| Polynucleibacter| Polynucleobacter| Polynucleobacter Heckmann and Schmidt 1987 emend. Hahn et al. 2009
Water quality: Polynucleobacter species are commonly found in freshwater lakes, rivers, and reservoirs, where they contribute to the microbial community structure and function. Changes in the abundance or composition of Polynucleobacter populations may reflect alterations in water quality parameters such as nutrient levels, organic matter content, and microbial diversity. Monitoring Polynucleobacter abundance in freshwater ecosystems can provide valuable information about water quality and ecosystem health.
Nutrient cycling: Polynucleobacter species are involved in the cycling of nutrients such as carbon, nitrogen, and phosphorus in freshwater environments. They can utilize various organic and inorganic compounds as carbon and energy sources, contributing to the decomposition of organic matter and the recycling of nutrients. By participating in nutrient cycling processes, Polynucleobacter bacteria help maintain the ecological balance and productivity of freshwater ecosystems.
Microbial interactions: Polynucleobacter species interact with other microorganisms in freshwater environments, including algae, protozoa, and other bacteria. These microbial interactions can influence nutrient dynamics, microbial community structure, and ecosystem functioning. For example, Polynucleobacter bacteria may compete with other bacteria for resources, participate in symbiotic relationships with algae or protozoa, or prey on other microbial cells as predators. Understanding these microbial interactions is important for elucidating the dynamics of freshwater ecosystems.
Ecosystem services: Healthy freshwater ecosystems provide essential ecosystem services that benefit human well-being, including water purification, nutrient cycling, and habitat provision. Polynucleobacter bacteria contribute to the functioning of freshwater ecosystems by participating in biogeochemical cycles, maintaining water quality, and supporting biodiversity. Protecting and conserving freshwater ecosystems, including the microbial communities they harbor, is important for ensuring the provision of these ecosystem services.
A lot more information is available when you are logged in and raise the display level
Other Sources for more information:
Statistics | NCBI | Data Punk | End Products Produced |
Different labs use different software to read the sample. See this post for more details.
One lab may say you have none, another may say you have a lot! - This may be solely due to the software they are using to estimate.
We deem lab specific values using values from the KM method for each specific lab to be the most reliable.
Lab | Frequency | UD-Low | UD-High | KM Low | KM High | Lab Low | Lab High | Mean | Median | Standard Deviation | Box Plot Low | Box Plot High | KM Percentile Low | KM Percentile High |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Other Labs | 0.4 | 1 | 50 | 0 | 45 | 17.3 | 16 | 14.1 | 1 | 50 | 9.1 %ile | 81.8 %ile | ||
biomesight | 16.89 | 0 | 10 | 10 | 50 | 0 | 148 | 34.9 | 20 | 57.8 | 20 | 60 | 0 %ile | 90.3 %ile |
thorne | 93.1 | 3 | 59 | 0 | 37 | 13.7 | 12 | 11.9 | 2 | 20 | 0 %ile | 100 %ile | ||
thryve | 0.27 | 19 | 130 | 0 | 178 | 65 | 46 | 57.9 | 19 | 130 | 20 %ile | 60 %ile |
Source of Ranges | Low Boundary | High Boundary | Low Boundary %age | High Boundary %age |
---|---|---|---|---|
Thorne (20/80%ile) | 4.87 | 10.09 | 0.0005 | 0.001 |
Lab | Frequency Seen | Average | Standard Deviation | Sample Count | Lab Samples |
---|---|---|---|---|---|
BiomeSight | 18.36 % | 0.004 % | 0.005 % | 544.0 | 2963 |
BiomeSightRdp | 6.452 % | 0.002 % | 0 % | 2.0 | 31 |
bugspeak | 100 % | 0.005 % | % | 1.0 | 1 |
CerbaLab | 66.667 % | 0.001 % | 0.001 % | 2.0 | 3 |
custom | 1.639 % | 0.001 % | % | 1.0 | 61 |
es-xenogene | 3.448 % | 0.002 % | % | 1.0 | 29 |
Medivere | 42.857 % | 0.001 % | 0.001 % | 3.0 | 7 |
Thorne | 80.769 % | 0.001 % | 0.001 % | 84.0 | 104 |
Thryve | 0.576 % | 0.01 % | 0.005 % | 8.0 | 1390 |
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