colostrum and milk MNCs were isolated as described previously . The viability of MNCs was determined by trypan blue exclusion.
PEDV plaque reduction VN assay
A plaque reduction VN assay was performed as described previously . Plaques were counted and the VN titers were determined by taking the reciprocal of the highest dilution of a serum/whey sample showing an 80% reduction in the number of plaques compared with seronegative control serum/whey. Samples negative at a dilution of 1:16 were assigned a titer of 1:2 for the calculation of geometric mean titers (GMTs).
PEDV whole virus Ab ELISA
A PEDV whole virus Ab ELISA was performed as described previously . The ELISA Ab titer was expressed as the reciprocal of the highest dilution that had a corrected A450 value (sample absorbance in the virus-coated well minus sample absorbance in the mock antigen-coated well) greater than the cut-off value (mean corrected A450 value of negative controls plus 3 standard deviations). Samples negative at a dilution of 1:4 were assigned a titer of 1:2 for the calculation of GMTs.
Total and PEDV Enzyme-Linked Immunosorbent Spot (ELISPOT)
Histologic analysis and evaluation of PEDV Ab+ cells in the MG
PEDV Ab+ cells in the MG were analyzed as described previously . Microscopic images (300× magnification) were obtained using a fluorescence microscope (Olympus IX70-S1F2). Mean numbers of PEDV Ab+ cells were evaluated by measuring at least 3–6 different tissue areas at 300× magnification for each sample time point (GD 104–114 and PCD 5–9) from mock, mock + VA, PEDV and PEDV + VA gilts.
Flow cytometry to assess B/T lymphocytes and homing marker integrin and receptor frequencies
Procedures for flow cytometry staining (including buffers used) were performed as described previously with minor modifications [16, 27]. Briefly, 100 μL of MNCs at 1 × 107 cells/mL were stained with anti-porcine CD21-PE (clone BB6-11C9.6, Southern Biotech, 1:50) and anti-porcine CD2 (clone MSA4, VMRD, 1:50) monoclonal Abs to determine B cell subsets . To determine expression of α4 integrin and β7 integrin, cells were stained with porcine cross-reactive anti-human α4 integrin (clone HP2/1, Abcam, Cambridge, MA, 1:100) and anti-mouse β7 integrin (clone FIB27, BD Biosciences, 1:50) monoclonal Abs. Additionally, to determine expression of IgA, cells were stained with anti-porcine IgA (clone K61 1B4, Bio-Rad, 1:50) monoclonal Ab. After washing, cells were stained with appropriate secondary antibodies. For intracellular CD79β, stained cells were permeabilized with Cytofix/Cytoperm (BD Biosciences), washed with Perm/Wash Buffer (BD Biosciences) and stained with porcine cross-reactive anti-mouse CD79β-FITC Ab (clone AT1072, Bio-Rad, 1:50) monoclonal Ab. Additionally, CD4+ (anti-porcine CD4, clone 74-12-4, Southern Biotech, 1:50) and CD8+ (anti-porcine CD8, clone 76-2-11, Southern Biotech, 1:50) T cells were assessed within the CD3+ (anti-porcine CD3, clone PPT3, Southern Biotech, 1:100) MNC population (T lymphocytes). Appropriate isotype matched control Abs were included. Acquisition of 50 000 events and analyses were done using the Accuri C6 flow cytometer (BD Biosciences, San Jose, CA, USA). All cells were first gated for singlets (FSC-H vs. FSC-A) and MNCs (SSC-A vs. FSC-A). To determine B cell subsets, MNC populations were analyzed by CD79β expression. α4+β7+ and IgA+β7+ MNCs were determined within the CD79β+ population as described previously .
Two-way analysis of variance (ANOVA-general linear model), followed by Bonferroni’s post-test, was used to compare serum VA concentrations, PEDV RNA shedding titers, fecal consistency scores, mean concentrations of serum cytokines, frequencies of blood MNC populations in flow cytometry, PEDV IgA and IgG ASCs, log-transformed PEDV IgA, IgG and VN Ab titers, normalized weights and PEDV Ab+ cells in the MG. The frequencies of cell populations and PEDV IgA and IgG ASCs in milk and ileum were compared among groups with the Mann–Whitney (nonparametric) t test. The log-rank (Mantel-Cox) test was used for comparison of survival curves amongst treatment groups. Statistical significance was assessed at P ≤ 0.05 for all comparisons. Assays were run by investigators blinded to sample and treatment identification prior to analysis. All statistical analyses and random number generation for treatment randomization were performed with GraphPad Prism 5 (GraphPad Software, Inc., CA, USA).
Serum VA concentrations decreased in gilts regardless of treatment, immediately prior to parturition
Oral VA supplementation in third trimester gilts did not significantly alter mean serum VA concentrations. However, when gilts (± VA) were pooled, there was a trend for decreased mean serum VA concentrations immediately prior to parturition (Figure 1C).
PEDV RNA shedding titers and PEDV-induced diarrhea were lower in PEDV + VA gilts
Oral VA supplementation modulated cytokine immune parameters during PEDV infection
There was a trend for higher IFN-α and IFN-γ, type I and II interferons, respectively, at PID 13–17 in PEDV but not PEDV + VA gilts while immunoregulatory cytokine IL-10 increased numerically at PID 6–8 in PEDV + VA compared with PEDV gilts (Additional file 1). Additionally, there was a trend for increased mean concentrations of IL-22, a cytokine that promotes tissue regeneration and repair in the gut  at PID 6–8 in PEDV + VA compared with PEDV gilts (Additional file 1). No other trends were observed for serum concentrations of TNF-α, IL-6, IL-12, IL-4 or TGF-β (Additional file 1).
Oral VA significantly increased pre-partum levels of circulating PEDV IgA ASCs and Abs and IgA+β7+ MNCs
PEDV + VA litters had decreased mortality and morbidity
Oral VA supplementation increased milk PEDV IgA ASCs, total IgA IgSCs, and IgA+β7+ cells post piglet challenge
PEDV Ab+ cells in the MG increased post piglet PEDV challenge
PEDV exposure post piglet challenge affected circulating ASC and Ab responses in gilts and piglets
IgA and IgG ASCs and ileal α4+β7+ B cells were increased in PEDV + VA gilts at PCD 21–29
To our knowledge, this is the first study to evaluate the effect of VA supplementation on maternal and lactogenic immunity during an enteric viral infection in swine. Vitamin A is a critical mediator of mucosal immune function and is essential for lymphocyte trafficking in the gut. For example, VAD leads to increased susceptibility to bacterial and viral pathogens and VA supplementation alleviates the negative effects of certain infectious diseases [18, 27, 29, 43]. This is particularly relevant during pregnancy and the neonatal period when there is greater risk for clinical and subclinical VAD [44, 45]. To investigate the impact of VA on maternal and lactogenic immunity, we supplemented third trimester PEDV-infected gilts with oral retinyl acetate beginning at GD 76 and throughout lactation. We demonstrated that VA supplementation of PEDV-infected gilts decreased fecal consistency scores in third trimester gilts. Also, PEDV IgA ASCs and Abs, IgA IgSCs and IgA+β7+ B cells in blood and/or milk were greater in PEDV + VA gilts coinciding with greater mean survival rates in PEDV-challenged nursing piglets. Our findings suggest that daily oral VA supplementation during pregnancy may act as a mucosal adjuvant, enhancing maternal IgA and lactogenic immunity during PEDV infection.
Currently, VA recommendations in swine are 4000 IU/kg of feed (~7250 IU/day) during gestation and 2000 IU/kg of feed (fed ad libitum) during lactation . However, these recommendations were developed assuming disease-free environments. Considering serum VA concentrations in swine decrease with increasing gestation  and parity (A.N. Vlasova and L.J. Saif, unpublished observations), it is likely that dietary VA recommendations for gestating gilts and sows are suboptimal during viral or bacterial infections. Due to the limited available studies on vitamin A supplementation in pregnant swine, we relied on literature from other species to inform our dose decision. Females of child-bearing age on a vitamin A-poor diet given a single oral dose of 30 000 IU retinyl palmitate produced a dose-related and sustained increase in plasma retinyl esters and retinoic acids . Additionally, supplementing pregnant women with an oral dose of 10 000 IU/day of vitamin A resulted in enhanced prenatal H1N1-vaccine responses in mothers . Therefore, if viral infection during swine pregnancy results in subclinical vitamin A deficiency, we reasoned that 30 000 IU would be an appropriate dose to elicit a physiological and immunological response. Additionally, based on nonhuman primate data, an oral dose of 30 000 IU retinoic acid is non-teratogenic . Indeed, the presumed upper safe level of dietary VA is up to ten times the nutritional requirements in swine . In in a previous study, harmful effects of VA toxicity were only observed in swine when more than 100 times the nutritional requirement was given over an extended period of time [31, 49]. Therefore, we reasoned that daily oral VA supplementation of 30 000 IU starting in the third trimester and lasting throughout lactation was unlikely to cause harmful effects. Indeed, no signs of hypervitaminosis A  were observed in gilts or piglets.
Serum retinol concentrations are homeostatically controlled over a range of adequate liver stores ; therefore it is not surprising that in our study, oral VA supplementation did not change serum retinol concentrations in gilts. Additionally, the rate of intestinal VA metabolism after oral supplementation contributes to the systemic exposure to VA metabolites . For example, in feed-restricted lactating sows fed 35 µmol of 3,4-didehydroretinyl acetate (vitamin A2), serum 3,4-didehydroretinyl ester concentrations peaked 3 h post-prandial and returned to near baseline levels by 24 h . If there were a transient increase in serum VA concentrations, it is unlikely that we would detect it as blood was collected from gilts immediately prior to VA supplementation at 0900 h. Similar to previous findings in swine and humans [27, 30], our study demonstrated decreased mean serum retinol concentrations immediately prior to parturition. This coincides at a time when chemokine CCR9 and CCR10 secretion and α4β7+ expression and their cognate receptors increase in the MG to recruit circulating ASCs into colostrum and milk [54, 55]. These results highlight the importance of understanding the role of VA during pregnancy and its potential effects on maternal immunity and the gut-MG-sIgA during an enteric viral infection.
We observed a lower and faster decline in mean peak PEDV RNA shedding titers and significantly decreased fecal consistency scores at PID 3 and 5 in PEDV + VA compared with PEDV gilts. This suggests that oral VA supplementation may enhance innate immune protection against PEDV in third trimester gilts. For example, previous studies of rats  and mice  reported decreased NK cell frequency and function during VAD and supplementation of β-carotene (a VA precursor) in vivo and in vitro increased NK cell cytotoxic activity . This is in agreement with previous work in our lab demonstrating an association between increased NK cell frequencies in blood and decreased clinical signs in PEDV-challenged piglets . PEDV infection is associated with local and systemic inflammation and increased concentrations of serum innate and proinflammatory cytokines [58, 59]. Indeed, protection against PEDV-induced disease was associated with a delay in serum proinflammatory cytokines post PEDV challenge in piglets . Our findings demonstrate a trend whereby PEDV + VA gilts had numerically reduced mean proinflammatory cytokines and increased immunoregulatory and tissue repair cytokines IL-10 and IL-22, respectively, coinciding with significantly decreased diarrhea scores compared with PEDV gilts. These responses may aide in establishment of gut homeostasis, thereby reducing the severity of PEDV infection in third trimester gilts.
Oral VA supplementation significantly increased pre-partum levels of circulating PEDV IgA ASCs, IgA+β7+ MNCs and PEDV IgA Abs post PEDV infection. For example, the significant increase in circulating PEDV IgA Abs and ASCs at PID 6–8 and 13–17, respectively, coinciding with significantly increased normalized IgA+β7+ cells in PEDV + VA gilts, suggests that oral VA supplementation increased migration of PEDV stimulated B cells from the intestine into the circulation post PEDV infection. Indeed, trafficking IgA ASCs predominate in the lymphoid tissues of the gut  and migrate into the circulation after intestinal infection . This is in agreement with previous studies from our lab demonstrating an IgA ASC dominant response after intestinal TGEV [61, 62], PEDV  and RV  infection in swine. Our lab also previously demonstrated that VA status influences anti-viral B cell immunity. For example, HRV-vaccinated VA sufficient piglets had increased HRV specific IgA ASCs and Abs in the duodenum post HRV challenge compared with vaccinated VAD piglets . Furthermore, mucosal associated adhesion receptors are imprinted on immune cells responding to tissue-specific immune interactions . For example, α4β7 integrin expression on intestinal lymphocytes increases after interaction with VA synthesizing DCs in intestinal Peyer’s patches, promoting cellular migration in the gut mucosa and lymphoid tissue . In our study, mean frequencies of α4+β7+ B cells (normalized to PID 0) increased numerically in PEDV (± VA) gilts at PID 6–8 and 13–17 and mean frequencies of IgA+β7+ B cells were significantly higher at PID 13–17 in PEDV + VA compared with mock and PEDV gilts. This suggests that VA supplementation may influence migration of IgA+ cells after PEDV infection.
In our study, PEDV-challenged litters of PEDV + VA gilts had a higher survival rate, significantly decreased PEDV RNA shedding titers at PCD 2 and a trend for lower mean fecal consistency scores at PCD 7–15. The increased survival rates in PEDV + VA litters coincided with higher frequencies of circulating α4+β7+ B cells at PID 6–8 (normalized to PID 0) in gilts and IgA IgSC in milk at PPD 8–14 (PCD 5–9). These results are in agreement with previous work in our lab demonstrating that increased lactogenic immune protection in PEDV nursing piglets correlated with PEDV IgA ASCs and Abs in milk . Additionally, in TGEV-infected sows, high rates of protection are associated with high titers of IgA Abs in colostrum and milk [8, 12, 64, 65, 66]. Similar findings were also reported in mice where supplementation of β-carotene (a proVA metabolite) during pregnancy and lactation increased IgA IgSC in the MG during lactation [67, 68]. The significant differences in milk PEDV IgA ASCs and total IgA IgSCs in PEDV + VA gilts were limited to post piglet PEDV challenge time points, suggesting a role for VA in enhancing anamnestic lactogenic immune responses. Future studies investigating the role of VA in milk and MG memory B cell function in swine are warranted.
While there were no differences in gilt serum immune responses between PEDV + VA and PEDV gilts post-partum, PEDV (± VA) gilt IgA ASCs and IgA and VN Abs increased to higher levels and at a faster rate compared with mock (± VA) gilts, suggesting an anamnestic response in PEDV-infected gilts after reexposure to PEDV and the naïve status of mock gilts at the time of piglet PEDV challenge. Lastly, gilt MG, spleen, MLN and ileum tissues were analyzed for PEDV IgA and IgG ASCs at PCD 21–29. Due to the high PEDV RNA shedding titers in the feces of mock litters, mock gilts had greater exposure to PEDV than PEDV (± VA) infected gilts during both primary (pre-partum) or secondary exposure (post piglet challenge). Therefore, the numbers of mean IgA ASCs in the spleen, MLN and ileum and IgG ASCs in the spleen and ileum were higher at PCD 21–29 in mock (± VA) compared with PEDV (± VA) gilts. Interestingly, however, VA supplemented gilts in both mock and PEDV groups had significantly higher mean PEDV IgA ASCs in the ileum compared with their respective nonsupplemented counterparts. Additionally, while not significant, mean frequencies of α4+β7+ B cells in ileum were higher in PEDV + VA compared with PEDV gilts. These data suggest that VA supplementation had an effect on local IgA immunity as demonstrated previously [24, 69] regardless of past PEDV exposure, potentiating the levels of trafficking IgA ASCs in serum and the MG. Considering that trafficking of IgA+ plasmablasts to the MG is dependent on CCR10  and that RA influences CCR9 and α4β7+-dependent B cell homing in the intestine [23, 24], future investigation of these molecules and their cognate receptor expression and function in VAD models of swine pregnancy is warranted.
While there are indications that VA regulates maternal Ab responses to mucosal pathogens during pregnancy, its potential applications to promote the health of neonates remains unexplored. Using a pregnant swine model, our data demonstrate that VA supplementation in third trimester PEDV-infected gilts have a dual benefit to mother and neonate. VA supplementation resulted in less severe diarrhea and lower PEDV RNA shedding titers in pregnant gilts suggesting that VA supplementation promotes homeostasis and immune regulation in the gut post PEDV infection. Additionally, VA supplemented gilts had increased anti-PEDV IgA immunity in blood, milk and ileum. This was associated with increased survival rates in PEDV + VA litters post PEDV challenge. Based on our innovative approach and results demonstrating that VA enhanced intestinal immunity during pregnancy and lactogenic immune protection in nursing piglets, future studies are warranted to better understand the mechanisms involved. This model is applicable to endemic and emerging enteric viral diseases in humans and animals, as similar maternal vaccination and VA supplementation strategies may be needed to enhance the gut-MG-sIgA axis and neonatal protection.
The authors thank Dr Qiuhong Wang for providing the wild-type PC22A strain of PEDV, Marcia Lee and Drs. Ayako Miyazaki and Sayaka Takanashi for their technical assistance, Dr Juliette Hanson for surgical and veterinary clinical assistance, Dennis Hartzler, Sara Tallmadge, Megan Strother, Ronna Wood and Jeffrey Ogg for animal care and assistance, and Drs. Prosper Boyaka and Qiuhong Wang for their critical review of the manuscript. This work was supported by USDA NADC ARS Grant #60054098, AFRI NIFA Fellows Program/USDA National Institute of Food and Agriculture Grant #60046830, NIH NICHD Grant R01 HD095881 and federal and state funds appropriated to the Ohio Agricultural Research and Development Center, The Ohio State University. Linda J. Saif is the senior corresponding author.
LJS, KML and SNL contributed conception and design of the study; SNL conducted the experiments, analyzed the data and wrote the manuscript; LJS, ANV supervised the work and contributed critical analysis to the results; FCP and MAA assisted with daily animal work, collected and processed samples and conducted RT-qPCR experiments and analysis; MAA and SNL conducted IHC experiments and analysis. All authors read and approved the final manuscript.
Ethics approval and consent to participate
All animal experiments were approved by the Institutional Animal Care and Use Committee at The Ohio State University. All methods were carried out in accordance with approved protocol and relevant regulations. All pigs were maintained, sampled, and euthanized humanely.
The authors declare that they have no competing interests.
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