Kallikrein-gene expression in the rat gastrointestinal tract

Serine proteases of small intestine mucosa--localization, functional properties, and physiological role

In this review we present data about small intestine serine proteases, which are a considerable part of the proteolytic apparatus in this major part of the gastrointestinal tract. Serine proteases of intestinal epitheliocytes, their structural-functional features, cellular localization, physiological substrates, and mechanisms of activity regulation are examined. Information about biochemical and functional properties of serine proteases is presented in a common context with morphological and physiological data, this being the basis for understanding the functional processes taking place in upper part of the intestine. Serine proteases play a key role in the physiology of the small intestine and provide the normal functioning of this organ as part of the digestive system in which hydrolysis and suction of food substances occur. They participate in renewal and remodeling of tissues, retractive activity of smooth musculature, hormonal regulation, and defense mechanisms of the intestine.

Salivary epidermal growth factor and intestinal adaptation in male and female mice

Salivary epidermal growth factor (sEGF) levels are increased in male mice after small bowel resection (SBR) and may be important during intestinal adaptation. Since males have greater sEGF than females, the influence of sex on postresection adaptation was tested. Females had lower sEGF; however, sEGF substantially increased in both sexes after a massive (50%) SBR. Adaptive increases in DNA and protein content, villus height, and crypt depth, as well as crypt cell proliferation rates in the remnant ileum, were not different between males and females. Although significant postresection increases in sEGF were identified, EGF mRNA and protein did not change within the submandibular gland. Glandular kallikrein-13 and ileal EGF receptor expression were greater after SBR in female mice. Intestinal adaptation is equivalent in female and male mice after SBR. Despite lower sEGF, females demonstrated increased expression of a kallikrein responsible for sEGF precursor cleavage as well as amplified ileal EGF receptor expression. These results endorse an important differential response between sexes regarding sEGF mobilization and intestinal receptor availability during adaptation.

Correlation of kinin generating activity with Helicobacter pylori-associated gastric infection

The kallikrein-kinin system involves a biologically complex set of interactive proteases that signal the first-line onset of inflammation and associated cellular processes. The basic enzymatic cleavage of kininogen substrate by the serine protease tissue kallikrein to liberate kinins is regulated by a number of factors. These may include the recently discovered bacterial involvement in the causation of gastritis. The gram-negative Helicobacter pylori organism, colonises the human gastric epithelium and initiates ulcerogenesis and may induce, in the longer term, tumour formation. The aim of this study was to investigate the role of kinins in H. pylori-induced gastric dyspepsia. During endoscopic examination, lavage aspirates of 23 patients were collected, and the tissue kallikrein content measured by a kinin-generating assay and an enzyme-linked immunosorbent assay. Gastric antral and pyloric biopsy tissue was histologically examined for degrees of inflammation and H. pylori infection, and then immunolabelled for tissue kallikrein and kinin receptors. Results show that labelled tissue kallikrein in the fundic glands and parietal cells of the diseased antrum was elevated with increasing severity of gastritis. Further, kinin-generating potential of the lavage fluid appeared to be greater with increasing evidence of infection. Tissue kallikrein immunosorbent assay levels were significantly raised in patients showing mild to moderate H. pylori infection. One outcome of this study may be the inclusion of kinin antagonists in management of gastric dyspepsia.

Ontogeny of the intrarenal kallikrein-kinin system: proposed role in renal development

The kallikrein-kinin system (KKS) plays an important role in the regulation of renal function. Endogenous kinins modulate renal microvascular resistance, medullary blood flow, and distal nephron sodium and water reabsorption. All the components of the KKS, including tissue kallikrein, kininogen, kininase II, and kinin receptors are expressed within the kidney, establishing a paracrine system capable of controlling local nephron functions. In this review, data will be presented demonstrating that the developing kidney expresses an endogenous, functionally active KKS. Molecular studies have shown that gene expression of the renal KKS in the rat is activated postnatally, and that the intrarenal distribution of KKS components is subject to developmental control. Furthermore, the developmental expression of KKS appears to be regulated primarily at the transcriptional level. Ontogenetic studies have also revealed that the bradykinin B-2 receptor gene is overexpressed in the developing rat kidney. As kinins are potent vasoactive and growth-promoting factors, it is proposed that endogenous kinins mediate developmental renal growth and differentiation, and modulate the maturational changes which occur in renal hemodynamics.

A physiological level of rhubarb fiber increases proglucagon gene expression and modulates intestinal glucose uptake in rats

Previous work demonstrated that a high fiber diet upregulates proglucagon mRNA and secretion of glucagon-like peptide-1 [GLP-1(7-37)] and insulin compared with an elemental fiber-free diet. This study examined whether similar intakes of fibers differing in physiochemical and fermentative properties alter the expression of intestinal hormones and intestinal absorptive properties. Sprague-Dawley rats were fed either a 50 g/kg cellulose or rhubarb fiber diet for 14 d. Ileal proglucagon mRNA levels were significantly higher in rats fed rhubarb fiber than in those fed cellulose fiber (9.3 +/- 0.9 vs. 6.2 +/- 1.0 densitometer units). Proglucagon mRNA in the colon did not differ between diet treatments. Plasma c-peptide concentrations were significantly higher 30 min after an oral glucose tolerance test in the rhubarb vs. cellulose group (1627 +/- 67 vs. 1290 +/- 71 pmol/L). Passive permeability, measured by the uptake of L-glucose, was significantly higher in the jejunum of rats fed cellulose compared with those fed rhubarb fiber. Adjusting total glucose uptake for passive permeability and unstirred water layer resistance resulted in a higher Km being calculated for the jejunum and ileum of the cellulose fiber group. Jejunal and ileal carrier-mediated uptakes (Vmax) were not altered by diet and reflected the lack of difference between groups in sodium-dependent glucose cotransporter (SGLT-1) and sodium-independent glucose transporter (GLUT2) mRNA levels. Replacing cellulose fiber with rhubarb fiber in a diet upregulated ileal proglucagon mRNA and resulted in a reduced passive permeability but did not affect glucose transport of the small intestine. This work establishes the importance of dietary fiber fermentability in modulating intestinal proglucagon expression and possibly glucose homeostasis.

Distribution of tissue kallikreins in lower vertebrates: potential physiological roles for fish kallikreins

Fish skeletal muscle prokallikrein was purified from black sea bass, Centropritis striata, and used for the production of polyclonal antiserum. Tissue proteins from primitive fish and teleosts, an alligator, and an insectivore were resolved by sodium dodecylsulfate-polyacrylamide gel electrophoresis, Western blotted, and probed with fish muscle prokallikrein antiserum. A recurring theme was the presence of approximately 36 and 72 kDa kallikrein-like proteins in skeletal muscle, heart, gill, kidney, and spleen of higher teleosts and in selected tissues of sturgeon, shark, alligator, and mole. The presence of immunoreactive kallikreins in osmoregulatory organs such as the gills of teleosts and the rectal gland of sharks signifies a potential role for these proteins in osmoregulation. Black sea bass, rock bass, and sturgeon contained many immunoreactive kallikreins in their swimbladders, which implicates a role for kallikreins in the regulation of blood flow and vascular permeability to facilitate gas exchange within the bladder. Kallikreins were consistently identified in skeletal muscle and heart of all the species evaluated and may regulate local blood flow, muscle contraction or relaxation, or participate in various transport processes. The antiserum to fish prokallikrein recognized immunoreactive kallikreins from pancreatic tissues from fish and lower vertebrates, but not from the pyloric caecum of sea bass. The wide distribution of tissue kallikrein in lower vertebrates suggests that it may participate in a variety of physiological functions.

The evaluation of tissue kallikrein in Helicobacter pylori-associated gastric ulcer disease

Helicobacter pylori (Hp) associated ulcer disease is a common form of gastric disorder involving mucosal damage and invasion of the mucosa by polymorphic inflammatory cells with concomitant changes in the epithelial cell structure. The bacteria are thought to adhere by specific junction zones to the epithelial cell surface resulting in the degeneration of the mucosal layer. Our study was undertaken to examine the relative status of tissue kallikrein (TK) in antral and fundic biopsies, endoscopically obtained from 10 patients suspected of having gastric disorders. For histological evidence of inflammation the tissue was stained with hematoxylin and eosin and classified as mild, active, chronic and chronic active gastritis. Hp infection was determined by Giemsa staining. For localisation of TK, slide-mounted tissue sections were subjected to PAP and immunofluorescent staining using a goat anti-human TK IgG antibody. The results revealed that in the antral control tissue, removed during partial antractomy, TK was immunovisualised along the luminal border of the deep pyloric glands. The surface epithelia and superficial glands showed no labelling. The fundic control tissue revealed an absence of TK in the superficial and surface epithelial glands, but was positive in the parietal cells. The fundic biopsy specimens showed similar immunoreactivity in these areas. By contrast, in the inflammed pyloric mucosa, there was a shift of TK localisation to the basal part of the glandular cells and there was also expression of TK in the superficial glands that showed histological evidence of regeneration. In the fundic biopsies there was no change observed in the sites of TK localisation (similar to control tissue). It was observed, that even though 8 of the 10 subjects exhibited Hp infection, the inflamed mucosa showed no discernable difference in the staining patterns between the infected and non-infected tissue sections. Our findings suggest an important role for a B1/B2 kinin antagonist in patients with gastritis.

Kinin receptor status in normal and inflammed gastric mucosa

No documented studies have been reported on the presence of B1 and B2 kinin receptors in the mammalian gastric mucosa. This first study aimed to immunolocalise sites of B1 and B2 kinin receptors in the human pyloric gastric mucosa and to evaluate its role in gastritis. Biopsies were obtained from patients with dyspepsia during endoscopic examination of the patient. The diagnosis and grading of the gastritis was performed on histological examination. Sections were immunostained for both B1 and B2 receptors using rabbit anti-human B1 and B2 kinin receptor antibodies. Control tissue was obtained from partial gastrectomy specimens, following surgical excision of the antrum for duodenal ulcers. The control antrum tissue showed strong immunoreactivity for kinin B2 receptors with positivity noted along the luminal border, at the base of the mucous and stem cells. The B1 receptor was not immunolocalised. Biopsies of all five patients with gastritis showed a decrease in immunolabelling of the B2 receptor and an induction of the B1 receptor especially in regenerating cells. In gastritis there is destruction of the normal mucosal glandular architecture with subsequent regeneration of the epithelial cells. The pyloric glands are infiltrated by acute inflammatory cells that cause crypt abscesses with loss of the epithelial cell membranes. This may explain the reduction in the immunolocalisation of the B2 kinin receptors and the induction of the B1 receptors in active gastritis. Follow up studies after treatment of the inflammation with a combination of B1/B2 kinin receptor antagonists are indicated.

Disparate tissue-specific expression of members of the tissue kallikrein multigene family of the rat

To understand the regulatory diversity of the rat family of linked kallikrein genes, we have assayed the expression of family members in 20 major organs. Reverse transcription-polymerase chain reaction analysis using primers and hybridization probes specific for each of the 10 expressed kallikrein genes showed that no two family members share the same organ-specific pattern of expression. The only common site of expression for all 10 known active genes is the submandibular gland. The presence of the mRNA for at least one family member is detected in 19 of these 20 organs (liver excepted), from as few as three organs to as many as 18 for individual family members. For individual genes there can be more than a 10(5)-fold variation in mRNA levels among organs, from a limit of detection of slightly less than 1 mRNA molecule/10 cells to more than 10,000 mRNA molecules/cell. Despite high sequence conservation and close linkage, the members of this family are expressed in very different and complex patterns. A gradient of diversity of expression corresponds to the order of the genes within the kallikrein family locus.

Molecular cloning, purification and in situ localization of human colon kallikrein

We have cloned and characterized a full-length cDNA encoding tissue kallikrein from a human colon carcinoma cell line (T84). The nucleic acid sequence of the colon kallikrein cDNA is identical to that of renal/pancreatic or tissue kallikrein cDNA. Reverse-transcription PCR followed by Southern-blot analysis using specific oligonucleotide probes showed expression of tissue kallikrein in human colon, pancreas and kidney. Tissue kallikrein mRNA was localized in glandular epithelial cells (goblet cells) in colon by in situ hybridization histochemistry. Human colon kallikrein was purified to apparent homogeneity by DEAE-Sepharose Cl-6B, aprotinin-affinity, and HQ/M perfusion chromatography. The purified colon kallikrein migrated as a broad, 40-45 kDa band in SDS/PAGE and was recognized by antibodies to human tissue kallikrein. The linear displacement curves for the colon kallikrein in an RIA were parallel with the human tissue kallikrein standard curve, indicating their immunological identity. The N-terminal sequence of the purified colon kallikrein matches completely with that of purified urinary or tissue kallikrein. These results indicate that human colon kallikrein is transcribed from the tissue kallikrein gene.

Development biology of the renal kallikrein-kinin system

Kinins are endothelium-dependent vasodilators and natriuretic paracrine peptides that participate in the regulation of blood pressure, renal hemodynamics and sodium excretion. Several lines of evidence suggest an important role for intrarenal kinins and their receptors in kidney growth and development. (1) The developing rat kidney expresses all the components of the tissue kallikrein-kinin system: tissue kallikrein, low molecular weight (LMW) kininogen, kininase II and kinin receptors. Also, the developing liver expresses high molecular weight and LMW kininogens. Thus, a complete kinin-generating system exists in the developing kidney. (2) Gene transcription, mRNA and protein abundance, and enzymatic activity of renal kallikrein are all markedly up-regulated during postnatal kidney growth, and a positive correlation exists between renal kallikrein synthesis and the maturational rise in renal blood flow. (3) Rat glomerular mesangial cells in culture express the kinin receptors and proliferate in response to bradykinin, suggesting that endogenous kinins and their receptors modulate glomerular growth. (4) The newborn period is characterized by an activation of kinin receptor gene expression, and chronic pharmacological blockade of kinin receptors suppresses DNA synthesis in the developing but not adult kidney. Collectively, these data provide the basis for the hypothesis that endogenous kinins and the kinin receptors play an important role in the developmental biology of the metanephric kidney.

Molecular aspects of kallikrein and kininogen in the maturing kidney

Kinins are vasoactive paracrine peptides which participate in a wide range of functions, including the regulation of local organ blood flow, systemic blood pressure, transepithelial water and electrolyte transport, cellular growth, capillary permeability and inflammatory response, and pain. The recent introduction of specific bradykinin receptor subtype antagonists has greatly advanced our understanding of the role of the kallikrein-kinin system (KKS) in various physiological and disease states. However, a major gap remains in our knowledge of the role of kinins in early development. In this review, evidence is presented that the developing nephron expresses both tissue kallikrein and kininogen, and that the genes encoding the components of the KKS are subject to considerable developmental regulation. The activity of the intrarenal kinin-generating system is lowest in the developing kidney and increases with age. Completion of nephrogenesis is characterized by a marked surge in intrarenal kallikrein synthesis and gene transcription. Maturation is associated with redistribution of intrarenal kallikrein and its messenger RNA from the inner to outer cortical nephrons following the centrifugal pattern of nephron development. Challenges for the future include delineation of the direct role of kinins in the maturation of renal functions and elucidation of the molecular mechanisms underlying the developmental expression of the KKS.

Tissue kallikrein in the rat pineal gland: an immunocytochemical study

Tissue kallikrein in the rat pineal gland was immunocytochemically investigated with the aid of specific antiserum against rat urinary kallikrein. We also compared the tissue kallikrein immunoreactivity of the pineal gland with that of the submandibular gland and kidney, which have been well established as tissue kallikrein-synthesizing organs. The cytoplasm of pinealocytes from both the superficial and the deep portion of the gland exhibited specific immunolabeling for tissue kallikrein, but the immunoreaction was weaker than that observed in exocrine organs. Two types of tissue kallikrein-immunoreactive pinealocytes were distinguished; the first predominant type displayed moderate immunostaining, whereas a small number of cells, the second type, were so intensely labeled that their cytoplasmic processes were clearly outlined. The results of the present study suggest the existence of different types of pinealocytes and a potential physiological role of tissue kallikrein in the rat pineal gland.

Ileal proglucagon gene expression in the rat: characterization in intestinal adaptation using in situ hybridization

BACKGROUND

Proglucagon-derived peptides are potential mediators of the adaptive response of the terminal ileum to massive small bowel resection. Ileal proglucagon messenger RNA (mRNA) levels increase during ileal adaptation. The present study explored the cellular basis of this response.

METHODS

Sections of control ileum, ileum 4 days after resection, and pancreas were analyzed by in situ hybridization with 35S-labeled complementary RNA (cRNA) probes.

RESULTS

Both the proglucagon and the peptide YY cRNA probes hybridized to discrete cells in the ileal mucosa, the disposition of which corresponds to that reported for intestinal L cells. Four days after resection there was a marked increase in the intensity of the signal for both probes without an increase in cell number. Insulin and histone H3 probes were used as controls to confirm the specificity of the hybridization seen with the L-cell specific, proglucagon, and peptide YY probes.

CONCLUSIONS

The increase in proglucagon mRNA levels after massive small bowel resection is caused by an increase in the cellular content. The parallel increase in PYY mRNA levels implies an L cell--rather than a proglucagon gene--specific response.

Tissue-specific expression of kallikrein family transgenes in mice and rats

To define the regulatory strategy for the transcriptional control of the kallikrein multigene family, we analyzed the expression of several kallikrein/SV40 T-antigen (TAg) fusion genes in transgenic mice and rats. Kallikrein family members are normally expressed at a high level in the submandibular gland and are expressed in a wide range of tissues that vary among individual family members. A total of 1.7 kb of proximal 5'-flanking DNA from the tissue kallikrein gene (rKlk1) was sufficient to confer much of the correct tissue-specific pattern on a TAg reporter gene. TAg mRNA was detectable in tissues that normally express rKlk1 and TAg-induced tumors arose in brain and pancreas. However, absolute levels of transgene mRNA were very low relative to the expression of the normal endogenous tissue kallikrein gene. In particular, expression in the salivary glands, normally very high for endogenous rKlk1, was either low or absent. An intact rKlk1 transgene with extensive flanking DNA (4.5 kb 5' and 4.7 kb 3') and complete intragenic (4 kb) sequences was expressed similarly to the fusion transgene, demonstrating that regulatory elements necessary for comprehensively correct expression are not contained within these additional gene regions. Two additional kallikrein/SV40 fusion transgenes were derived from other family members, one from the rKlk2 gene, which encodes tonin, and another from the rKlk8 gene, which encodes a prostate kallikrein. Whereas the endogenous rKlk2 and rKlk8 genes normally are expressed at high levels in rat salivary glands, they were not expressed in the salivary glands as transgenes. The results for these transgenes of three different family members indicate that control elements that direct the particular nonsalivary gland expression pattern characteristic of each family member may be present within the proximal 5'-flanking region of each gene, whereas regulatory sequences necessary for normal levels of expression in these tissues and for maximal salivary gland expression are not. We propose that the gene-associated regulatory sequences are complemented by a dominant control region that imposes salivary gland expression on the extended kallikrein family locus.

Evolution of the rat kallikrein gene family: gene conversion leads to functional diversity

Kallikrein-like simple serine proteases are encoded by closely related members of a gene family in several mammalian species. Molecular cloning and genomic Southern blot analysis after conventional and pulsed-field gel electrophoresis indicate that the rat kallikrein gene family comprises 15-20 members, probably closely linked at a single locus. Determination of the nucleotide sequences of the rGK-3, -4, and -6 genes here completes sequence data for a total of nine rat kallikrein family members. Comparison of the rat gene sequences to each other and to those of human and mouse kallikrein family genes reveals patterns of relatedness indicative of concerted evolution. Analysis of nucleotide sequence variants in kallikrein family members shows that most sequence variants are shared by multiple family members; the patterns of shared variants are complex and indicate multiple short gene conversions between family members. Sequence exchanges between family members generate novel assortments of variants in amino acid coding regions that may affect substrate specificity and thereby contribute to the diversity of enzyme activity. Furthermore, small sequence exchanges also may play a role in generating the diverse patterns of tissue-specific expression of rat family members. These analyses indicate an important role for gene conversion in the evolution of the functional diversity of these duplicated genes.

Mineralocorticoid receptor gene expression in the gastrointestinal tract: distribution and ontogeny

The gastrointestinal tract is a well characterized target tissue for aldosterone, where it regulates electrolyte transport, particularly in the descending colon. Previous studies have demonstrated the presence of aldosterone receptors in gastrointestinal tissues. We have used specific cRNA probes for the rat mineralocorticoid receptor to explore both the distribution and ontogeny of mineralocorticoid receptor gene expression in the gastrointestinal tract. Mineralocorticoid receptor gene expression is found throughout the small and large intestine, but is absent from the stomach. The highest levels are observed in the distal colon, and significant expression is found in the duodenum; in both tissues levels of expression are higher than those in kidney. In both the developing duodenum and colon, mineralocorticoid receptor gene expression precedes the development of the full physiological response to aldosterone. These findings emphasise the colon as an important target tissue for aldosterone, and raise the question of potential roles for aldosterone in the duodenum.