Temporal and Spatial Diversity of the Tap Water Microbiota in a Norwegian Hospital

We analyzed the temporal and spatial diversity of the microbiota in a low-usage and a high-usage hospital tap. We identified a tap-specific colonization pattern, with potential human pathogens being overrepresented in the low-usage tap. We propose that founder effects and local adaptation caused the tap-specific colonization patterns. Our conclusion is that tap-specific colonization represents a potential challenge for water safety.Humans are exposed to and consume large amounts of tap water in their everyday life, with the tap water microbiota representing a potent reservoir for pathogens (8). Despite the potential impact, our knowledge about the ecological diversification processes of the tap water microbiota is limited (4, 11).The aim of the present work was to determine the temporal and spatial distribution patterns of the planktonic tap water microbiota. We compared the summer and winter microbiota from two hospital taps supplied from the same water source. We analyzed 16S rRNA gene clone libraries by using a novel alignment-independent approach for operational taxonomic unit (OTU) designation (6), while established OTU diversity and richness estimators were used for the ecological interpretations.Tap water samples (1 liter) from a high-usage kitchen and a low-usage toilet cold-water tap in Akershus University Hospital, Lørenskog, Norway, were collected in January and July 2006. The total DNA was isolated and the 16S rRNA gene PCR amplified and sequenced. Based on the sequences, we estimated the species richness and diversity, we calculated the distances between the communities, and trees were constructed to reflect the relatedness of the microbiota in the samples analyzed. Details about these analytical approaches are given in the materials and methods section in the supplemental material.Our initial analysis of species composition was done using the RDPII hierarchical classifier. We found that the majority of pathogen-related bacteria in our data set belonged to the class Gammaproteobacteria. The genera encompassed Legionella, Pseudomonas, and Vibrio (Table ​(Table1).1). We found a significant overrepresentation of pathogen-related bacteria in the toilet tap (P = 0.04), while there were no significant differences between summer and winter samples. Legionella showed the highest relative abundance for the pathogen-related bacteria. With respect to the total diversity, we found that Proteobacteria dominated the tap water microbiota (representing 86% of the taxa) (see Table S1 in the supplemental material). There was, however, a large portion (56%) of the taxa that could not be assigned to the genus level using this classifier.

TABLE 1.

Cloned sequences related to human pathogens^a

Specific Degradation of the Mucus Adhesion-Promoting Protein (MapA) of Lactobacillus reuteri to an Antimicrobial Peptide

The intestinal flora of mammals contains lactic acid bacteria (LAB) that may provide positive health effects for the host. Such bacteria are referred to as probiotic bacteria. From a pig, we have isolated a Lactobacillus reuteri strain that produces an antimicrobial peptide (AMP). The peptide was purified and characterized, and it was unequivocally shown that the AMP was a well-defined degradation product obtained from the mucus adhesion-promoting protein (MapA); it was therefore termed AP48-MapA. This finding demonstrates how large proteins might inherit unexpected pleiotropic functions by conferring antimicrobial capacities on the producer. The MapA/AP48-MapA system is the first example where a large protein of an intestinal LAB is shown to give rise to such an AMP. It is also of particular interest that the protein that provides this AMP is associated with the binding of the bacterium producing it to the surface/lining of the gut. This finding gives us new perspective on how some probiotic bacteria may successfully compete in this environment and thereby contribute to a healthy microbiota.Mammals have a microbiota in their digestive tract that contains lactic acid bacteria (LAB). It has been increasingly evident that some of these lactic acid bacteria produce antimicrobial peptides that may contribute to the positive effect on their host. Such bacteria are often referred to as probiotics, and one of their important beneficial effects is their ability to produce antimicrobial compounds that prevent or interfere with the growth of pathogenic bacteria in the host.It is known that the fecal microflora of pigs/piglets is large and diverse and develops rapidly after birth. Lactobacillus reuteri is among the very first lactic acid bacteria that colonize the intestine of new-born piglets, and their numbers gradually increase until they become the most dominant LAB in pigs (5, 17, 28). Other lactobacilli that are also part of the gut microbiota of pigs include L. amylovorus, L. acidophilus, L. salivarius, and L. casei (4, 8). Probiotic isolates have been identified within all these species, and many of them are today used as food/feed supplements to support good health (4, 11, 27). An important part of the antimicrobial arsenal produced by lactic acid bacteria (LAB) is a group of peptides called bacteriocins, which are ribosomally synthesized antibiotic-like peptides (antimicrobial peptides [AMPs]) (3, 7, 19). The bacteriocins constitute a wide range of structurally different peptides that are divided into different classes and subclasses. Some are modified (the lantibiotics, or class I), while others are basically unmodified (class II) (3, 6, 19).Most bacteriocins are derived from prepeptides, each containing a short leader sequence (14 to 30 amino acids [aa]) which is cleaved off during the secretion of the mature peptide (19). In recent years, a new group of AMPs have been recognized (18); these are different from regular bacteriocins in that they are derived from larger proteins through specific degradations, leading to a defined peptide possessing antimicrobial activity. Such antimicrobial peptides have been known for a long time in mammalian systems. For instance, lactoferrin, a protein in milk, is readily degraded to a specific antimicrobial peptide through heat, acid treatment, or pepsin digestion (14, 24, 26). Defined histone fragments with antimicrobial properties have been isolated from different eukaryotic species (1, 2, 15, 21, 23), and a few antimicrobial peptides derived from larger proteins have been isolated in bacteria, including Helicobacter pylori (22), propionic acid bacteria (9, 10), and Clostridium beijerinckii (13). Such antimicrobial peptides are most likely formed by proteolytic degradation during cell proliferation or death.     

Therapeutic vaccination against a murine lymphoma by intratumoral injection of a cationic anticancer peptide

Cationic antimicrobial peptides (CAPs) exhibit promising anticancer activities. In the present study, we have examined the in vivo antitumoral effects of a 9-mer peptide, LTX-302, which is derived from the CAP bovine lactoferricin (LfcinB). A20 B cell lymphomas of BALB/c origin were established by subcutaneous inoculation in syngeneic mice. Intratumoral LTX-302 injection resulted in tumor necrosis and infiltration of inflammatory cells followed by complete regression of the tumors in the majority of the animals. This effect was T cell dependent, since the intervention was inefficient in nude mice. Successfully treated mice were protected against rechallenge with A20 cells, but not against Meth A sarcoma cells. Tumor resistance could be adoptively transferred with spleen cells from LTX-302-treated mice. Resistance was abrogated by depletion of T lymphocytes, or either the CD4⁺ or CD8⁺ T cell subsets. Taken together, these data suggest that LTX-302 treatment induced long-term, specific cellular immunity against the A20 lymphoma and that both CD4⁺ and CD8⁺ T cells were required. Thus, intratumoral administration of lytic peptide might, in addition to providing local tumor control, confer a novel strategy for therapeutic vaccination against cancer.     

The effects of mulching and abandonment on the viability of the perennial grassland species Plantago lanceolata

Abandonment and fragmentation are the primary causes of decline for many light-demanding grassland species in the modern agricultural landscape. In order to maintain a flora rich in such species, design of management practices based upon knowledge of life-history consequences following management shifts is essential. In this study, we investigated the demography of the perennial grassland species Plantago lanceolata for 4 years in one mulched site and two abandoned sites to compare how the two treatments influenced population dynamics. Compared to abandonment, mulching had a small but positive effect on the population growth rate (λ) of P. lanceolata. In both the mulched and the abandoned sites, growth and stasis among the largest plants contributed most strongly to λ, while the contribution of fecundity was negligible in both treatments. λ of P. lanceolata varied more between years than between treatments, most notably because λ values below unity were observed in the abandoned sites in a 1-year period that included a severe winter. The population of the mulched site consisted of larger ramets and had higher clonal growth rates than the populations of the abandoned sites. This explains the apparently higher resilience to unfavorable climatic conditions in the mulched site. We conclude that management by mulching is better than abandonment for the long-term persistence of P. lanceolata. However, due to low recruitment also in the mulched site, even mulching may be insufficient for P. lanceolata to persist over long time periods.     

Meningococcal genome dynamics

Neisseria meningitidis (the meningococcus) is an important commensal, pathogen and model organism that faces up to the environment in its exclusive human host with a small but hyperdynamic genome. Compared with Escherichia coli, several DNA-repair genes are absent in N. meningitidis, whereas the gene products of others interact differently. Instead of responding to external stimuli, the meningococcus spontaneously produces a plethora of genetic variants. The frequent genomic alterations and polymorphisms have profound consequences for the interaction of this microorganism with its host, impacting structural and antigenic changes in crucial surface components that are relevant for adherence and invasion as well as antibiotic resistance and vaccine development.     

Evolutionarily conserved pattern of gene segment usage within the mammalian<Emphasis Type="Italic"> TCRβ</Emphasis> locus

Antigen receptor gene rearrangement is mediated by interactions between the VDJ recombinase and the recombination signal sequences that flank the antigen receptor gene segments. In this report I present phylogenetic analyses that suggest a remarkable evolutionary conservation of the recombination signal sequences flanking some of the orthologous T-cell receptor- locus gene segments between human and mouse. Comparison of published data on the usage of the same gene segments between human and mouse indicates similar conservation in the shape of the primary T-cell receptor- repertoire. I propose that interactions between the recombinase and its cognate recognition sequences play a hitherto underestimated role in the formation of the specific pattern of the primary, combinatorial antigen receptor repertoire and that this pattern appears to be conserved in diverse mammalian species. Generation of a conserved pattern of the primary T-cell receptor repertoire may be critical for efficient selection of immature T lymphocytes.