Enteroids: promising in vitro models for studies of intestinal physiology

The lack of sophisticated in vitro models limits our current understanding of gastrointestinal functions in farm animals. Conventional 2D cell lines o...
2 downloads 0 Views 738KB Size
Subscriber access provided by MIDWESTERN UNIVERSITY

Review

Enteroids: promising in vitro models for studies of intestinal physiology and nutrition in farm animals Yuebang Yin, Songge Guo, Dan Wan, Xin Wu, and Yulong Yin J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b06908 • Publication Date (Web): 11 Feb 2019 Downloaded from http://pubs.acs.org on February 12, 2019

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 40

Journal of Agricultural and Food Chemistry

1

Enteroids: promising in vitro models for studies of intestinal

2

physiology and nutrition in farm animals

3 4

Yue-Bang Yin†,‡, Song-Ge Guo†,ǂ, Dan Wan†, Xin Wu†*, Yu-Long Yin†

5 6

† Key Laboratory of Agro-ecological Processes in Subtropical Region, Institute of

7

Subtropical Agriculture, Chinese Academy of Sciences; Hunan Provincial

8

Engineering Research Center for Healthy Livestock and Poultry Production;

9

Scientific Observing and Experimental Station of Animal Nutrition and Feed

10

Science in South-Central, Ministry of Agriculture; Hunan Provincial Key

11

Laboratory of Animal Nutritional Physiology and Metabolic Process, Changsha,

12

Hunan, 410125, China.

13 14 15 16

‡ Department of Gastroenterology and Hepatology, Erasmus MC University Medical Center, Rotterdam, The Netherlands ǂ College of bioscience and biotechnology, Hunan Agricultural University, Changsha, Hunan, 410128, China

17 18

Correspondence to:

19

*[email protected] (X.W.); Institute of Subtropical Agriculture, Chinese Academy of

20

Sciences, Changsha, 410125, China.

21 22

Word count: Abstract, 151 words; Text, 4276 words.

1

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 2 of 40

23

Running title: Enteroids for studies of farm animals

24

Keywords: Enteroid, Intestinal studies, Livestock, Veterinary sciences, Animal

25

nutrition, Farm animals

26

Abbreviations:

27

GI: Gastrointestinal; 2D: 2 dimensional; FABPs: Fatty acid-binding proteins; IP:

28

Intestinal peptidase; LGR5+: Leucine-rich repeat-containing G-protein coupled

29

receptor 5 positive; ISCs: Intestinal stem cells; EGF: Epidermal growth factor;

30

HuNoVs: Human noroviruses; ISEMF: Intestinal subepithelial myofibroblasts; GSK3i:

31

Glycogen synthase kinase 3 inhibitor; LPS: Lipopolysaccharides; TLR4: Toll-like

32

receptor 4; TLRs: Toll-like receptors; MAP: Mitogen-activated protein.

2

ACS Paragon Plus Environment

Page 3 of 40

Journal of Agricultural and Food Chemistry

34

ABSTRACT

35

The lack of sophisticated in vitro models limits our current understanding of

36

gastrointestinal functions in farm animals. Conventional 2D cell lines or primary cells

37

fail to recapitulate the physiology of in vivo intestinal epithelium. In contrast stem

38

cell-derived, non-transformed 3D enteroids partially recreate the villus-crypt anatomy

39

of the native intestine and comprise most if not all intestinal cell types including

40

enterocytes, enteroendocrine cells, goblet cells, Paneth cells and stem cells. This

41

review summarizes the techniques used for generating and culturing enteroids of

42

various farm animal species, focuses on important factors influencing the longevity of

43

enteroids, and provides an overview of their current applications in modeling

44

veterinary pathogens and in developing chemicals and bioactives for treating animal

45

disease and improving production performance. It also mentions current limitations of

46

enteroid models and potential solutions, and highlights the opportunities for using

47

these enteroids as a platform in studies regarding veterinary sciences and animal

48

nutrition.

49

3

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

51

Page 4 of 40

INTRODUCTION

52

The gastrointestinal (GI) tract is the predominant site for exposure of the body to

53

a variety of food, nutrients, drugs and metabolites, toxins and bacteria (1), and thus GI

54

homeostasis is crucial for maintaining health of animals. Within the GI tract, the

55

intestinal epithelium contains a variety of cell types including enterocytes,

56

enteroendocrine cells, enterochromaffin cells, Paneth cells, goblet cells, and intestinal

57

stem cells (2, 3). This complex structure allows the intestinal epithelium to carry out

58

multiple functions, including nutrient and electrolyte absorption, metabolism,

59

electrolyte and hormone secretion, pathogen-host interaction, and innate immunity.

60

To study such functions in vitro, many different 2-dimensional (2D) cultures of

61

intestinal tumor-based cell lines or immortalized epithelial cells have been developed

62

(4). However several shortcomings of the tumor-based cell lines or immortalized

63

epithelial cells have limited their application: for instance, they only contain a single

64

cell type, lack the complexity and physiology of native epithelium, and often

65

accumulate mutations (5). Freshly isolated primary cells and explanted intestinal

66

tissues are thought to mimic in vivo physiology more accurately, but they cannot be

67

maintained in culture for a long term, which limits their application in developmental,

68

physiological and regenerative studies (1). Hence, there is an urgent need for the

69

development of more suitable in vitro models.

70

In 2009, Dr. Toshiro Sato and Dr. Hans Clevers firstly reported the culturing of

71

an in vitro 3D-intestinal model from single intestinal stem cells, which was named

72

intestinal organoid, enteroid, or mini-gut (6). The enteroids in part recapitulate the

4

ACS Paragon Plus Environment

Page 5 of 40

Journal of Agricultural and Food Chemistry

73

intestinal villus-crypt anatomy, and harbour most if not all of the various intestinal

74

cell types, a major advantage in comparison with single cell type-based cell lines (6).

75

Following a fast growing number of studies use enteroids as in vitro models in various

76

fields, including virology (7-9), bacteriology (10), oncology (11), and pharmacology

77

(12). Importantly, because enteroids derived from a single animal can be expanded for

78

multiple passages and at an almost unlimited scale, the introduction of this new

79

intestinal model has strongly reduced the number of experimental animals sacrificed

80

for intestinal studies, with positive ethical implications (1).

81

A proper health and homeostasis of the GI tract is of prime importance for the

82

technical performance of farm animals. However, until shortly a lack of reliable in

83

vitro experimental models hampered the understanding of molecular mechanisms

84

involved in nutrition, physiology, and pathogen-host interactions of farm animals.

85

Two-D cultures of cell lines have been used frequently in studies of pig intestine, such

86

as the porcine intestinal epithelial cell lines SD-PJEC (13) and IPEC-J2 (14).

87

However, to the best of our knowledge, very few studies using intestinal epithelial

88

cell lines of poultry, cattle, and other farm animals have been reported. Intestinal

89

primary cells are frequently exploited as a model in livestock studies, but the culturing

90

process is often complicated, and the failure to achieve long-term passaging is a major

91

hurdle (15). Therefore culturing enteroids from farm animals, though technically in its

92

infancy, may offer an attractive alternative, considering the mature state of the

93

technique pioneered for human and mouse enteroids. Indeed, a rapidly expanding list

94

of studies have recognized the importance of enteroids in livestock studies, and

5

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 6 of 40

95

enteroids of pigs (16-20), chicken (3, 19, 21), cows (4, 16, 19), sheep (19), and horses

96

(19) have been successfully cultured. In this review we will discuss the current in

97

vitro intestinal epithelial models used in livestock studies, and highlight the

98

importance and potential applications of enteroids in the livestock field.

99 100

CURRENT IN VITRO INTESTINAL EPITHELIAL MODELS

101

DEVELOPED FOR LIVESTOCK STUDIES

102 103

The IPEC-J2 cell line consists of non-transformed intestinal epithelial cells,

104

cultured originally from the jejunal epithelium of a newborn piglet. The model has

105

been broadly used in studies of animal nutrition and in veterinary applications. The

106

cell line was developed by Dr Helen Berschneider at the North Carolina State

107

University in 1989 (22). As a nontumorigenic cell line, IPEC-J2 is better able to

108

mimic in vivo physiology than many other tumor-based cell lines (14). In livestock

109

studies, IPEC-J2 has been used in a variety of studies including the effects of nutrients

110

on intestinal function (23-25), bioactives (26, 27), probiotics (28), nutrient-pathogen

111

interaction (29), barrier and transport (30, 31), cellular signaling (32), toxicity and

112

viability (33, 34), and veterinary medicine (35), etc (Table 2). However, IPEC-J2 has

113

turned out to lack brush border enzyme activity and the expression of genes

114

controlling major gel-forming mucin (i.e. Muc2) (14). A subclone of the IPEC-J2

115

cells, named SD-PJEC was developed by Sun and colleagues (13), and has been used

116

to investigate infections of swine influenza virus (13, 36). Recently, Kaiser et al

6

ACS Paragon Plus Environment

Page 7 of 40

Journal of Agricultural and Food Chemistry

117

established a primary intestinal epithelial cell model based on the primary crypt cells

118

of specific-pathogen-free layer-type chickens, which showed the characteristics of in

119

vivo epithelial cells, and was thought to be a suitable model for probing pathogen-host

120

interactions (37). However, this model fails to regenerate (37), thus limits its

121

application in biological studies. Primary bovine intestinal epithelial cells were

122

successfully cultured from different intestinal sections of Chinese Holstein cows,

123

which recapitulated prime features of in vivo bovine intestine including the expression

124

of fatty acid-binding proteins (FABPs), villin, and intestinal peptidase (IP), while the

125

cells showed signs of senescence after 5 passages (15). Ovine intestinal carcinoma

126

(ST6) cell lines were used to model infection of jaagsiekte sheep retrovirus that cause

127

pulmonary adenomatosis in sheep (38). Human colorectal cancer lines including

128

Caco-2 and HT29 cells are also used as a model in many livestock studies (39).

129

However these human cell models are hampered by the same limitations as exist for

130

animal cell lines. In conclusion, considering the inherent shortcomings of 2D cell

131

lines and a lack of reliable in vitro models for many livestock species, more suitable

132

in vitro models for GI tract studies of farm animals are desperately needed.

133 134

BRIEF INTRODUCTION OF ENTEROIDS

135

The long term culture of primary intestinal epithelial cells as enteroids have

136

become feasible only following the discovery of Leucine-rich repeat-containing

137

G-protein coupled receptor 5 positive (LGR5+) as a true marker of adult intestinal

138

stem cells (ISCs) residing at the bottom of intestinal crypts, and the identification of a

7

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 8 of 40

139

broad collection of growth factors needed for stem cell proliferation and preventing

140

anoikis (40). These growth factors allow ISCs to grow and expand permanently in the

141

absence of a tumorogenic mutation (40). Enteroids were successfully cultured first

142

from mouse (6) and human intestine (41). The key signaling pathways involved in

143

enteroid growth are the Wnt/β-catenin, EGF/Ras/Raf/MEK/ERK, Notch, and bone

144

morphogenetic protein (BMP) pathway (42). Wnt signaling plays a key role in

145

maintaining stemness and self-renewal ability of ISCs, which is through to engage the

146

cognate Frizzled receptors serving to stabilize β-catenin and thus to activate

147

downstream target genes supporting stemness (42). Epidermal growth factor (EGF)

148

binds to its receptor EGFR, to activate Ras/Raf/MEK/ERK axis to regulate mitosis of

149

ISCs (42). EGF is also capable of activating the PI3K/Akt and ErbB pathway

150

involved in regulating proliferation (1). The Notch pathway is crucial for supporting

151

the multipotency and proliferation of stem cells and maintaining the secretory

152

differentiation (43). BMP is mainly active in the villus domain of intestinal epithelium,

153

and exerts the promotion of spatially arranged differentiation of ISCs, and inhibitory

154

effects on the β-catenin activity, thus playing an important role as a regulator of the

155

number of ISCs in crypts (43). Suppressing the BMP pathway is therefore beneficial

156

for the stemness of ISCs. Based on the machinery of regulating ISCs, supplements of

157

key factors are required for enteroid growth, including Wnt3a, EGF, R-spondin1

158

(agonist of WNT signaling), and Noggin (inhibitor of BMP protein). Other elements

159

involved in the stemness machinery are also of benefit for enteroid growth including

160

B27 and N2 supplement, CHIR99021 (agonist of WNT signaling), N-acetylcysteine,

8

ACS Paragon Plus Environment

Page 9 of 40

Journal of Agricultural and Food Chemistry

161

nicotinamide (inhibitor of sirtuins), A83-01 (TGF-β receptor 1 inhibitor), and

162

Y-27632 (Rock inhibitor) (1, 6, 41).

163

Enteroids have several clear advantages in comparison with cell lines (Table 1).

164

They are cultured from intestinal stem cells, generate villus-crypt structures, and

165

spontaneously differentiate into multiple cell lineages, including enterocytes,

166

enteroendocrine cells, Paneth cells, goblet cells and tuft cells, thus they exquisitely

167

resemble their organ of origin in architecture and function (6, 42). In contrast cell

168

lines are often tumor-based, immortalized and contain a single cell type, thus failing

169

to resemble the complicated structure and mutual interactions of distinct cell types in

170

the native epithelium. Enteroids can be passaged for multiple generations without

171

genomic mutation (44), while cell lines do more readily acquire genomic mutations

172

after repeated passaging (45). Thus the enteroid model appears to circumvent the

173

inherent drawbacks of 2D cells. In humans, several studies have demonstrated that

174

results obtained using enteroid models more closely reflect in vivo results compared

175

with outcomes obtained in intestinal cell lines. For example, Yin and colleagues

176

demonstrated that a broadly used antiviral agent, interferon ɑ (IFNɑ), was less

177

effective against rotavirus infection in human enteroids than in Caco2 cells, which

178

was consistent with observations in the clinic (7). Another example is that human

179

noroviruses (HuNoVs) are confirmed to have tropism for tuft cells (CD300lf receptor)

180

in mice (46), whilst HuNoVs are demonstrated to have tropism for enterocytes in

181

human enteroids (47). Most recently, de Winter-de Groot et al isolated enteroids from

182

34 infants diagnosed with cystic fibrosis (CF), and used confocal microscopical

9

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 10 of 40

183

measurements of forskolin-induced swelling (FIS) to assess the residual activity of

184

mutated CFTR chloride channels in the CF enteroids. They found that enteroid based

185

FIS showed a strong correlation with clinical outcome parameters and biomarkers of

186

CF at the individual level, including sweat chloride concentration (SCC) and intestinal

187

current measurement (ICM), thereby confirming the ability of enteroids to mimic in

188

vivo physiology (48). In summary these studies clearly indicate that enteroids function

189

as a more advanced in vitro model in comparison with cell line models.

190 191

ENTEROIDS CULTURED FROM FARM ANIMALS

192 193

Enteric disease and homeostasis play important roles in the technical

194

performance of farm animals. Since 2D cell line models and primary cell isolation

195

approaches are not available for many of the species, the enteroid technique offers an

196

attractive alternative for recreating intestinal epithelium in vitro. Currently enteroids

197

have been successfully cultured from pig, chicken, bovine, horse, and sheep intestine

198

(Table 3). These enteroids may provide a promising new platform in animal science

199

and veterinary studies.

200 201

Porcine enteroids. The successful isolation of porcine enteroids was reported first by

202

Gonzalez et al, who applied a minor modification of the culture protocol for mouse

203

and human enteroids in which they used purified recombinant Noggin, R-Spondin1,

204

and Wnt3a to replace conditioned media of these factors (17). Porcine enteroids

10

ACS Paragon Plus Environment

Page 11 of 40

Journal of Agricultural and Food Chemistry

205

exhibited clear budding (indicating crypt-like structure) and contained distinct

206

intestinal cell types including enteroendocrine cells, absorptive enterocytes, goblet

207

cells, and stem/progenitor cells (17). They were able to polarize and to form

208

well-defined tight junctions (17). Porcine enteroids were also amenable for

209

transduction by lentiviruses (18), offering a robust tool for in vitro studies. Enteroids

210

cultured with this technique could be passaged at least 8 times for a total of 4.5

211

months (17). In two other studies, porcine enteroids were cultured with supplements

212

of purified EGF, Noggin, and R-spondin1 (ENR medium), together with Wnt3a- or

213

intestinal subepithelial myofibroblasts (ISEMF)-conditioned medium, and in the

214

presence of glycogen synthase kinase 3 inhibitor (GSK3i) (18, 49). These enteroids

215

could be passaged up to 10 times, but after this stage growth retardation occurred and

216

further passaging was not feasible (18). However, porcine enteroids could be

217

successfully passaged up to 49 times by supplementation of Wnt3a, R-Spondin1 and

218

Noggin conditioned media (19). Van der Hee et al used conditioned media of

219

recombinant Noggin (15% v/v), R-spondin1 (15% v/v), and Wnt3A (30% v/v) to

220

culture porcine enteroids, which could be maintained for at least several months (11).

221

A recent study indicated that porcine enteroids could be kept viable for up to 13

222

passages (3 months) using a commercial culture medium named IntestiCult (Stem

223

Cell Technologies) (16), however the composition of this medium is not specified in

224

detail. Together, it is plausible that Wnt3a, R-Spondin1 and Noggin conditioned

225

medium perform better for growth of porcine enteroids than purified recombinant

226

surrogates.

11

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 12 of 40

227

One practical limitation of the use of 3D enteroids is the orientation of their

228

apical border facing the organoid lumen, implying that food components,

229

microorganisms, chemicals, drugs, bioactive and toxic compounds added to the

230

medium are poorly exposed to the luminal side of the organoids (44).This is of

231

relevance because apical and basolateral membranes of intestinal epithelial cells have

232

different expression level for numerous receptors such as Toll-like receptors (TLRs)

233

and cytokine receptors (20). Though microinjection is able to deliver substances into

234

the lumen of a single enteroid (50), the heterogeneity in enteroid size, difficulties of

235

synchronous exposure and variability in injected volumes compromise the validation

236

of this method (20). To circumvent these limitations, van der Hee et al developed a

237

novel approach to culture enteroids two-dimensionally, in which 3D enteroids were

238

enzymatically-dissociated into single-cell suspensions, and were then transferred on

239

Matrigel pre-coated culture plates or Transwell filters (20). Two-D enteroids are

240

capable of forming tight junctions with high transepithelial electrical resistance in

241

three days, thus representing a robust platform for exploring intestinal permeability

242

and intestinal functions including drug and nutrient absorption and hormone secretion

243

(20). These 2D enteroids are also suitable for studying innate immunity, infection and

244

disease-associated polymorphisms (20). Thus, 2D porcine enteroids may compensate

245

for certain limitations of 3D enteroids.

246 247

Chicken enteroids. Chicken enteroids were cultured successfully for the first time by

248

Pierzchalska et al, in which they used a mixture of purified R-spondin1 and Noggin,

12

ACS Paragon Plus Environment

Page 13 of 40

Journal of Agricultural and Food Chemistry

249

and other enteroid growth factors (51). These chicken enteroids could be cultured and

250

passaged for more than 5 weeks (51). Chicken enteroids were shown to express

251

markers of various intestinal cell types including enteroendocrine cells, absorptive

252

enterocytes, goblet cells, and stem/progenitor cells (51). Li et al also used purified

253

R-spondin1 and Noggin to culture chicken enteroids, and they mentioned that these

254

enteroids could grow for at least one week, while no further tracking was reported

255

(50). Other studies reported that Wnt3a, R-Spondin1 and Noggin conditioned media

256

allowed chicken enteroids to grow up to 35 passages for 125 days (19). Interestingly,

257

chicken embryo enteroids consist of both epithelial cells and myofibroblasts, which is

258

different from mouse, human, porcine and other mammalian enteroids (2).

259

Collectively, as concluded previously for porcine enteroids, R-spondin1 and Noggin

260

condition media might be superior in comparison with purified growth factors for the

261

long-term culture of chicken enteroids. Chicken enteroids might provide an important

262

platform for studying infection, immunity, nutrition, and nutrient transport in chicken

263 264

Enteroids from cattle and other farm animals. Three-D bovine enteroids were

265

cultured with supplementation of Wnt3a, R-Spondin1 and Noggin conditioned media,

266

and could be passaged up to 45 times for 165 days (19). Bovine enteroids could also

267

be cultured with commercial IntestiCult Organoid Growth Medium (STEMCELL

268

Technologies, UK), but these enteroids could only be maintained in culture for 11

269

days, and then failed to expand after passaging (19). Again, the exact composition of

270

the commercial media is not publicly available but it was reported that supplementing

13

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 14 of 40

271

additional inhibitors including Rho-associated kinase inhibitor (Y27632), p38

272

mitogen-activated protein (MAP) kinase inhibitor (SB202190) and TGF-βR inhibitor

273

(LY2157299) allowed bovine enteroids cultured in IntestiCult Organoid Growth

274

Medium to be passaged up to 5-8 times for 2 months without morphological changes

275

(19). Another study showed that a mixture of commercial IntestiCult Medium and

276

Wnt3a conditioned media supplemented with purified recombinant R-spondin1,

277

Noggin and other inhibitors allowed bovine enteroids to be cultivated for over 12

278

passages (16). Thus, it seems that Wnt3a, Noggin and R-spondin1 condition media

279

and inhibitors controlling stemness-related pathways might be useful for increasing

280

culture longevity of bovine enteroids.

281

Sheep and horse enteroids were also successfully cultured with supplementation

282

of Wnt3a, R-Spondin1 and Noggin conditioned media, which could be passaged 66

283

times for 239 days, and 44 times for 168 days, respectively (19). Recently, Stewart

284

and colleagues published a protocol for the cultures of horse enteroids, which were

285

confirmed to contain four distinct cell types including ISCs, enteroendocrine cells,

286

goblet cells, and Paneth cells (52). It is expected that these enteroid models will turn

287

out to be highly useful in providing new information about intestinal characteristics

288

and function in these two species.

289 290

A combined protocol for the culture of farm animal enteroids. Based on

291

information from the available recent studies, a culture protocol for farm animal

292

enteroids could be composed, which largely resembles the protocol for culturing

14

ACS Paragon Plus Environment

Page 15 of 40

Journal of Agricultural and Food Chemistry

293

mouse and human enteroids (6, 7, 19-21, 52). The intestine samples are longitudinally

294

opened, and the muscle layers are peeled away with forceps in case of adult animals;

295

it is not necessary to separate epithelial layer and muscular layer for young animals.

296

Then, the villi are removed by gently scraping mucosal surface using a glass slide,

297

followed by cutting tissue into small pieces (5 × 5 mm). The tissue pieces are then

298

washed with cold PBS until the supernatant looks clear (the remaining villi on the

299

tissue can be visualized clearly by eyes), followed by incubation with 2.5 - 10 mM

300

(depending on species) ethylenediaminetetraacetic acid (EDTA) and 1 mM

301

dithiothreitol (DTT) in PBS for half an hour (small intestine) or one hour (large

302

intestine) at 4°C on a 50 rpm rocker. The supernatant, containing villi and debris, is

303

discarded, and 15 mL cold PBS is added, followed by repeated vortexing (3x 10

304

seconds). Crypts are collected by filtering the supernatant through a 100 μm cell

305

strainer. This procedure is performed thrice, followed by spinning down at 1200 rpm

306

for 2 min at 4°C. Then the crypt pellet is resuspended in Dulbecco's Modified Eagle

307

Medium: Nutrient Mixture F-12 (DMEM/F12) containing 25 µg/mL gentamicin and

308

100 U/mL penicillin/streptomycin depleted of growth factors (Noggin, R-spondin1,

309

Wnt3A and extra inhibitors), followed by spinning down at 600 rpm for 2 min at 4°C.

310

Then the crypt pellet is resuspended in DMEM/F12 containing 25 µg/mL gentamicin

311

and 100 U/mL penicillin/streptomycin without growth factors, and the number of

312

crypts is counted under a light microscope. Crypts (200-500) are resuspended in

313

growth factor reduced Matrigel and settled in the wells of a 24-well plate. Following

314

Matrigel solidification, 500 μL culture medium (DMEM/F12 containing gentamicin,

15

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 16 of 40

315

P/S, growth factors including Noggin, R-spondin1, Wnt3A, EGF, and extra inhibitors

316

including Y27632, SB202190 and LY2157299) is added, followed by placing the

317

24-well plate in cell culture incubator. The development of the enteroid structure is

318

illustrated in Figure 1. During the first day in culture, crypts will quickly seal at their

319

upper opening and grow into a spherical shape (day 1), then the spheroids undergo

320

continuous budding events (day 3-4) to finally become a mature enteroid containing a

321

multiplicity of intestinal cell types (day 5).

322 323

CURRENT APPLICATIONS OF FARM ANIMAL ENTEROIDS

324 325

Enteroids of farm animals model pathogen infections. A lack of suitable in vitro

326

models hampers our understanding of the pathogenesis of veterinary infections and

327

the development of effective treatments. Toxoplasma gondii or Salmonella

328

typhimurium were confirmed to be able to infect porcine enteroids (16). It is also

329

found that bovine enteroids were sensitive for infections of Toxoplasma gondii and

330

Salmonella typhimurium (16). Although the application of enteroids to model

331

pathogen infections in other farm animals has not been reported yet, this model should

332

open up new avenues for studying veterinary pathogens in distinct species.

333 334

Enteroids of farm animals model the effects of chemicals on animal disease and

335

production performance. As an exquisite in vitro model, enteroids are expected to

336

be suitable for developing chemicals with benefit for treating disease or improving

337

body function. Human enteroids have already been used to screen a G-protein coupled 16

ACS Paragon Plus Environment

Page 17 of 40

Journal of Agricultural and Food Chemistry

338

receptor (GPCR)-modulating compound library, showing that β2-adrenergic receptor

339

agonists are capable to induce cystic fibrosis transmembrane conductance regulator

340

(CFTR) function in the GI tract of CF patients (53). A set of immunosuppressive

341

chemicals have been screened in human enteroids, demonstrating that mycophenolic

342

acid (MPA) is able to potently inhibit rotavirus infection (8). Interestingly, in human

343

enteroids a plant extract of tannins, isolated from Syzygium guineense, was found to

344

exert an anti-cancer effect depending on the Wnt signaling pathway (54). Enteroids

345

cultured from farm animals have been used for investigating the effect of chemicals

346

on animal production performance, although the available data are still sparse.

347

Pierzchalska et al found that prostaglandin E2 was able to boost chicken embryo

348

enteroid growth (51), and the same group demonstrated that a synthetic Toll-like

349

receptor (TLR) 2 agonist promoted the growth of chicken embryo enteroids (3).

350

Melatonin, an important hormone generated by the pineal gland, was shown to

351

increase amino acid transport using chicken enteroids (55). In porcine enteroids, it

352

was found that lipopolysaccharides were able to internalize TLR4 to the early

353

endosome (56). Interestingly, since pig and human intestine have many genetic,

354

anatomical and physiological properties in common, the porcine enteroid model is

355

also thought to be a proper platform for developing medicines treating human diseases

356

(1). At this point in time, explorative studies in enteroids to investigate the effect of

357

chemicals on animal disease and production performance in most other farm animals

358

(e.g. cattle, sheep, goat, horse) are still in a design stage and have not been reported

359

yet. However we anticipate that enteroids will turn out to become excellent in vitro

17

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 18 of 40

360

models to explore the utilization of both synthetic and natural chemicals in animal

361

husbandry.

362 363

CONCLUSIONS AND PROSPECTS

364

To date, enteroids of almost all of livestock species including pigs, chicken,

365

bovine, sheep and horse have been successfully cultured. Similar to enteroids cultured

366

from humans and mice, farm animal enteroids recapitulate the physiology of in vivo

367

intestinal epithelium composed of villus and crypt domains containing a large variety

368

of intestinal cell types (Figure 2). It seems that Wnt3a, Noggin and R-spondin1

369

condition medium are superior to purified recombinant factors for long-term culture

370

of enteroids, and inhibitors controlling stemness related pathways are necessary for

371

increasing their longevity. Farm animal enteroids are expected to become a suitable

372

model for investigating immunity, inflammation, infections, pathogen-host interaction,

373

and intestinal barrier functions (Figure 2). Of note, Wu et al recently used human

374

ileal enteroids to confirm that human milk oligosaccharides (HMOs) were capable of

375

increasing enteroid crypt budding (57). Moreover mouse enteroids have been used for

376

evaluating nutrient sensing, transport, and incretin secretion (58). Thus, this novel

377

model raises expectations as a powerful platform for studying animal nutrition and

378

food technology. So far however, applications in this direction are rare, thus more

379

efforts should be invested into this field of research. Enteroids also provide the option

380

to study nutrition at an individualized level, since they are capable of retaining

381

individual variations in genetics (polymorphisms) and maintain an epigenetic memory

18

ACS Paragon Plus Environment

Page 19 of 40

382

Journal of Agricultural and Food Chemistry

(59).

383

Although enteroids offer a great potential in biological studies, there are also

384

several shortcomings that may limit their application: (1) The cost of culturing

385

enteroids is still considerable, in particular due to the Matrigel component (2).

386

Moreover, Matrigel is undefined, and the amount of growth factors and other

387

important components in Matrigel may differ considerably between batches (2). To

388

circumvent these problems, a hanging drop culture was developed for enteroid culture,

389

in which only 5% Matrigel and smaller amount of culture media were needed as

390

compared with the approach of immersing enteroids in Matrigel (2). In addition, a

391

hanging drop culture avoids the time cost of Matrigel solidification and speeds up the

392

culture procedure (2). In the future, more creative approaches should be developed to

393

reduce the culture cost and simplify culture precedure. (2) A standardized operation

394

procedure (SOP) for farm animal enteroid culture is lacking, which may result in

395

variations in quality and properties of enteroids cultured by different groups (1), thus,

396

more efforts should be invested to generate a standardized protocol. (3) Enteroids do

397

not contain the complex immune and neural systems that exist in vivo, which reduces

398

their ability to faithfully mimic bodily physiology. However the co-culturing of

399

enteroids with immune or neural cells may in part circumvent this pitfall (60). (4)

400

Spherical morphology and their embedding in Martrigel may prevent lumen

401

penetration of chemicals or bioactives and washout; however intraluminal

402

micro-injection of the 3D organoids or converting them into a 2D monolayer culture

403

may overcome most of these hurdles (18, 20).

19

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 20 of 40

404

Collectively, although enteroid models still face several unsolved technical

405

difficulties and limitations, in our opinion they should receive more attention as useful

406

new exploratory models in intestinal studies of farm animals, and may potentially lead

407

to important new insights in the research area for livestock studies.

408 409

20

ACS Paragon Plus Environment

Page 21 of 40

Journal of Agricultural and Food Chemistry

411

Figure legends

412

Figure 1: A schematic diagram illustrating morphology changes of enteroids as a

413

function of time. Each crypt quickly seals the upper opening, followed by growing

414

into a spherical shape (day 1), then the spheroid structure undergoes continuous

415

budding events (day 3-4) to finally become a mature enteroid containing various

416

intestinal cell types (day 5), followed by accumulation of a large body of dead cells in

417

the lumen (day 6). The picture was taken by the first author to illustrate the real

418

morphology of porcine enteroids.

419

Figure 2: Schematic of the morphology of farm animal enteroids and their

420

applications.

421 422

21

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 22 of 40

424

ACKNOWLEDGEMENT

425

Funding Resources

426

This work was supported by National Key Research and Development Program of

427

China (2016YFD0500504), the earmarked fund for China Agriculture Research

428

System (CARS-35), Science and Technology Service Network Initiative program of

429

Chinese Academy of Sciences, Agricultural innovation project of Hunan Province

430

(2018ZD12), and CAS President’s International Fellowship for Visiting Scientists

431

(2019VBA0015).

432

Conflict of Interest

433

The authors declare no competing financial interest.

434

Author contributes

435

YB. Y., X. W., and YL. Y. designed and structured the article, S. G. and YB. Y. were

436

involved in searching literature, S. G. and D. W. were involved in discussion, and X.

437

W. checked and revised manuscript, YB. Y. wrote the manuscript.

438

22

ACS Paragon Plus Environment

Page 23 of 40

Journal of Agricultural and Food Chemistry

440

REFERENCES

441

1.

Olayanju, A.; Jones, L.; Greco, K.; Goldring, C. E.; Ansari, T., Application of

442

porcine gastrointestinal organoid units as a potential in vitro tool for drug

443

discovery and development. J Appl Toxicol 2018.

444

2.

in a hanging drop culture. Cytotechnology 2018, 70, 1085-1095.

445 446

Panek, M.; Grabacka, M.; Pierzchalska, M., The formation of intestinal organoids

3.

Pierzchalska, M.; Panek, M.; Czyrnek, M.; Gielicz, A.; Mickowska, B.; Grabacka,

447

M., Probiotic Lactobacillus acidophilus bacteria or synthetic TLR2 agonist boost

448

the growth of chicken embryo intestinal organoids in cultures comprising

449

epithelial cells and myofibroblasts. Comp Immunol Microbiol Infect Dis 2017, 53,

450

7-18.

451

4.

Hamilton, C. A.; Young, R.; Jayaraman, S.; Sehgal, A.; Paxton, E.; Thomson, S.;

452

Katzer, F.; Hope, J.; Innes, E.; Morrison, L. J.; Mabbott, N. A., Development of

453

in vitro enteroids derived from bovine small intestinal crypts. Vet Res 2018, 49,

454

54.

455

5.

Yin, Y.; Chen, S.; Hakim, M. S.; Wang, W.; Xu, L.; Dang, W.; Qu, C.; Verhaar,

456

A. P.; Su, J.; Fuhler, G. M.; Peppelenbosch, M. P.; Pan, Q., 6-Thioguanine

457

inhibits rotavirus replication through suppression of Rac1 GDP/GTP cycling.

458

Antiviral Res 2018, 156, 92-101.

459

6.

Sato, T.; Vries, R. G.; Snippert, H. J.; van de Wetering, M.; Barker, N.; Stange, D.

460

E.; van Es, J. H.; Abo, A.; Kujala, P.; Peters, P. J.; Clevers, H., Single Lgr5 stem

461

cells build crypt-villus structures in vitro without a mesenchymal niche. Nature

23

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

2009, 459, 262-5.

462 463

Page 24 of 40

7.

Yin, Y.; Bijvelds, M.; Dang, W.; Xu, L.; van der Eijk, A. A.; Knipping, K.;

464

Tuysuz, N.; Dekkers, J. F.; Wang, Y.; de Jonge, J.; Sprengers, D.; van der Laan,

465

L. J.; Beekman, J. M.; Ten Berge, D.; Metselaar, H. J.; de Jonge, H.; Koopmans,

466

M. P.; Peppelenbosch, M. P.; Pan, Q., Modeling rotavirus infection and antiviral

467

therapy using primary intestinal organoids. Antiviral Res 2015, 123, 120-31.

468

8.

Yin, Y.; Wang, Y.; Dang, W.; Xu, L.; Su, J.; Zhou, X.; Wang, W.; Felczak, K.;

469

van der Laan, L. J.; Pankiewicz, K. W.; van der Eijk, A. A.; Bijvelds, M.;

470

Sprengers, D.; de Jonge, H.; Koopmans, M. P.; Metselaar, H. J.; Peppelenbosch,

471

M. P.; Pan, Q., Mycophenolic acid potently inhibits rotavirus infection with a

472

high barrier to resistance development. Antiviral Res 2016, 133, 41-9.

473

9.

Yin, Y.; Dang, W.; Zhou, X.; Xu, L.; Wang, W.; Cao, W.; Chen, S.; Su, J.; Cai,

474

X.; Xiao, S.; Peppelenbosch, M. P.; Pan, Q., PI3K-Akt-mTOR axis sustains

475

rotavirus infection via the 4E-BP1 mediated autophagy pathway and represents

476

an antiviral target. Virulence 2018, 9, 83-98.

477

10. Zhang, Y. G.; Wu, S.; Xia, Y.; Sun, J., Salmonella-infected crypt-derived

478

intestinal organoid culture system for host-bacterial interactions. Physiol Rep

479

2014, 2.

480

11. van Lidth de Jeude, J. F.; Spaan, C. N.; Meijer, B. J.; Smit, W. L.; Soeratram, T.

481

T.; Wielenga, M. C. B.; Westendorp, B. F.; Lee, A. S.; Meisner, S.; Vermeulen, J.

482

L.; Wildenberg, M. E.; van den Brink, G. R.; Muncan, V.; Heijmans, J.,

483

Heterozygosity of chaperone Grp78 reduces intestinal stem cell regeneration

24

ACS Paragon Plus Environment

Page 25 of 40

484

Journal of Agricultural and Food Chemistry

potential and protects against adenoma formation. Cancer Res 2018.

485

12. Dekkers, J. F.; Wiegerinck, C. L.; de Jonge, H. R.; Bronsveld, I.; Janssens, H. M.;

486

de Winter-de Groot, K. M.; Brandsma, A. M.; de Jong, N. W.; Bijvelds, M. J.;

487

Scholte, B. J.; Nieuwenhuis, E. E.; van den Brink, S.; Clevers, H.; van der Ent, C.

488

K.; Middendorp, S.; Beekman, J. M., A functional CFTR assay using primary

489

cystic fibrosis intestinal organoids. Nat Med 2013, 19, 939-45.

490

13. Sun, Z.; Huber, V. C.; McCormick, K.; Kaushik, R. S.; Boon, A. C.; Zhu, L.;

491

Hause, B.; Webby, R. J.; Fang, Y., Characterization of a porcine intestinal

492

epithelial cell line for influenza virus production. J Gen Virol 2012, 93, 2008-16.

493

14. Vergauwen, H., The IPEC-J2 Cell Line. In The Impact of Food Bioactives on

494

Health: in vitro and ex vivo models, Verhoeckx, K.; Cotter, P.; Lopez-Exposito, I.;

495

Kleiveland, C.; Lea, T.; Mackie, A.; Requena, T.; Swiatecka, D.; Wichers, H.,

496

Eds. Cham (CH), 2015; pp 125-134.

497

15. Zhan, K.; Lin, M.; Liu, M. M.; Sui, Y. N.; Zhao, G. Q., Establishment of primary

498

bovine intestinal epithelial cell culture and clone method. In Vitro Cell Dev Biol

499

Anim 2017, 53, 54-57.

500

16. Derricott, H.; Luu, L.; Fong, W. Y.; Hartley, C. S.; Johnston, L. J.; Armstrong, S.

501

D.; Randle, N.; Duckworth, C. A.; Campbell, B. J.; Wastling, J. M.; Coombes, J.

502

L., Developing a 3D intestinal epithelium model for livestock species. Cell Tissue

503

Res 2018.

504

17. Gonzalez, L. M.; Williamson, I.; Piedrahita, J. A.; Blikslager, A. T.; Magness, S.

505

T., Cell lineage identification and stem cell culture in a porcine model for the

25

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

506

Page 26 of 40

study of intestinal epithelial regeneration. PLoS One 2013, 8, e66465.

507

18. Khalil, H. A.; Lei, N. Y.; Brinkley, G.; Scott, A.; Wang, J.; Kar, U. K.; Jabaji, Z.

508

B.; Lewis, M.; Martin, M. G.; Dunn, J. C.; Stelzner, M. G., A novel culture

509

system for adult porcine intestinal crypts. Cell Tissue Res 2016, 365, 123-34.

510

19. Powell, R. H.; Behnke, M. S., WRN conditioned media is sufficient for in vitro

511

propagation of intestinal organoids from large farm and small companion animals.

512

Biol Open 2017, 6, 698-705.

513

20. van der Hee, B.; Loonen, L. M. P.; Taverne, N.; Taverne-Thiele, J. J.; Smidt, H.;

514

Wells, J. M., Optimized procedures for generating an enhanced, near

515

physiological 2D culture system from porcine intestinal organoids. Stem Cell Res

516

2018, 28, 165-171.

517

21. Li, J.; Li, J., Jr.; Zhang, S. Y.; Li, R. X.; Lin, X.; Mi, Y. L.; Zhang, C. Q., Culture

518

and characterization of chicken small intestinal crypts. Poult Sci 2018, 97,

519

1536-1543.

520

22. Berschneider, H. M., Development of normal cultured small intestinal epithelial

521

cell lines which transport Na and Cl. Gastroenterology 1989, 96(Suppl. Pt. 2),

522

A41.

523

23. Pan, L.; Zhao, Y.; Yuan, Z.; Farouk, M. H.; Zhang, S.; Bao, N.; Qin, G., The

524

Integrins Involved in Soybean Agglutinin-Induced Cell Cycle Alterations in

525

IPEC-J2. Mol Cells 2017, 40, 109-116.

526

24. Yang, J. W.; Tian, G.; Chen, D. W.; Yao, Y.; He, J.; Zheng, P.; Mao, X. B.; Yu,

527

J.; Huang, Z. Q.; Yu, B., Involvement of PKA signalling in anti-inflammatory

26

ACS Paragon Plus Environment

Page 27 of 40

Journal of Agricultural and Food Chemistry

528

effects of chitosan oligosaccharides in IPEC-J2 porcine epithelial cells. J Anim

529

Physiol Anim Nutr (Berl) 2018, 102, 252-259.

530 531

25. Lee, S. I.; Kang, K. S., N-acetylcysteine modulates lipopolysaccharide-induced intestinal dysfunction. Sci Rep 2019, 9, 1004.

532

26. Jeong Gu, M.; Han, S. E.; Hwang, K.; Mayer, E.; Reisinger, N.; Schatzmayr, D.;

533

Park, B. C.; Han, S. H.; Yun, C. H., Hydrolyzed Fumonisin B1 induces less

534

inflammatory responses than Fumonisin B1 in the co-culture model of porcine

535

intestinal epithelial and immune cells. Toxicol Lett 2019.

536

27. Omonijo, F. A.; Liu, S.; Hui, Q.; Zhang, H.; Lahaye, L.; Bodin, J. C.; Gong, J.;

537

Nyachoti, M.; Yang, C., Thymol improves barrier function and attenuates

538

inflammatory

539

lipopolysaccharide (LPS)-induced inflammation. J Agric Food Chem 2018.

responses

in

porcine

intestinal

epithelial

cells

during

540

28. Liu, H.; Hou, C.; Wang, G.; Jia, H.; Yu, H.; Zeng, X.; Thacker, P. A.; Zhang, G.;

541

Qiao, S., Lactobacillus reuteri I5007 Modulates Intestinal Host Defense Peptide

542

Expression in the Model of IPEC-J2 Cells and Neonatal Piglets. Nutrients 2017,

543

9.

544

29. An, R.; Tang, Z.; Li, Y.; Li, T.; Xu, Q.; Zhen, J.; Huang, F.; Yang, J.; Chen, C.;

545

Wu, Z.; Li, M.; Sun, J.; Zhang, X.; Chen, J.; Wu, L.; Zhao, S.; Qingyan, J.; Zhu,

546

W.; Yin, Y.; Sun, Z., Activation of Pyruvate Dehydrogenase by Sodium

547

Dichloroacetate Shifts Metabolic Consumption from Amino Acids to Glucose in

548

IPEC-J2 Cells and Intestinal Bacteria in Pigs. J Agric Food Chem 2018, 66,

549

3793-3800.

27

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 28 of 40

550

30. Liao, P.; Liao, M.; Li, L.; Tan, B.; Yin, Y., Effect of deoxynivalenol on apoptosis,

551

barrier function, and expression levels of genes involved in nutrient transport,

552

mitochondrial biogenesis and function in IPEC-J2 cells. Toxicol Res (Camb)

553

2017, 6, 866-877.

554

31. Paszti-Gere, E.; Barna, R. F.; Kovago, C.; Szauder, I.; Ujhelyi, G.; Jakab, C.;

555

Meggyeshazi, N.; Szekacs, A., Changes in the distribution of type II

556

transmembrane serine protease, TMPRSS2 and in paracellular permeability in

557

IPEC-J2 cells exposed to oxidative stress. Inflammation 2015, 38, 775-83.

558

32. Zhai, Z.; Ni, X.; Jin, C.; Ren, W.; Li, J.; Deng, J.; Deng, B.; Yin, Y., Cecropin A

559

Modulates Tight Junction-Related Protein Expression and Enhances the Barrier

560

Function of Porcine Intestinal Epithelial Cells by Suppressing the MEK/ERK

561

Pathway. Int J Mol Sci 2018, 19.

562

33. Springler, A.; Vrubel, G. J.; Mayer, E.; Schatzmayr, G.; Novak, B., Effect of

563

Fusarium-Derived Metabolites on the Barrier Integrity of Differentiated Intestinal

564

Porcine Epithelial Cells (IPEC-J2). Toxins (Basel) 2016, 8.

565

34. Tang, X.; Liu, B.; Wang, X.; Yu, Q.; Fang, R., Epidermal Growth Factor, through

566

Alleviating

Oxidative

Stress,

Protect

IPEC-J2

567

Lipopolysaccharides-Induced Apoptosis. Int J Mol Sci 2018, 19.

Cells

from

568

35. Jung, K.; Miyazaki, A.; Hu, H.; Saif, L. J., Susceptibility of porcine IPEC-J2

569

intestinal epithelial cells to infection with porcine deltacoronavirus (PDCoV) and

570

serum cytokine responses of gnotobiotic pigs to acute infection with IPEC-J2 cell

571

culture-passaged PDCoV. Vet Microbiol 2018, 221, 49-58.

28

ACS Paragon Plus Environment

Page 29 of 40

Journal of Agricultural and Food Chemistry

572

36. Thomas, M.; Pierson, M.; Uprety, T.; Zhu, L.; Ran, Z.; Sreenivasan, C. C.; Wang,

573

D.; Hause, B.; Francis, D. H.; Li, F.; Kaushik, R. S., Comparison of Porcine

574

Airway and Intestinal Epithelial Cell Lines for the Susceptibility and Expression

575

of Pattern Recognition Receptors upon Influenza Virus Infection. Viruses 2018,

576

10.

577

37. Kaiser, A.; Willer, T.; Steinberg, P.; Rautenschlein, S., Establishment of an In

578

Vitro Intestinal Epithelial Cell Culture Model of Avian Origin. Avian Dis 2017,

579

61, 229-236.

580 581

38. Palmarini, M.; Sharp, J. M.; Lee, C.; Fan, H., In vitro infection of ovine cell lines by Jaagsiekte sheep retrovirus. J Virol 1999, 73, 10070-8.

582

39. Xu, Q.; Fan, H.; Yu, W.; Hong, H.; Wu, J., Transport Study of Egg-Derived

583

Antihypertensive Peptides (LKP and IQW) Using Caco-2 and HT29 Coculture

584

Monolayers. J Agric Food Chem 2017, 65, 7406-7414.

585 586

40. Huch, M.; Koo, B. K., Modeling mouse and human development using organoid cultures. Development 2015, 142, 3113-25.

587

41. Sato, T.; Stange, D. E.; Ferrante, M.; Vries, R. G.; Van Es, J. H.; Van den Brink,

588

S.; Van Houdt, W. J.; Pronk, A.; Van Gorp, J.; Siersema, P. D.; Clevers, H.,

589

Long-term expansion of epithelial organoids from human colon, adenoma,

590

adenocarcinoma, and Barrett's epithelium. Gastroenterology 2011, 141, 1762-72.

591 592 593

42. Sato, T.; Clevers, H., Growing self-organizing mini-guts from a single intestinal stem cell: mechanism and applications. Science 2013, 340, 1190-4. 43. Holmberg, F. E.; Seidelin, J. B.; Yin, X.; Mead, B. E.; Tong, Z.; Li, Y.; Karp, J.

29

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 30 of 40

594

M.; Nielsen, O. H., Culturing human intestinal stem cells for regenerative

595

applications in the treatment of inflammatory bowel disease. EMBO Mol Med

596

2017, 9, 558-570.

597 598 599 600

44. Yin, Y.; Zhou, D., Organoid and Enteroid Modeling of Salmonella Infection. Front Cell Infect Microbiol 2018, 8, 102. 45. Dai, X.; Cheng, H.; Bai, Z.; Li, J., Breast Cancer Cell Line Classification and Its Relevance with Breast Tumor Subtyping. J Cancer 2017, 8, 3131-3141.

601

46. Wilen, C. B.; Lee, S.; Hsieh, L. L.; Orchard, R. C.; Desai, C.; Hykes, B. L., Jr.;

602

McAllaster, M. R.; Balce, D. R.; Feehley, T.; Brestoff, J. R.; Hickey, C. A.;

603

Yokoyama, C. C.; Wang, Y. T.; MacDuff, D. A.; Kreamalmayer, D.; Howitt, M.

604

R.; Neil, J. A.; Cadwell, K.; Allen, P. M.; Handley, S. A.; van Lookeren

605

Campagne, M.; Baldridge, M. T.; Virgin, H. W., Tropism for tuft cells

606

determines immune promotion of norovirus pathogenesis. Science 2018, 360,

607

204-208.

608

47. Ettayebi, K.; Crawford, S. E.; Murakami, K.; Broughman, J. R.; Karandikar, U.;

609

Tenge, V. R.; Neill, F. H.; Blutt, S. E.; Zeng, X. L.; Qu, L.; Kou, B.; Opekun, A.

610

R.; Burrin, D.; Graham, D. Y.; Ramani, S.; Atmar, R. L.; Estes, M. K.,

611

Replication of human noroviruses in stem cell-derived human enteroids. Science

612

2016, 353, 1387-1393.

613

48. de Winter-de Groot, K. M.; Janssens, H. M.; van Uum, R. T.; Dekkers, J. F.;

614

Berkers, G.; Vonk, A.; Kruisselbrink, E.; Oppelaar, H.; Vries, R.; Clevers, H.;

615

Houwen, R. H. J.; Escher, J. C.; Elias, S. G.; de Jonge, H. R.; de Rijke, Y. B.;

30

ACS Paragon Plus Environment

Page 31 of 40

Journal of Agricultural and Food Chemistry

616

Tiddens, H.; van der Ent, C. K.; Beekman, J. M., Stratifying infants with cystic

617

fibrosis for disease severity using intestinal organoid swelling as a biomarker of

618

CFTR function. Eur Respir J 2018, 52.

619

49. Stieler Stewart, A.; Freund, J. M.; Blikslager, A. T.; Gonzalez, L. M., Intestinal

620

Stem Cell Isolation and Culture in a Porcine Model of Segmental Small Intestinal

621

Ischemia. J Vis Exp 2018.

622

50. Wilson, S. S.; Tocchi, A.; Holly, M. K.; Parks, W. C.; Smith, J. G., A small

623

intestinal organoid model of non-invasive enteric pathogen-epithelial cell

624

interactions. Mucosal Immunol 2015, 8, 352-61.

625

51. Pierzchalska, M.; Grabacka, M.; Michalik, M.; Zyla, K.; Pierzchalski, P.,

626

Prostaglandin E2 supports growth of chicken embryo intestinal organoids in

627

Matrigel matrix. Biotechniques 2012, 52, 307-15.

628 629

52. Stewart, A. S.; Freund, J. M.; Gonzalez, L. M., Advanced three-dimensional culture of equine intestinal epithelial stem cells. Equine Vet J 2018, 50, 241-248.

630

53. Vijftigschild, L. A.; Berkers, G.; Dekkers, J. F.; Zomer-van Ommen, D. D.;

631

Matthes, E.; Kruisselbrink, E.; Vonk, A.; Hensen, C. E.; Heida-Michel, S.;

632

Geerdink, M.; Janssens, H. M.; van de Graaf, E. A.; Bronsveld, I.; de Winter-de

633

Groot, K. M.; Majoor, C. J.; Heijerman, H. G.; de Jonge, H. R.; Hanrahan, J. W.;

634

van der Ent, C. K.; Beekman, J. M., beta2-Adrenergic receptor agonists activate

635

CFTR in intestinal organoids and subjects with cystic fibrosis. Eur Respir J 2016,

636

48, 768-79.

637

54. Koval, A.; Pieme, C. A.; Queiroz, E. F.; Ragusa, S.; Ahmed, K.; Blagodatski, A.;

31

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 32 of 40

638

Wolfender, J. L.; Petrova, T. V.; Katanaev, V. L., Tannins from Syzygium

639

guineense suppress Wnt signaling and proliferation of Wnt-dependent tumors

640

through a direct effect on secreted Wnts. Cancer Lett 2018, 435, 110-120.

641

55. Liu, L.; Zhang, S.; Bao, J.; He, X.; Tong, D.; Chen, C.; Ying, Q.; Zhang, Q.;

642

Zhang, C.; Li, J., Melatonin Improves Laying Performance by Enhancing

643

Intestinal Amino Acids Transport in Hens. Front Endocrinol (Lausanne) 2018, 9,

644

426.

645

56. Koltes D A, G. N. K., Characterization of porcine intestinal enteroid cultures

646

under a lipopolysaccharide challenge. Journal of Animal Science 2016, 94

647

335-339.

648

57. Wu, R. Y.; Li, B.; Koike, Y.; Maattanen, P.; Miyake, H.; Cadete, M.;

649

Johnson-Henry, K. C.; Botts, S. R.; Lee, C.; Abrahamsson, T. R.; Landberg, E.;

650

Pierro, A.; Sherman, P. M., Human Milk Oligosaccharides Increase Mucin

651

Expression in Experimental Necrotizing Enterocolitis. Mol Nutr Food Res 2019,

652

63, e1800658.

653 654

58. Zietek, T.; Rath, E.; Haller, D.; Daniel, H., Intestinal organoids for assessing nutrient transport, sensing and incretin secretion. Sci Rep 2015, 5, 16831.

655

59. Middendorp, S.; Schneeberger, K.; Wiegerinck, C. L.; Mokry, M.; Akkerman, R.

656

D.; van Wijngaarden, S.; Clevers, H.; Nieuwenhuis, E. E., Adult stem cells in the

657

small intestine are intrinsically programmed with their location-specific function.

658

Stem Cells 2014, 32, 1083-91.

659

60. Biton, M.; Haber, A. L.; Rogel, N.; Burgin, G.; Beyaz, S.; Schnell, A.; Ashenberg,

32

ACS Paragon Plus Environment

Page 33 of 40

Journal of Agricultural and Food Chemistry

660

O.; Su, C. W.; Smillie, C.; Shekhar, K.; Chen, Z.; Wu, C.; Ordovas-Montanes, J.;

661

Alvarez, D.; Herbst, R. H.; Zhang, M.; Tirosh, I.; Dionne, D.; Nguyen, L. T.;

662

Xifaras, M. E.; Shalek, A. K.; von Andrian, U. H.; Graham, D. B.;

663

Rozenblatt-Rosen, O.; Shi, H. N.; Kuchroo, V.; Yilmaz, O. H.; Regev, A.; Xavier,

664

R. J., T Helper Cell Cytokines Modulate Intestinal Stem Cell Renewal and

665

Differentiation. Cell 2018, 175, 1307-1320 e22.

666 667 668 669 670 671 672 673 674 675 676 677 678 679 680 681 682 683 684 685 686 687 688 689 690 691 692 693 694 695 696 697

33

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 34 of 40

698 699 700 701 702 703 704 705

Table 1. Comparison between enteroids and intestinal cell lines. Enteroids

Intestinal cell lines

Origin

Adult stem cell

Cell type

Multiple

Tumor-based, immortalized cells or non-transformed tumorigenic cells Single

Morphology

3D, and containing villus 2D or mono-layer without and crypt domains villus and crypt domain No Yes

Mutation 706 707

34

ACS Paragon Plus Environment

Page 35 of 40

Journal of Agricultural and Food Chemistry

Table 2. Cell models for intestinal studies of livestock animals (selected). Author

Year

Type of model

Species

Application/finding

Jeong Gu et al

2019

IPEC-J2 cells

Pig

Hydrolyzed Fumonisin B1 has less ability in induction of inflammatory responses compared with Fumonisin B1.

Lee et al

2019

IPEC-J2 cells

Pig

N-acetylcysteine could govern intestinal inflammation, permeability, and wound healing to improve livestock intestinal health.

An et al

2018

IPEC-J2 cells

Pig

Investigated the effects of the pyruvate dehydrogenase kinase (PDK)/pyruvate dehydrogenase alpha 1 (PDHA1) pathway on amino acid consumption.

Omonijo et al

2018

IPEC-J2 cells

Pig

Thymol is benefit for improving barrier function and inflammatory responses during lipopolysaccharide (LPS)-induced inflammation

Liu et al

2017

IPEC-J2 cells

Pig

Detected effect of Lactobacillus reuteri I5007 on intestinal endogenous host defense peptides expression.

Liao et al

2017

IPEC-J2 cells

Pig

Studied the effect of deoxynivalenol on apoptosis, barrier function, and expression levels of genes involved in nutrient transport, mitochondrial biogenesis and function.

Pan et al

2017

IPEC-J2 cells

Pig

Studied the effects of soybean agglutinin (SBA) on cell proliferation and cell cycle progression.

Paszti-Gere et al

2015

IPEC-J2 cells

Pig

Investigated the effect of oxidative stress on barrier integrity and localization of transmembrane serine proteinase 2.

Springler et al

2016

IPEC-J2 cells

Pig

Investigated the effect of fusarium-derived metabolites on the intestinal barrier integrity.

Sun et al

2012

SD-PJEC

Pig

Studied features of a porcine intestinal epithelial cell line for influenza virus production.

Tang et al

2018

IPEC-J2 cells

Pig

Epidermal growth factor protect IPEC-J2 Cells from lipopolysaccharides-induced apoptosis via alleviating oxidative stress.

Thomas et al

2018

SD-PJEC

Pig

Compared porcine airway and intestinal epithelial cell lines for the susceptibility and expression of pattern recognition receptors upon influenza virus infection.

Jung et al

2018

IPEC-J2 cells

Pig

Investigated porcine deltacoronavirus (PDCoV) infection.

Yang et al

2018

IPEC-J2 cells

Pig

Investigated the anti-inflammatory activity of low-molecular-weight chitosan oligosaccharide.

Zhai et al

2018

IPEC-J2 cells

Pig

Cecropin A regulated the expression level of tight junction-related protein and enhanced the intestinal barrier function by

Kaiser et al

2017

Primary intestinal

Chicken

inhibiting the MEK/ERK pathway. Successfully established an in vitro primary intestinal epithelial cell of chicken.

epithelial cell

35

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Zhan et al Palmarini et al

2017 1999

Page 36 of 40

Primary intestinal

Holstein

Developed a method of establishment of primary bovine intestinal epithelial cells.

epithelial cells

cows

Intestinal

Ovine

Studied infection of jaagsiekte sheep retrovirus

Human

Investigated the mechanisms of the transport of antihypertensive tripeptides LKP and IQW derived from egg white.

carcinoma cells Xu et al

2017

Caco-2 and HT29

Table 3. Enteroids of different livestock species and origins of growth factors. Author

Year

Species

Enteroid type

Intestinal

Passages/time

Noggin

R-spondin1

Wnt3a type

13/3 months

IntestiCult

IntestiCult

IntestiCult

segment Derricott et al

2018

Pig

3D

Proximal jejunum

Stewart et al

2018

Pig

3D

Jejunum

Not mentioned

Purified

Purified

Purified

Van der Hee et al

2018

Pig

3D and 2D

Ileum

Several months

Conditioned

Conditioned

Conditioned

Powell and Behnke

2017

Pig

3D

Terminal ileum

49 passages

Conditioned

Conditioned

Conditioned

Khalil et al

2016

Pig

3D

Mid-jejunum

10 passages

Purified

Purified

Conditioned

Gonzalez et al

2013

pig

3D

The duodenum,

8/4.5 months

Purified

Purified

Purified

jejunum, ileum, proximal

and

distal colon Li et al

2018

Chicken

3D

Whole jejunum

One week

Purified

Purified

Not mentioned

Powell and Behnke

2017

Chicken

3D

Terminal ileum

35/125 days

Conditioned

Conditioned

Conditioned

36

ACS Paragon Plus Environment

Page 37 of 40

Journal of Agricultural and Food Chemistry

Pierzchalska et al

2012

Chicken

3D

Small intestines

5 weeks

Purified

Purified

Not mentioned

Derricott et al

2018

Bovine

3D

Proximal

12 passages

IntestiCult

IntestiCult

Conditioned

jejunum Hamilton et al

2018

Bovine

3D

Ileum

11 days

IntestiCult

IntestiCult

IntestiCult

Powell and Behnke

2017

Bovine

3D

Terminal ileum

45/165 days

Conditioned

Conditioned

Conditioned

Powell and Behnke

2017

Sheep

3D

Terminal ileum

66/239 days

Conditioned

Conditioned

Conditioned

Stewart et al

2018

Horse

3D

Jejunum

Not mentioned

Purified

Purified

Purified

Powell and Behnke

2017

Horse

3D

Terminal ileum

44/168 days

Conditioned

Conditioned

Conditioned

37

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 38 of 40

Table of Contents Graphic (TOC)

38

ACS Paragon Plus Environment

Page 39 of 40

Journal of Agricultural and Food Chemistry

A schematic diagram illustrating morphology changes of enteroids as a function of time. Each crypt quickly seals the upper opening, followed by growing into a spherical shape (day 1), then the spheroid structure undergoes continuous budding events (day 3-4) to finally become a mature enteroid containing various intestinal cell types (day 5), followed by accumulation of a large body of dead cells in the lumen (day 6). The picture was taken by the first author to illustrate the real morphology of porcine enteroids. 229x155mm (96 x 96 DPI)

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Schematic of the morphology of farm animal enteroids and their applications. 250x125mm (96 x 96 DPI)

ACS Paragon Plus Environment

Page 40 of 40