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16S ribosomal RNA

April 26, 2024

For the mitochondrially encoded 16S RNA, see MT-RNR2.

16S ribosomal RNA (or 16S rRNA) is the RNA component of the 30S subunit of a prokaryotic ribosome (SSU rRNA). It binds to the Shine-Dalgarno sequence and provides most of the SSU structure.

Molecular structure of the 30S Subunit from Thermus thermophilus. Proteins are shown in blue and the single RNA strand in orange.[1]

The genes coding for it are referred to as 16S rRNA genes and are used in reconstructing phylogenies, due to the slow rates of evolution of this region of the gene.[2] Carl Woese and George E. Fox were two of the people who pioneered the use of 16S rRNA in phylogenetics in 1977.[3] Multiple sequences of the 16S rRNA gene can exist within a single bacterium.[4]

Functions edit

Structure edit

 
SSU Ribosomal RNA, bacteria and archaea. From Woese 1987.[6]

Universal primers edit

The 16S rRNA gene is used for phylogenetic studies[7] as it is highly conserved between different species of bacteria and archaea.[8] Carl Woese pioneered this use of 16S rRNA in 1977.[2] It is suggested that 16S rRNA gene can be used as a reliable molecular clock because 16S rRNA sequences from distantly related bacterial lineages are shown to have similar functionalities.[9] Some thermophilic archaea (e.g. order Thermoproteales) contain 16S rRNA gene introns that are located in highly conserved regions and can impact the annealing of "universal" primers.[10] Mitochondrial and chloroplastic rRNA are also amplified.[11]

The most common primer pair was devised by Weisburg et al. (1991)[7] and is currently referred to as 27F and 1492R; however, for some applications shorter amplicons may be necessary, for example for 454 sequencing with titanium chemistry the primer pair 27F-534R covering V1 to V3.[12] Often 8F is used rather than 27F. The two primers are almost identical, but 27F has an M instead of a C. AGAGTTTGATCMTGGCTCAG compared with 8F.[13]

Primer name Sequence (5–3) Ref.
8F AGA GTT TGA TCC TGG CTC AG [14][15]
27F AGA GTT TGA TCM TGG CTC AG [13]
336R ACT GCT GCS YCC CGT AGG AGT CT [16]
337F GAC TCC TAC GGG AGG CWG CAG [17]
518R GTA TTA CCG CGG CTG CTG G
533F GTG CCA GCM GCC GCG GTA A
785F GGA TTA GAT ACC CTG GTA
806R GGA CTA CVS GGG TAT CTA AT [18][19]
907R CCG TCA ATT CCT TTR AGT TT
928F TAA AAC TYA AAK GAA TTG ACG GG [16]
1100F YAA CGA GCG CAA CCC
1100R GGG TTG CGC TCG TTG
U1492R GGT TAC CTT GTT ACG ACT T [14][15]
1492R CGG TTA CCT TGT TAC GAC TT [20]

PCR and NGS applications edit

In addition to highly conserved primer binding sites, 16S rRNA gene sequences contain hypervariable regions that can provide species-specific signature sequences useful for identification of bacteria.[21][22] As a result, 16S rRNA gene sequencing has become prevalent in medical microbiology as a rapid and cheap alternative to phenotypic methods of bacterial identification.[23] Although it was originally used to identify bacteria, 16S sequencing was subsequently found to be capable of reclassifying bacteria into completely new species,[24] or even genera.[7][25] It has also been used to describe new species that have never been successfully cultured.[26][27] With third-generation sequencing coming to many labs, simultaneous identification of thousands of 16S rRNA sequences is possible within hours, allowing metagenomic studies, for example of gut flora.[28]

Hypervariable regions edit

The bacterial 16S gene contains nine hypervariable regions (V1–V9), ranging from about 30 to 100 base pairs long, that are involved in the secondary structure of the small ribosomal subunit.[29] The degree of conservation varies widely between hypervariable regions, with more conserved regions correlating to higher-level taxonomy and less conserved regions to lower levels, such as genus and species.[30] While the entire 16S sequence allows for comparison of all hypervariable regions, at approximately 1,500 base pairs long it can be prohibitively expensive for studies seeking to identify or characterize diverse bacterial communities.[30] These studies commonly utilize the Illumina platform, which produces reads at rates 50-fold and 12,000-fold less expensive than 454 pyrosequencing and Sanger sequencing, respectively.[31] While cheaper and allowing for deeper community coverage, Illumina sequencing only produces reads 75–250 base pairs long (up to 300 base pairs with Illumina MiSeq), and has no established protocol for reliably assembling the full gene in community samples.[32] Full hypervariable regions can be assembled from a single Illumina run, however, making them ideal targets for the platform.[32]

While 16S hypervariable regions can vary dramatically between bacteria, the 16S gene as a whole maintains greater length homogeneity than its eukaryotic counterpart (18S ribosomal RNA), which can make alignments easier.[33] Additionally, the 16S gene contains highly conserved sequences between hypervariable regions, enabling the design of universal primers that can reliably produce the same sections of the 16S sequence across different taxa.[34] Although no hypervariable region can accurately classify all bacteria from domain to species, some can reliably predict specific taxonomic levels.[30] Many community studies select semi-conserved hypervariable regions like the V4 for this reason, as it can provide resolution at the phylum level as accurately as the full 16S gene.[30] While lesser-conserved regions struggle to classify new species when higher order taxonomy is unknown, they are often used to detect the presence of specific pathogens. In one study by Chakravorty et al. in 2007, the authors characterized the V1–V8 regions of a variety of pathogens in order to determine which hypervariable regions would be most useful to include for disease-specific and broad assays.[35] Amongst other findings, they noted that the V3 region was best at identifying the genus for all pathogens tested, and that V6 was the most accurate at differentiating species between all CDC-watched pathogens tested, including anthrax.[35]

While 16S hypervariable region analysis is a powerful tool for bacterial taxonomic studies, it struggles to differentiate between closely related species.[34] In the families Enterobacteriaceae, Clostridiaceae, and Peptostreptococcaceae, species can share up to 99% sequence similarity across the full 16S gene.[36] As a result, the V4 sequences can differ by only a few nucleotides, leaving reference databases unable to reliably classify these bacteria at lower taxonomic levels.[36] By limiting 16S analysis to select hypervariable regions, these studies can fail to observe differences in closely related taxa and group them into single taxonomic units, therefore underestimating the total diversity of the sample.[34] Furthermore, bacterial genomes can house multiple 16S genes, with the V1, V2, and V6 regions containing the greatest intraspecies diversity.[8] While not the most precise method of classifying bacterial species, analysis of the hypervariable regions remains one of the most useful tools available to bacterial community studies.[36]

Promiscuity of 16S rRNA genes edit

Under the assumption that evolution is driven by vertical transmission, 16S rRNA genes have long been believed to be species-specific, and infallible as genetic markers inferring phylogenetic relationships among prokaryotes. However, a growing number of observations suggest the occurrence of horizontal transfer of these genes. In addition to observations of natural occurrence, transferability of these genes is supported experimentally using a specialized Escherichia coli genetic system. Using a null mutant of E. coli as host, growth of the mutant strain was shown to be complemented by foreign 16S rRNA genes that were phylogenetically distinct from E. coli at the phylum level.[37][38] Such functional compatibility was also seen in Thermus thermophilus.[39] Furthermore, in T. thermophilus, both complete and partial gene transfer was observed. Partial transfer resulted in spontaneous generation of apparently random chimera between host and foreign bacterial genes. Thus, 16S rRNA genes may have evolved through multiple mechanisms, including vertical inheritance and horizontal gene transfer; the frequency of the latter may be much higher than previously thought.[40]

16S ribosomal databases edit

The 16S rRNA gene is used as the standard for classification and identification of microbes, because it is present in most microbes and shows proper changes.[41] Type strains of 16S rRNA gene sequences for most bacteria and archaea are available on public databases, such as NCBI. However, the quality of the sequences found on these databases is often not validated. Therefore, secondary databases that collect only 16S rRNA sequences are widely used. The most frequently used databases are listed below:

MIMt edit

MIMt is a compact non-redundant 16S database for a rapid metagenomic samples identification. It is composed of 39.940 full 16S sequences belonging to 17,625 well classified bacteria and archaea species. All sequences were obtained from complete genomes deposited in NCBI and for each of the sequences full taxonomic hierarchy is provided. It contains no redundancy, so only one representative for each species was considered avoiding same sequences from differente strains, isolates or patovars resulting in a very fast tool for microorganisms identification, compatible with any classification software (QIIME, Mothur, DADA, etc).[42]

EzBioCloud edit

EzBioCloud database, formerly known as EzTaxon, consists of a complete hierarchical taxonomic system containing 62,988 bacteria and archaea species/phylotypes which includes 15,290 valid published names as of September 2018. Based on the phylogenetic relationship such as maximum-likelihood and OrthoANI, all species/subspecies are represented by at least one 16S rRNA gene sequence. The EzBioCloud database is systematically curated and updated regularly which also includes novel candidate species. Moreover, the website provides bioinformatics tools such as ANI calculator, ContEst16S and 16S rRNA DB for QIIME and Mothur pipeline.[43]^^

Ribosomal Database Project edit

The Ribosomal Database Project (RDP) is a curated database that offers ribosome data along with related programs and services. The offerings include phylogenetically ordered alignments of ribosomal RNA (rRNA) sequences, derived phylogenetic trees, rRNA secondary structure diagrams and various software packages for handling, analyzing and displaying alignments and trees. The data are available via ftp and electronic mail. Certain analytic services are also provided by the electronic mail server.[44] Due to its large size the RDP database is often used as the basis for bioinformatic tool development and creating manually curated databases.[45]

SILVA edit

SILVA provides comprehensive, quality checked and regularly updated datasets of aligned small (16S/18S, SSU) and large subunit (23S/28S, LSU) ribosomal RNA (rRNA) sequences for all three domains of life as well as a suite of search, primer-design and alignment tools (Bacteria, Archaea and Eukarya).[46]

GreenGenes edit

GreenGenes is a quality controlled, comprehensive 16S rRNA gene reference database and taxonomy based on a de novo phylogeny that provides standard operational taxonomic unit sets. Beware that it utilizes taxonomic terms proposed from phylogenetic methods applied years ago between 2012 and 2013. Since then, a variety of novel phylogenetic methods have been proposed for Archaea and Bacteria.[47][48]

References edit

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External links edit

  • University of Washington Laboratory Medicine: Molecular Diagnosis | Bacterial Sequencing
  • MIMt 16S database
  • The Ribosomal Database Project 2020-08-19 at the Wayback Machine
  • Ribosomes and Ribosomal RNA: (rRNA)
  • SILVA rRNA database

April 26, 2024
ribosomal, mitochondrially, encoded, rnr2, this, article, missing, information, about, rfam, rrna, bacteria, rrna, archaea, please, expand, article, include, this, information, further, details, exist, talk, page, december, 2020, rrna, component, subunit, prok. For the mitochondrially encoded 16S RNA see MT RNR2 This article is missing information about Rfam SSU rRNA bacteria SSU rRNA archaea Please expand the article to include this information Further details may exist on the talk page December 2020 16S ribosomal RNA or 16S rRNA is the RNA component of the 30S subunit of a prokaryotic ribosome SSU rRNA It binds to the Shine Dalgarno sequence and provides most of the SSU structure Molecular structure of the 30S Subunit from Thermus thermophilus Proteins are shown in blue and the single RNA strand in orange 1 The genes coding for it are referred to as 16S rRNA genes and are used in reconstructing phylogenies due to the slow rates of evolution of this region of the gene 2 Carl Woese and George E Fox were two of the people who pioneered the use of 16S rRNA in phylogenetics in 1977 3 Multiple sequences of the 16S rRNA gene can exist within a single bacterium 4 Contents 1 Functions 2 Structure 3 Universal primers 3 1 PCR and NGS applications 3 2 Hypervariable regions 4 Promiscuity of 16S rRNA genes 5 16S ribosomal databases 5 1 MIMt 5 2 EzBioCloud 5 3 Ribosomal Database Project 5 4 SILVA 5 5 GreenGenes 6 References 7 External linksFunctions editLike the large 23S ribosomal RNA it has a structural role acting as a scaffold defining the positions of the ribosomal proteins The 3 end contains the anti Shine Dalgarno sequence which binds upstream to the AUG start codon on the mRNA The 3 end of 16S RNA binds to the proteins S1 and S21 which are known to be involved in initiation of protein synthesis 5 Interacts with 23S aiding in the binding of the two ribosomal subunits 50S and 30S Stabilizes correct codon anticodon pairing in the A site by forming a hydrogen bond between the N1 atom of adenine residues 1492 and 1493 and the 2 OH group of the mRNA backbone Structure edit nbsp SSU Ribosomal RNA bacteria and archaea From Woese 1987 6 Universal primers editThe 16S rRNA gene is used for phylogenetic studies 7 as it is highly conserved between different species of bacteria and archaea 8 Carl Woese pioneered this use of 16S rRNA in 1977 2 It is suggested that 16S rRNA gene can be used as a reliable molecular clock because 16S rRNA sequences from distantly related bacterial lineages are shown to have similar functionalities 9 Some thermophilic archaea e g order Thermoproteales contain 16S rRNA gene introns that are located in highly conserved regions and can impact the annealing of universal primers 10 Mitochondrial and chloroplastic rRNA are also amplified 11 The most common primer pair was devised by Weisburg et al 1991 7 and is currently referred to as 27F and 1492R however for some applications shorter amplicons may be necessary for example for 454 sequencing with titanium chemistry the primer pair 27F 534R covering V1 to V3 12 Often 8F is used rather than 27F The two primers are almost identical but 27F has an M instead of a C AGAGTTTGATCMTGGCTCAG compared with 8F 13 Primer name Sequence 5 3 Ref 8F AGA GTT TGA TCC TGG CTC AG 14 15 27F AGA GTT TGA TCM TGG CTC AG 13 336R ACT GCT GCS YCC CGT AGG AGT CT 16 337F GAC TCC TAC GGG AGG CWG CAG 17 518R GTA TTA CCG CGG CTG CTG G 533F GTG CCA GCM GCC GCG GTA A 785F GGA TTA GAT ACC CTG GTA 806R GGA CTA CVS GGG TAT CTA AT 18 19 907R CCG TCA ATT CCT TTR AGT TT 928F TAA AAC TYA AAK GAA TTG ACG GG 16 1100F YAA CGA GCG CAA CCC 1100R GGG TTG CGC TCG TTG U1492R GGT TAC CTT GTT ACG ACT T 14 15 1492R CGG TTA CCT TGT TAC GAC TT 20 PCR and NGS applications edit In addition to highly conserved primer binding sites 16S rRNA gene sequences contain hypervariable regions that can provide species specific signature sequences useful for identification of bacteria 21 22 As a result 16S rRNA gene sequencing has become prevalent in medical microbiology as a rapid and cheap alternative to phenotypic methods of bacterial identification 23 Although it was originally used to identify bacteria 16S sequencing was subsequently found to be capable of reclassifying bacteria into completely new species 24 or even genera 7 25 It has also been used to describe new species that have never been successfully cultured 26 27 With third generation sequencing coming to many labs simultaneous identification of thousands of 16S rRNA sequences is possible within hours allowing metagenomic studies for example of gut flora 28 Hypervariable regions edit The bacterial 16S gene contains nine hypervariable regions V1 V9 ranging from about 30 to 100 base pairs long that are involved in the secondary structure of the small ribosomal subunit 29 The degree of conservation varies widely between hypervariable regions with more conserved regions correlating to higher level taxonomy and less conserved regions to lower levels such as genus and species 30 While the entire 16S sequence allows for comparison of all hypervariable regions at approximately 1 500 base pairs long it can be prohibitively expensive for studies seeking to identify or characterize diverse bacterial communities 30 These studies commonly utilize the Illumina platform which produces reads at rates 50 fold and 12 000 fold less expensive than 454 pyrosequencing and Sanger sequencing respectively 31 While cheaper and allowing for deeper community coverage Illumina sequencing only produces reads 75 250 base pairs long up to 300 base pairs with Illumina MiSeq and has no established protocol for reliably assembling the full gene in community samples 32 Full hypervariable regions can be assembled from a single Illumina run however making them ideal targets for the platform 32 While 16S hypervariable regions can vary dramatically between bacteria the 16S gene as a whole maintains greater length homogeneity than its eukaryotic counterpart 18S ribosomal RNA which can make alignments easier 33 Additionally the 16S gene contains highly conserved sequences between hypervariable regions enabling the design of universal primers that can reliably produce the same sections of the 16S sequence across different taxa 34 Although no hypervariable region can accurately classify all bacteria from domain to species some can reliably predict specific taxonomic levels 30 Many community studies select semi conserved hypervariable regions like the V4 for this reason as it can provide resolution at the phylum level as accurately as the full 16S gene 30 While lesser conserved regions struggle to classify new species when higher order taxonomy is unknown they are often used to detect the presence of specific pathogens In one study by Chakravorty et al in 2007 the authors characterized the V1 V8 regions of a variety of pathogens in order to determine which hypervariable regions would be most useful to include for disease specific and broad assays 35 Amongst other findings they noted that the V3 region was best at identifying the genus for all pathogens tested and that V6 was the most accurate at differentiating species between all CDC watched pathogens tested including anthrax 35 While 16S hypervariable region analysis is a powerful tool for bacterial taxonomic studies it struggles to differentiate between closely related species 34 In the families Enterobacteriaceae Clostridiaceae and Peptostreptococcaceae species can share up to 99 sequence similarity across the full 16S gene 36 As a result the V4 sequences can differ by only a few nucleotides leaving reference databases unable to reliably classify these bacteria at lower taxonomic levels 36 By limiting 16S analysis to select hypervariable regions these studies can fail to observe differences in closely related taxa and group them into single taxonomic units therefore underestimating the total diversity of the sample 34 Furthermore bacterial genomes can house multiple 16S genes with the V1 V2 and V6 regions containing the greatest intraspecies diversity 8 While not the most precise method of classifying bacterial species analysis of the hypervariable regions remains one of the most useful tools available to bacterial community studies 36 Promiscuity of 16S rRNA genes editUnder the assumption that evolution is driven by vertical transmission 16S rRNA genes have long been believed to be species specific and infallible as genetic markers inferring phylogenetic relationships among prokaryotes However a growing number of observations suggest the occurrence of horizontal transfer of these genes In addition to observations of natural occurrence transferability of these genes is supported experimentally using a specialized Escherichia coli genetic system Using a null mutant of E coli as host growth of the mutant strain was shown to be complemented by foreign 16S rRNA genes that were phylogenetically distinct from E coli at the phylum level 37 38 Such functional compatibility was also seen in Thermus thermophilus 39 Furthermore in T thermophilus both complete and partial gene transfer was observed Partial transfer resulted in spontaneous generation of apparently random chimera between host and foreign bacterial genes Thus 16S rRNA genes may have evolved through multiple mechanisms including vertical inheritance and horizontal gene transfer the frequency of the latter may be much higher than previously thought 40 16S ribosomal databases editThe 16S rRNA gene is used as the standard for classification and identification of microbes because it is present in most microbes and shows proper changes 41 Type strains of 16S rRNA gene sequences for most bacteria and archaea are available on public databases such as NCBI However the quality of the sequences found on these databases is often not validated Therefore secondary databases that collect only 16S rRNA sequences are widely used The most frequently used databases are listed below MIMt edit MIMt is a compact non redundant 16S database for a rapid metagenomic samples identification It is composed of 39 940 full 16S sequences belonging to 17 625 well classified bacteria and archaea species All sequences were obtained from complete genomes deposited in NCBI and for each of the sequences full taxonomic hierarchy is provided It contains no redundancy so only one representative for each species was considered avoiding same sequences from differente strains isolates or patovars resulting in a very fast tool for microorganisms identification compatible with any classification software QIIME Mothur DADA etc 42 EzBioCloud edit EzBioCloud database formerly known as EzTaxon consists of a complete hierarchical taxonomic system containing 62 988 bacteria and archaea species phylotypes which includes 15 290 valid published names as of September 2018 Based on the phylogenetic relationship such as maximum likelihood and OrthoANI all species subspecies are represented by at least one 16S rRNA gene sequence The EzBioCloud database is systematically curated and updated regularly which also includes novel candidate species Moreover the website provides bioinformatics tools such as ANI calculator ContEst16S and 16S rRNA DB for QIIME and Mothur pipeline 43 Ribosomal Database Project edit The Ribosomal Database Project RDP is a curated database that offers ribosome data along with related programs and services The offerings include phylogenetically ordered alignments of ribosomal RNA rRNA sequences derived phylogenetic trees rRNA secondary structure diagrams and various software packages for handling analyzing and displaying alignments and trees The data are available via ftp and electronic mail Certain analytic services are also provided by the electronic mail server 44 Due to its large size the RDP database is often used as the basis for bioinformatic tool development and creating manually curated databases 45 SILVA edit SILVA provides comprehensive quality checked and regularly updated datasets of aligned small 16S 18S SSU and large subunit 23S 28S LSU ribosomal RNA rRNA sequences for all three domains of life as well as a suite of search primer design and alignment tools Bacteria Archaea and Eukarya 46 GreenGenes edit GreenGenes is a quality controlled comprehensive 16S rRNA gene reference database and taxonomy based on a de novo phylogeny that provides standard operational taxonomic unit sets Beware that it utilizes taxonomic terms proposed from phylogenetic methods applied years ago between 2012 and 2013 Since then a variety of novel phylogenetic methods have been proposed for Archaea and Bacteria 47 48 References edit Schluenzen F Tocilj A Zarivach R Harms J Gluehmann M Janell D et al September 2000 Structure of functionally activated small ribosomal subunit at 3 3 angstroms resolution Cell 102 5 615 623 doi 10 1016 S0092 8674 00 00084 2 PMID 11007480 S2CID 1024446 a b Woese CR Fox GE November 1977 Phylogenetic structure of the prokaryotic domain the primary kingdoms Proceedings of the National Academy of Sciences of the United States of America 74 11 5088 5090 Bibcode 1977PNAS 74 5088W doi 10 1073 pnas 74 11 5088 PMC 432104 PMID 270744 nbsp Woese CR Kandler O Wheelis ML June 1990 Towards a natural system of organisms proposal for the domains Archaea Bacteria and Eucarya Proceedings of the National Academy of Sciences of the United States of America 87 12 4576 4579 Bibcode 1990PNAS 87 4576W doi 10 1073 pnas 87 12 4576 PMC 54159 PMID 2112744 Case RJ Boucher Y Dahllof I Holmstrom C Doolittle WF Kjelleberg S January 2007 Use of 16S rRNA and rpoB genes as molecular markers for microbial ecology studies Applied and Environmental Microbiology 73 1 278 288 Bibcode 2007ApEnM 73 278C doi 10 1128 AEM 01177 06 PMC 1797146 PMID 17071787 Czernilofsky AP Kurland CG Stoffler G October 1975 30S ribosomal proteins associated with the 3 terminus of 16S RNA FEBS Letters 58 1 281 284 doi 10 1016 0014 5793 75 80279 1 PMID 1225593 S2CID 22941368 Woese CR June 1987 Bacterial evolution Microbiological Reviews 51 2 221 271 doi 10 1128 MR 51 2 221 271 1987 PMC 373105 PMID 2439888 a b c Weisburg WG Barns SM Pelletier DA Lane DJ January 1991 16S ribosomal DNA amplification for phylogenetic study Journal of Bacteriology 173 2 697 703 doi 10 1128 jb 173 2 697 703 1991 PMC 207061 PMID 1987160 a b Coenye T Vandamme P November 2003 Intragenomic heterogeneity between multiple 16S ribosomal RNA operons in sequenced bacterial genomes FEMS Microbiology Letters 228 1 45 49 doi 10 1016 S0378 1097 03 00717 1 PMID 14612235 Tsukuda M Kitahara K Miyazaki K August 2017 Comparative RNA function analysis reveals high functional similarity between distantly related bacterial 16 S rRNAs Scientific Reports 7 1 9993 Bibcode 2017NatSR 7 9993T doi 10 1038 s41598 017 10214 3 PMC 5577257 PMID 28855596 Jay ZJ Inskeep WP July 2015 The distribution diversity and importance of 16S rRNA gene introns in the order Thermoproteales Biology Direct 10 35 35 doi 10 1186 s13062 015 0065 6 PMC 4496867 PMID 26156036 Walker Sidney P Barrett Maurice Hogan Glenn Flores Bueso Yensi Claesson Marcus J Tangney Mark 2020 10 01 Non specific amplification of human DNA is a major challenge for 16S rRNA gene sequence analysis Scientific Reports 10 1 16356 doi 10 1038 s41598 020 73403 7 ISSN 2045 2322 PMC 7529756 PMID 33004967 Human Microbiome Project DACC Home www hmpdacc org Archived from the original on 2010 10 30 a b Primers 16S ribosomal DNA Francois Lutzoni s Lab lutzonilab net Archived from the original on 2012 12 27 a b Eden PA Schmidt TM Blakemore RP Pace NR April 1991 Phylogenetic analysis of Aquaspirillum magnetotacticum using polymerase chain reaction amplified 16S rRNA specific DNA International Journal of Systematic Bacteriology 41 2 324 325 doi 10 1099 00207713 41 2 324 PMID 1854644 a b James Greg 15 May 2018 Universal Bacterial Identification by PCR and DNA Sequencing of 16S rRNA Gene PCR for Clinical Microbiology Springer Dordrecht pp 209 214 doi 10 1007 978 90 481 9039 3 28 ISBN 978 90 481 9038 6 a b Weidner S Arnold W Puhler A March 1996 Diversity of uncultured microorganisms associated with the seagrass Halophila stipulacea estimated by restriction fragment length polymorphism analysis of PCR amplified 16S rRNA genes 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Fields MW June 2006 Microbial diversity in water and sediment of Lake Chaka an athalassohaline lake in northwestern China Applied and Environmental Microbiology 72 6 3832 3845 Bibcode 2006ApEnM 72 3832J doi 10 1128 AEM 02869 05 PMC 1489620 PMID 16751487 Pereira F Carneiro J Matthiesen R van Asch B Pinto N Gusmao L Amorim A December 2010 Identification of species by multiplex analysis of variable length sequences Nucleic Acids Research 38 22 e203 doi 10 1093 nar gkq865 PMC 3001097 PMID 20923781 Kolbert CP Persing DH June 1999 Ribosomal DNA sequencing as a tool for identification of bacterial pathogens Current Opinion in Microbiology 2 3 299 305 doi 10 1016 S1369 5274 99 80052 6 PMID 10383862 Clarridge JE October 2004 Impact of 16S rRNA gene sequence analysis for identification of bacteria on clinical microbiology and infectious diseases Clinical Microbiology Reviews 17 4 840 62 table of contents doi 10 1128 CMR 17 4 840 862 2004 PMC 523561 PMID 15489351 Lu T Stroot PG Oerther DB July 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168226 PMID 8899989 Sanschagrin S Yergeau E August 2014 Next generation sequencing of 16S ribosomal RNA gene amplicons Journal of Visualized Experiments 90 doi 10 3791 51709 PMC 4828026 PMID 25226019 Gray MW Sankoff D Cedergren RJ July 1984 On the evolutionary descent of organisms and organelles a global phylogeny based on a highly conserved structural core in small subunit ribosomal RNA Nucleic Acids Research 12 14 5837 5852 doi 10 1093 nar 12 14 5837 PMC 320035 PMID 6462918 a b c d Yang B Wang Y Qian PY March 2016 Sensitivity and correlation of hypervariable regions in 16S rRNA genes in phylogenetic analysis BMC Bioinformatics 17 1 135 doi 10 1186 s12859 016 0992 y PMC 4802574 PMID 27000765 Bartram AK Lynch MD Stearns JC Moreno Hagelsieb G Neufeld JD June 2011 Generation of multimillion sequence 16S rRNA gene libraries from complex microbial communities by assembling paired end illumina reads Applied and Environmental Microbiology 77 11 3846 3852 Bibcode 2011ApEnM 77 3846B doi 10 1128 AEM 02772 10 PMC 3127616 PMID 21460107 a b Burke CM Darling AE 2016 09 20 A method for high precision sequencing of near full length 16S rRNA genes on an Illumina MiSeq PeerJ 4 e2492 doi 10 7717 peerj 2492 PMC 5036073 PMID 27688981 Van de Peer Y Chapelle S De Wachter R September 1996 A quantitative map of nucleotide substitution rates in bacterial rRNA Nucleic Acids Research 24 17 3381 3391 doi 10 1093 nar 24 17 3381 PMC 146102 PMID 8811093 a b c Vetrovsky T Baldrian P 2013 02 27 The variability of the 16S rRNA gene in bacterial genomes and its consequences for bacterial community analyses PLOS ONE 8 2 e57923 Bibcode 2013PLoSO 857923V doi 10 1371 journal pone 0057923 PMC 3583900 PMID 23460914 a b Chakravorty S Helb D Burday M Connell N Alland D May 2007 A detailed analysis of 16S ribosomal RNA gene segments for the diagnosis of pathogenic bacteria Journal of Microbiological Methods 69 2 330 339 doi 10 1016 j mimet 2007 02 005 PMC 2562909 PMID 17391789 a b c Jovel J Patterson J Wang W Hotte N O Keefe S Mitchel T et al 2016 01 01 Characterization of the Gut Microbiome Using 16S or Shotgun Metagenomics Frontiers in Microbiology 7 459 doi 10 3389 fmicb 2016 00459 PMC 4837688 PMID 27148170 Kitahara K Yasutake Y Miyazaki K November 2012 Mutational robustness of 16S ribosomal RNA shown by experimental horizontal gene transfer in Escherichia coli Proceedings of the National Academy of Sciences of the United States of America 109 47 19220 19225 Bibcode 2012PNAS 10919220K doi 10 1073 pnas 1213609109 PMC 3511107 PMID 23112186 Tsukuda M Kitahara K Miyazaki K August 2017 Comparative RNA function analysis reveals high functional similarity between distantly related bacterial 16 S rRNAs Scientific Reports 7 1 9993 Bibcode 2017NatSR 7 9993T doi 10 1038 s41598 017 10214 3 PMC 5577257 PMID 28855596 Miyazaki K Tomariguchi N August 2019 Occurrence of randomly recombined functional 16S rRNA genes in Thermus thermophilus suggests genetic interoperability and promiscuity of bacterial 16S rRNAs Scientific Reports 9 1 11233 Bibcode 2019NatSR 911233M doi 10 1038 s41598 019 47807 z PMC 6677816 PMID 31375780 Miyazaki Kentaro Tomariguchi Natsuki 2019 08 02 Occurrence of randomly recombined functional 16S rRNA genes in Thermus thermophilus suggests genetic interoperability and promiscuity of bacterial 16S rRNAs Scientific Reports 9 1 11233 Bibcode 2019NatSR 911233M doi 10 1038 s41598 019 47807 z ISSN 2045 2322 PMC 6677816 PMID 31375780 Yarza P Yilmaz P Pruesse E Glockner FO Ludwig W Schleifer KH et al September 2014 Uniting the classification of cultured and uncultured bacteria and archaea using 16S rRNA gene sequences Nature Reviews Microbiology 12 9 635 645 doi 10 1038 nrmicro3330 PMID 25118885 S2CID 21895693 MIMt Mass Identification of Metagenomics tests mimt bu biopolis pt Retrieved 11 February 2024 Yoon S H Ha S M Kwon S Lim J Kim Y Seo H and Chun J 2017 Introducing EzBioCloud A taxonomically united database of 16S rRNA and whole genome assemblies Int J Syst Evol Microbiol 67 1613 1617 Larsen N Olsen GJ Maidak BL McCaughey MJ Overbeek R Macke TJ Marsh TL Woese CR 1993 The ribosomal database project Nucleic Acids Res Jul 1 21 13 3021 3 Allard G Ryan FJ Jeffery IB Claesson MJ October 2015 SPINGO a rapid species classifier for microbial amplicon sequences BMC Bioinformatics 16 1 324 doi 10 1186 s12859 015 0747 1 PMC 4599320 PMID 26450747 Elmar Pruesse Christian Quast Katrin Knittel Bernhard M Fuchs Wolfgang Ludwig Jorg Peplies Frank Oliver Glockner 2007 Nucleic Acids Res SILVA a comprehensive online resource for quality checked and aligned ribosomal RNA sequence data compatible with ARB December 35 21 7188 7196 DeSantis TZ Hugenholtz P Larsen N Rojas M Brodie EL Keller K et al July 2006 Greengenes a chimera checked 16S rRNA gene database and workbench compatible with ARB Applied and Environmental Microbiology 72 7 5069 5072 Bibcode 2006ApEnM 72 5069D doi 10 1128 aem 03006 05 PMC 1489311 PMID 16820507 McDonald D Price MN Goodrich J Nawrocki EP DeSantis TZ Probst A et al March 2012 An improved Greengenes taxonomy with explicit ranks for ecological and evolutionary analyses of bacteria and archaea The ISME Journal 6 3 610 618 Bibcode 2012ISMEJ 6 610M doi 10 1038 ismej 2011 139 PMC 3280142 PMID 22134646 External links editUniversity of Washington Laboratory Medicine Molecular Diagnosis Bacterial Sequencing MIMt 16S database The Ribosomal Database Project Archived 2020 08 19 at the Wayback Machine Ribosomes and Ribosomal RNA rRNA SILVA rRNA database Greengenes 16S rDNA data and tools EzBioCloud Retrieved from https en wikipedia org w index php title 16S ribosomal RNA amp oldid 1212133039, wikipedia, wiki, book, books, library,

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