Impact of probiotics on colonic microflora in patients with colitis: a prospective double blind randomised crossover study.

BACKGROUND & AIMS: The aim of this study was to investigate the spectrum of colonic microflora in patients with colitis and if this could be altered with one month's treatment with synbiotics. METHODS: This was a pilot study in which patients were randomised to either receive a synbiotics preparation for a month and then "crossed over" to receive a placebo, or alternatively to receive the placebo first followed in the second month by synbiotic. Stool samples were collected on entry into the study and then at the end of first and second months respectively. Colonic microflora was measured by terminal restriction fragment length polymorphism technique. Quantitative PCR was used to determine the concentration of individual species. RESULTS: Sixteen patients completed the study of whom 8 had Crohn's colitis and 8 had ulcerative colitis. Their median age was 62 (IQR 50-65) years. An average of 22 terminal restriction fragments (T-RF's) was identified in each patient. Dice cluster analysis showed that each patient had a unique microbial composition which did not change significantly at different time points in the study, irrespective of whether they had probiotics or the placebo. Probiotic organisms were identified in stool samples but did not alter overall spectrum of microflora. In this pilot study we were unable to identify any specific characteristics related to nature of colitis. CONCLUSIONS: This study suggests that there is no difference in colonic microflora between patients with Crohn's or Ulcerative colitis and that the spectrum of bacteria was not altered by synbiotic administration.

Better living through microbial action: the benefits of the mammalian gastrointestinal microbiota on the host.

Mammals live in a homeostatic symbiosis with their gastrointestinal microbiota. The mammalian host provides the microbiota with nutrients and a stable environment; whereas the microbiota helps shaping the host's gut mucosa and provides nutritional contributions. Microorganisms start colonizing the gut immediately after birth followed by a succession of populations until a stable, adult microbiota has been established. However, physiological conditions differ substantially among locations in the gut and determine bacterial density and diversity. While Firmicutes and Bacteroidetes dominate the gut microbiota in all mammals, the bacterial genera and species diversity is huge and reflects mammalian phylogeny. The main function of the gastrointestinal epithelium is to absorb nutrients and to retain water and electrolytes, yet at the same time it is an efficient barrier against harmful compounds and microorganisms, and is able to neutralize antagonists coincidentally breaching the barrier. These processes are influenced by the microbiota, which modify epithelial expression of genes involved in nutrient uptake and metabolism, mucosal barrier function, xenobiotic metabolism, enteric nervous system and motility, hormonal and maturational responses, angiogenesis, cytoskeleton and extracellular matrix, signal transduction, and general cellular functions. Whereas such effects are local at the gut epithelium they may eventually have systemic consequences, e.g. on body weight and composition.

The microbiota of pigs influenced by diet texture and severity of Lawsonia intracellularis infection.

Pigs with and without naturally occurring Lawsonia intracellularis infection were fed diets with different texture. In a previous study from 79 pig herds using a similar feeding on pelleted or non-pelleted form showed that the non-pelleted diet was associated with a reduced prevalence of L. intracellularis. In this study a mechanistic approach was taken for explaining and testing this observation by studying the microbiota and the occurrence of L. intracellularis in the distal ileum of 54 pigs by terminal restriction fragment length polymorphism (T-RFLP) analysis, Real-Time PCR and in situ hybridization. The texture of the diet influenced the microbiota, and from a quantitative discriminative analysis of the terminal restriction fragments (T-RFs) of ileum samples it was deduced that Clostridium spp. and Lactobacillus spp. were associated with the non-pelleted diet and Streptococcus spp. with the pelleted diet. In experimentally infected pigs it was verified that 89bp and 90bp sized T-RFs (HhaI) from ileum represented L. intracellularis. The non-pelleted diet seemed to reduce the relative amount of L. intracellularis in the total microbiota of the ileum, but the number of pigs detected positive with L. intracellularis by Real-Time PCR was not influenced. The five pigs with highest L. intracellularis content showed T-RFs that were not present in profiles from less or non-infected pigs, which may indicate that some bacterial species were associated with L. intracellularis infection.

Antimicrobial treatment reduces intestinal microflora and improves protein digestive capacity without changes in villous structure in weanling pigs.

The immediate post-weaning period is often associated with gut malfunction and diarrhoea for young pigs. Administration of antimicrobials remains an effective way to control weaning diarrhoea but it remains unclear how they affect gut physiology and microbiology although this is a prerequisite for being able to devise better alternatives. Hence, for 7 d we treated pigs, weaned at 24 d of age, with a combination of amoxicillin (25 mg/kg feed and injection of 8.75 mg/kg body weight per 12 h) and ZnO (2.5 g/kg feed). The pigs treated with antimicrobials (n 11) showed no signs of gut malfunction at any time, whereas untreated weaned controls (n 11) developed clinical diarrhoea. The antimicrobial treatment resulted in a higher daily weight gain compared with weaned controls (101 v. -44 g/d, P < 0.0001), whereas both groups had a similar degree of villous atrophy compared with unweaned 24-d-old controls (n 8; P < 0.05). The antimicrobial treatment gave a dramatic reduction in small intestinal microbial diversity, and specifically prevented tissue colonization with Escherichia coli compared with weaned controls. Further, the antimicrobial treatment improved amylase, trypsin and small intestinal aminopeptidase A and N activities (all P < 0.05). Specifically for the colon, the antimicrobial treatment was associated with reduced tissue weight ( -23 %, P < 0.05), reduced concentration of SCFA (P < 0.05), and increased mucosal goblet cell area (P < 0.0001) compared with weaned controls. We conclude that the beneficial effects of antimicrobials are mediated not only through reduction in intestinal bacterial load, but also through a stimulation of protein digestive function and goblet cell density.

Development of an improved species specific PCR test for detection of Haemophilus parasuis.

A PCR test for identification of Haemophilus parasuis was optimized using the 16S rDNA sequences of the 15 serotype reference strains of H. parasuis. The test was evaluated on a collection of 218 Danish field isolates as well as on 81 representatives of 27 other species, including genetically affiliated species within Pasteurellaceae. In addition, DNA preparations from 56 H. parasuis isolates from North America were included. To obtain a test that was specific for H. parasuis, a multiplex PCR using 3 different primers was developed. The PCR test produced an amplicon of approximately 1090 bp only with representatives of H. parasuis. The test was further evaluated on 55 clinical samples from 16 Danish pigs suspected for being infected with H. parasuis, showing polyserositis or septicemia at autopsy as well as on 492 nasal swabs. The test was compared with the performance of a PCR test earlier published by Oliveira et al. [Oliveira, S., Galina, L., Pijoan, C., 2001. Development of a PCR test to diagnose Haemophilus parasuis infections. J. Vet. Diagn. Invest. 13, 495-501]. The sensitivity of the present PCR test was found to be slightly lower when applied on clinical samples from diseased pigs and 10-fold lower when tested on pure cultures of H. parasuis (5CFU and 0.5CFU/PCR reaction, respectively). Addition of 1.4 x 10(5) Escherichia coli to each PCR tube did not alter the sensitivity of the tests. No difference in sensitivity of the tests was observed when tested on purified DNA. On the other hand, the present PCR test was found to be 100% species specific for H. parasuis, in contrast to the PCR test of Oliveira et al., which also tested positive for strains belonging to A. indolicus, A. porcinus, and A. minor, species commonly occurring in the upper respiratory tract. However, when the PCR test of Oliveira et al. is used on samples from systemic locations the chances for false positive results are apparently low. The present PCR test represents a rapid and reliable method for genetically based identification of H. parasuis. The high species specificity of the test makes it suitable for detection of H. parasuis in clinical samples, regardless of the presence of affiliated species and contaminating flora. As the two PCR tests differ in sensitivity and specificity, the use of both PCR tests for different purposes is a possibility.

Estimating amplification efficiency improves multiplex real-time PCR quantification of Bacillus licheniformis and Bacillus subtilis spores in animal feed.

A multiplex real-time PCR assay was developed for absolute quantification in animal feed of Bacillus subtilis CH201 and Bacillus licheniformis CH200 spores, which constitute the viable component of the microbial growth promoter, BioPlus 2B. Spores were lysed using a bead-beating protocol. DNA was extracted and purified from the lysates with the Qiagen DNeasy Plant Kit. Two standard curves for absolute quantification were made and tested. Standard curve-1 was made from feed samples spiked with BioPlus 2B, while standard curve-2 was made from serially diluted DNA extracted from BioPlus 2B powder. Feed samples supplemented with BioPlus 2B were quantified using both standard curves. The detection limit of the assay was 10(4) CFU g(-1) of feed. The amplification efficiency (Eff) of each PCR was determined using the LinRegPCR software and Eff differences between individual samples and standards were corrected for. When compared to plate counts, standard curve-1 slightly under-estimated the number of spores (mean=-2.47% of plate counts). A spore density-dependent Eff was found, and Eff for standard curve-1 could not be determined. Standard curve-2 over-estimated spore numbers when not corrected for individual Eff (mean=+5.46% of plate counts). Standard curve-2 Eff was independent (Eff(mean)=1.96) of spore density. The assay quantified the numbers of spores in feed samples very similar to plate counts (mean=+0.47% of plate counts), when standard curve-2 was used and individual Eff was accounted for.

Freezing at -800 degrees C distorts the DNA composition of bacterial communities in intestinal samples.

Terminal-restriction fragment length polymorphism (T-RFLP) was used to evaluate how to store intestinal specimens for bacterial community analysis. Bacterial communities are increasingly often described by means of DNA-based methods and it is common practice to store intestinal or faecal specimens either at -20 degrees C or -80 degrees C. In this study, samples of intestines from five different pigs were stored at -80 degrees C and -20 degrees C, respectively and a thawing and freezing procedure was carried out three times for each intestinal per pig per temperature. The cumulative sum of the T-RFLP peak heights (T-RF intensities) decreased as the temperature decreased. The composition of the bacterial community changed when stored at -80 degrees C compared to the samples stored at -20 degrees C. Thus it is recommended from this study that samples of intestinal content are stored at -20 degrees C before use for bacterial community analysis, instead of the current practice at -80 degrees C.

Effects of copper amendment on the bacterial community in agricultural soil analyzed by the T-RFLP technique.

Abstract The impact of copper amendment on the bacterial community in agricultural soil was investigated by a 2-year field experiment complemented by short-term microcosm studies. In the field, the amendments led to total copper contents that were close to the safety limits laid down by European authorities. In parallel, bioavailable copper was determined with a copper-specific bioluminescent Pseudomonas reporter strain. The amounts of total Cu as well as of bioavailable Cu in the field declined throughout the experiment. Bacterial community structure was examined by terminal restriction fragment length polymorphism (T-RFLP) analysis of community DNA amplified with primers specific for 16S rDNA from the Bacteria domain, the Rhizobium-Agrobacterium group and the Cytophaga group. Similarity analysis of T-RFLP profiles from field samples demonstrated an impact of copper at the domain level and within the Rhizobium-Agrobacterium group. Comparable Cu effects were observed for microcosms, but in addition an impact on community structure within the Cytophaga group was observed.

Culture-independent analysis of gut bacteria: the pig gastrointestinal tract microbiota revisited.

The phylogenetic diversity of the intestinal bacterial community in pigs was studied by comparative 16S ribosomal DNA (rDNA) sequence analysis. Samples were collected from a total of 24 pigs representing a variety of diets, ages, and herd health status. A library comprising 4,270 cloned 16S rDNA sequences obtained directly by PCR from 52 samples of either the ileum, the cecum, or the colon was constructed. In total, 375 phylotypes were identified using a 97% similarity criterion. Three hundred nine of the phylotypes (83%) had a <97% sequence similarity to any sequences in the database and may represent yet-uncharacterized bacterial genera or species. The phylotypes were affiliated with 13 major phylogenetic lineages. Three hundred four phylotypes (81%) belonged to the low-G+C gram-positive division, and 42 phylotypes (11.2%) were affiliated with the Bacteroides and Prevotella group. Four clusters of phylotypes branching off deeply within the low-G+C gram-positive bacteria and one in the Mycoplasma without any cultured representatives were found. The coverage of all the samples was 97.2%. The relative abundance of the clones approximated a lognormal distribution; however, the phylotypes detected and their abundance varied between two libraries from the same sample. The results document that the intestinal microbial community is very complex and that the majority of the bacterial species colonizing the gastrointestinal tract in pigs have not been characterized.