The human proteome in stomach (original) (raw)
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Stomach
The stomach-specific proteome
The stomach is the first reservoir for food intake and is limited by the cardia at the esophageal-stomach junction and pylorus at the stomach-duodenal junction. The main function of the stomach is to digest food by providing an acidic milieu and secretion of digestive enzymes. The acidic environment ensures enzyme activity and provides a barrier against ingested microorganisms. Food is mechanically processed into chyme via muscular contortions and slowly released to the duodenum for further breakdown and nutrient uptake. The stomach mucosa consists of a number of specialized cell types including chief cells, parietal cells, mucous producing cells and endocrine cells. Transcriptome analysis shows that 72% (n=14516) of all human proteins (n=20162) are expressed in the stomach and 321 of these genes show an elevated expression in the stomach compared to other tissue types.
- 321 elevated genes
- 35 enriched genes
- 81 group enriched genes
- Stomach has most group enriched gene expression in common with intestine
The stomach transcriptome
Transcriptome analysis of the stomach can be visualized with regard to the specificity and distribution of transcribed mRNA molecules (Figure 1). Specificity illustrates the number of genes with elevated or non-elevated expression in the stomach compared to other tissues. Elevated expression includes three subcategory types of elevated expression:
- Tissue enriched: At least four-fold higher mRNA level in stomach compared to any other tissues.
- Group enriched: At least four-fold higher average mRNA level in a group of 2-5 tissues compared to any other tissue.
- Tissue enhanced: At least four-fold higher mRNA level in stomach compared to the average level in all other tissues.
Distribution, on the other hand, visualizes how many genes have, or do not have, detectable levels (nTPM≥1) of transcribed mRNA molecules in the stomach compared to other tissues. As evident in Table 1, all genes elevated in stomach are categorized as:
- Detected in single: Detected in a single tissue
- Detected in some: Detected in more than one but less than one-third of tissues
- Detected in many: Detected in at least a third but not all tissues
- Detected in all: Detected in all tissues
Figure 1. (A) The distribution of all genes across the five categories based on transcript specificity in stomach as well as in all other tissues. (B) The distribution of all genes across the six categories, based on transcript detection (nTPM≥1) in stomach as well as in all other tissues.
As shown in Figure 1, 321 genes show some level of elevated expression in the stomach compared to other tissues. The three categories of genes with elevated expression in stomach compared to other organs are shown in Table 1. In Table 2, the 12 genes with the highest enrichment in stomach are defined.
Table 1. The number of genes in the subdivided categories of elevated expression in stomach.
Distribution in the 36 tissues | ||||||
---|---|---|---|---|---|---|
Detected in single | Detected in some | Detected in many | Detected in all | Total | ||
Specificity | Tissue enriched | 3 | 17 | 14 | 1 | 35 |
Group enriched | 0 | 43 | 37 | 1 | 81 | |
Tissue enhanced | 4 | 58 | 130 | 13 | 205 | |
Total | 7 | 118 | 181 | 15 | 321 |
Table 2. The 12 genes with the highest level of enriched expression in stomach. "Tissue distribution" describes the transcript detection (nTPM≥1) in stomach as well as in all other tissues. "mRNA (tissue)" shows the transcript level in stomach as nTPM values. "Tissue specificity score (TS)" corresponds to the fold-change between the expression level in stomach and the tissue with the second-highest expression level.
Gene | Description | Tissue distribution | mRNA (tissue) | Tissue specificity score |
---|---|---|---|---|
PGA5 | pepsinogen A5 | Detected in many | 38780.0 | 2028 |
CBLIF | cobalamin binding intrinsic factor | Detected in single | 1533.7 | 1873 |
GKN1 | gastrokine 1 | Detected in many | 36428.6 | 1856 |
PGA4 | pepsinogen A4 | Detected in many | 64644.4 | 1277 |
PGA3 | pepsinogen A3 | Detected in many | 86662.3 | 613 |
GAST | gastrin | Detected in some | 9294.1 | 167 |
ATP4B | ATPase H+/K+ transporting subunit beta | Detected in some | 1067.1 | 152 |
LIPF | lipase F, gastric type | Detected in many | 36201.8 | 142 |
MUC5AC | mucin 5AC, oligomeric mucus/gel-forming | Detected in some | 180.4 | 102 |
ATP4A | ATPase H+/K+ transporting subunit alpha | Detected in some | 819.1 | 83 |
GKN2 | gastrokine 2 | Detected in some | 4488.5 | 57 |
TFF1 | trefoil factor 1 | Detected in many | 7747.8 | 48 |
Protein expression of genes elevated in stomach
In-depth analysis of the elevated genes in the stomach using antibody-based protein profiling allowed us to visualize the protein expression patterns in the stomach with respect to cellular compartments. In the list of stomach elevated genes multiple protein locations are found; GKN1 is localized to the superficial layer of the gastric mucosa, CBLIF show clear relation to parietal cells and PGC is predominant in chief cells.
GKN1 - gastric mucosa
CBLIF - parietal cells
PGC - chief cells
Gene expression shared between stomach and other tissues
There are 81 group enriched genes expressed in stomach. Group enriched genes are defined as genes showing a 4-fold higher average level of mRNA expression in a group of 2-5 tissues, including stomach, compared to all other tissues.
To illustrate the relation of stomach tissue to other tissue types, a network plot was generated, displaying the number of genes with a shared expression between different tissue types.
Figure 2. An interactive network plot of the stomach enriched and group enriched genes connected to their respective enriched tissues (grey circles). Red nodes represent the number of stomach enriched genes and orange nodes represent the number of genes that are group enriched. The sizes of the red and orange nodes are related to the number of genes displayed within the node. Each node is clickable and results in a list of all enriched genes connected to the highlighted edges. The network is limited to group enriched genes in combinations of up to 3 tissues, but the resulting lists show the complete set of group enriched genes in the particular tissue.
The stomach shares most group enriched gene expression with intestinal tissues like small intestine and duodenum. One example of a protein enriched in the stomach and duodenum is REP15, encoding a protein involved in recycling of the transferrin receptor to the cell surface. REP15 is expressed in gastric mucosa in the stomach and glandular cells in the duodenum.
REP15 - stomach
REP15 - duodenum
Stomach histology
The stomach lies in the upper part of the abdomen between the esophagus and duodenum which forms the most proximal portion of the small intestine. It mixes food with gastric enzymes and fluids, converting the contents to a semi-fluid mass of partly digested food (chyme). The chyme is then slowly passed to the duodenum for further breakdown and absorption.
The stomach is a direct continuation of the esophagus and can be divided into different regions; the most proximal part is the cardia, followed by the fundus, corpus, antrum and pylorus. The fundus and corpus constitute about 80% of the stomach and differ from the antrum and pylorus both functionally and histologically. At the gastroesophageal junction the mucosa abruptly changes from a stratified squamous epithelium to simple cuboidal. The mucosa is thick and lined with simple columnar epithelium. The surface epithelium invaginates, creating gastric pits into which the fundus glands open. The fundus glands are straight glands that extend from the lowest portion of the mucosa to their opening at the bottom of the gastric pits. The fundic glands stain darker compared to the gastric pits. In the stomach, the lamina muscularis mucosae consist of two layers of smooth muscle and can easily be recognized. The submucosa is a thick layer of loose connective tissue with numerous blood and lymphatic vessels. Villous folds separate the gastric pits and display a connective tissue core, which is part of the lamina propria mucosae. The gastric pits are lined by pale stained simple columnar epithelium which secretes mucus into the stomach lumen. This mucus protects the stomach wall from the acidic gastric contents. A mucinous globule is typically present in the apical portion of the cells with an oval-shaped nucleus. The fundus glands have a narrow neck, a middle principal part and a lower base. In the neck portion, mucous neck cells are located. Their cytoplasm stain poorly with hematoxylin and eosin, but they can be recognized by their round nuclei. They secrete acidic mucus. In the principal part, parietal (oxyntic) cells are located. They have a strongly eosinophilic cytoplasm and a round, centrally located nucleus. They secrete hydrochloric acid and intrinsic factor. At the base of the glands, strongly basophilic cells are present. These are the chief cells that secrete large amounts of pepsinogen, a proteolytic enzyme.
The distal portion of the stomach, or the pylorus, connects the stomach to the duodenum. It has the same general structure as the fundus and body of the stomach with epithelial lined villous folds that invaginate into gastric pits. The cells lining the villous folds are surface mucous cells that produce alkaline mucus to protect the gastric mucosa from the acidic content of the stomach. At the bottom of the gastric pits the pyloric glands open. Instead of being simple tubular glands as the fundus glands, they are branched tubular glands. The cells of the pyloric glands are almost exclusively mucous secreting, resembling the mucous neck cells of the fundus glands. Within the pyloric glands gastrin producing enteroendocrine cells are also present.
The histology of human stomach including detailed images and information about the different cell types can be viewed in the Protein Atlas Histology Dictionary.
Background
Here, the protein-coding genes expressed in stomach are described and characterized, together with examples of immunohistochemically stained tissue sections that visualize corresponding protein expression patterns of genes with elevated expression in stomach.
Transcript profiling was based on a combination of two transcriptomics datasets (HPA and GTEx), corresponding to a total of 14590 samples from 50 different human normal tissue types. The final consensus normalized expression (nTPM) value for each tissue type was used for the classification of all genes according to the tissue-specific expression into two different categories, based on specificity or distribution.
Relevant links and publications
Uhlén M et al., Tissue-based map of the human proteome. Science (2015)
PubMed: 25613900 DOI: 10.1126/science.1260419
Fagerberg L et al., Analysis of the human tissue-specific expression by genome-wide integration of transcriptomics and antibody-based proteomics. Mol Cell Proteomics. (2014)
PubMed: 24309898 DOI: 10.1074/mcp.M113.035600
Gremel G et al., The human gastrointestinal tract-specific transcriptome and proteome as defined by RNA sequencing and antibody-based profiling. J Gastroenterol. (2015)
PubMed: 24789573 DOI: 10.1007/s00535-014-0958-7