48:
492:, the bulging of the outer membrane followed by the constriction and release of small, spherical structures from the bacterium, and are composed of various periplasmic components, including proteins and lipids, as well as some genetic material. OMVs play significant roles in intracellular communication, virulence/bacterial defenses, and adaptation to environmental stress. OMVs released by
20:
1541:
Bedore, Stacy R.; Schmidt, Alicia L.; Slarks, Lauren E.; Duscent-Maitland, Chantel V.; Elliott, Kathryn T.; Andresen, Silke; Costa, Flavia G.; Weerth, R. Sophia; Tumen-Velasquez, Melissa P.; Nilsen, Lindsey N.; Dean, Cassandra E.; Karls, Anna C.; Hoover, Timothy R.; Neidle, Ellen L. (2022-08-09).
636:
alternative, emulsan, helping to break apart aggregated hydrophobic compounds like oil. Emulsan serves a range of industrial functions from a basic degreaser to emulsification of oil for subsequent removal or aid in transport, as the oil's viscosity is decreased and can move more smoothly through
445:
an ideal microbe for laboratory experiments. Collections of multiple single-gene mutations, caused by deletions, on dispensable genes of the ADP1 strain have been constructed. With the knowledge of the entire genome sequence and the mutants, scientists are able to know how the ADP1 strain will
708:
ADP1 would result in a further optimized ability to degrade difficult compounds like lignin and make it into a useable molecule, like lipids. This will lead to more efficient use of lignin-containing plants like trees as well as provide an alternative fuel source to petroleum-based products.
1804:
de
Berardinis, Véronique; Vallenet, David; Castelli, Vanina; Besnard, Marielle; Pinet, Agnès; Cruaud, Corinne; Samair, Sumitta; Lechaplais, Christophe; Gyapay, Gabor; Richez, Céline; Durot, Maxime; Kreimeyer, Annett; Le Fèvre, François; Schächter, Vincent; Pezo, Valérie (2008).
2078:
Vallenet, David; Nordmann, Patrice; Barbe, Valérie; Poirel, Laurent; Mangenot, Sophie; Bataille, Elodie; Dossat, Carole; Gas, Shahinaz; Kreimeyer, Annett; Lenoble, Patricia; Oztas, Sophie; Poulain, Julie; Segurens, Béatrice; Robert, Catherine; Abergel, Chantal (2008-03-19).
700:, a complex organic polymer in plants responsible for reinforcing the rigidity of the cell wall and making them "woody." This is typically discarded during industrial processes as it is difficult to breakdown the lignin into something usable. Similar to creating an
1336:
Stuani, Lucille; Lechaplais, Christophe; Salminen, Aaro V.; Ségurens, Béatrice; Durot, Maxime; Castelli, Vanina; Pinet, Agnès; Labadie, Karine; Cruveiller, Stéphane; Weissenbach, Jean; de
Berardinis, VĂ©ronique; Salanoubat, Marcel; Perret, Alain (December 2014).
452:
can undergo gene duplication and amplification (gda) mutations. Gda mutations are a form of spontaneous mutations that occur where a gene is copied many times and repeated in the genome, but there are many unknowns about the mechanism behind these mutations.
178:
is named after the late Dr. Ronald Bayly, an
Australian microbiologist who contributed significantly to research on aromatic compound catabolism in diverse bacteria. The new species designation, in 2003, was found to apply to an already well-studied
388:
uses arginine to first produce cyanophycin polypeptides, a transient source of nitrogen, which can then be converted to polyaspartic acid. Cyanophycin is predominantly formed when nitrogen sources are low, and said nitrogen is released by
500:, contributing to the microbe's high survival rate and antibiotic resistance; however, environmental stress factors can impact the efficiency of these OMVs, ranging from levels of vesicle release to genetic content and HGT abilities.
239:
is used for industrial purposes, and has shown promise as a method for alternative fuel sources, monitoring operation and efficiency of machinery impacting the environment, and aiding in cleaning up oil spills.
421:'s genome sequence is solely devoted for encoding the machinery required for efficient uptake of exogenous DNA into its cell. If there are complementary sequences upstream and downstream of the exogenous DNA,
436:
DNA strand break repair system to ensure success of DNA sequence exchange. Most bacteria struggle to achieve this exchange of adaptive traits from outside DNA via simple point mutations, so the ease at which
571:. The microbe has also been studied for its potential use an alternative triacylglycerol (TAG) source, as under nitrogen limiting conditions it is able to transform excess organic matter into
770:
Vaneechoutte, Mario; Young, David M.; Ornston, L. Nicholas; De Baere, Thierry; Nemec, Alexandr; Van Der
Reijden, Tanny; Carr, Emma; Tjernberg, Ingela; Dijkshoorn, Lenie (January 2006).
2529:
637:
pipes. Additionally, emulsified oil can act as another source of energy. then makes it easier to degrade the compounds and remove them from the environment, ranging from functions.
1025:
Bedore, Stacy R.; Neidle, Ellen L.; Pardo, Isabel; Luo, Jin; Baugh, Alyssa C.; Duscent-Maitland, Chantel V.; Tumen-Velasquez, Melissa P.; Santala, Ville; Santala, Suvi (2023),
532:, due to their ability to adhere to medical devices composed of plastic or glass. It has been found that two possible genes may be significant to biofilm formation within the
614:
is a soil-based microbe, and can be sourced from contaminated environments like diesel oil- and crude oil-contaminated soils, contaminated river waters, activated sludge,
2205:"A Novel Bifunctional Wax Ester Synthase/Acyl-CoA:Diacylglycerol Acyltransferase Mediates Wax Ester and Triacylglycerol Biosynthesis inAcinetobacter calcoaceticus ADP1"
2503:
626:
has potential use for cleaning up contaminated natural environments via degradation, especially with management and supplementation of other necessary nutrients.
2614:
2542:
547:, specifically the strain ADP1, has been used for over a quarter of a century in several molecular biology studies due to its strong ability to easily undergo
1680:
Hülter, Nils; Sørum, Vidar; Borch-Pedersen, Kristina; Liljegren, Mikkel M.; Utnes, Ane L. G.; Primicerio, Raul; Harms, Klaus; Johnsen, Pål J. (2017-02-15).
618:, and more. The microbe is able to live in activated sludge that arise from a variety of pollutants, especially kinds those containing aromatic compounds,
514:
species. Biofilms arise from the aggregation of surface microbial cells enveloped within a matrix of extracellular polymeric substances. The biofilms of
217:, meaning that it can take up free exogenous DNA from its surroundings. If there are complementary sequences upstream and downstream the exogenous DNA,
2490:
2516:
457:
has been used by scientists as a model organism for researching gda mutations, one example is its ability to adapt and survive on the substrate
183:
strain known as ADP1 (previously known as BD413), a derivative of a soil isolate characterized in 1969. Strain ADP1 was previously designated
2382:
2339:
2304:
2013:
Fulsundar, Shweta; Harms, Klaus; Flaten, Gøril E.; Johnsen, Pål J.; Chopade, Balu Ananda; Nielsen, Kaare M. (June 2014). Kivisaar, M. (ed.).
1739:
Utnes, Ane L G; Sørum, Vidar; Hülter, Nils; Primicerio, Raul; Hegstad, Joachim; Kloos, Julia; Nielsen, Kaare M; Johnsen, Pål J (2015-10-01).
1656:
1621:
1405:
1255:
1217:
1056:
1903:"Genome-wide selection for increased copy number in Acinetobacter baylyi ADP1: locus and context-dependent variation in gene amplification"
369:
amino acids as both a primary carbon and nitrogen source, thus opening the door to see how D-enantiomers can be used for bacterial growth.
2638:
2607:
1864:"Gene amplification involves site-specific short homology-independent illegitimate recombination in Acinetobacter sp. strain ADP1"
595:
ADP1 so that it is able to still produce wax esters in a nitrogen-rich environment. This is achieved by overexpressing the gene
1504:"Overproduction, purification, and transcriptional activity of recombinant Acinetobacter baylyi ADP1 RNA polymerase holoenzyme"
473:. These genes are amplified to avoid the accumulation of muconate, the toxic intermediate, produced from benzoate metabolism .
579:(TAGs) as a lipid storage form through the isoenzymes wax ester synthase/diacylglycerol acyltransferase. The concentration of
2643:
1901:
Seaton, Sarah C; Elliott, Kathryn T; Cuff, Laura E; Laniohan, Nicole S; Patel, Poonam R; Niedle, Ellen L (29 December 2011).
347:
2521:
2600:
946:
331:
681:'s abilities to survive in contaminated environments as well as natural transformation in order to use the microbe as a
47:
281:
as organic carbon and energy sources through the β-ketoadipate pathway. Aromatic compounds are first transformed into
446:
function in any situation, which expands the capability of the strain for industrial and environmental applications.
306:
glucose metabolism is slower in comparison to its metabolism of aromatic compounds, as it lacks a gene encoding for
259:
can be cultured in media using organic carbon sources to survive such as succinate, pyruvate, acetate, and ethanol.
2547:
772:"Naturally Transformable Acinetobacter sp. Strain ADP1 Belongs to the Newly Described Species Acinetobacter baylyi"
693:
when activated by pollutant degradation mechanisms, the monitoring of soils and water supplies would be elevated.
2015:"Gene Transfer Potential of Outer Membrane Vesicles of Acinetobacter baylyi and Effects of Stress on Vesiculation"
233:
are exceptionally efficient in comparison to all studied microbes, thus contributing to its experimental utility.
548:
461:. The catabolism of benzoate yields a metabolite that is toxic at high concentrations in the cell, muconate. For
406:
222:
1940:
Ezezika, Obidimma C.; Collier-Hyams, Lauren S.; Dale, Haley A.; Burk, Andrew C.; Neidle, Ellen L. (March 2006).
481:
426:
230:
1286:
Salcedo-Vite, Karina; Sigala, Juan-Carlos; Segura, Daniel; Gosset, Guillermo; Martinez, Alfredo (2019-08-01).
646:
s ability to create TAGs has been used as a potential alternative method of producing TAG-based products like
1080:
Santala, Suvi; Efimova, Elena; Kivinen, Virpi; Larjo, Antti; Aho, Tommi; Karp, Matti; Santala, Ville (2011).
615:
529:
520:
1502:
Calil
Brondani, Juliana; Afful, Derrick; Nune, Hanna; Hart, Jesse; Cook, Shelby; Momany, Cory (June 2023).
1027:"Natural transformation as a tool in Acinetobacter baylyi: Streamlined engineering and mutational analysis"
2633:
2419:
485:
226:
203:
729:
Carr, Emma L.; Kämpfer, Peter; Patel, Bharat K. C.; Gürtler, Volker; Seviour, Robert J. (April 9, 2003).
2246:"Wax ester production in nitrogen-rich conditions by metabolically engineered Acinetobacter baylyi ADP1"
671:
132:
1902:
1863:
704:
mutant strain specifically for monitoring of cleanliness of soils and waterways, incorporating DNA in
2477:
2092:
2026:
1961:
1752:
1555:
1447:
783:
603:, as this will redirect the movement of carbon in ADP1's metabolism so that it becomes a wax ester.
568:
263:
is known as an omnipresent soil bacterium, meaning it can be found in a variety of soils in nature.
252:
670:
is particularly notable with TAG production as it has low selectivity on what kind of alcohol-based
315:
79:
898:, A Nutritionally Versatile Bacterial Species That Is Highly Competent for Natural Transformation"
1503:
1436:"Metabolic Engineering of Acinetobacter baylyi ADP1 for Improved Growth on Gluconate and Glucose"
1288:"Acinetobacter baylyi ADP1 growth performance and lipid accumulation on different carbon sources"
564:
214:
42:
2508:
2374:
1741:"Growth phase-specific evolutionary benefits of natural transformation in Acinetobacter baylyi"
2555:
2464:
2378:
2364:
2345:
2335:
2310:
2300:
2275:
2226:
2185:
2167:
2128:
2110:
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1995:
1977:
1922:
1883:
1844:
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1786:
1768:
1721:
1703:
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1007:
925:
917:
874:
856:
817:
799:
752:
381:
278:
270:
2584:
837:"Interspecies Transformation of Acinetobacter : Genetic Evidence for a Ubiquitous Genus"
2560:
2370:
2265:
2257:
2216:
2175:
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2118:
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2050:
2034:
1985:
1969:
1914:
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864:
848:
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742:
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576:
560:
405:
is its ability to take in free DNA from the environment. It does so by importing the DNA by
171:
1146:"Synthetic metabolic pathway for the production of 1-alkenes from lignin-derived molecules"
1082:"Improved Triacylglycerol Production in Acinetobacter baylyi ADP1 by Metabolic Engineering"
913:
587:
that the ADP1 strain produces depends on the organic matter present in medium of which the
2580:
1544:"Regulation of l - and d -Aspartate Transport and Metabolism in Acinetobacter baylyi ADP1"
690:
525:
307:
286:
89:
1434:
Kannisto, Matti; Aho, Tommi; Karp, Matti; Santala, Ville (2014-11-15). Liu, S.-J. (ed.).
1339:"Novel metabolic features in Acinetobacter baylyi ADP1 revealed by a multiomics approach"
2400:"Intracellular Lipid Production from Lignin Model Monomers by Acinetobacter baylyi ADP1"
2096:
2030:
1965:
1756:
1559:
1451:
787:
2270:
2245:
2180:
2147:
2123:
2080:
2055:
2014:
1990:
1839:
1806:
1781:
1740:
1716:
1681:
1584:
1543:
1476:
1435:
1371:
1338:
1180:
1145:
1144:
Luo, Jin; Lehtinen, Tapio; Efimova, Elena; Santala, Ville; Santala, Suvi (2019-03-11).
1116:
1081:
812:
771:
441:
can take in and incorporate foreign DNA is beneficial to its survival. This also makes
390:
69:
1287:
869:
836:
409:, a mechanism that incorporates exogenous DNA into its chromosome, characteristic of
2627:
1941:
1918:
659:
651:
633:
206:
166:
109:
99:
2534:
1973:
1807:"A complete collection of single-gene deletion mutants of Acinetobacter baylyi ADP1"
297:. Both catechol and protocatechuate can be formed into succinyl-CoA and acetyl-CoA.
213:-positive, nitrate-negative, oxidase-negative, and non-fermentative. The species is
2244:
Luo, Jin; Efimova, Elena; Losoi, Pauli; Santala, Ville; Santala, Suvi (June 2020).
619:
489:
458:
354:
339:
290:
2469:
852:
795:
2442:
2105:
2163:
366:
362:
2399:
1303:
1038:
2261:
1879:
1698:
1519:
1354:
1162:
663:
311:
294:
2349:
2314:
2171:
2114:
2046:
1981:
1830:
1772:
1707:
1666:
1631:
1575:
1467:
1415:
1362:
1311:
1265:
1227:
1171:
1107:
1026:
921:
860:
803:
555:
is used in multiple laboratory techniques as a model organism. These include
2081:"Comparative Analysis of Acinetobacters: Three Genomes for Three Lifestyles"
1098:
682:
647:
580:
572:
524:
is the most commonly associated with various infectious diseases, including
465:
to survive on benzoate, it requires high levels of expression in two genes,
380:
to produce a biodegradable alternative to petroleum-based plastics known as
19:
2329:
2294:
2279:
2230:
2221:
2204:
2189:
2132:
2064:
1999:
1926:
1887:
1848:
1790:
1725:
1646:
1611:
1593:
1527:
1485:
1395:
1380:
1319:
1245:
1207:
1189:
1125:
1011:
929:
821:
756:
510:
formation, particularly as a control in comparative experiments with other
1764:
878:
747:
730:
536:
species: Fimbrial-biogenesis protein (3317) and
Putative Surface protein.
2436:
2038:
1567:
1459:
556:
497:
377:
319:
282:
210:
59:
1822:
1047:
591:
is grown on. Work has been done to genetically modify the metabolism of
496:
offer a mode of gene transfer that is not susceptible to degradation by
26:
under 10x ocular lens and 100x objective lens with crystal violet stain.
2495:
2451:
1394:
Williams, Peter A.; Kay, Catherine M. (2008). Gerischer, Ulrike (ed.).
655:
507:
327:
170:. The species designation was given after the discovery of strains in
2456:
1682:"Costs and benefits of natural transformation in Acinetobacter baylyi"
986:"Acinetobacter baylyi ADP1: Transforming the choice of model organism"
338:
has to use a work-around of transforming the phosphoenolpyruvate into
731:"Seven novel species of Acinetobacter isolated from activated sludge"
697:
343:
2413:
1002:
985:
255:, known for its fast growth rate and ability to be easily cultured.
361:
is an example of metabolic versatility with its ability to utilize
289:, which then are transformed into the citric acid cycle substrates
191:. Research, particularly in the field of genetics, has established
2328:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
2293:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
1645:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
1610:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
1244:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
1206:
Gutnick, David L.; Bach, Horacio (2008). Gerischer, Ulrike (ed.).
892:
Young, David M.; Parke, Donna; Ornston, L. Nicholas (2005-10-01).
18:
735:
International
Journal of Systematic and Evolutionary Microbiology
2482:
2417:
506:
strains have also been associated with bacterial adhesion and
269:
prefers to utilize organic carbon sources that can enter the
1946:
Operon: Functional
Divergence of Two LysR-Type Paralogs in
330:
by first oxidizing it into gluconate, which feeds into the
1250:. Norfolk, UK: Caister Academic Press. pp. 241, 249.
518:
species can range in adhesion strength and thickness, and
2334:. Norfolk, UK: Caister Academic Press. pp. 250–251.
2299:. Norfolk, UK: Caister Academic Press. pp. 239–240.
2203:
Kalscheuer, Rainer; SteinbĂĽchel, Alexander (March 2003).
947:"Acinetobacter baylyi Biofilm Formation Dependent Genes"
2588:
984:
Elliott, Kathryn T.; Neidle, Ellen L. (April 9, 2011).
322:. When glucose is the primary carbon source available,
221:
can incorporate the foreign DNA into its own genome by
251:
metabolic pathways have been used for many studies in
894:"Opportunities for Genetic Investigation Afforded by
1651:. Norfolk, UK: Caister Academic Press. p. 232.
1616:. Norfolk, UK: Caister Academic Press. p. 252.
1212:. Norfolk, UK: Caister Academic Press. p. 253.
2426:
1400:. Norfolk, UK: Caister Academic Press. p. 99.
2146:Lopez, D.; Vlamakis, H.; Kolter, R. (2010-07-01).
658:. They are currently made with the TAG sources of
417:has been completely sequenced, and roughly 35% of
2406:. Examined by Ville Santala and Dr. Suvi Santala.
353:Unlike other bacteria that can predominantly use
209:. It grows under strictly aerobic conditions, is
2366:Kirk-Othmer Encyclopedia of Chemical Technology
1862:Reams, Andrew B; Neidle, Ellen L (7 May 2004).
346:, which can then become pyruvate and enter the
2608:
8:
2615:
2601:
2414:
2375:10.1002/0471238961.12090714120914.a01.pub2
2152:Cold Spring Harbor Perspectives in Biology
31:
2269:
2220:
2179:
2122:
2104:
2054:
1989:
1838:
1780:
1715:
1697:
1583:
1475:
1370:
1179:
1161:
1115:
1097:
1046:
1001:
868:
811:
746:
951:Journal of Pure and Applied Microbiology
482:horizontal gene transfer (HGT) processes
393:when environmental nitrogen is limited.
718:
2019:Applied and Environmental Microbiology
1954:Applied and Environmental Microbiology
1548:Applied and Environmental Microbiology
1440:Applied and Environmental Microbiology
1292:Applied Microbiology and Biotechnology
1239:
1237:
1201:
1199:
914:10.1146/annurev.micro.59.051905.105823
776:Applied and Environmental Microbiology
724:
722:
696:One of the most abundant resources is
632:also has the potential as a non-toxic
480:ability in natural transformation, or
1605:
1603:
1497:
1495:
1429:
1427:
1425:
1331:
1329:
1281:
1279:
1277:
1275:
1139:
1137:
1135:
941:
939:
429:. This mechanism strongly depends on
7:
2576:
2574:
2331:Acinetobacter molecular microbiology
2296:Acinetobacter molecular microbiology
2250:Metabolic Engineering Communications
1648:Acinetobacter molecular microbiology
1613:Acinetobacter molecular microbiology
1397:Acinetobacter molecular microbiology
1247:Acinetobacter molecular microbiology
1209:Acinetobacter molecular microbiology
1075:
1073:
979:
977:
975:
973:
971:
969:
967:
484:, may be aided by the mechanisms of
164:is a bacterial species of the genus
1508:Protein Expression and Purification
2587:. You can help Knowledge (XXG) by
350:and later the citric acid cycle.
14:
174:in Victoria, Australia, in 2003.
1919:10.1111/j.1365-2958.2011.07945.x
677:It has been proposed to combine
46:
2363:Kirk-Othmer, ed. (2001-01-26).
2209:Journal of Biological Chemistry
1974:10.1128/aem.72.3.1749-1758.2006
689:ADP1 strain that will generate
1033:, Elsevier, pp. 207–234,
835:Juni, Elliot (November 1972).
488:(OMVs). OMVs are produced via
348:pyruvate dehydrogenase complex
1:
2398:Luo, Jin Jr (November 2016).
902:Annual Review of Microbiology
853:10.1128/jb.112.2.917-931.1972
796:10.1128/AEM.72.1.932-936.2006
2106:10.1371/journal.pone.0001805
1868:Journal of Molecular Biology
622:, and aliphatic substances.
401:One major characteristic of
372:Experiments have shown that
198:Similar to other species of
2164:10.1101/cshperspect.a000398
334:. Without pyruvate kinase,
189:Acinetobacter calcoaceticus
2660:
2639:Bacteria described in 2003
2573:
1304:10.1007/s00253-019-09910-z
1039:10.1016/bs.mim.2023.01.002
685:. By incorporating DNA in
2262:10.1016/j.mec.2020.e00128
1880:10.1016/j.jmb.2004.03.031
1811:Molecular Systems Biology
1699:10.1186/s12866-017-0953-2
1542:Alexandre, Gladys (ed.).
1520:10.1016/j.pep.2023.106254
1355:10.1007/s11306-014-0662-x
1163:10.1186/s12934-019-1097-x
138:
131:
43:Scientific classification
41:
34:
2404:Master of Science Thesis
1942:"CatM Regulation of the
1150:Microbial Cell Factories
1086:Microbial Cell Factories
666:, and recycled greases.
530:urinary tract infections
332:Entner-Doudoroff pathway
231:homologous recombination
1099:10.1186/1475-2859-10-36
841:Journal of Bacteriology
616:lignocellulosic biomass
521:Acinetobacter baumannii
486:outer membrane vesicles
2222:10.1074/jbc.M210533200
1907:Molecular Microbiology
599:and deleting the gene
549:genetic transformation
407:natural transformation
227:natural transformation
27:
2644:Pseudomonadales stubs
2369:(1 ed.). Wiley.
1765:10.1038/ismej.2015.35
748:10.1099/ijs.0.02486-0
551:. For these reasons,
202:, it is a nonmotile,
195:as a model organism.
22:
2535:acinetobacter-baylyi
2428:Acinetobacter baylyi
2039:10.1128/AEM.04248-13
1948:Acinetobacter baylyi
1568:10.1128/aem.00883-22
1460:10.1128/AEM.01837-14
896:Acinetobacter baylyi
569:bacterial metabolism
476:The facilitation of
310:, a vital enzyme in
253:microbial metabolism
161:Acinetobacter baylyi
142:Acinetobacter baylyi
36:Acinetobacter baylyi
2097:2008PLoSO...3.1805V
2031:2014ApEnM..80.3469F
1966:2006ApEnM..72.1749E
1823:10.1038/msb.2008.10
1757:2015ISMEJ...9.2221U
1560:2022ApEnM..88E.883B
1452:2014ApEnM..80.7021K
788:2006ApEnM..72..932V
376:uses intracellular
316:phosphoenolpyruvate
277:is able to utilize
215:naturally competent
80:Gammaproteobacteria
16:Species of bacteria
1031:Genome Engineering
279:aromatic compounds
28:
2596:
2595:
2571:
2570:
2556:Open Tree of Life
2420:Taxon identifiers
2384:978-0-471-48494-3
2341:978-1-904455-20-2
2306:978-1-904455-20-2
2215:(10): 8075–8082.
2025:(11): 3469–3483.
1751:(10): 2221–2231.
1658:978-1-904455-20-2
1623:978-1-904455-20-2
1446:(22): 7021–7027.
1407:978-1-904455-20-2
1298:(15): 6217–6229.
1257:978-1-904455-20-2
1219:978-1-904455-20-2
1058:978-0-12-823540-9
996:(12): 1075–1080.
382:polyaspartic acid
314:for transforming
271:citric acid cycle
157:
156:
2651:
2617:
2610:
2603:
2575:
2564:
2563:
2551:
2550:
2538:
2537:
2525:
2524:
2512:
2511:
2499:
2498:
2486:
2485:
2473:
2472:
2460:
2459:
2447:
2446:
2445:
2415:
2408:
2407:
2395:
2389:
2388:
2360:
2354:
2353:
2325:
2319:
2318:
2290:
2284:
2283:
2273:
2241:
2235:
2234:
2224:
2200:
2194:
2193:
2183:
2143:
2137:
2136:
2126:
2108:
2075:
2069:
2068:
2058:
2010:
2004:
2003:
1993:
1960:(3): 1749–1758.
1937:
1931:
1930:
1898:
1892:
1891:
1859:
1853:
1852:
1842:
1801:
1795:
1794:
1784:
1745:The ISME Journal
1736:
1730:
1729:
1719:
1701:
1686:BMC Microbiology
1677:
1671:
1670:
1642:
1636:
1635:
1607:
1598:
1597:
1587:
1554:(15): e0088322.
1538:
1532:
1531:
1499:
1490:
1489:
1479:
1431:
1420:
1419:
1391:
1385:
1384:
1374:
1349:(6): 1223–1238.
1333:
1324:
1323:
1283:
1270:
1269:
1241:
1232:
1231:
1203:
1194:
1193:
1183:
1165:
1141:
1130:
1129:
1119:
1101:
1077:
1068:
1067:
1066:
1065:
1050:
1022:
1016:
1015:
1005:
981:
962:
961:
959:
958:
943:
934:
933:
889:
883:
882:
872:
832:
826:
825:
815:
767:
761:
760:
750:
726:
645:
585:triacylglycerols
577:triacylglycerols
561:gene duplication
413:. The genome of
172:activated sludge
144:
51:
50:
32:
2659:
2658:
2654:
2653:
2652:
2650:
2649:
2648:
2624:
2623:
2622:
2621:
2581:Pseudomonadales
2572:
2567:
2559:
2554:
2546:
2541:
2533:
2528:
2520:
2515:
2507:
2502:
2494:
2489:
2481:
2476:
2468:
2463:
2455:
2450:
2441:
2440:
2435:
2422:
2412:
2411:
2397:
2396:
2392:
2385:
2362:
2361:
2357:
2342:
2327:
2326:
2322:
2307:
2292:
2291:
2287:
2243:
2242:
2238:
2202:
2201:
2197:
2145:
2144:
2140:
2077:
2076:
2072:
2012:
2011:
2007:
1939:
1938:
1934:
1900:
1899:
1895:
1861:
1860:
1856:
1803:
1802:
1798:
1738:
1737:
1733:
1679:
1678:
1674:
1659:
1644:
1643:
1639:
1624:
1609:
1608:
1601:
1540:
1539:
1535:
1501:
1500:
1493:
1433:
1432:
1423:
1408:
1393:
1392:
1388:
1335:
1334:
1327:
1285:
1284:
1273:
1258:
1243:
1242:
1235:
1220:
1205:
1204:
1197:
1143:
1142:
1133:
1079:
1078:
1071:
1063:
1061:
1059:
1024:
1023:
1019:
1003:10.1002/iub.530
983:
982:
965:
956:
954:
945:
944:
937:
891:
890:
886:
834:
833:
829:
769:
768:
764:
728:
727:
720:
715:
691:bioluminescence
643:
609:
559:, specifically
542:
526:cystic fibrosis
399:
326:can metabolize
308:pyruvate kinase
287:protocatechuate
246:
153:
146:
140:
127:
90:Pseudomonadales
45:
17:
12:
11:
5:
2657:
2655:
2647:
2646:
2641:
2636:
2626:
2625:
2620:
2619:
2612:
2605:
2597:
2594:
2593:
2569:
2568:
2566:
2565:
2552:
2539:
2526:
2513:
2500:
2487:
2474:
2461:
2448:
2432:
2430:
2424:
2423:
2418:
2410:
2409:
2390:
2383:
2355:
2340:
2320:
2305:
2285:
2236:
2195:
2158:(7): a000398.
2138:
2070:
2005:
1932:
1913:(3): 520–535.
1893:
1874:(4): 643–656.
1854:
1796:
1731:
1672:
1657:
1637:
1622:
1599:
1533:
1491:
1421:
1406:
1386:
1325:
1271:
1256:
1233:
1218:
1195:
1131:
1069:
1057:
1017:
963:
935:
908:(1): 519–551.
884:
847:(2): 917–931.
827:
782:(1): 932–936.
762:
741:(4): 953–963.
717:
716:
714:
711:
660:vegetable oils
608:
605:
541:
538:
398:
395:
391:cyanophycinase
245:
242:
223:transformation
155:
154:
147:
136:
135:
129:
128:
124:A. baylyi
121:
119:
115:
114:
107:
103:
102:
97:
93:
92:
87:
83:
82:
77:
73:
72:
70:Pseudomonadota
67:
63:
62:
57:
53:
52:
39:
38:
15:
13:
10:
9:
6:
4:
3:
2:
2656:
2645:
2642:
2640:
2637:
2635:
2634:Moraxellaceae
2632:
2631:
2629:
2618:
2613:
2611:
2606:
2604:
2599:
2598:
2592:
2590:
2586:
2583:article is a
2582:
2577:
2562:
2557:
2553:
2549:
2544:
2540:
2536:
2531:
2527:
2523:
2518:
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2497:
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2368:
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2359:
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2337:
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2324:
2321:
2316:
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2302:
2298:
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2289:
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2281:
2277:
2272:
2267:
2263:
2259:
2255:
2251:
2247:
2240:
2237:
2232:
2228:
2223:
2218:
2214:
2210:
2206:
2199:
2196:
2191:
2187:
2182:
2177:
2173:
2169:
2165:
2161:
2157:
2153:
2149:
2142:
2139:
2134:
2130:
2125:
2120:
2116:
2112:
2107:
2102:
2098:
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2090:
2086:
2082:
2074:
2071:
2066:
2062:
2057:
2052:
2048:
2044:
2040:
2036:
2032:
2028:
2024:
2020:
2016:
2009:
2006:
2001:
1997:
1992:
1987:
1983:
1979:
1975:
1971:
1967:
1963:
1959:
1955:
1951:
1949:
1945:
1936:
1933:
1928:
1924:
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1916:
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1908:
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1897:
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1240:
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1234:
1229:
1225:
1221:
1215:
1211:
1210:
1202:
1200:
1196:
1191:
1187:
1182:
1177:
1173:
1169:
1164:
1159:
1155:
1151:
1147:
1140:
1138:
1136:
1132:
1127:
1123:
1118:
1113:
1109:
1105:
1100:
1095:
1091:
1087:
1083:
1076:
1074:
1070:
1060:
1054:
1049:
1044:
1040:
1036:
1032:
1028:
1021:
1018:
1013:
1009:
1004:
999:
995:
991:
987:
980:
978:
976:
974:
972:
970:
968:
964:
952:
948:
942:
940:
936:
931:
927:
923:
919:
915:
911:
907:
903:
899:
897:
888:
885:
880:
876:
871:
866:
862:
858:
854:
850:
846:
842:
838:
831:
828:
823:
819:
814:
809:
805:
801:
797:
793:
789:
785:
781:
777:
773:
766:
763:
758:
754:
749:
744:
740:
736:
732:
725:
723:
719:
712:
710:
707:
703:
699:
694:
692:
688:
684:
680:
675:
673:
669:
665:
661:
657:
653:
652:oleochemicals
649:
642:
638:
635:
634:biosurfactant
631:
627:
625:
621:
617:
613:
606:
604:
602:
598:
594:
590:
586:
582:
578:
574:
570:
566:
565:amplification
562:
558:
554:
550:
546:
539:
537:
535:
534:Acinetobacter
531:
527:
523:
522:
517:
516:Acinetobacter
513:
512:Acinetobacter
509:
505:
501:
499:
495:
491:
487:
483:
479:
474:
472:
468:
464:
460:
456:
451:
447:
444:
440:
435:
432:
428:
427:recombination
424:
420:
416:
412:
408:
404:
396:
394:
392:
387:
383:
379:
375:
370:
368:
364:
360:
356:
355:L-amino acids
351:
349:
345:
341:
337:
333:
329:
325:
321:
317:
313:
309:
305:
302:
298:
296:
292:
288:
284:
280:
276:
272:
268:
264:
262:
258:
254:
250:
243:
241:
238:
234:
232:
228:
224:
220:
216:
212:
208:
207:coccobacillus
205:
204:Gram-negative
201:
200:Acinetobacter
196:
194:
190:
186:
185:Acinetobacter
182:
181:Acinetobacter
177:
173:
169:
168:
167:Acinetobacter
163:
162:
151:
145:
143:
137:
134:
133:Binomial name
130:
126:
125:
120:
117:
116:
113:
112:
111:Acinetobacter
108:
105:
104:
101:
100:Moraxellaceae
98:
95:
94:
91:
88:
85:
84:
81:
78:
75:
74:
71:
68:
65:
64:
61:
58:
55:
54:
49:
44:
40:
37:
33:
30:
25:
21:
2589:expanding it
2578:
2427:
2403:
2393:
2365:
2358:
2330:
2323:
2295:
2288:
2253:
2249:
2239:
2212:
2208:
2198:
2155:
2151:
2141:
2091:(3): e1805.
2088:
2084:
2073:
2022:
2018:
2008:
1957:
1953:
1947:
1943:
1935:
1910:
1906:
1896:
1871:
1867:
1857:
1814:
1810:
1799:
1748:
1744:
1734:
1689:
1685:
1675:
1647:
1640:
1612:
1551:
1547:
1536:
1511:
1507:
1443:
1439:
1396:
1389:
1346:
1343:Metabolomics
1342:
1295:
1291:
1246:
1208:
1153:
1149:
1089:
1085:
1062:, retrieved
1048:10261/350462
1030:
1020:
993:
989:
955:. Retrieved
953:. 2020-02-01
950:
905:
901:
895:
887:
844:
840:
830:
779:
775:
765:
738:
734:
705:
701:
695:
686:
678:
676:
667:
640:
639:
629:
628:
623:
620:heavy metals
611:
610:
607:Applications
600:
596:
592:
588:
552:
544:
543:
533:
519:
515:
511:
503:
502:
493:
490:vesiculation
477:
475:
470:
466:
462:
454:
449:
448:
442:
438:
433:
430:
425:can perform
422:
418:
414:
410:
402:
400:
385:
373:
371:
358:
352:
340:oxaloacetate
335:
323:
303:
300:
299:
291:succinyl-CoA
274:
266:
265:
260:
256:
248:
247:
236:
235:
218:
199:
197:
192:
188:
184:
180:
175:
165:
160:
159:
158:
149:
141:
139:
123:
122:
110:
35:
29:
23:
664:animal fats
567:as well as
540:ADP1 Strain
478:A. baylyi's
2628:Categories
2256:: e00128.
2148:"Biofilms"
1514:: 106254.
1064:2024-04-10
990:IUBMB Life
957:2024-02-15
713:References
581:wax esters
573:wax esters
312:glycolysis
295:acetyl-CoA
244:Metabolism
2443:Q16870362
2350:154685348
2315:154685348
2172:1943-0264
2115:1932-6203
2047:0099-2240
1982:0099-2240
1831:1744-4292
1773:1751-7362
1708:1471-2180
1692:(1): 34.
1667:154685348
1632:154685348
1576:0099-2240
1468:0099-2240
1416:154685348
1363:1573-3882
1312:0175-7598
1266:154685348
1228:154685348
1172:1475-2859
1156:(1): 48.
1108:1475-2859
1092:(1): 36.
922:0066-4227
861:0021-9193
804:0099-2240
706:A. baylyi
702:A. baylyi
687:A. baylyi
683:biosensor
679:A. baylyi
674:to use.
672:substrate
668:A. baylyi
648:cosmetics
641:A. baylyi
630:A. baylyi
624:A. baylyi
612:A. baylyi
593:A. baylyi
589:A. baylyi
553:A. baylyi
545:A. baylyi
504:A. baylyi
498:nucleases
494:A. baylyi
471:catBCIJFD
463:A. baylyi
455:A. baylyi
450:A. baylyi
443:A. baylyi
439:A. baylyi
423:A. baylyi
419:A. baylyi
415:A. baylyi
411:A. baylyi
403:A. baylyi
386:A. baylyi
374:A. baylyi
359:A. baylyi
336:A. baylyi
324:A. baylyi
275:A. baylyi
273:quickly.
267:A. baylyi
261:A. baylyi
257:A. baylyi
249:A. baylyi
237:A. baylyi
219:A. baylyi
193:A. baylyi
176:A. baylyi
118:Species:
24:A. baylyi
2509:10030924
2437:Wikidata
2280:32477866
2231:12502715
2190:20519345
2133:18350144
2085:PLOS ONE
2065:24657872
2000:16517618
1944:benABCDE
1927:22211470
1888:15099734
1849:18319726
1791:25848876
1726:28202049
1594:35862682
1528:36804950
1486:25192990
1381:25374488
1320:31144015
1190:30857542
1126:21592360
1012:22034222
930:16153178
822:16391138
757:12892111
656:biofuels
557:genetics
459:benzoate
434:baylyi's
397:Genetics
378:arginine
320:pyruvate
304:baylyi's
283:catechol
211:catalase
187:sp. and
96:Family:
66:Phylum:
60:Bacteria
56:Domain:
2496:3223268
2452:BacDive
2271:7251950
2181:2890205
2124:2265553
2093:Bibcode
2056:4018862
2027:Bibcode
1991:1393229
1962:Bibcode
1840:2290942
1817:: 174.
1782:4579475
1753:Bibcode
1717:5312590
1585:9361831
1556:Bibcode
1477:4249021
1448:Bibcode
1372:4213383
1181:6410514
1117:3112387
879:4563985
813:1352221
784:Bibcode
508:biofilm
342:, then
328:glucose
106:Genus:
86:Order:
76:Class:
2561:225445
2548:202950
2522:958772
2483:972984
2381:
2348:
2338:
2313:
2303:
2278:
2268:
2229:
2188:
2178:
2170:
2131:
2121:
2113:
2063:
2053:
2045:
1998:
1988:
1980:
1925:
1886:
1847:
1837:
1829:
1789:
1779:
1771:
1724:
1714:
1706:
1665:
1655:
1630:
1620:
1592:
1582:
1574:
1526:
1484:
1474:
1466:
1414:
1404:
1379:
1369:
1361:
1318:
1310:
1264:
1254:
1226:
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