Pseudomonas sp. TDA1: Difference between revisions

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'''''Escherichia coli''''' ({{IPAc-en|ˌ|ɛ|ʃ|ə|ˈ|r|ɪ|k|i|ə|_|ˈ|k|oʊ|l|aɪ
==Scientific Classification==
}}),<ref>{{OED|coli}}</ref><ref>Wells, J. C. (2000) Longman Pronunciation Dictionary. Harlow [England], Pearson Education Ltd.</ref> also known as '''''E. coli''''' ({{IPAc-en|ˌ|iː|_|ˈ|k|oʊ|l|aɪ
Domain: [[Bacteria]]
}}),<ref>Wells, J. C. (2000) Longman Pronunciation Dictionary. Harlow [England], Pearson Education Ltd.</ref> is a [[Gram-negative bacteria|Gram-negative]], [[Facultative anaerobic organism|facultative anaerobic]], [[Bacillus (shape)|rod-shaped]], [[coliform bacteria|coliform bacterium]] of the [[genus]] ''[[Escherichia]]'' that is commonly found in the lower [[intestine]] of [[warm-blooded]] organisms (endotherms).<ref>{{cite journal | vauthors = Tenaillon O, Skurnik D, Picard B, Denamur E | title = The population genetics of commensal Escherichia coli | journal = Nature Reviews. Microbiology | volume = 8 | issue = 3 | pages = 207–17 | date = March 2010 | pmid = 20157339 | doi = 10.1038/nrmicro2298 }}</ref><ref name="Singleton">{{cite book | author = Singleton P| title = Bacteria in Biology, Biotechnology and Medicine | edition = 5th | publisher = Wiley | year = 1999 | pages= 444–454| isbn = 978-0-471-98880-9}}</ref> Most ''E. coli'' [[Strain (biology)|strains]] are harmless, but some [[serotype]]s can cause serious [[Foodborne illness|food poisoning]] in their hosts, and are occasionally responsible for [[food contamination]] incidents that prompt [[product recall]]s.<ref name="CDC">{{cite web | title=Escherichia coli| work=CDC National Center for Emerging and Zoonotic Infectious Diseases| url=https://www.cdc.gov/ecoli/index.html/ | access-date=2 October 2012}}</ref><ref name="Vogt">{{cite journal | vauthors = Vogt RL, Dippold L | title = Escherichia coli O157:H7 outbreak associated with consumption of ground beef, June-July 2002 | journal = Public Health Reports | volume = 120 | issue = 2 | pages = 174–8 | year = 2005 | pmid = 15842119 | pmc = 1497708 | doi = 10.1177/003335490512000211 }}</ref> The harmless strains are part of the [[Human microbiota|normal microbiota]] of the [[Gut (zoology)|gut]], and can benefit their hosts by producing [[Vitamin K|vitamin K<sub>2</sub>]],<ref name="Bentley">{{cite journal | vauthors = Bentley R, Meganathan R | title = Biosynthesis of vitamin K (menaquinone) in bacteria | journal = Microbiological Reviews | volume = 46 | issue = 3 | pages = 241–80 | date = September 1982 | pmid = 6127606 | pmc = 281544 | doi = 10.1128/MMBR.46.3.241-280.1982 }}</ref> (which helps blood to clot) and preventing colonisation of the intestine with [[pathogenic bacteria]], having a symbiotic relationship.<ref name="Hudault">{{cite journal | vauthors = Hudault S, Guignot J, Servin AL | title = Escherichia coli strains colonising the gastrointestinal tract protect germfree mice against Salmonella typhimurium infection | journal = Gut | volume = 49 | issue = 1 | pages = 47–55 | date = July 2001 | pmid = 11413110 | pmc = 1728375 | doi = 10.1136/gut.49.1.47 }}</ref><ref name="Reid">{{cite journal | vauthors = Reid G, Howard J, Gan BS | title = Can bacterial interference prevent infection? | journal = Trends in Microbiology | volume = 9 | issue = 9 | pages = 424–8 | date = September 2001 | pmid = 11553454 | doi = 10.1016/S0966-842X(01)02132-1 }}</ref> ''E. coli'' is expelled into the environment within fecal matter.  The bacterium grows massively in fresh fecal matter under aerobic conditions for 3 days, but its numbers decline slowly afterwards.<ref name="Russell2001">{{cite journal | vauthors = Russell JB, Jarvis GN | title = Practical mechanisms for interrupting the oral-fecal lifecycle of Escherichia coli | journal = Journal of Molecular Microbiology and Biotechnology | volume = 3 | issue = 2 | pages = 265–72 | date = April 2001 | pmid = 11321582 | doi =  }}</ref>
<br> Phylum: [[Proteobacteria]]
<br> Class: [[Gammaproteobacteria]]
<br> Order: [[Pseudomonadales]]
<br> Family: [[Pseudomonadaceae]]
<br> Genus: [[Pseudomonas]]
<br> Species: P. sp. TDA1


''E. coli'' and other [[facultative anaerobic organism|facultative anaerobes]] constitute about 0.1% of [[gut microbiota]],<ref name="pmid15831718">{{cite journal | vauthors = Eckburg PB, Bik EM, Bernstein CN, Purdom E, Dethlefsen L, Sargent M, Gill SR, Nelson KE, Relman DA | display-authors = 6 | title = Diversity of the human intestinal microbial flora | journal = Science | volume = 308 | issue = 5728 | pages = 1635–8 | date = June 2005 | pmid = 15831718 | pmc = 1395357 | doi = 10.1126/science.1110591 | bibcode = 2005Sci...308.1635E }}</ref> and [[fecal–oral route|fecal–oral transmission]] is the major route through which pathogenic strains of the bacterium cause disease. Cells are able to survive outside the body for a limited amount of time, which makes them potential [[indicator organism]]s to test environmental samples for [[Feces|fecal contamination]].<ref name="Feng_2002">{{cite web |author1=Feng P |author2=Weagant S |author3=Grant, M |title=Enumeration of ''Escherichia coli'' and the Coliform Bacteria |work=Bacteriological Analytical Manual (8th ed.) |publisher=FDA/Center for Food Safety & Applied Nutrition |date=1 September 2002 |url=http://www.cfsan.fda.gov/~ebam/bam-4.html |access-date=25 January 2007 |url-status=dead |archive-url=https://web.archive.org/web/20090519200935/http://www.cfsan.fda.gov/~ebam/bam-4.html |archive-date=19 May 2009 }}</ref><ref name="Thompson">{{cite news |first=Andrea |last=Thompson | name-list-format = vanc |title=E. coli Thrives in Beach Sands |url=http://www.livescience.com/health/070604_beach_ecoli.html |work= |publisher=Live Science |date=4 June 2007 |access-date=3 December 2007 }}</ref> A growing body of research, though, has examined environmentally persistent ''E. coli'' which can survive for  and grow outside a host. <ref>{{cite journal | vauthors = Montealegre MC, Roy S, Böni F, Hossain MI, Navab-Daneshmand T, Caduff L, Faruque AS, Islam MA, Julian TR | display-authors = 6 | title = Risk Factors for Detection, Survival, and Growth of Antibiotic-Resistant and Pathogenic Escherichia coli in Household Soils in Rural Bangladesh | journal = Applied and Environmental Microbiology | volume = 84 | issue = 24 | pages = e01978–18 | date = December 2018 | pmid = 30315075 | pmc = 6275341 | doi = 10.1128/AEM.01978-18 }}</ref>
==Introduction==


The bacterium can be grown and cultured easily and inexpensively in a laboratory setting, and has been intensively investigated for over 60 years. ''E. coli'' is a [[Chemotroph#Chemoheterotroph|chemoheterotroph]] whose chemically defined medium must include a source of carbon and energy.<ref name=":0" /> ''E. coli'' is the most widely studied [[prokaryote|prokaryotic]] [[model organism]], and an important species in the fields of [[biotechnology]] and [[microbiology]], where it has served as the [[host organism]] for the majority of work with [[recombinant DNA]]. Under favorable conditions, it takes as little as 20 minutes to reproduce.<ref>{{cite web|title=Bacteria|url=http://www.microbiologyonline.org.uk/about-microbiology/introducing-microbes/bacteria|publisher=Microbiologyonline|access-date=27 February 2014|archive-url=https://web.archive.org/web/20140227212658/http://www.microbiologyonline.org.uk/about-microbiology/introducing-microbes/bacteria|archive-date=27 February 2014|url-status=live}}</ref>
Pseudomonas sp. TDA1 is a [[gram-negative]], rod-shaped, heterotrophic bacterium. It is a soil-dwelling, solvent-tolerant [[extremophile]] like many of the Pseudomonas genus and was discovered in soil samples from underneath a waste site containing abundant brittle plastic waste, a toxic environment due to the compounds produced by degrading plastic4.


==Biology and biochemistry==
P. sp. TDA1 is remarkable because of its ability to metabolize [[polyurethane]] and its subunits (including P. sp. TDA1’s namesake, 2,4-TDA), which make up polyurethane plastic. This could be of great utility for dealing with the massive amounts of plastic disposed of every year, which currently reside in landfills where they decay to produce toxic, sometimes carcinogenic chemicals8.


==History and Discovery==


===Type and morphology===
The first record of P. sp. TDA1 was published March 27, 2020 in the Frontiers in Microbiology journal. A research team headed by Hermann J. Heipieper of the [[Helmholtz Centre for Environmental Research-UFZ]] in Leipzig, Germany isolated P. sp. TDA1 from a waste site containing many brittle, polyurethane plastics4. The team was searching for a microorganism capable of growing on and metabolizing subunits of polyurethane for use in biorecycling, and they were able to grow a culture of P. sp. TDA1 with only 2,4-TDA as a source of carbon and nitrogen. They used [[16S rRNA]] gene sequencing and membrane fatty acid (MFA) profiling to identify the bacterium as a Pseudomonas sp.; alignment with the RDP database4. P. sp. TDA1 matches many of the characteristics of the Pseudomonas genus: rod-shaped, gram-negative, aerobic, [[chemoorganotrophic]], and able to grow in the absence of organic material5. Pseudomonas species had been documented to attack polyurethane compounds previously, but sp. TDA1 was yet undocumented9.


==Genome==


=== Metabolism ===
The P. sp. TDA1 genome was sequenced in the same study in which the bacterium was discovered in 2020. It is 5,910,795 base pairs long and as is typical of bacteria it is only one chromosome2. Since it was discovered and sequence so recently, information like guanosine-cytosine (GC) content is unavailable at this time. Sequencing was done using an Illumina MiSeq sequencer with a 250-bp paired-end protocol, demultiplexed by MiSeq reporter software, and assembled using the Velvet assembly program. Comparison to the UniprotKB genome database and the basic local alignment search tool (BLAST) database in NCBI was used to suggest enzymes and genes which might have been used in the digestion of polyurethane. These analyses identified many catabolic genes for aromatic compounds, including multiple [[oxygenases]] (which add oxygen from the air to compounds to degrade them)4.
 
==Metabolism==
 
The ability to metabolize polyurethane (PU) monomers and oligomers is the hallmark characteristic of P. sp. TDA1 and the reason it was discovered. Polyurethane polymers and components were able to replace both carbon and nitrogen in the P. sp. TDA1 environment without depriving the bacteria of the nutrients they needed for survival4. The primary polyurethane component focused on is 2,4-TDA.
 
P. sp. TDA1 was grown on an agar plate in a mineral medium with 2,4-TDA (a polyurethane subunit) as the only source of carbon. It did not grow on plates with no carbon source, showing that the bacterium was not autotrophic and was indeed using the 2,4-TDA to survive. Strain TDA1 grew in a nitrogen-deficient media as well, in which 2,4-TDA was both the only carbon and nitrogen source. In both instances, the growth of Pseudomonas sp. TDA1 corresponded to a decrease in 2,4-TDA; high performance liquid chromatography (HPLC) was used to show that the decrease of 2,4-TDA was significantly greater on plates containing P. sp. TDA1 than on control plates with no bacteria4. This demonstrated that P. sp. TDA1 was metabolizing and living off of 2,4-TDA.
 
Researchers proposed a metabolic, oxidative pathway through which the bacterium breaks down the 2,4-TDA. This pathway begins with an electron transferring group hydroxylating the methyl group of 2,4-TDA to a primary alcohol. Next, an [[alcohol dehydrogenase]] and an [[aldehyde dehydrogenase]] catalyze the production of 2,4-diaminobenzoate (4-aminoanthranilate). This anthranilate is proposed to be converted to energy by benzoate 1,2-dioxygenase, with 4-aminocatechol as an intermediate. The ring of 4-aminocatechol could be cleaved through an extradiol and homoprotocatechuate meta-pathway4. As of yet, however, this mechanism still needs to be confirmed by additional biochemical analysis.
 
==Environmental and Industrial Implications==
 
Polyurethane is one of the most universally used plastics, predominantly found in furniture, construction materials, and appliances. Demand for the material is expected to exceed 56 billion U.S. dollars by 2021, with 16 million tons estimated demand in 20166. Part of the reason polyurethane is so popular is its resilience, particularly to heat. It can take up to 1000 years to degrade and is expensive to recycle3. When left in landfills, as it often is, polyurethane introduces toxic chemicals as it slowly breaks down, harming the environment and potentially exposing humans to carcinogens.
 
It is clear that there is an urgent need for a more effective way to deal with polyurethane waste (in addition to reducing plastic consumption).  Researchers are looking for this solution in microbes, leading to the discovery of P. sp. TDA1. While this bacterium could conceivably be recruited to digest plastic waste, researchers have a more ambitious (and industrially applicable) solution in mind: figuring out the mechanism by which this bacterium degrades polyurethane8. This would enable industrial recycling centers to chemically digest polyurethane to its key components en masse. Even more ambitiously, there is the potential to modify these systems to convert harmful, difficult to digest plastic waste into more ecofriendly, biodegradable plastic or simply create novel bioplastics for human use9. These are all future prospects, however, for which the groundwork is only beginning to be laid.
 
==References==
1. A Newly Discovered Microbe Feasts on a Particularly Problematic Plastic. (n.d.). Earther. Retrieved April 6, 2020, from https://earther.gizmodo.com/a-newly-discovered-microbe-feasts-on-a-particularly-pro-1842528893
<br> 2. ASM973719v1—Genome—Assembly—NCBI. (n.d.). Retrieved April 6, 2020, from https://www.ncbi.nlm.nih.gov/assembly/GCF_009737195.1
<br> 3. Chapter 3: 26 Household Items That Don’t Disintegrate In Landfills. (n.d.). The Junkluggers National Hub Site. Retrieved April 6, 2020, from https://www.junkluggers.com/about-us/news-and-events/35424-chapter-3-26-household-items-that-dont-disintegrate-in-landfills.html
<br> 4. Espinosa, M. J. C., Blanco, A. C., Schmidgall, T., Atanasoff-Kardjalieff, A. K., Kappelmeyer, U., Tischler, D., Pieper, D. H., Heipieper, H. J., & Eberlein, C. (2020). Toward Biorecycling: Isolation of a Soil Bacterium That Grows on a Polyurethane Oligomer and Monomer. Frontiers in Microbiology, 11. https://doi.org/10.3389/fmicb.2020.00404
<br> 5. Palleroni, N. J. (2015). Pseudomonas. In Bergey’s Manual of Systematics of Archaea and Bacteria (pp. 1–1). American Cancer Society. https://doi.org/10.1002/9781118960608.gbm01210
<br> 6. Polyurethane Production, Pricing and Market Demand. (n.d.). Retrieved April 6, 2020, from https://www.plasticsinsight.com/resin-intelligence/resin-prices/polyurethane/
<br> 7. Pseudomonas sp. TDA1. (n.d.). Retrieved April 6, 2020, from https://www.uniprot.org/taxonomy/2681304
<br> 8. Scientists identify microbe that could help degrade polyurethane-based plastics. (n.d.-a). Retrieved April 6, 2020, from https://phys.org/news/2020-03-scientists-microbe-degrade-polyurethane-based-plastics.html
<br> 9. Scientists identify microbe that could help degrade polyurethane-based plastics: A strain of an extremophile group of bacteria is capable of ingesting toxic organic compounds as its sole source of carbon, nitrogen and energy. (n.d.-b). ScienceDaily. Retrieved April 6, 2020, from https://www.sciencedaily.com/releases/2020/03/200327081436.htm

Latest revision as of 12:57, 16 December 2022

Scientific Classification

Domain: Bacteria
Phylum: Proteobacteria
Class: Gammaproteobacteria
Order: Pseudomonadales
Family: Pseudomonadaceae
Genus: Pseudomonas
Species: P. sp. TDA1

Introduction

Pseudomonas sp. TDA1 is a gram-negative, rod-shaped, heterotrophic bacterium. It is a soil-dwelling, solvent-tolerant extremophile like many of the Pseudomonas genus and was discovered in soil samples from underneath a waste site containing abundant brittle plastic waste, a toxic environment due to the compounds produced by degrading plastic4.

P. sp. TDA1 is remarkable because of its ability to metabolize polyurethane and its subunits (including P. sp. TDA1’s namesake, 2,4-TDA), which make up polyurethane plastic. This could be of great utility for dealing with the massive amounts of plastic disposed of every year, which currently reside in landfills where they decay to produce toxic, sometimes carcinogenic chemicals8.

History and Discovery

The first record of P. sp. TDA1 was published March 27, 2020 in the Frontiers in Microbiology journal. A research team headed by Hermann J. Heipieper of the Helmholtz Centre for Environmental Research-UFZ in Leipzig, Germany isolated P. sp. TDA1 from a waste site containing many brittle, polyurethane plastics4. The team was searching for a microorganism capable of growing on and metabolizing subunits of polyurethane for use in biorecycling, and they were able to grow a culture of P. sp. TDA1 with only 2,4-TDA as a source of carbon and nitrogen. They used 16S rRNA gene sequencing and membrane fatty acid (MFA) profiling to identify the bacterium as a Pseudomonas sp.; alignment with the RDP database4. P. sp. TDA1 matches many of the characteristics of the Pseudomonas genus: rod-shaped, gram-negative, aerobic, chemoorganotrophic, and able to grow in the absence of organic material5. Pseudomonas species had been documented to attack polyurethane compounds previously, but sp. TDA1 was yet undocumented9.

Genome

The P. sp. TDA1 genome was sequenced in the same study in which the bacterium was discovered in 2020. It is 5,910,795 base pairs long and as is typical of bacteria it is only one chromosome2. Since it was discovered and sequence so recently, information like guanosine-cytosine (GC) content is unavailable at this time. Sequencing was done using an Illumina MiSeq sequencer with a 250-bp paired-end protocol, demultiplexed by MiSeq reporter software, and assembled using the Velvet assembly program. Comparison to the UniprotKB genome database and the basic local alignment search tool (BLAST) database in NCBI was used to suggest enzymes and genes which might have been used in the digestion of polyurethane. These analyses identified many catabolic genes for aromatic compounds, including multiple oxygenases (which add oxygen from the air to compounds to degrade them)4.

Metabolism

The ability to metabolize polyurethane (PU) monomers and oligomers is the hallmark characteristic of P. sp. TDA1 and the reason it was discovered. Polyurethane polymers and components were able to replace both carbon and nitrogen in the P. sp. TDA1 environment without depriving the bacteria of the nutrients they needed for survival4. The primary polyurethane component focused on is 2,4-TDA.

P. sp. TDA1 was grown on an agar plate in a mineral medium with 2,4-TDA (a polyurethane subunit) as the only source of carbon. It did not grow on plates with no carbon source, showing that the bacterium was not autotrophic and was indeed using the 2,4-TDA to survive. Strain TDA1 grew in a nitrogen-deficient media as well, in which 2,4-TDA was both the only carbon and nitrogen source. In both instances, the growth of Pseudomonas sp. TDA1 corresponded to a decrease in 2,4-TDA; high performance liquid chromatography (HPLC) was used to show that the decrease of 2,4-TDA was significantly greater on plates containing P. sp. TDA1 than on control plates with no bacteria4. This demonstrated that P. sp. TDA1 was metabolizing and living off of 2,4-TDA.

Researchers proposed a metabolic, oxidative pathway through which the bacterium breaks down the 2,4-TDA. This pathway begins with an electron transferring group hydroxylating the methyl group of 2,4-TDA to a primary alcohol. Next, an alcohol dehydrogenase and an aldehyde dehydrogenase catalyze the production of 2,4-diaminobenzoate (4-aminoanthranilate). This anthranilate is proposed to be converted to energy by benzoate 1,2-dioxygenase, with 4-aminocatechol as an intermediate. The ring of 4-aminocatechol could be cleaved through an extradiol and homoprotocatechuate meta-pathway4. As of yet, however, this mechanism still needs to be confirmed by additional biochemical analysis.

Environmental and Industrial Implications

Polyurethane is one of the most universally used plastics, predominantly found in furniture, construction materials, and appliances. Demand for the material is expected to exceed 56 billion U.S. dollars by 2021, with 16 million tons estimated demand in 20166. Part of the reason polyurethane is so popular is its resilience, particularly to heat. It can take up to 1000 years to degrade and is expensive to recycle3. When left in landfills, as it often is, polyurethane introduces toxic chemicals as it slowly breaks down, harming the environment and potentially exposing humans to carcinogens.

It is clear that there is an urgent need for a more effective way to deal with polyurethane waste (in addition to reducing plastic consumption). Researchers are looking for this solution in microbes, leading to the discovery of P. sp. TDA1. While this bacterium could conceivably be recruited to digest plastic waste, researchers have a more ambitious (and industrially applicable) solution in mind: figuring out the mechanism by which this bacterium degrades polyurethane8. This would enable industrial recycling centers to chemically digest polyurethane to its key components en masse. Even more ambitiously, there is the potential to modify these systems to convert harmful, difficult to digest plastic waste into more ecofriendly, biodegradable plastic or simply create novel bioplastics for human use9. These are all future prospects, however, for which the groundwork is only beginning to be laid.

References

1. A Newly Discovered Microbe Feasts on a Particularly Problematic Plastic. (n.d.). Earther. Retrieved April 6, 2020, from https://earther.gizmodo.com/a-newly-discovered-microbe-feasts-on-a-particularly-pro-1842528893
2. ASM973719v1—Genome—Assembly—NCBI. (n.d.). Retrieved April 6, 2020, from https://www.ncbi.nlm.nih.gov/assembly/GCF_009737195.1
3. Chapter 3: 26 Household Items That Don’t Disintegrate In Landfills. (n.d.). The Junkluggers National Hub Site. Retrieved April 6, 2020, from https://www.junkluggers.com/about-us/news-and-events/35424-chapter-3-26-household-items-that-dont-disintegrate-in-landfills.html
4. Espinosa, M. J. C., Blanco, A. C., Schmidgall, T., Atanasoff-Kardjalieff, A. K., Kappelmeyer, U., Tischler, D., Pieper, D. H., Heipieper, H. J., & Eberlein, C. (2020). Toward Biorecycling: Isolation of a Soil Bacterium That Grows on a Polyurethane Oligomer and Monomer. Frontiers in Microbiology, 11. https://doi.org/10.3389/fmicb.2020.00404
5. Palleroni, N. J. (2015). Pseudomonas. In Bergey’s Manual of Systematics of Archaea and Bacteria (pp. 1–1). American Cancer Society. https://doi.org/10.1002/9781118960608.gbm01210
6. Polyurethane Production, Pricing and Market Demand. (n.d.). Retrieved April 6, 2020, from https://www.plasticsinsight.com/resin-intelligence/resin-prices/polyurethane/
7. Pseudomonas sp. TDA1. (n.d.). Retrieved April 6, 2020, from https://www.uniprot.org/taxonomy/2681304
8. Scientists identify microbe that could help degrade polyurethane-based plastics. (n.d.-a). Retrieved April 6, 2020, from https://phys.org/news/2020-03-scientists-microbe-degrade-polyurethane-based-plastics.html
9. Scientists identify microbe that could help degrade polyurethane-based plastics: A strain of an extremophile group of bacteria is capable of ingesting toxic organic compounds as its sole source of carbon, nitrogen and energy. (n.d.-b). ScienceDaily. Retrieved April 6, 2020, from https://www.sciencedaily.com/releases/2020/03/200327081436.htm