Influence of resistant starch on the SCFA production and cell counts of butyrate-producing Eubacterium spp. in the human intestine.

AIMS: The genus Eubacterium, which is the second most common genus in the human intestine, includes several known butyrate producers. We hypothesized that Eubacterium species play a role in the intestinal butyrate production and are inducible by resistant starch. METHODS AND RESULTS: In a human pilot study species-specific and group-specific 16S rRNA-targeted, Cy3 (indocarbocyanine)-labelled oligonucleotide probes were used to quantify butyrogenic species of the genera Eubacterium, Clostridium and Ruminococcus. Following the intake of RS type III a significant increase in faecal butyrate but not in total SCFA was observed. However, increase in butyrate was not accompanied by a proliferation in the targeted bacteria. CONCLUSIONS: The tested Eubacterium species have the capacity to produce butyrate but do not appear to play a major role for butyric acid production in the human intestine. SIGNIFICANCE AND IMPACT OF THE STUDY: In view of the fact that the bacteria responsible for butyrate production are largely unknown, it is still difficult to devise a dietary intervention to stimulate butyrogenic bacteria in a targeted way.

Pharmacokinetics and bioavailability of quercetin glycosides in humans.

Due to its potentially beneficial impact on human health, the polyphenol quercetin has come into the focus of medicinal interest. However, data on the bioavailability of quercetin after oral intake are scarce and contradictory. Previous investigations indicate that the disposition of quercetin may depend on the sugar moiety of the glycoside or the plant matrix. To determine the influence of the sugar moiety or matrix on the absorption of quercetin, two isolated quercetin glycosides and two plant extracts were administered to 12 healthy volunteers in a four-way crossover study. Each subject received an onion supplement or quercetin-4'-O-glucoside (both equivalent to 100 mg quercetin), as well as quercetin-3-O-rutinoside and buckwheat tea (both equivalent to 200 mg quercetin). Samples were analyzed by HPLC with a 12-channel coulometric array detector. In human plasma, only quercetin glucuronides, but no free quercetin, could be detected. There was no significant difference in the bioavailability and pharmacokinetic parameters between the onion supplement and quercetin-4'-O-glucoside. Peak plasma concentrations were 2.3 +/- 1.5 microg x mL(-1) and 2.1 +/- 1.6 microg x mL(-1) (mean +/- SD) and were reached after 0.7 +/- 0.2 hours and 0.7 +/- 0.3 hours, respectively. After administration of buckwheat tea and rutin, however, peak plasma levels were--despite the higher dose-only 0.6 +/- 0.7 microg x mL(-1) and 0.3 +/- 0.3 microg x mL(-1), respectively. Peak concentrations were reached 4.3 +/- 1.8 hours after administration of buckwheat tea and 7.0 +/- 2.9 hours after ingestion of rutin. The terminal elimination half-life was about 11 hours for all treatments. Thus, the disposition of quercetin in humans primarily depends on the sugar moiety. To a minor extent, the plant matrix influences both the rate and extent of absorption in the case of buckwheat tea administration compared with the isolated compound. The site of absorption seems to be different for quercetin-4'-O-glucoside and quercetin-3-O-rutinoside. The significance of specific carriers on the absorption of quercetin glycosides, as well as specific intestinal beta-glucosidases, needs to be further evaluated.

Cellular and subcellular localization of gastrointestinal glutathione peroxidase in normal and malignant human intestinal tissue.

The gastrointestinal glutathione peroxidase (GI-GPx) is believed to prevent absorption of hydroperoxides. GI-GPx is expressed in the intestine together with the other three glutathione peroxidase isoenzymes, raising the question of the physiological role of the different GPx types. We therefore studied the cellular and subcellular distribution of GI-GPx in normal and malignant tissue obtained from patients with colorectal cancer or familial polyposis by immunohistochemistry. In healthy ileum epithelium GI-GPx was preferentially enriched in Paneth cells. In unaffected crypts of colon and rectum, it decreased gradually from the ground to the luminal surface. In crypt ground, GI-GPx was uniformly distributed, whereas in cells at the luminal surface it was concentrated in structures capping the nuclei at the apical pole. In colorectal cancer, GI-GPx expression depended on the stage of malignant transformation. In early stages, GI-GPx was increased and pronouncedly associated with the vesicular structures. In progressed stages of malignancy, structures disintegrated and GI-GPx distribution became more diffuse. These observations support the hypothesis that GI-GPx, apart from being a barrier against hydroperoxide absorption, might be involved in cell growth and differentiation.

Biochemical and genetic basis of red cell enzyme deficiencies.

Enzyme deficiencies have been identified in all erythrocyte pathways. Their frequencies differ with respect to the affected enzyme, the severity of the clinical manifestations and the geographical distribution. Most mutations are found within the coding sequences of genes, missense mutations occurring more often than deletions, insertions, splice site defects or premature stop codons. Promoter mutations are rare. The clinical manifestations are chronic or non-chronic haemolytic anaemias. The first of these are characterized by an impairment of cell function at normal values of the external load parameters kATPase and kGSHox. Haemolysis with a non-chronic course is induced only at enhanced values of the load parameters, caused by free radical generation by oxidative drugs, fava beans, infections, fever and physical exercise. The development of secondary haemochromatosis is the most common cause of mortality in patients suffering from severe chronic non-spherocytic haemolytic anaemia. Intracellular iron deposits must be prevented by timely treatment with effective chelating agents.

Deficiency of epithelial basement membrane laminin in ulcerative colitis affected human colonic mucosa.

Imbalances in epithelium-matrix interactions have been discussed as a pathomechanism in ulcerative colitis, causing a colonic mucosal barrier dysfunction. Laminin, the major noncollagenous component of the basement membrane, plays a role in epithelial basal lamina formation and promotes differentiation of human enterocytes. We therefore investigated the distribution of laminin in ulcerative colitis affected colonic tissues. Tissue specimens from both affected and nonaffected colonic regions were obtained from ten patients with ulcerative colitis during colonoscopies or operations. Healthy tissue from five patients with colorectal cancer was used as control. After histological classification, the localization and distribution of the basement membrane associated extracellular matrix proteins were determined by immunohistochemistry. Paraffin-embedded sections were incubated with antibodies against laminin and type IV and V collagen. No positive immunoreactivity against laminin was found in most of the epithelial basement membranes surrounding the crypts in affected colonic tissues, without involvement of the subendothelial structures. In contrast, a type IV and V collagen accumulation occurred in all these tissue samples. The lack of laminin in combination with an overexpression of type IV and V collagen, as reported for the first time in this paper, leads to changes in basement membrane structure. These findings indicate that the three-dimensional network of the colonic epithelial basement membrane and its function are seriously disturbed in exacerbating ulcerative colitis. This provides new insights into the importance of cell-matrix interactions for physiological and pathological mechanisms in the etiology of ulcerative colitis.

Flavonols and flavones of parsley cell suspension culture change the antioxidative capacity of plasma in rats.

The flavonoid aglycones from an illuminated parsley (Petroselinum crispum (Mill.) Nym.) cell suspension culture were identified and quantified as the flavones apigenin, luteolin and chrysoeriol and the flavonols kaempferol, quercetin and isorhamnetin. Flavonoid extracts from these cultures were purified by solid phase extraction from RP C-18 phase and given by gavage to rats. Only extract from illuminated culture increased the antioxidative capacity (AOC) of blood plasma temporarily with maximum values after 1 h. It is concluded that the course of AOC reflects changes in the plasma content of flavonoids.

Distribution pattern of a flavonoid extract in the gastrointestinal lumen and wall of rats.

Purified flavonoid extract from illuminated parsley (Petroselinum crispum (Mill.) Nym.) cell culture was administered by gavage to Wistar rats. The dose corresponded to 6.9 mg flavonoids on aglycone base/kg body mass. Segments of the gastrointestinal wall from stomach to colon, their luminal contents, and liver and kidneys were collected at time intervals between 1 and 12 h and investigated by HPLC of the respective extracts for flavonoids. The spreading of the flavonoids was accompanied by partial deglycosylation that began already in the stomach where at first quercetin and later apigenin, chrysoeriol and isorhamnetin aglycones were detected. We got evidence of flavonoid absorption by the stomach that does not require the liberation of aglycones. Due to obvious differences in metabolization and absorption rates the composition and the content of flavonoids changes in the gastrointestinal segments and their contents with time. Flavonoids could be detected neither within the gastrointestinal lumen after 12 h nor in the kidneys at any time. But traces of flavonoids were found in the livers at 1.5 and 12 h.

Dietary resistant starch and chronic inflammatory bowel diseases.

These studies were performed to test the benefit of resistant starch on ulcerative colitis via prebiotic and butyrate effects. Butyrate, propionate, and acetate are produced in the colon of mammals as a result of microbial fermentation of resistant starch and other dietary fibers. Butyrate plays an important role in the colonic mucosal growth and epithelial proliferation. A reduction in the colonic butyrate level induces chronic mucosal atrophy. Short-chain fatty acid enemas increase mucosal generation, crypt length, and DNA content of the colonocytes. They also ameliorate symptoms of ulcerative colitis in human patients and rats injected with trinitrobenzene sulfonic acid (TNBS). Butyrate, and also to a lesser degree propionate, are substrates for the aerobic energy metabolism, and trophic factors of the colonocytes. Adverse butyrate effects occur in normal and neoplastic colonic cells. In normal cells, butyrate induces proliferation at the crypt base, while inhibiting proliferation at the crypt surface. In neoplastic cells, butyrate inhibits DNA synthesis and arrests cell growth in the G1 phase of the cell cycle. The improvement of the TNBS-induced colonic inflammation occurred earlier in the resistant starch (RS)-fed rats than in the RS-free group. This benefit coincided with activation of colonic epithelial cell proliferation and the subsequent restoration of apoptosis. The noncollagenous basement membrane protein laminin was regenerated initially in the RS-fed group, demonstrating what could be a considered lower damage to the intestinal barrier function. The calculation of intestinal short-chain fatty acid absorption confirmed this conclusion. The uptake of short-chain fatty acids in the colon is strongly inhibited in the RS-free group, but only slightly reduced in the animals fed with RS. Additionally, RS enhanced the growth of intestinal bacteria assumed to promote health. Further studies involving patients suffering from ulcerative colitis are necessary to determine the importance of RS in the therapy of a number of intestinal diseases and the maintenance of health.

[COX-2 associated loss of apoptosis activity in intestinal neoplams in Apc gene knock-out mice]. / COX-2-assoziierter Verlust der Apoptoseaktivität in intestinalen Neoplasien Apc-Gen-defekter Mäuse.

The aim of the study was to characterize both apoptotic and proliferating cells histologically and to analyze localisation and distribution of various apoptosis-associated proteins in tumours of different stages of degeneration in the animal model of Apc-gene defect mice. Such animals show clinical symptoms similar to those of patients suffering from Familial Adenomatous Polyposis (FAP) but develop the neoplasm's mainly in the small intestine. Tumours from all parts of the gut of 90 days old non-treated MIN-mice were classified as adenocarcinomas, histologically. The apoptosis-associated proteins bax, bcl-2, p53 and the COX-2 enzyme were investigated immunohistochemically. Additionally the localisation and distribution of proliferating (BrdU-labeling) and apoptotic (KLENOW, TUNEL) cells were analysed. In the summary we point out: 1. The activity of apoptosis increases in early stage of neoplasm as a defensive mechanism of mucosa. 2. A decrease in apoptosis rate occurs during carcinogenesis. 3. The inversely correlating, clear COX-2 accumulation accompanying carcinoma development supplies evidence for cyclooxygenase-inhibitor treatment is a promising therapeutic attempt in early stage of FAP.

[Molecular etiology of colorectal carcinogenesis, clinical manifestations and therapy]. / Molekulare Ursachen kolorektaler Kanzerogenese, klinische Manifestation und Therapie.

Mutations of tumor suppressor genes, of the mismatch DNA repair system, and of the TGF-beta-II-receptor are the main causes for a higher risk of colorectal cancer. Among mutations of the Ape gene, which characterize the clinical manifestation of the familial polyposis (FAP), point mutations are dominating which create new stop codons or arise from deletions or insertions of nucleotides causing frame shifts. Because the binding site of beta-catenin is localized in the C-terminus of the Ape protein, disturbances result in the cellular signal transfer from its loss. Consequently, the interactions of the usually formed Ape-beta-catenin complex with the cytoskeleton and the cadherin system in the plasma membrane as well as the translocation of beta-catenin into the nucleus cannot be realized. Mutations in the genes of the mismatch DNA repair system and of the TGF-beta-II-receptor, the main defects of the HNPCC (hereditary nonpolyposis colorectal cancer), are exclusively identified in sequences of microsatellites. Because the majority of Apc gene mutations is also localized in repetitive motifs even in CpG islands primary disturbances are to postulate in the methylation pattern of the genes producing germline and somatic mutations. Generally, complexly connected reactions are involved in this cascade of colorectal cancer genesis. This fact explains the relatively late clinical manifestation of the disease and offers the possibility to identify carriers with an increased risk of colorectal cancer development in order to integrate them into a programme of control and preventive medicine. Beside the known treatment by surgery and cytostatics, inhibitors of prostaglandin synthesis gain therapeutic significance. Cancerogenesis can be efficiently suppressed by inhibition of the COX-2-induction (cyclo-oxygenase-2). There is a lack of clinical experience for a decision whether a high intraluminal level of butyrate in the large intestine can delay colorectal carcinogenesis.

Molecular analysis of 29 pyruvate kinase-deficient patients from central Europe with hereditary hemolytic anemia.

We investigated the DNA of 29 unrelated pyruvate kinase (PK) deficiency (PKD) patients from Central Europe with hereditary nonspherocytic hemolytic anemia for mutations in the PK-L/R gene. Among 58 potentially affected alleles, 53 mutations were identified, of which 17 were different from each other. Of these 17 mutations, 13 were single-nucleotide (nt) substitutions resulting in amino acid exchanges, G787A (Gly263-Arg), G994A (Gly332-Ser), G1006T (Ala336-Ser), G1010A (Arg337-Gln), A1081G (Asn361-Asp), G1127T (Ser376-Ile), G1174A (Ala392-Thr), G1281T (Glu427-Asp), C1454T (Ser485-Phe), C1456T (Arg486-Trp), G1493A (Arg498-His), G1529A (Arg510-Gin), and C1594T (Arg532-Trp); 1 in-frame triplet deletion, 1060delAAG (delLys354); 1 in-frame triplet insertion, 1203insAGC (insSer after Cys401); 1 splicesite mutation, 101-1G-A; and 1 frameshift deletion, 628delGT. Six mutations, 628delGT, G787A, G1010A, G1127T, G1281T, and C1454T, are described for the first time. To test the hypothesis of a single origin of the most common PK mutation in the European population, G1529A, we investigated all patients at four polymorphic sites in the PK-L/R gene: C/A at nt 1705, C/T at nt 1992, the (ATT)n microsatellite in intron J, and a polymorphism (T)10/(T)19 in intron I. Nine patients homozygous for mutation G1529A were consistent in all four markers. In the group of patients homozygous for mutation G1529A, the hematologic parameters and clinical manifestations have been studied in detail. Although having an identical mutation in the PK-L/R gene, the patients are affected differently. Their appearance ranges from a very mild compensated hemolysis to a severe anemia. Possible molecular explanations are discussed.

Complete genomic sequence of the human PK-L/R-gene includes four intragenic polymorphisms defining different haplotype backgrounds of normal and mutant PK-genes.

The human pyruvate kinase L/R-gene has been completely sequenced in unrelated normal individuals and in pyruvate kinase-deficient patients by a PCR-based direct genomic sequencing approach and analyzed for polymorphisms. The total length of the gene is 8409 nucleotides. Four polymorphic sites have been detected: C/A1705 and C/T1992 in exon 12, a T-stretch in intron 1 occurring in the two polymorphic forms (T)10 and (T)19 and an (ATT)n microsatellite in intron J which has been found in the variation (ATT)11-17. Haplotype analysis using these four markers has been applied to trace the genetic background in PK-deficiencies. The results support the idea of a single origin of most of the individual PK-mutations.

Hemolytic anemias due to erythrocyte enzyme deficiencies.

Red blood cells can only fulfil their functions over the normal period of approximately 120 days with 1.7 x 10(5) circulatory cycles efficiently if they withstand external and internal loads. This requires ATP and redox equivalents, which have to be permanently regenerated by the energy and redox metabolism. These pathways are necessary to maintain the biconcave shape of the cells, their specific intracellular cation concentrations, the reduced state of hemoglobin with a divalent iron and the sulfhydryl groups of enzymes, glutathione and membrane components. If an enzyme deficiency of one of these metabolic pathways limits the ATP and/or NADPH production, distinct membrane alterations result causing a removal of the damaged cells by the monocyte-macrophage system. Most metabolic needs of erythrocytes are covered by glycolysis, the oxidative pentose phosphate pathway (OPPP), the glutathione cycle, nucleotide metabolism and MetHb reductase. Hereditary enzyme deficiencies of all these pathways have been identified; those that cause non-spherocytic hemolytic anemia are listed in Table 4. Their frequencies differ markedly both with respect to the affected enzyme and geographic distribution. Glucose-6-phosphate dehydrogenase enzymopathies (G6PD) are with more than 400 million cases by far the most common deficiency. The highest gene frequency has been found with 0.7 among Kurdish Jews. G6PD deficiencies are furthermore prevalent with frequencies of about 0.1 among Africans, Black Americans, and populations of Mediterranean countries and South East Asia. In Middle and Northern Europe the frequency of G6PD is much lower, and with approximately 0.0005, comparable with the frequency of pyruvate kinase (PK) enzymopathies, the most frequent enzyme deficiency in glycolysis in this area (Luzzatto, 1987; Beutler and Kuhl, 1990). The relationship between the degree of enzyme deficiency and the extent of metabolic dysfunction in red blood cells and other tissues depend on several factors: on the importance of the affected enzyme; its expression rate; the stability of the mutant enzyme against proteolytic degradation and functional abnormalities; the possibility to compensate the deficiency by an overexpression of the corresponding isoenzyme or by the use of an alternative metabolic pathway. Difficulties in estimating the quantitative degree of disorder in severe cases are due to the fact that these populations contain many reticulocytes, which generally have higher enzyme activities and concentrations of intermediates than erythrocytes. An alternative approach to predict metabolic changes is the analysis by mathematical modeling. Mathematical modeling of the main metabolic pathways of human erythrocytes has reached an advanced level (Rapoport et al., 1976; Holzhütter et al., 1985; Schuster et al., 1988). Models have been successfully employed to describe stationary and time-dependent metabolic states of the cell under normal conditions as well as in the presence of enzyme deficiencies. Figure 5 shows computational results of erythrocyte enzyme deficiencies. This analysis is based on the comprehensive mathematical model of the energy and redox metabolism for human erythrocyte presented in Fig. 6. Stationary states of the cell metabolism have been calculated by varying the activity of each of the participating enzymes by several orders of magnitude. To predict consequences of enzyme deficiencies a performance function has been introduced (Schuster and Holzhütter, 1995). It takes into account the homeostasis of three essential metabolic variables: the energetic state (ATP), the reductive capacity (reduced glutathione) and the osmotic state. From the data given in Fig. 5 one can conclude that generally the metabolic impairment resulting in deficiencies occurs earlier for enzymes with high control coefficients than for those catalyzing equilibrium reactions. On the other hand the flux curves of latter enzymes decrease more steeply below a critica

Mutations in the pyruvate kinase L gene in patients with hereditary hemolytic anemia.

We have completely sequenced the introns of the human L-type pyruvate kinase (PK) gene using the published cDNA sequence. Subsequently, DNA from 12 unrelated PK deficiency (PKD) patients of Central European origin was investigated for mutations in this gene by solid-phase sequencing. We detected 10 different mutations, 9 of which result in single amino acid alterations, whereas the tenth destroys a splice site. Eight of the 10 mutations have not been described before. We found 7 missense mutations: G994-->A (Gly-332-->Ser), G1006-->T (Ala-336-->Ser), A1081-->G (Asn-361-->Asp), G1174-->A (Ala-392-->Thr), G1493-->A (Arg-498-->His), G1529-->A (Arg-510-->Gln), C1594-->T (Arg-532-->Trp), one in-frame triplet deletion (del) as well as one insertion (ins): del AAG1060-62 (del Lys-354), ins AGC after C1203 (ins Ser after Cys-401), and one splice-site mutation at the border of intron A to exon 3: g/G283-->a/G. Although the enzymatic properties are substantially changed in all PK mutations, only two affected amino acid positions are in or close to the active site. Mutations C1594-->T, G994-->A, del AAG1060-62 and the splice-site mutation g/G283-->a/G have been detected in two different patients each. Mutation G1529-->A was found in five different alleles. Haplotype analysis with the A/C polymorphism at position 1705 gave evidence for a single origin of this most frequent mutation in PKD as suggested by Baronciani and Beutler (Proc Natl Acad Sci USA 90:4324, 1993). Carrier detection and prenatal diagnosis are now feasible for the affected families.

A miniaturized electrode configuration for isoelectric focusing.

An electrode configuration is described which allows fast isoelectric focusing (IEF) with conventional IEF systems. The equipment, which can be fixed on the cooling plate of a conventional IEF system, consists of a base plate on which flappable electrode holders are fastened. The handling is simple and needs only little time. Graphite rods are used as electrodes, thus avoiding the use of buffer strips. Samples are applied with special applicator strips--permitting the analysis of up to 19 samples on a 50 x 40 mm polyacrylamide gel and up to 44 samples on a 100 x 70 mm gel. Only 30 min are needed for one IEF run.

[A titrographic method for determining the glycolysis flow rate with Plasmodium berghei-infected red blood cells]. / Ein titrographisches Verfahren zur Bestimmung der Glykolyse-Flussrate mit Plasmodium berghei infizierter roter Blutzellen.

A procedure is described for the elucidation of the glycolytic flux rate of red blood cells infected with the malarial parasite Plasmodium berghei. It is based on the titration of the protons originating from the glycolytic lactate accumulation. Compared with traditional methods of biochemical measurements of glucose consumption or accumulation of lactate the proposed procedure shows the following advantages: continuously measurement is possible; constancy of the pH-value during the measurement; lower amounts of biological material are necessary (increased sensitivity) increased accuracy; The method can also be applied to studies on other cells and species with normal or increased glycolytic flux rate.

[Diagnosis of genetically determined diseases]. / Diagnostik genetisch bedingter Erkrankungen.

Enzymopathies of pyruvate kinase are caused by defects of structural genes forming stable and unstable mutants, respectively. Stable mutants of PK are characterized by high S0,5 PEP and nearly unchanged Vmax. A decrease of PEP affinity can be the result from a very high allosteric constant L0 or from an increased KPEP. From the pattern of PAGE can be concluded that stable PK mutants are tetraheteromers composed of two normal and two shortened polypeptide chains. We suppose that this is the result of a mutation of a codon which stops the polypeptide synthesis of PK earlier. Most PK mutants are unstable. They are characterized by low catalytic activity and high PEP affinity. The kinetic properties of unstable mutants are changed posttranslational by proteolytic modifications. Furthermore low S0,5 PEP values result from a persistence of the isoenzyme PK-K in reticulocytes and erythrocytes, respectively. A prenatal diagnosis of PK enzymopathies can be carried out with a very small blood volume by using the method of isoelectrophoretic focussing.

Phosphofructokinase from Plasmodium berghei: a kinetic model of allosteric regulation.

As in mammalian cells, phosphofructokinase (PFK) is of major regulatory importance in the glucose metabolism of Plasmodium berghei. The malarial enzyme shows allosteric properties similar to PFK from various sources; it is activated by fructose-6-phosphate and inhibited by ATP, but differs with respect to allosteric regulation. Enzyme activity is only marginally increased by AMP, a potent activator of many phosphofructokinases. Phosphoenolpyruvate, which is reported to inhibit PFK activity, efficiency activates the malarial enzyme. No activation by ADP was observed. Instead, ADP inhibits the enzyme non-allosterically and competitively to the substrate MgATP. Phosphate stimulates the catalytic activity of malarial PFK independently of the activation by F6P and PEP.