Expression of enhancing factor gene and its localization in mouse tissues.

Enhancing factor (EF), a 14 kDa protein, isolated from mouse small intestines, has been reported from this laboratory. Based on our earlier studies EF has been implicated in cell proliferation. Preliminary immunohistochemical studies have shown EF to be localized in the Paneth cells of small intestines. In this paper we report the tissue distribution of EF using conditions optimized for immunohistochemical staining. In addition, the data are supported by northern blot analysis using a nick translated cDNA probe specific for EF. The results indicate that EF gene is actively transcribed mainly in the intestines. The chief source of synthesis of EF appears to be the Paneth cells located at the base of the crypts of Lieberkühn.     

Ontogeny of enhancing factor in mouse intestines and skin

Summary Enhancing Factor (EF) is a 14 kDa protein isolated from mouse small intestines, which enhances the binding of ¹²⁵I-EGF to A431 cells. This observation as well as our earlier in vitro studies have indicated that EF is a modulator of EGF. In adult mice, localization of EF by immunohistochemistry shows it is present pre-dominantly in the Paneth cells of the small intestines and to a lesser extent in the stomach and colon. This study of the ontogeny of EF shows that the appearance of the protein coincides with the appearance of mature Paneth cells. In new born mouse skin EF is localized in the hair follicles in the first hair cycle from day 2 to day 8. It is however absent in the adult skin. Thus EF is associated with tissues which have a high growth rate.     

Ontogeny of enhancing factor in mouse intestines and skin.

Enhancing Factor (EF) is a 14 kDa protein isolated from mouse small intestines, which enhances the binding of 125I-EGF to A431 cells. This observation as well as our earlier in vitro studies have indicated that EF is a modulator of EGF. In adult mice, localization of EF by immunohistochemistry shows it is present predominantly in the Paneth cells of the small intestines and to a lesser extent in the stomach and colon. This study of the ontogeny of EF shows that the appearance of the protein coincides with the appearance of mature Paneth cells. In new born mouse skin EF is localized in the hair follicles in the first hair cycle from day 2 to day 8. It is however absent in the adult skin. Thus EF is associated with tissues which have a high growth rate.     

Expression of enhancing factor/phospholipase A2 in ICRC mice

Enhancing factor (EF), a growth factor modulator, recently identified as the mouse secretory phospholipase A₂ (PLA₂), has been isolated in our laboratory from the intestines of mice. EF modulates the action of epidermal growth factor (EGF) by mediating an almost 2-fold increase in EGF binding in a radioreceptor assay. EF has been localized immunohistochemically to the Paneth cells of the intestine, adjacent to the proliferating stem cell population. Although very weak staining was observed in the intestines of ICRC mice (ICRC is an inbred strain of mouse developed at this Institute) as compared to Balb/c mice, the enhancing activity was not detected in the partially purified, acid soluble intestinal proteins of the ICRC strain. However, studies using polyclonal antibodies against purified EF demonstrated that EF from Balb/c and ICRC intestines are either immunologically identical or closely related to each other although, quantitatively, EF was very low in ICRC mice. RFLP studies indicated that ICRC mice carry a mutation in the coding region of the EF gene resulting in loss of the BamHI. restriction site. On sequencing, a T insertion was found at position 166 from the ATG site thereby causing a disruption in the ORF. This probably results in undetectable levels of enhancing activity. In this paper we report the molecular characterization of the ICRC mouse with respect to theenhancing factor gene     

Trace amounts of enhancing factor/phospholipase A2 in mouse peritoneal exudate cells

Enhancing factor (EF), a mouse phospholipase A₂ (PLA₂), has been purified from the small intestines, based on its ability to increase the binding of epidermal growth factor in a radioreceptor assay. EF/PLA₂ was found to be localized predominantly in the Paneth cells in the small intestines. Whether mouse intestinal EF/PLA₂ is identical/similar to mouse secretory PLA₂ was to be determined. Phospholipases are known to play a crucial role in the process of inflammation. This paper reports the presence of trace amounts of EF/PLA₂ in the peritoneal exudate cells. Western blot analysis of the acid extracts showed the presence of a 14 kDa immunologically cross-reactive protein. RT-PCR analysis using EF specific primers amplified a ∼700 bp product which was further confirmed to be EF-specific by nested PCR analysis and sequencing. Presence of EF in the peritoneal exudate cells could be a unique mode of transport of growth factor modulator to the site of injury to aid in regeneration/cell proliferation of damaged tissue.     

Slow cycling intestinal stem cell and Paneth cell responses to Trichinella spiralis infection

There is limited information regarding responses by slow cycling stem cells during T. spiralis-induced T-cell mediated intestinal inflammation and how such responses may relate to those of Paneth cells. Transgenic mice, in which doxycycline induces expression of histone 2B (H2B)-green fluorescent protein (GFP), were used. Following discontinuation of doxycycline (“chase” period), retention of H2B-GFP enabled the identification of slow cycling stem cells and long-lived Paneth cells. Inflammation in the small intestine (SI) was induced by oral administration of T. spiralis muscle larvae. Epithelial retention of H2B-GFP per crypt cell position (cp) was studied following immunohistochemistry and using the Score and Wincrypts program. Compared to non-infected controls, there was significant reduction in the number of H2B-GFP-retaining stem cells in T. spiralis-infected small intestines. H2B-GFP-retaining stem cells peaked at around cp 4 in control sections, but smaller peaks at higher cell positions (>10) were seen in sections of inflamed small intestines. In the latter, there was a significant increase in the total number of Paneth cells, with significant reduction in H2B-GFP-retaining Paneth cells, but a marked increase in unlabelled (H2B-GFP-negative) Paneth cells. In conclusion, following T. spiralis-infection, putative slow cycling stem cell numbers were reduced. A marked increase in newly generated Paneth cells at the crypt base led to higher cell positions of the remaining slow cycling stem cells.     

Paneth cells: histochemical and morphometric study in control and Solanum glaucophyllum intoxicated rabbits

The intestinal epithelium has a critical roll in host defence. One specialised cell type involved in this function is the Paneth cell, which secretes many substances with antimicrobial properties in response to different stimuli. Under pathological conditions, changes in the Paneth cell number, morphology and location as well as in granule number, morphology and composition have been reported. In the normal animal, 1,25-dihydroxyvitamin D3 participates in the maintenance of mineral homeostasis, immunomodulation and cell proliferation and differentiation. Solanum glaucophyllum, a calcinogenic plant containing high levels of 1,25-dihydroxyvitamin D3, is responsible for a condition known as enzootic calcinosis in ruminants, characterised by loss of body condition and mineralization of soft tissues. Using and established rabbit model, this study analyses the changes that rabbit Paneth cells undergo during intoxication with S. glaucophyllum. Male New Zealand white rabbits were experimentally intoxicated with S. glaucophyllum for 15 or 30 days. Lectin, immunohistochemical and morphometric studies were carried out on Paneth cells from samples of jejunum. SBA, DBA and WGA lectins bound to Paneth cells-granules in both normal and intoxicated rabbits, with more heterogenity in the labelling of granules from intoxicated rabbits. Paneth cells in both groups were immunonegative for lysosyme. A time and dose-dependent increase in the size and number of Paneth cells was found in both intoxicated groups. We suggest that the changes described in these cells may be directly or indirectly induced by S. glaucophyllum intoxication.     

新生BALB/c小鼠肠道潘氏细胞的分布规律

观察BALB/c小鼠小肠潘氏细胞的分布规律。应用石蜡切片、H&E染色技术和LeicaQwin显微图像处理系统,分别对2 d、4 d、6 d、8 d、10 d BALB/c小鼠小肠内潘氏细胞的形态发育、分布规律进行观察和分析。结果发现,4日龄前的BALB/c小鼠各段小肠中肠腺发育尚不完整,未见有潘氏细胞。6日龄后,潘氏细胞开始出现,数量随日龄增加呈递增趋势增长,各日龄间差异显著(P<0.05)。BALB/c小鼠肠道潘氏细胞存在于小肠,十二指肠和空肠较少,回肠较多,各组(不同日龄/肠段)之间差异显著(P<0.05)。     

Purification of the enhancing factor from mouse intestines

A unique polypeptide, called enhancing factor (EF), which enhances the binding of labeled epidermal growth factor (EGF) to cells, has been isolated. It has been purified to homogeneity from the acid-soluble proteins of mouse intestines. Earlier, EF was partially purified by two cycles of gel-permeation chromatography on Bio-Gel columns. We now report the final purification of EF on high-performance liquid chromatography (HPLC), using a reverse-phase column (mu Bondapak C18). The purity of the protein was confirmed when a single peak was obtained in HPLC. Also, a single protein band was obtained in SDS-PAGE. Purified EF has the same properties in vitro as those reported earlier for partially purified EF.     

Immunohistochemical localization of epidermal growth factor in rat and man

Epidermal growth factor (EGF) is a peptide which stimulates cell mitotic activity and differentiation, has a cytoprotective effect on the gastroduodenal mucosa, and inhibits gastric acid secretion. The immunohistochemical localization of EGF in the Brunner's glands and the submandibular glands is well documented. The localization of EGF in other tissues is still unclarified. In the present study, the immunohistochemical localization of EGF in tissues from rat, man and a 20 week human fetus were investigated. In man and rat, immunoreaction was found in the submandibular glands, the serous glands of the nasal cavity, Brunner's glands of the duodenum, the Paneth cells of the small intestine, and the tubular cells of the kidney. In the fetus EGF was found in the kidney and in the intestinal Paneth cells. Antisera raised against rat submandibular EGF did not recognize EGF in human tissues, whereas antisera against human urinary EGF worked in rat as well as man. EGF was found only in cells with an exocrine function.     

The stem cells of small intestinal crypts: where are they?

Recently, there has been resurgence of interest in the question of small intestinal stem cells, their precise location and numbers in the crypts. In this article, we attempt to re-assess the data, including historical information often omitted in recent studies on the subject. The conclusion we draw is that the evidence supports the concept that active murine small intestinal stem cells in steady state are few in number and are proliferative. There are two evolving, but divergent views on their location (which may be more related to scope of capability and reversibility than to location) several lineage labelling and stem cell self-renewing studies (based on Lgr5 expression) suggest a location intercalated between the Paneth cells (crypt base columnar cells (CBCCs)), or classical cell kinetic, label-retention and radiobiological evidence plus other recent studies, pointing to a location four cell positions luminally from the base of the crypt The latter is supported by recent lineage labelling of Bmi-1-expressing cells and by studies on expression of Wip-1 phosphatase. The situation in the human small intestine remains unclear, but recent mtDNA mutation studies suggest that the stem cells in humans are also located above the Paneth cell zone. There could be a distinct and as yet undiscovered relationship between these observed traits, with stem cell properties both in cells of the crypt base and those at cell position 4.     

Immunohistochemical localization of epidermal growth factor in rat and man

Summary Epidermal growth factor (EGF) is a peptide which stimulates cell mitotic activity and differentiation, has a cytoprotective effect on the gastroduodenal mucosa, and inhibits gastric acid secretion.The immunohistochemical localization of EGF in the Brunner's glands and the submandibular glands is well documented. The localization of EGF in other tissues is still unclarified.In the present study, the immunohistochemical localization of EGF in tissues from rat, man and a 20 week human fetus were investigated. In man and rat, immunoreaction was found in the submandibular glands, the serous glands of the nasal cavity, Brunner's glands of the duodenum, the Paneth cells of the small intestine, and the tubular cells of the kidney. In the fetus EGF was found in the kidney and in the intestinal Paneth cells.Antisera raised against rat submandibular EGF did not recognize EGF in human tissues, whereas antisera against human urinary EGF worked in rat as well as man. EGF was found only in cells with an exocrine function.     

潘氏细胞研究进展

潘氏细胞是位于小肠腺底部的浆液性腺上皮细胞,其主要特征是细胞顶部有大量粗大的嗜酸性分泌颗粒,内含防御素、溶菌酶、sIgA等多种抗菌物质。表达于潘氏细胞的NOD2、Toll样受体9、肝癌-肠-胰腺／胰腺炎相关蛋白、RegⅢγ、肿瘤坏死因子仅、粒细胞-巨噬细胞集落刺激因子、白介素-17等也是免疫与炎症反应的重要成分。金属硫蛋白、富半胱氨酸肠蛋白、潘氏细胞锌结合蛋白等金属结合蛋白均分布于潘氏细胞,提示潘氏细胞参与金属代谢。潘氏细胞是构成肠黏膜屏障的重要细胞成分。NOD2单核苷酸多态性与克罗恩病有关。潘氏细胞化生常发生于胃、大肠的炎症与肿瘤病变,其病理意义有待于进一步研究。     

A genetic study of the role of the Wnt/beta-catenin signalling in Paneth cell differentiation

Wnt/β-catenin signalling plays a key role in the homeostasis of the intestinal epithelium. Whereas its role in the maintenance of the stem cell compartment has been clearly demonstrated, its role in the Paneth cell fate remains unclear. We performed genetic studies to elucidate the functions of the Wnt/β-catenin pathway in Paneth cell differentiation. We analysed mice with inducible gain-of-function mutations in the Wnt/β-catenin pathway and mice with a hypomorphic β-catenin allele that have not been previously described. We demonstrated that acute activation of Wnt/β-catenin signalling induces de novo specification of Paneth cells in both the small intestine and colon and that colon cancers resulting from Apc mutations expressed many genes involved in Paneth cell differentiation. This suggests a key role for the Wnt/β-catenin pathway in Paneth cell differentiation. We also showed that a slight decrease in β-catenin gene dosage induced a major defect in Paneth cell differentiation, but only a modest effect on crypt morphogenesis. Overall, our findings show that a high level of β-catenin activation is required to determine Paneth cell fate and that fine tuning of β-catenin signalling is critical for correct Paneth cell lineage.     

Immunohistochemical characterization of a crypt cell-specific plasma membrane protein in rat small intestine epithelium using a monoclonal antibody

Proteins of the basolateral membrane (BLM) of small intestine epithelial cells of adult rats, in the MW ranges of 50-65 KD, 85-100 KD, and over 100 KD, were obtained as follows. After isolation of the BLM and subsequent SDS-PAGE and transblotting of the proteins on nitrocellulose sheets, the bands in these MW ranges were cut out of the nitrocellulose sheet and extracted. Balb/C mice were immunized with these protein fractions and a monoclonal antibody (MAb) was then produced. MAb SI/CC1 obtained via immunization with the 50-65 KD protein fraction shows specificity for the crypt epithelium of the small intestine. It can be used to characterize, by light and electron microscopic immunohistochemical methods, a crypt cell protein (SI/CC1-Ag) with a very specific localization. Fluorescence labeling shows that the SI/CC1-Ag can be found only in the epithelium of small intestine crypts (except for the granules in eosinophilic granulocytes). The epithelium of the colon, as well as the epithelia of other organs, could not be labeled. In the small intestine crypts, SI/CC1-Ag is found only in the Paneth cells located in the basal crypt section, and in the undifferentiated cells in the middle crypt section; it is lacking in the cells of the upper crypt section. Gold labeling shows that SI/CC1-Ag in the undifferentiated cells is localized exclusively in the basolateral PM domain. On the Paneth cells, the content of the secretory granules is labeled, along with the basolateral PM domain; the labeling sometimes present on their luminal part is probably due to passively absorbed secretion from these cells. The SI/CC1-Ag in the BLM of undifferentiated and Paneth cells is found only on Days 21-23 post partum, whereas the Paneth cell granules could be labeled as early as the Day 16 post partum. With immunodetection with SI/CC1, one band at about 55 KD is specifically labeled in the protein pattern of the isolated small intestine cell BLM. In the protein pattern of the isolated crypt cells two bands were labeled, again one at 55 KD and one at about 120 KD. These findings indicate that SI/CC1-Ag is a 55 KD protein that appears on Days 21-23 post partum in the BLM of undifferentiated cells and of Paneth cells.     

Gut commensal bacteria,Paneth cells and their relations to radiation enteropathy

In steady state, the intestinal epithelium forms an important part of the gut barrier to defend against luminal bacterial attack. However, the intestinal epithelium is compromised by ionizing irradiation due to its inherent self-renewing capacity. In this process, small intestinal bacterial overgrowth is a critical event that reciprocally alters the immune milieu. In other words, intestinal bacterial dysbiosis induces inflammation in response to intestinal injuries, thus influencing the repair process of irradiated lesions. In fact, it is accepted that commensal bacteria can generally enhance the host radiation sensitivity. To address the determination of radiation sensitivity, we hypothesize that Paneth cells press a critical “button” because these cells are central to intestinal health and disease by using their peptides, which are responsible for controlling stem cell development in the small intestine and luminal bacterial diversity. Herein, the most important question is whether Paneth cells alter their secretion profiles in the situation of ionizing irradiation. On this basis, the tolerance of Paneth cells to ionizing radiation and related mechanisms by which radiation affects Paneth cell survival and death will be discussed in this review. We hope that the relevant results will be helpful in developing new approaches against radiation enteropathy.     

Identification of xanthine dehydrogenase/xanthine oxidase as a rat Paneth cell zinc-binding protein

Paneth cells are zinc-containing cells localized in small intestinal crypts, but their function has not been fully elucidated. Previously, we showed that an intravenous injection of diphenylthiocarbazone (dithizone), a zinc chelator, induced selective killing of Paneth cells, and purified a zinc-binding protein in Paneth cells. In the present study, we further characterized one of these proteins, named zinc-binding protein of Paneth cells (ZBPP)-1. Partial amino acid sequences of ZBPP-1 showed identity with rat xanthine dehydrogenase (XD)/xanthine oxidase (XO). Anti-rat XD antibody (Ab) recognized ZBPP-1, and conversely anti ZBPP-1 Ab recognized 85 kDa fragment of rat XD in Western blotting. Messenger RNA and protein levels of XD were consistent with our previous data on the fluctuation of Paneth cell population after dithizone injection. Thus, ZBPP-1 is an 85 kDa fragment of XD/XO in Paneth cells. XD/XO in Paneth cells may play important roles in intestinal function.