User:Flsxx/测试
假单胞菌属(Pseudomonas)是假单胞菌科(Pseudomonadaceae)的一属,为一种革兰氏阴性菌。假单胞菌属广泛分布于土壤和水体中,在人体中亦有分布,多为化能有机营养型,某些种为兼性化能无机营养型,专性氧化(呼吸)代谢,所有种都以氧为最终电子受体,一些能以硝酸盐呼吸。细胞形态典型为极生鞭毛杆菌,体多呈现直或微弯的杆状,无菌柄及鞘,不产芽孢,许多种能够积累聚-β-羟基丁酸盐,作为储藏物质。大多数种能以单级毛或多级毛运动,进行呼吸性代谢,最终电子受体为氧,铜绿假单胞菌和个别情况下以硝酸盐为电子受体,进行厌氧呼吸,进行反硝化作用。一些种对植物及人畜具有致病性,如铜绿假单胞菌(P. aeruginosa)、鼻疽假单胞菌(P. mallei)和青枯病假单胞菌(P. solanacearum)等。直径约0.5至1微米,长约1至4微米。该属基因组DNA的GC比范围为58-69%。[1]
该属的模式种为铜绿假单胞菌。目前临床上越来越多地将铜绿假单胞菌视作一种条件致病菌,几种不同的流行病学研究表明,其临床分离菌株的抗生素耐药性呈现上升趋势。[2]
该属的种在代谢上表现出极大的多样性,因此能在多种生境下生长。由于该属的细菌易于进行体外培养,并且人们已经对该属下越来越多个种的基因组加以研究,假单胞菌属已经成为重要的科研对象,主要的有人体条件致病菌铜绿假单胞菌、植物致病菌丁香假单胞菌、土壤细菌恶臭假单胞菌和植物促生菌荧光假单胞菌等。[3]
由于假单胞菌在水体及植物种子(如双子叶植物)上广泛分布,在微生物学领域已经早有研究。Walter Migula在1894年和1900年给“假单胞菌”这一属名的定义相当模糊,是指一种革兰氏阴性、棒状、极生鞭毛的细菌,一些种能产生孢子。[4][5]但关于孢子的描述事后证明是错误的,这是一些储藏物质的折光性造成的误判。[6] Despite the vague description, the type species, Pseudomonas pyocyanea (basonym of Pseudomonas aeruginosa), proved the best descriptor.[6]
分类历史
最初对假单胞菌进行分类是在19世纪末Walter Migula最早鉴别出该属的时候,至于这一名称的构词法,在当时并无明确说法,最早提到则在伯杰系统细菌学手册的第7版上,称是希腊语 ψευδες(pseudes,“假的”)和 μονάς / μονάδα(-monas,“单个”);但也可能Migula的本意就是指“假的”滴虫(Monas,一种鞭毛虫类原生生物)。后来,monad一词在早期微生物学史上用于表示单细胞生物。[6]不久以后,许多与Migula最初的模糊描述有或多或少匹配的物种被从各种生境中分离出来,在当时其中许多被分类到这个属。但是,后来人们用更新的分类学原则,并采用诸如保守生物大分子研究等更多手段,将其中一些物种重新分类归于其他属。[7]
最近,16S rRNA的序列分析使得许多细菌的分类再次受到挑战。[8]结果,金色单胞菌属(Chryseomonas)和黄色单胞菌属(Flavimonas)的种被并入假单胞菌属。[9]一些原属于假单胞菌属的种被划分到伯克氏菌属(Burkholderia)及雷尔氏菌属(Ralstonia)。[10][11]
2000年,人们得到了第一个假单胞菌属菌株的全基因组序列,近年来更多菌株的序列也测序完成,包括铜绿假单胞菌PAO1(2000年)、恶臭假单胞菌KT2440(2002年)、P. protegens Pf-5(2005年)、绿针假单胞菌GP72(2012年)等。[7][12]
2008年在《科学美国人》(Scientific American)上发表的一篇文章表明,假单胞菌可能是云当中冰晶最常见的成核中心,可能说明假单胞菌对地球上雨和雪的形成起到了有极为重要的作用。[13]
特征
假单胞菌属的种符合以下的定义性特征:[14]
- 棒状;
- 革兰氏阴性;
- 单极或多极鞭毛,可运动;
- 好氧;
- 不产芽孢;
- 过氧化氢酶检测阳性;
- 氧化酶检测阳性。
也有其他一些仅能够判定可能属于假单胞菌属的特征(有例外),包括在环境铁含量不足的情况下分泌绿脓菌荧光素(pyoverdine,一种有荧光的黄绿色铁载体),[15]一些特定的假单胞菌还能产生另一些铁载体,如铜绿假单胞菌代谢产生绿脓菌素,[16],或荧光假单胞菌代谢产生thioquinolobactin。[17]
生物膜的形成
All species and strains of Pseudomonas are Gram-negative rods, and have historically been classified as strict aerobes. Exceptions to this classification have recently been discovered in Pseudomonas biofilms.[18] A significant number of cells can produce exopolysaccharides which are associated with biofilm formation. Secretion of exopolysaccharide such as alginate, makes it difficult for pseudomonads to be phagocytosed by mammalian white blood cells.[19] Exopolysaccharide production also contributes to surface-colonising biofilms which are difficult to remove from food preparation surfaces. Growth of pseudomonads on spoiling foods can generate a "fruity" odor.
Pseudomonas have the ability to metabolize a variety of nutrients. Combined with the ability to form biofilms, they are thus able to survive in a variety of unexpected places. For example, they have been found in areas where pharmaceuticals are prepared. A simple carbon source, such as soap residue or cap liner-adhesives is a suitable place for them to thrive. Other unlikely places where they have been found include antiseptics, such as quaternary ammonium compounds, and bottled mineral water.
Antibiotic resistance
Being Gram-negative bacteria, most Pseudomonas spp. are naturally resistant to penicillin and the majority of related beta-lactam antibiotics, but a number are sensitive to piperacillin, imipenem, ticarcillin, or ciprofloxacin.[19] Aminoglycosides such as tobramycin, gentamicin, and amikacin are other choices for therapy.
This ability to thrive in harsh conditions is a result of their hardy cell wall that contains porins. Their resistance to most antibiotics is attributed to efflux pumps, which pump out some antibiotics before the antibiotics are able to act.
Pseudomonas aeruginosa is a highly relevant opportunistic human pathogen. One of the most worrying characteristics of P. aeruginosa is its low antibiotic susceptibility. This low susceptibility is attributable to a concerted action of multidrug efflux pumps with chromosomally encoded antibiotic resistance genes (e.g. mexAB-oprM, mexXY, etc.,[20]) and the low permeability of the bacterial cellular envelopes. Besides intrinsic resistance, P. aeruginosa easily develops acquired resistance either by mutation in chromosomally encoded genes, or by the horizontal gene transfer of antibiotic resistance determinants. Development of multidrug resistance by P. aeruginosa isolates requires several different genetic events that include acquisition of different mutations and/or horizontal transfer of antibiotic resistance genes. Hypermutation favours the selection of mutation-driven antibiotic resistance in P. aeruginosa strains producing chronic infections, whereas the clustering of several different antibiotic resistance genes in integrons favours the concerted acquisition of antibiotic resistance determinants. Some recent studies have shown phenotypic resistance associated to biofilm formation or to the emergence of small-colony-variants may be important in the response of P. aeruginosa populations to antibiotic treatment.[7]
Taxonomy
The studies on the taxonomy of this complicated genus groped their way in the dark while following the classical procedures developed for the description and identification of the organisms involved in sanitary bacteriology during the first decades of the 20th century. This situation sharply changed with the proposal to introduce as the central criterion the similarities in the composition and sequences of macromolecular components of the ribosomal RNA. The new methodology clearly showed the genus Pseudomonas, as classically defined, consisted in fact of a conglomerate of genera that could clearly be separated into five so-called rRNA homology groups. Moreover, the taxonomic studies suggested an approach that might prove useful in taxonomic studies of all other prokaryotic groups. A few decades after the proposal of the new genus Pseudomonas by Migula in 1894, the accumulation of species names assigned to the genus reached alarming proportions. At present, the number of species in the current list has contracted more than 90%. In fact, this approximated reduction may be even more dramatic if one considers the present list contains many new names, i.e., relatively few names of the original list survived in the process. The new methodology and the inclusion of approaches based on the studies of conservative macromolecules other than rRNA components, constitutes an effective prescription that helped to reduce Pseudomonas nomenclatural hypertrophy to a manageable size.[7]
Pathogenicity
Animal pathogens
Infectious species include P. aeruginosa, P. oryzihabitans, and P. plecoglossicida. P. aeruginosa flourishes in hospital environments, and is a particular problem in this environment since it is the second most common infection in hospitalized patients (nosocomial infections). This pathogenesis may in part be due to the proteins secreted by P. aeruginosa. The bacterium possesses a wide range of secretion systems, which export numerous proteins relevant to the pathogenesis of clinical strains.[21]
Plant pathogens
P. syringae is a prolific plant pathogen. It exists as over 50 different pathovars, many of which demonstrate a high degree of host plant specificity. There are numerous other Pseudomonas species that can act as plant pathogens, notably all of the other members of the P. syringae subgroup, but P. syringae is the most widespread and best studied.
Although not strictly a plant pathogen, P. tolaasii can be a major agricultural problem, as it can cause bacterial blotch of cultivated mushrooms.[22] Similarly, P. agarici can cause drippy gill in cultivated mushrooms.[23]
Use as biocontrol agents
Since the mid-1980s, certain members of the Pseudomonas genus have been applied to cereal seeds or applied directly to soils as a way of preventing the growth or establishment of crop pathogens. This practice is generically referred to as biocontrol. The biocontrol properties of P. fluorescens and P. protegens strains (CHA0 or Pf-5 for example) are currently best understood, although it is not clear exactly how the plant growth-promoting properties of P. fluorescens are achieved. Theories include: that the bacteria might induce systemic resistance in the host plant, so it can better resist attack by a true pathogen; the bacteria might out compete other (pathogenic) soil microbes, e.g. by siderophores giving a competitive advantage at scavenging for iron; the bacteria might produce compounds antagonistic to other soil microbes, such as phenazine-type antibiotics or hydrogen cyanide. There is experimental evidence to support all of these theories.[24]
Other notable Pseudomonas species with biocontrol properties include P. chlororaphis, which produces a phenazine-type antibiotic active agent against certain fungal plant pathogens,[25] and the closely related species P. aurantiaca which produces di-2,4-diacetylfluoroglucylmethane, a compound antibiotically active against Gram-positive organisms.[26]
Use as bioremediation agents
Some members of the genus Pseudomonas are able to metabolise chemical pollutants in the environment, and as a result can be used for bioremediation. Notable species demonstrated as suitable for use as bioremediation agents include:
- P. alcaligenes, which can degrade polycyclic aromatic hydrocarbons.[27]
- P. mendocina, which is able to degrade toluene.[28]
- P. pseudoalcaligenes is able to use cyanide as a nitrogen source.[29]
- P. resinovorans can degrade carbazole.[30]
- P. veronii has been shown to degrade a variety of simple aromatic organic compounds.[31][32]
- P. putida has the ability to degrade organic solvents such as toluene.[33] At least one strain of this bacterium is able to convert morphine in aqueous solution into the stronger and somewhat expensive to manufacture drug hydromorphone (Dilaudid).
- Strain KC of P. stutzeri is able to degrade carbon tetrachloride.[34]
Food spoilage agents
As a result of their metabolic diversity, ability to grow at low temperatures and ubiquitous nature, many Pseudomonas spp. can cause food spoilage. Notable examples include dairy spoilage by P. fragi,[35] mustiness in eggs caused by P. taetrolens and P. mudicolens,[36] and P. lundensis, which causes spoilage of milk, cheese, meat, and fish.[37]
Species previously classified in the genus
Recently, 16S rRNA sequence analysis redefined the taxonomy of many bacterial species previously classified as being in the Pseudomonas genus.[8] Species which moved from the Pseudomonas genus are listed below; clicking on a species will show its new classification. Note that the term 'pseudomonad' does not apply strictly to just the Pseudomonas genus, and can be used to also include previous members such as the genera Burkholderia and Ralstonia.
α proteobacteria: P. abikonensis, P. aminovorans, P. azotocolligans, P. carboxydohydrogena, P. carboxidovorans, P. compransoris, P. diminuta, P. echinoides, P. extorquens, P. lindneri, P. mesophilica, P. paucimobilis, P. radiora, P. rhodos, P. riboflavina, P. rosea, P. vesicularis.
β proteobacteria: P. acidovorans, P. alliicola, P. antimicrobica, P. avenae, P. butanovorae, P. caryophylli, P. cattleyae, P. cepacia, P. cocovenenans, P. delafieldii, P. facilis, P. flava, P. gladioli, P. glathei, P. glumae, P. graminis, P. huttiensis, P. indigofera, P. lanceolata, P. lemoignei, P. mallei, P. mephitica, P. mixta, P. palleronii, P. phenazinium, P. pickettii, P. plantarii, P. pseudoflava, P. pseudomallei, P. pyrrocinia, P. rubrilineans, P. rubrisubalbicans, P. saccharophila, P. solanacearum, P. spinosa, P. syzygii, P. taeniospiralis, P. terrigena, P. testosteroni.
γ-β proteobacteria: P. beteli, P. boreopolis, P. cissicola, P. geniculata, P. hibiscicola, P. maltophilia, P. pictorum.
γ proteobacteria: P. beijerinckii, P. diminuta, P. doudoroffii, P. elongata, P. flectens, P. halodurans, P. halophila, P. iners, P. marina, P. nautica, P. nigrifaciens, P. pavonacea, P. piscicida, P. stanieri.
δ proteobacteria: P. formicans.
Bacteriophage
There are a number of bacteriophage that infect Pseudomonas, e.g.
- Pseudomonas phage Φ6
- Pseudomonas aeruginosa phage EL [38]
- Pseudomonas aeruginosa phage ΦKMV [39]
- Pseudomonas aeruginosa phage LKD16 [40]
- Pseudomonas aeruginosa phage LKA1 [40]
- Pseudomonas aeruginosa phage LUZ19
- Pseudomonas aeruginosa phage ΦKZ [38]
See also
- culture collection for a list of culture collections
Footnotes
<references>标签中name属性为“name”的参考文献没有在文中使用References
- ^ 周德庆, 徐士菊. 微生物学辞典. 天津: 天津科学技术出版社, 2005.
- ^ Van Eldere J. Multicentre surveillance of Pseudomonas aeruginosa susceptibility patterns in nosocomial infections. J. Antimicrob. Chemother. 2003, 51 (2): 347–352. PMID 12562701. doi:10.1093/jac/dkg102. 已忽略未知参数
|month=(建议使用|date=) (帮助) - ^ 3.0 3.1 Madigan M; Martinko J (editors). Brock Biology of Microorganisms 11th. Prentice Hall. 2005. ISBN 0-13-144329-1. 引证错误:带有name属性“Brock”的
<ref>标签用不同内容定义了多次 - ^ Migula, W. (1894) Über ein neues System der Bakterien. Arb Bakteriol Inst Karlsruhe 1: 235–328.
- ^ Migula, W. (1900) System der Bakterien, Vol. 2. Jena, Germany: Gustav Fischer.
- ^ 6.0 6.1 6.2 Norberto J. Palleroni. The Pseudomonas Story: Editorial. Environmental Microbiology. 2010-06-07, 12 (6): 1377–1383 [2019-06-25]. doi:10.1111/j.1462-2920.2009.02041.x (英语).
- ^ 7.0 7.1 7.2 7.3 Cornelis P (editor). Pseudomonas: Genomics and Molecular Biology 1st. Caister Academic Press. 2008. ISBN 1-904455-19-0.
- ^ 8.0 8.1 Anzai Y, Kim H, Park, JY, Wakabayashi H. Phylogenetic affiliation of the pseudomonads based on 16S rRNA sequence. Int J Syst Evol Microbiol. 2000, 50 (4): 1563–89. PMID 10939664. doi:10.1099/00207713-50-4-1563.
- ^ Anzai, Y; Kudo, Y; Oyaizu, H. The phylogeny of the genera Chryseomonas, Flavimonas, and Pseudomonas supports synonymy of these three genera. Int J Syst Bacteriol. 1997, 47 (2): 249–251. PMID 9103607. doi:10.1099/00207713-47-2-249. 已忽略未知参数
|unused_data=(帮助) - ^ E. Yabuuchi, Y. Kosako, H. Oyaizu, I. Yano, H. Hotta, Y. Hashimoto, T. Ezaki, M. Arakawa. Proposal of Burkholderia gen. nov. and transfer of seven species of the genus Pseudomonas homology group II to the new genus, with the type species Burkholderia cepacia (Palleroni and Holmes 1981) comb. nov. Microbiology and Immunology. 1992, 36 (12): 1251–1275 [2019-06-25]. ISSN 0385-5600. PMID 1283774.
- ^ E. Yabuuchi, Y. Kosako, I. Yano, H. Hotta, Y. Nishiuchi. Transfer of two Burkholderia and an Alcaligenes species to Ralstonia gen. Nov.: Proposal of Ralstonia pickettii (Ralston, Palleroni and Doudoroff 1973) comb. Nov., Ralstonia solanacearum (Smith 1896) comb. Nov. and Ralstonia eutropha (Davis 1969) comb. Nov. Microbiology and Immunology. 1995, 39 (11): 897–904 [2019-06-25]. ISSN 0385-5600. PMID 8657018.
- ^ X. Shen, M. Chen, H. Hu, W. Wang, H. Peng, P. Xu, X. Zhang. Genome Sequence of Pseudomonas chlororaphis GP72, a Root-Colonizing Biocontrol Strain. Journal of Bacteriology. 2012-03-01, 194 (5): 1269–1270 [2019-06-25]. ISSN 0021-9193. PMC 3294805
. PMID 22328763. doi:10.1128/JB.06713-11 (英语).
- ^ Do Microbes Make Snow?
- ^ Krieg, Noel. Bergey's Manual of Systematic Bacteriology, Volume 1. Baltimore: Williams & Wilkins. 1984. ISBN 0-683-04108-8.
- ^ Meyer JM; Geoffroy VA; Baida N; et al. Siderophore typing, a powerful tool for the identification of fluorescent and nonfluorescent pseudomonads. Appl. Environ. Microbiol. 2002, 68 (6): 2745–2753. PMC 123936 . PMID 12039729. doi:10.1128/AEM.68.6.2745-2753.2002. 已忽略未知参数
|author-separator=(帮助) - ^ Lau GW, Hassett DJ, Ran H, Kong F. The role of pyocyanin in Pseudomonas aeruginosa infection. Trends in molecular medicine. 2004, 10 (12): 599–606. PMID 15567330. doi:10.1016/j.molmed.2004.10.002.
- ^ Matthijs S, Tehrani KA, Laus G, Jackson RW, Cooper RM, Cornelis P. Thioquinolobactin, a Pseudomonas siderophore with antifungal and anti-Pythium activity. Environ. Microbiol. 2007, 9 (2): 425–434. PMID 17222140. doi:10.1111/j.1462-2920.2006.01154.x.
- ^ Hassett D, Cuppoletti J, Trapnell B, Lymar S, Rowe J, Yoon S, Hilliard G, Parvatiyar K, Kamani M, Wozniak D, Hwang S, McDermott T, Ochsner U. Anaerobic metabolism and quorum sensing by Pseudomonas aeruginosa biofilms in chronically infected cystic fibrosis airways: rethinking antibiotic treatment strategies and drug targets. Adv Drug Deliv Rev. 2002, 54 (11): 1425–1443. PMID 12458153. doi:10.1016/S0169-409X(02)00152-7.
- ^ 19.0 19.1 Ryan KJ; Ray CG (editors). Sherris Medical Microbiology 4th. McGraw Hill. 2004. ISBN 0-8385-8529-9.
- ^ Poole K. Efflux-mediated multiresistance in Gram-negative bacteria. Clin. Microbiol. Infect. 2004, 10 (1): 12–26. PMID 14706082. doi:10.1111/j.1469-0691.2004.00763.x. 已忽略未知参数
|month=(建议使用|date=) (帮助) - ^ Hardie. The Secreted Proteins of Pseudomonas aeruginosa: Their Export Machineries, and How They Contribute to Pathogenesis. Bacterial Secreted Proteins: Secretory Mechanisms and Role in Pathogenesis. Caister Academic Press. 2009. ISBN 978-1-904455-42-4.
- ^ Brodey CL, Rainey PB, Tester M, Johnstone K. Bacterial blotch disease of the cultivated mushroom is caused by an ion channel forming lipodepsipeptide toxin. Molecular Plant–Microbe Interaction. 1991, 1 (4): 407–11. doi:10.1094/MPMI-4-407.
- ^ Young JM. Drippy gill: a bacterial disease of cultivated mushrooms caused by Pseudomonas agarici n. sp. NZ J Agric Res. 1970, 13 (4): 977–90. doi:10.1080/00288233.1970.10430530.
- ^ Haas D, Defago G. Biological control of soil-borne pathogens by fluorescent pseudomonads. Nature Reviews in Microbiology. 2005, 3 (4): 307–319. PMID 15759041. doi:10.1038/nrmicro1129.
- ^ Chin-A-Woeng TF; et al. Root colonization by phenazine-1-carboxamide-producing bacterium Pseudomonas chlororaphis PCL1391 is essential for biocontrol of tomato foot and root rot. Mol Plant Microbe Interact. 2000, 13 (12): 1340–1345. PMID 11106026. doi:10.1094/MPMI.2000.13.12.1340. 已忽略未知参数
|author-separator=(帮助) - ^ Esipov; et al. New antibiotically active fluoroglucide from Pseudomonas aurantiaca. Antibiotiki. 1975, 20 (12): 1077–81. PMID 1225181.
- ^ O'Mahony MM, Dobson AD, Barnes JD, Singleton I. The use of ozone in the remediation of polycyclic aromatic hydrocarbon contaminated soil. Chemosphere. 2006, 63 (2): 307–314. PMID 16153687. doi:10.1016/j.chemosphere.2005.07.018.
- ^ Yen KM; Karl MR; Blatt LM; et al. Cloning and characterization of a Pseudomonas mendocina KR1 gene cluster encoding toluene-4-monooxygenase. J. Bacteriol. 1991, 173 (17): 5315–27. PMC 208241 . PMID 1885512. 已忽略未知参数
|author-separator=(帮助) - ^ Huertas MJ; Luque-Almagro VM; Martínez-Luque M; et al. Cyanide metabolism of Pseudomonas pseudoalcaligenes CECT5344: role of siderophores. Biochem. Soc. Trans. 2006, 34 (Pt 1): 152–5. PMID 16417508. doi:10.1042/BST0340152. 已忽略未知参数
|author-separator=(帮助) - ^ Nojiri H; Maeda K; Sekiguchi H; et al. Organization and transcriptional characterization of catechol degradation genes involved in carbazole degradation by Pseudomonas resinovorans strain CA10. Biosci. Biotechnol. Biochem. 2002, 66 (4): 897–901. PMID 12036072. doi:10.1271/bbb.66.897. 已忽略未知参数
|author-separator=(帮助) - ^ Nam; et al. A novel catabolic activity of Pseudomonas veronii in biotransformation of pentachlorophenol. Applied Microbiology and Biotechnology. 2003, 62 (2–3): 284–290. PMID 12883877. doi:10.1007/s00253-003-1255-1.
- ^ Onaca; et al. Degradation of alkyl methyl ketones by Pseudomonas veronii. Journal of Bacteriology. 2007 Mar 9, 189 (10): 3759–3767. PMC 1913341 . PMID 17351032. doi:10.1128/JB.01279-06. 已忽略未知参数
|unused_data=(帮助); - ^ Marqués S, Ramos JL. Transcriptional control of the Pseudomonas putida TOL plasmid catabolic pathways. Mol. Microbiol. 1993, 9 (5): 923–929. PMID 7934920. doi:10.1111/j.1365-2958.1993.tb01222.x.
- ^ Sepulveda-Torres; et al. Generation and initial characterization of Pseudomonas stutzeri KC mutants with impaired ability to degrade carbon tetrachloride. Arch Microbiol. 1999, 171 (6): 424–429. PMID 10369898. doi:10.1007/s002030050729.
- ^ Pereira, JN, and Morgan, ME. Nutrition and physiology of Pseudomonas fragi. J Bacteriol. 1957 Dec, 74 (6): 710–3. PMC 289995 . PMID 13502296.
- ^ Levine, M, and Anderson, DQ. Two New Species of Bacteria Causing Mustiness in Eggs. J Bacteriol. 1932 Apr, 23 (4): 337–47. PMC 533329 . PMID 16559557.
- ^ Gennari, M, and Dragotto, F. A study of the incidence of different fluorescent Pseudomonas species and biovars in the microflora of fresh and spoiled meat and fish, raw milk, cheese, soil and water. J Appl Bacteriol. 1992 Apr, 72 (4): 281–8. PMID 1517169. doi:10.1111/j.1365-2672.1992.tb01836.x.
- ^ 38.0 38.1 Kirsten Hertveldt, Rob Lavigne, Elena Pleteneva, Natalia Sernova, Lidia Kurochkina, Roman Korchevskii, Johan Robben, Vadim Mesyanzhinov, Victor N. Krylov, Guido Volckaert. Genome comparison of Pseudomonas aeruginosa large phages. Journal of Molecular Biology. 2005-12-02, 354 (3): 536–545 [2019-06-25]. ISSN 0022-2836. PMID 16256135. doi:10.1016/j.jmb.2005.08.075.
- ^ Rob Lavigne, Jean-Paul Noben, Kirsten Hertveldt, Pieter-Jan Ceyssens, Yves Briers, Debora Dumont, Bart Roucourt, Victor N. Krylov, Vadim V. Mesyanzhinov, Johan Robben, Guido Volckaert. The structural proteome of Pseudomonas aeruginosa bacteriophage phiKMV. Microbiology (Reading, England). 2006-02, 152 (Pt 2): 529–534 [2019-06-25]. ISSN 1350-0872. PMID 16436440. doi:10.1099/mic.0.28431-0.
- ^ 40.0 40.1 Pieter-Jan Ceyssens, Rob Lavigne, Wesley Mattheus, Andrew Chibeu, Kirsten Hertveldt, Jan Mast, Johan Robben, Guido Volckaert. Genomic analysis of Pseudomonas aeruginosa phages LKD16 and LKA1: establishment of the phiKMV subgroup within the T7 supergroup. Journal of Bacteriology. 2006-10, 188 (19): 6924–6931 [2019-06-25]. ISSN 0021-9193. PMC 1595506 . PMID 16980495. doi:10.1128/JB.00831-06.
- ^ R. E. Buchanan. Taxonomy. Annual Review of Microbiology. 1955, 9: 1–20 [2019-06-25]. ISSN 0066-4227. PMID 13259458. doi:10.1146/annurev.mi.09.100155.000245.
External links
 |
维基共享资源上的相关多媒体资源:Flsxx/测试 |