Báo cáo khoa học: "An immunohistochemical study of the gastrointestinal endocrine cells in the ddY mice" doc

The regional distribution and relative frequency of gastrointestinal endocrine cells were varied with the GI tract, and some peculiar distributional patterns were found in ddY mice.. In

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An immunohistochemical study of the gastrointestinal endocrine cells

in the ddY mice

Sae-kwang Ku, Hyeung-sik Lee 1,

*, Jae-hyun Lee 2

Pharmacology & Toxicology Lab., Central Research Laboratories, Dong-Wha Pharm Ind Co., Anyang 430-017, Korea

1

Department of Herbal Biotechnology, Daegu Haany University, Daegu 712-715, Korea

2

Department of Histology, College of Veterinary Medicine, Kyungpook National University, Daegu 702-701, Korea

The distributions and frequencies of some endocrine cells

in the gastrointestinal (GI) tract of ddY mice were studied

with immunohistochemical method using 7 types of

antisera against bovine chromogranin (BCG), serotonin,

gastrin, cholecystokinin (CCK)-8, somatostatin, glucagon

and human pancreatic polypeptide (HPP) All of 7 types of

immunoreactive (IR) cells were identified Most of IR cells

in the intestinal portion were generally spherical or spindle

in shape (open typed cell) while cells showing round in

shape (close typed cell) were found in the intestinal gland

and stomach regions occasionally Their relative

frequencies were varied according to each portion of GI

tract BCG-IR cells were demonstrated throughout whole

GI tract except for the cecum and they were most

predominant in the fundus and pylorus Serotonin-IR cells

were detected throughout whole GI tract and they were

most predominant cell types in this species of mice

Gastrin-IR cells were restricted to the pylorus and CCK-8-Gastrin-IR cells

were demonstrated in the pylorus, duodenum and jejunum

with numerous frequencies in the pylorus Somatostatin-IR

cells were detected throughout whole GI tract except for the

cecum and rectum and they showed more numerous

frequencies in the stomach regions In addition,

glucagon-IR cells were restricted to the fundus, duodenum and

jejunum with rare frequencies, and HPP-IR cells were

restricted to the rectum only with rare frequency In

conclusion, some strain-dependent unique distributional

patterns of gastrointestinal endocrine cells were found in

GI tract of ddY mice.

Key words: Gastrointestinal tract, endocrine cell, ddY mouse,

immunohistochemistry, PAP method

Introduction

The ddY mouse is an closed colony albino mouse From non-inbred dd of Institute of Infectious Diseases, University

of Tokyo, 1953 [39], most suitable one among 6 strains was

tested for the culture of Clonorchis sinensis [16] Now it is

widely distributed and one of the most widely used inbred mouse strains in Japan and other countries This strain is particularly well known for the induction of osteoporosis by ovariectomy [42] and sciatic neurectomy [30]

Gastrointestinal endocrine cells dispersed in the epithelia and gastric glands of the digestive tract synthesized various kinds of gastrointestinal hormones and played an important role in the physiological functions of the alimentary tract [2] Until now, the investigation of gastrointestinal endocrine cells is considered to be an important part of a phylogenic study [5] In addition, the regional distributions and relative frequencies of these endocrine cells were varied with animal species and feeding habits [34] Many studies have elucidated the regional distribution and relative frequency of different endocrine cells in the gastrointestinal (GI) tract of the various vertebrates including various species of rodents, and also the researches or data processing about gastrointestinal endocrine cells in the mouse strains have been widely executed In the Rodentia, the localization of endocrine cells in the GI tract of the Manchurian chipmunk [23] and gerbil [26] was demonstrated, and the distribution

of the endocrine cells in the intestinal tract was also detected

in the Korean tree squirrel [22,24] And also endocrine cells

in the GI tract of homozygous obese mouse were

investigated [36,37] and Pinto et al [27] showed that the

gastrointestinal endocrine cells in genetically diabetic (db/ db) mouse had quite different distributional patterns compared to those of nondiabetic control (db/+) mouse In addition, the changes of regional distribution and relative frequency of some gastrointestinal endocrine cells in mice with ageing were also reported [31-33] and the regional distribution and relative frequency of gastrointestinal endocrine cells in hairless [21] and C57BL/6 [20] were also

*Corresponding author

Tel: 82-53-819-1436; Fax: 82-53-819-1574

E-mail: endohist@dhu.ac.kr

demonstrated Although many studies have elucidated the

regional distribution and relative frequency of different

endocrine cells in the GI tract of the various vertebrates

including various species and strains of rodents, the reports

dealing with the endocrine cells in GI tract of ddY mice

were seldom in spite of their biological, physiological and

anatomical differences from the other rodents and

usefulness in many research fields

The objective of this study was to clarify the regional

distribution and relative frequency of the endocrine cells in

the GI tract of ddY mice by specific immunohistochemistry

using 7 types of antisera against bovine chromogranin

(BCG), serotonin, gastrin, cholecystokinin (CCK)-8,

somatostatin, glucagon and human pancreatic polypeptide

(HPP)

Materials and Methods

Five adult female ddY mice (6-wk old, 24-26 g body

weight upon receipt) were acquired from Japan SLC

(Shizuoka, Japan) and used in this study after

acclimatization for one week Animals were allocated 5 per

C) and humidity (30-35%) controlled room during acclimatization periods

Light: dark cycle was 12hr: 12hr and feed (Samyang, Korea)

and water were supplied ad libitum.

After anesthetizing, the GI tract of mouse was divided into

8 portions according to general classification of mammalian

GI tract [29] For inducing gastric and/or intestinal empty,

animals were fasted about 24 hours After phlebotomization,

samples from the fundus, pylorus, duodenum, jejunum,

ileum, cecum, colon and rectum were fixed in Bouin's

were prepared Representative sections of each tissue were

stained with hematoxylin and eosin for light microscopic

examination of the normal gastrointestinal architecture

The each representative section was deparaffinized,

rehydrated and immunostained with the peroxidase-anti

reaction was performed with normal goat serum prior to

incubation with the specific antisera (Table 1) After rinsing

in phosphate buffered saline (PBS; 0.01 M, pH 7.4), the

sections were incubated in secondary antiserum They were then washed in PBS buffer and finally the PAP complex was prepared The peroxidase reaction was carried out in a solution 3,3'-diaminobenzidine tetrahydrochloride containing

immunostaining, the sections were lightly counterstained with Mayer's hematoxylin and the immunoreactive (IR) cells were observed under light microscope

The specificity of each immunohistochemical reaction was determined as recommended by Sternberger [38], including the replacement of specific antiserum by the same antiserum, which had been preincubated with its corresponding antigen The relative frequency of IR cell was

mean values were below 2/one field), a few (+; mean values were below 5/one field); moderate (++; mean values were below 10/one field) and numerous (+++; mean values were

up to 20/one field), according to their observed mean numbers as seen under one filed of light microscope (×200) and the observation of each regions of GI tract was conducted as triplet by 3 histologists

Results

In this study, all of seven kinds of the IR endocrine cells were detected with the antisera against BCG, serotonin, gastrin, CCK-8, somatostatin, glucagon and HPP in the GI tract of ddY mice (Table 2) According to the location of the

GI tract, different regional distributions and relative frequencies of these IR cells were observed and these differences are shown in Table 2 The regional distribution and relative frequency of gastrointestinal endocrine cells were varied with the GI tract, and some peculiar distributional patterns were found in ddY mice Most of these IR cells in the intestinal portions were generally spherical or spindle in shape (open typed cell), while occasionally round in shape (close typed cell) cells were also found in the intestinal gland and stomach regions

BCG-IR cells

BCG-IR cells were observed throughout the whole GI tract except for the cecum and they showed highest

Table 1 Antisera used in this study

Antisera raised1

BCG2

CCK-82

HPP2

1 All antisera were raised in rabbits; 2 BCG: bovine SP-1/chromogranin, CCK-8: cholecystokinin-8, HPP: human pancreatic polypeptide

frequencies in the fundus and pylorus (Table 2) Close typed

cells with rare frequencied open typed cells were dispersed

in the basal portions of the mucosa, between chief and

parietal cells, of the fundus with numerous frequency (Fig

1a, b) In the pylorus, close typed or occasionally open typed

BCG-IR cells were situated in the basal portions of the

gastric mucosa especially in the pyloric gland regions with

numerous frequency but no cells were observed in the upper

part of the pyloric mucosa and epithelial lining (Fig 1c, d)

In the duodenum, close typed cells were located in the intestinal glands, which were located in the basal portion of duodenal mucosa and open typed cells were located in the inter-epithelial cell regions with moderate frequency (Fig 1e) In the jejunum and ileum, open typed BCG-IR cells having long cytoplasmic process which was extended to the lumen, were mainly located in the inter-epithelial cell regions with moderate or a few frequencies, respectively and close typed cells were restricted to the intestinal gland

Table 2 Regional distributions and relative frequencies of the gastrointestinal endocrine cells in the gastrointestinal tract of the ddY

mice

Jej1

BCG2

+++3

-CCK-82

-Som2

-HPP2

1 Duo: duodenum, Jej: jejunum; 2 BCG: bovine SP-1/chromogranin, Som: somatostatin, HPP: human pancreatic polypeptide, CCK-8: cholecystokinin-8;

3 Relative frequencies; +++: numerous, ++: moderate, +: a few, ±: rare, -: not detected.

Fig 1 BCG-IR cells in the in the GI tract of ddY mice They were demonstrated in the fundus (a, b), pylorus (c, d), duodenum (e),

jejunum (f), ileum (g), colon (h) and rectum (i) but no cells were detected in the cecum Scale bars = 40µm PAP method

regions (Fig 1f, g) In the colon, open typed BCG-IR cells

were demonstrated in the inter-epithelial cell regions with a

few frequency (Fig 1h) and close typed cells were

demonstrated in the intestinal gland regions of the rectum

with rare frequency (Fig 1i) In the cecum, no BCG-IR cells

were detected in this study

Serotonin-IR cells

Serotonin-IR cells were observed throughout the whole

GI tract with variable relative frequencies in each portion of

the GI tract and they were predominant cell type in this

strain of mice (Table 2) In the fundus, open and close typed

cells were dispersed in the whole gastric mucosa, between

chief and parietal cells, with a few frequency (Fig 2a)

Although some open typed cells were also observed in the

relatively upper parts of pyloric gastric mucosa, most of

cells were mainly situated in the basal portions with

numerous frequency and they were poly-morphic but close

typed appearances (Fig 2b~d) In the small intestine,

serotonin-IR cells were demonstrated in the inter-epithelial

cells or intestinal glands, which were located in the basal

portion of mucosal layer with moderate to numerous

frequencies, respectively Open typed cells were restricted to the inter-epithelial cell regions while most of close typed cells were found in the intestinal gland regions (Fig 2eg) Similar to that of the small intestine, open and close typed serotonin-IR cells were widely dispersed in the mucosa of the large intestine (Fig 2h~j) with moderate to numerous frequencies, respectively

Gastrin- and CCK-8-IR cells

Gastrin-IR cells were restricted to the pylorus with numerous frequency (Table 2) Close typed gastrin-IR cells were exclusively located in the basal portion of pyloric gastric mucosa but occasionally open typed cells were situated in that regions mixed with close type cells (Fig 3a, b)

CCK-8-IR cells were detected in the pylorus, duodenum and jejunum with numerous, a few and rare frequencies, respectively (Table 2) In the pylorus, CCK-8-IR cells were located in the basal portion of pyloric gastric mucosa with numerous frequency and most of these cells were close typed cells but occasionally open typed cells were situated in that regions mixed with close-typed cells similar to that of gastrin-IR cells (Fig 3c, d) Open and close typed cells were

Fig 2 Serotonin-IR cells in the in the GI tract of ddY mice These IR cells were located in the epithelium and gastric or intestinal gland

regions of the fundus (a), pylorus (b~d), duodenum (e), jejunum (f), ileum (g), cecum (h), colon (i) and rectum (j) Scale bars = 40µm PAP method

demonstrated in the inter-epithelial cell and intestinal gland

regions of the duodenum (Fig 3e) and open typed

CCK-8-IR cells were restricted to the inter-epithelial cell regions of

the jejunum (Fig 3f) However, no gastrin- and CCK-8-IR

cells were observed in the remaining portions of the GI tract

of this strain of mice

Somatostatin-IR cells

Somatostatin-IR cells were demonstrated throughout the

whole GI tract except for the cecum and rectum, and they

showed highest frequencies in the fundus and pylorus (Table

2) They were dispersed in the whole gastric mucosa,

between chief and parietal cells (Fig 4a) However, close

typed cells were exclusively located in the basal portion of

pyloric gastric mucosa but occasionally open typed cells

were situated in that regions mixed with close type cells

(Fig 4b) In the duodenum (Fig 4c, d), jejunum (Fig 4e, f)

and ileum (Fig 4g), open typed cells having long cytoplasmic processes were located in the inter-epithelial cell regions with a few frequencies, respectively However,

no close typed cells were demonstrated in that portion of the

GI tract In the colon, open typed somatostatin-IR cells were detected in the inter-epithelial cell regions with rare frequency (Fig 1h)

Glucagon-IR cells

Close typed glucagon-IR cells were restricted to the fundus, duodenum and jejunum with rare frequencies (Table 2) In the fundus, they were located in the gastric mucosa between chief and parietal cells (Fig 5a) In the duodenum (Fig 5b) and jejunum (Fig 5c), close typed glucagon-IR cells were demonstrated in the basal regions of the epithelial lining

HPP-IR cells

Open typed HPP-IR cells were restricted to the inter-epithelial cell regions of the rectum (Fig 6a, b) with rare frequency (Table 2)

Discussion

It is generally accepted that the endocrine cells in the alimentary tracts appeared remarkably different depending

on the regional distribution, relative frequency, cell types with animal species and each regional part of the GI tract In addition, many studies have elucidated the regional distribution and relative frequency of different endocrine cells in the GI tract of the various vertebrates including various species of rodents Also the researches or data processing about gastrointestinal endocrine cells in the mice strains have been widely executed [20,21,27,37] The gastrointestinal endocrine cells were generally divided into two types, one was round to spherical shaped close typed cells which were located in the stomach regions, and the other was spherical to spindle shaped open typed cells which were situated in the intestinal regions In this study, close typed cells were mainly located in the gastric or intestinal gland regions whereas most of open typed cells were found

in the epithelial regions of ddY mice

Chromogranin (CG) belongs to a family of large anionic proteins (CG A, B and secretogranin), the members of which are known to be present in the secretory granules of a broad spectrum of amine and peptide-producing cells of adrenal medulla and gastrointestinal endocrine system, as well as in some neurons of the peptidergic and catecholaminergic nervous system of several mammals [12, 28] CGs have been found to occur in large variety of endocrine organs and cells outside the adrenal medulla, and they have been claimed as common “markers” of all neuroendocrine cells [4,11] Although, the distributional patterns of these CG-IR cells in the GI tract of Rodentia

Fig 3 Gastrin- and CCK-8-IR cells in the GI tract of ddY mice.

Gastrin-IR cells were restricted to the pylorus (a, b), and

CCK-8-IR cells were demonstrated in the pylorus (c, d), duodenum (e)

and jejunum (f) Scale bars = 40µm PAP method

were seldom, Hawkins et al [14] reported that CGA-IR

cells were demonstrated throughout the whole GI tract of 7

species of laboratory animals including mouse In the

present study, BCG-IR cells were detected throughout the

whole GI tract of ddY mice except for the cecum These

results were, well corresponded to those of previous studies

[12,14,28] However, it is considered that single use of BCG

is not suitable as a marker of endocrine cells because the

relative frequencies of BCG-IR cells were not detected or

lower than those of serotonin- and other IR cells in case of

some regions If mixed or concomitantly immunostained

with other types of CGs, it is considered that CGs are

suitable as marker of other endocrine cells in this strain of

mouse similar to that of C57BL/6 mouse [20]

Serotonin, consisted of monoamines, was widely

distributed in nervous system and in gastric epithelial

endocrine cells [9] The main functions of serotonin were

inhibition of gastric acid secretion and contraction of

smooth muscle in the GI tract [13] El-Salhy et al [9]

reported that serotonin-IR cells were detected throughout

the GI tract of all species and established in the GI tract at

the early stage of vertebrate evolution In addition, these IR

cells were detected in the whole alimentary tract including

esophagus of low vertebrates [19] Serotonin-IR cells were

detected in the whole GI tract of the gerbil [26], common

chipmunk [25], rat [15] and several strains of mice [20,21,

33] In the present study, serotonin-IR cells were detected

throughout the whole GI tract and they were most

predominant endocrine cell types in ddY mice These results

were considered as similar to most of other mammals [1,15,

20,21,25,26,31,41] However, it is considered that

serotonin-IR cells in this strain of mouse showed somewhat higher relative frequency than those of other mammals especially other rodents [20,21]

It is generally accepted that gastrin and CCK-8 originated from the same ancestor and in the human duodenum a large fraction of these cells, besides reacting with non-C terminal CCK antibodies and C-terminal gastrin/CCK antibodies, also show immunoreactivity with C-terminal gastrin-34 antibodies, colocalised with CCK in a variable portion of secretory granules [35] Gastrin secretion by intestinal G cell promotes gastric acid secretion, and CCK secretion by intestinal I cell stimulates the secretion of pancreatic enzyme secretion In present study, gastrin-IR cells were restricted to the pylorus and CCK-8-IR cells were demonstrated in the pylorus, duodenum and jejunum of ddY mice and these results were well corresponded to those of hairless mice [21] and C57BL/6 mice [20] Generally, it is well known that gastrin- and CCK-8-IR cells were located in the gastric mucosa and whole small intestinal tract in mammals

[18,41] However, Lee et al., [22] reported that

gastrin/CCK-IR cells were abundant in the pyloric gland region but scarce

in the duodenum and no cells were found in the other gastrointestinal regions of the Korean tree squirrel In the GI tract of gerbil [26], gastrin-IR cells were restricted to the pylorus and CCK-8-IR cells were located in the pylorus and duodenum similar to that of Korean tree squirrel Although somewhat different aspects were also demonstrated, these results were well corresponded to those of present study However, in the GI tract of Manchurian chipmunk,

gastrin-IR cells were demonstrated from the fundus to ileum and CCK-8-IR cells were detected from the duodenum to ileum [23] These differences were considered that it might be due

Fig 4 Somatostatin-IR cells in the GI tract of ddY mice Somatostatin-IR cells were demonstrated in the fundus (a), pylorus (b), duodenum

(c, d), jejunum (e, f), ileum (g) and colon (h) but no cells were detected in the cecum and rectum Scale bars = 40µm PAP method

to the differences of the antisera tested or the methods and/or

species differences used in the each study [6,7,40]

Somatostatin, consisting of 14 amino acids, was first

isolated from hypothalamus of sheep and can be divided into

straight form and cyclic form [3] This substance inhibits the

secretion of the other neuroendocrine hormones [17] It is

known that somatostatin-IR cells show the widest

distribution in the whole GI tract except for the large

intestine of all vertebrate species investigated, including the

primitive agnathans with serotonin-IR cells [10] However,

somewhat species-dependent variations on the distributional

pattern of these IR cells have been reported In the GI tract

of Manchurian chipmunk, they were detected throughout

the whole GI tract and showed the highest frequencies in the

pylorus [25] but they were restricted to the pylorus of the

gerbil [26] In mice strains, somatostatin-IR cells decrease in

the duodenum of NMRI mice with age [31] and in the

antrum of diabetic mouse regardless of their obesity [8,37]

In hairless [21] and C57BL/6 mice [20], somatostatin-IR cells were demonstrated from fundus to ileum and showed highest frequency in the fundus In the present study, somatostatin-IR cells were detected throughout the whole

GI tract except for cecum and rectum These results were somewhat similar to those of other mouse strains [8,20,21, 37] and the Manchurian chipmunk [25] but quite different from those of the gerbil [26]

Glucagon is synthesized in the A cells of the pancreas and regulates serum glucose levels These IR cells have been demonstrated in various mammals They were demonstrated

in the whole GI tract of the common tree shrew [41] and

persisted that these

IR cells were only detected in the intestinal tract of the

Philippine carabao and Lee et al [22] reported that they

were restricted to the cardia and fundus of the Korean tree squirrel In addition, glucagon-IR cells were detected in the stomach and small intestine of Manchurian chipmunk [23] and they were restricted to the fundus with relatively low frequencies in hairless mice [21] In addition, they were restricted to the fundus, ileum and colon [20] Collectively it

is considered that the distributional patterns of glucagon-IR cells in the GI tract of the mammals show species-dependent variation Especially, appearances of these IR cells in large intestine were also reported in mouse [31,32] However, no glucagon-IR cells were demonstrated in the GI tract of the gerbil [26] In the present study, glucagon-IR cells were restricted to the fundus, duodenum and jejunum with rare

Fig 5 Glucagon-IR cells in the GI tract of ddY mice Close typed

glucagon-IR cells were restricted to the fundus (a), duodenum (b)

and jejunum (c) Scale bars = 40µm PAP method

Fig 6 HPP-IR cells in the GI tract of ddY mice Open typed

HPP-IR cells were restricted to the rectum (a, b) Scale bars =

40µm PAP method

frequencies, respectively These findings were somewhat

different from those of previous studies [18,20-23,26,31,32,

41] and these differences were considered as species and/or

strain-dependent variations

Since PP was isolated from insulin extraction of pancreas

at 1961, the regional distribution of PP-IR cells in the

mammalian species was relatively well known but

species-dependant differences existed among the mammals [1,22,

25,26,41] These IR cells were demonstrated from the

fundus to the jejunum of the Manchurian chipmunk [25] and

restricted to the fundus of C57BL/6 mice [20] but no cells

were detected in the GI tract of gerbil [26] and hairless

mouse [21] In the present study, somewhat differed from

that of other rodents, HPP-IR cells were restricted to the

rectum with rare frequency

In conclusion, the regional distribution and relative

frequency of the GI tract endocrine cells in the ddY mice is

similar to that of other rodents However, strain-dependent

unique distributional patterns of gastrointestinal endocrine

cells were also found in ddY mice especially to the CCK-8-,

glucagons- and PP-IR endocrine cells

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