Identification of Acinetobacter baumannii Strains with Monoclonal Antibodies against the O Antigens of Their Lipopolysaccharides

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Clinical and Diagnostic Laboratory Immunology, May 1999, p. 323-329, Vol. 6, No. 3
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Identification of Acinetobacter baumannii Strains with Monoclonal Antibodies against the O Antigens of Their Lipopolysaccharides

Ralph Pantophlet, Lore Brade, and Helmut Brade^*

Division of Medical and Biochemical Microbiology, Research Center Borstel, Center for Medicine and Biosciences, Borstel, Germany

Received 6 November 1998/Returned for modification 19 January 1999/Accepted 24 February 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Despite the emergence of Acinetobacter baumannii strains as nosocomial pathogens, simple methods for their phenotypic identificationare still unavailable. Murine monoclonal antibodies specific forthe O-polysaccharide moiety of the lipopolysaccharide (LPS) oftwo A. baumannii strains were obtained after immunization withheat-killed bacteria. The monoclonal antibodies were characterizedby enzyme immunoassay and by Western and dot blot analyses andwere investigated for their potential use for the identificationof A. baumannii strains. The antibodies reacted with 46 of the80 A. baumannii clinical isolates that were investigated, andreactivity was observed with 11 of 14 strains which were isolatedduring outbreaks in different northwestern European cities; noreactivity was observed with Acinetobacter strains of other genomicspecies, including the closely related genomic species 1 (Acinetobactercalcoaceticus), 3, and 13 sensu Tjernberg and Ursing, or withother gram-negative bacterial strains. The results show that O-antigen-specificmonoclonal antibodies such as the ones described are convenientreagents which can be used to identify Acinetobacter strains inclinical and researchlaboratories.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The genus Acinetobacter belongs to the family Moraxellaceae (36), and its members are ubiquitous in the natural and clinicalenvironments (1, 20, 38, 39, 44, 47). However, Acinetobacterstrains have also been recognized as opportunistic nosocomialpathogens in recent years (2, 3). Urethritis, pneumonia,meningitis, and septicemia are the major diseases caused by thesebacteria (3, 43), which, in addition, are usually highlyresistant to a large spectrum of antibiotics (43). Acinetobacterbaumannii (genomic species 2) is the most frequently occurringAcinetobacter sp. among clinical Acinetobacter isolates, and mosthospital outbreaks are attributed to this species (3). Althoughother Acinetobacter species such as genomic species 3, A. johnsonii(genomic species 7), A. lwoffii (genomic species 8), and A. radioresistens(genomic species 12) may also be found among clinical Acinetobacterisolates, these species are usually considered to represent contaminationor colonization rather than infection when they are isolated fromclinical specimens (38, 40), particularly since these speciesare also present on the skin and mucous membranes of humans aspart of their normal bacterial flora (39). Unfortunately, thereis still lack of simple methods for the rapid identification ofAcinetobacter strains in clinical laboratories (3, 6, 43).This is partly due to the confused taxonomic status associatedwith the genus (6, 11, 48) and also to the diversity ofthe strains, which is reflected in the different pheno- and genotypicgroups that have been described (3, 6). To date, DNA-DNAhybridization studies have resulted in the delineation of 20 DNAhomology groups, of which only 7 have received a formal speciesname (4, 5, 12, 42). Many strains described so far haveremained unclassified (4, 5, 42).

Gram-negative bacteria express lipopolysaccharides (LPSs) at their outer surface (24, 25, 32). These LPSs consist ofa polysaccharide covalently linked to a lipid component, termedlipid A, which anchors the LPS in the outer membrane (18, 31-33,35). In enterobacteria, the polysaccharide is divided into thecore oligosaccharide (linked to lipid A) and the O polysaccharideor O antigen (32, 33, 35). This type of LPS is referredto as the smooth- or S-form phenotype (33-35); the O antigens arecharacteristic for a given LPS and the parental bacterial strain,a fact on which serotyping schemes for various enteric and alsononenteric gram-negative bacteria are based (21, 27, 30,32, 34, 35). Since all recently investigated LPSs from Acinetobacterstrains have been shown to be of the smooth phenotype (13-17, 45,46), a serotyping scheme for identification of members of thisgenus may also be possible. Recently, we reported on the specificityof hyperimmune rabbit sera against Acinetobacter LPS to examinethe feasibility of such an identification scheme for Acinetobacterstrains (29). Although they were shown to be useful (29),such antisera have certain disadvantages which make them unsuitablefor routine applications, such as the presence of core-reactiveantibodies as well as protein and possible capsular antibodies,which may lead to false-positive reactions when unabsorbed seraare used for O serotyping (23, 29, 37). Thus, to overcomethis problem, we decided to generate monoclonal antibodies (MAbs)against the O antigens of various clinical and environmental Acinetobacterisolates.

In this report, we describe the generation and characterization of two MAbs specific for the O antigen of A. baumannii LPSand show that they can be used for the identification of A. baumanniistrains, particularly for the tracing in hospital wards of strainsoriginating from two epidemiologically important A. baumanniiclonalgroups.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacteria. The A. baumannii strains (n = 82) investigated in this study are listed in Table 1. They consisted mostly of clinical isolatesfrom different parts of Scandinavia, The Netherlands, and theUnited Kingdom. Acinetobacter strains belonging to other genomicspecies were also examined (genomic species 1 [A. calcoaceticus;n = 8], genomic species 3 [n = 13], genomic species 4 [A. haemolyticus;n = 7], genomic species 5 [A. junii; n = 5], genomic species 6[n = 1], genomic species 7 [A. johnsonii; n = 8], genomic species8/9, which is considered a single entity [42] [A. lwoffii; n= 13], genomic species 10 [n = 3], genomic species 11 [n = 6],genomic species 12 [A. radioresistens; n = 7], genomic species13 sensu Tjernberg and Ursing [42] [n = 11], and genomic species14 [n = 4]). All Acinetobacter strains had previously been identifiedto the species level by DNA-DNA hybridization and other methodsand were from the culture collection of L. Dijkshoorn (LeidenUniversity Medical Center, Leiden, The Netherlands). The strainswere originally obtained from A. Horrevorts (Canisius WilhelminaZiekenhuis, Nijmegen, The Netherlands), P. Gerner-Smidt (StatensSeruminstitut, Copenhagen, Denmark), T. L. Pitt (Central PublicHealth Laboratory, London, United Kingdom), I. Tjernberg and J.Ursing (Malmö University Hospital, Malmö, Sweden), and P. Janssen(University of Ghent, Ghent, Belgium). The non-Acinetobacter strainsinvestigated in this study were obtained from R. Podschun (NationalReference Center of Klebsiella species, Kiel, Germany) or werefrom our own culture collection (Salmonella spp. [n = 10], Escherichiacoli [n = 4], Shigella sonnei [n = 8], Enterobacter spp. [n =10], Pseudomonas sp. [n = 6], Stenotrophomonas maltophilia [n= 6], Serratia spp. [n = 10], Burkholderia cepacia [n = 2], Hafniaspp. [n = 10], and Proteus spp. [n = 20]).

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TABLE 1. Reactivities of MAbs S48-3-13 and S48-3-17 in dot and Western blots with LPSs from proteinase K-treated bacterial whole-cell lysates from A. baumannii clinical isolates investigated in this study and O-banding patterns obtained following acid hydrolysis of membrane-bound LPSs and immunostaining with MAb S1 of proteinase K-treated bacterial lysates from A. baumannii strains which did not react with MAb S48-3-13 or MAb S48-3-17

Bacterial LPSs, whole-cell lysates, and proteinase K digestion. The Acinetobacter strains against which MAbs were prepared (see below) were grown in a fermentor (10 liters), and the cellswere killed with phenol and centrifuged. LPS was extracted fromthe sedimented bacteria by the hot phenol-water method (49)and was lyophilized. Preparation of whole-cell lysates (undilutedor diluted 1:4 in sample buffer [45]) and proteinase K digestionwere performed as described previously (29).

MAbs. MAbs were prepared by conventional protocols after immunization of mice with heat-killed bacteria. A. baumannii 24 and 34,against which rabbit immune sera have been produced in a previousstudy (29), were selected as immunogens. BALB/c mice (four miceper antigen) were injected intravenously on days 0, 7, 14, and21 with 20, 20, 60, and 120 µg of antigen, respectively. Animalsera were screened on day 28 for antibodies against the respectiveimmunogen by a dot blot assay with purified LPS as the antigen(see below). The animal whose serum had exhibited the strongestreactivity was given a booster intravenous injection on day 125and booster intraperitoneal injections on days 126 and 127, with200 µg of antigen administered in each injection. Two days afterthe last injection, the animals were exsanguinated and the spleenswere removed. Spleen cells were prepared and fused at a ratioof 1:1 with mouse myeloma X63Ag8 cells by using polyethylene glycol1500 (Boehringer Mannheim) according to conventional protocols.Primary hybridomas were screened by dot blot and enzyme immunoassay(EIA) with isolated LPS as the antigen. Relevant hybridomas werecloned three times by limiting dilution, isotyped with a commerciallyavailable isotyping kit (Bio-Rad), and purified by affinity chromatographyon Protein G (Pharmacia). The antibodies were checked for purityby sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)and subsequent Coomassie staining. The purified MAbs were storedat $-$ 20°C until furtheruse.

Serological assays. EIA and Western blotting were performed as described previously (29) with LPS and proteinase K-digested whole-cell lysates,respectively, as antigens. For Western blotting, 1:4-diluted bacteriallysates were treated with proteinase K, separated by SDS-PAGEwith a 10% separating gel, electrotransferred overnight onto apolyvinylidene difluoride (PVDF) membrane, and immunostained asdescribed previously (29, 45). For dot blotting, proteinaseK-digested lysates were diluted 1:3 in distilled water, of which1 µl was dotted onto nitrocellulose. For the screening of animalsera and primary hybridoma supernatants, 0.5 µg of purified LPSwas applied to the nitrocellulose membrane. After drying (37°C,2 h), the membranes were blocked in blot buffer (45) supplementedwith 10% nonfat dry milk and were immunostained as described abovefor the Western blots (29, 45).

Acid hydrolysis of membrane-bound LPS. Membrane-bound LPS was hydrolyzed under acidic conditions as described in a previous study (28). Briefly, lysates (undiluted)were digested with proteinase K, separated by SDS-PAGE with a10% separating gel, and transferred onto PVDF membranes. The membraneswere then incubated at 100°C for 1 h in heat-resistant glass containerscontaining 0.1 M HCl. After extensive washing in blot buffer (atleast six times), they were blocked in blot buffer supplementedwith 10% nonfat dry milk and were immunostained with lipid A-specificMAb S1 as described previously (28). Parallel gels were stainedwith alkaline silver nitrate as reported elsewhere (45).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Immunization of mice and preparation of MAbs. BALB/c mice were successfully immunized with heat-killed bacteria from A. baumannii 24 or 34. The primary hybridomas (n =864) were tested for antibody reactivity by dot blotting and EIAwith purified LPS as the antigen. Eleven hybridomas reacted withstrain 34, whereas only 1 was observed to react with strain 24.None of the hybridomas reacted with both strains. Among the 11hybridomas which were found to react with strain 34, the 1 withthe highest reactivity was selected for further studies. The antibodieswere cloned by limiting dilution (three times), isotyped, andsubsequently purified by chromatography on Protein G; purity wasascertained by Coomassie staining following SDS-PAGE (data notshown). MAb S48-3-13 against strain 24 was of the immunoglobulinG3 (IgG3) isotype, and MAb S48-3-17 against strain 34 was of theIgG1 isotype. The results described below were obtained with affinity-purifiedMAbs.

Specificities of MAbs. The antibodies were tested by EIA with LPS (5 µg/ml; 50 µl/well) as the antigen. MAbs S48-3-13 and S48-3-17 reacted (opticaldensity at 405 nm, >0.2) at concentrations of 5 and 40 ng/ml,respectively, with the homologous antigen (strains 24 and 34,respectively). No heterologous reactivity (concentration of antibodyyielding an optical density at 405 nm of >0.2, >5,000 ng/ml) wasobserved. Next, checkerboard titrations were performed with antigenconcentrations of between 32 and 4,000 ng/ml (1.6 to 200 ng ofantigen per well) and antibody concentrations of between 0.5 and1,000 ng/ml. The binding curves showed that both antibodies bindto the homologous LPS over a broad range of antigen concentrations(Fig. 1). Proteinase K-treated bacterial lysates or LPSs fromA. baumannii 24 and 34 were separated by SDS-PAGE, blotted ontoPVDF membranes, and immunostained with the homologous or heterologousantibody. A banding pattern characteristic of that of an O-polysaccharidechain could be observed for both strains (Fig. 2 and 3, lanes1). Identical patterns were observed when LPS was used. No heterologousreactivity was observed, and no reaction with the core lipid Aregion was observed when the LPSs were separated on a 15% gel(data not shown). To show that both antibodies were indeed directedagainst the LPS and not another polysaccharide, the followingexperiment was performed (28); proteinase K-treated whole-celllysates from both strains were separated by SDS-PAGE, transferredonto a PVDF membrane, and subjected to hydrolysis in 0.1 M HCl.The free 4'-monophosphoryl lipid A (41), which remained membranebound, could be detected in situ by MAb S1, which recognizes thispartial structure (22). For both strains, the pattern was indistinguishablefrom that observed when the LPS was stained with the homologousantibody, thus indicating that the antibodies were indeed directedagainst the O polysaccharide (data not shown).

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FIG. 1. Checkerboard titrations of MAbs S48-3-13 (A) and S48-3-17 (B) by EIA with LPSs from A. baumannii 24 and 34, respectively, as solid-phase antigens. Plates were coated with antigen at concentrations of 4,000 (

), 2,000 (

), 1,000 ( $black-triangle$ ), 500 ( $black-lozenge$ ), 250 ( $open circle$ ), 125 (

), 63 ( $triangle$ ), and 32 ( $diamond$ ) ng/ml (50 µl per well) and were reacted with MAbs at the concentrations indicated on the abscissa. OD₄₀₅, optical density at 405 nm.

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FIG. 2. Representative Western blot of S48-3-13-positive A. baumannii clinical isolates after SDS-PAGE of the proteinase K-digested whole-cell lysates (10 µl each), transfer onto a PVDF membrane, and immunostaining with MAb S48-3-13. Bacteria are, from left to right, strain 24 (homologous strain; lane 1), strain 26 (lane 2), strain RUH 508 (lane 3), strain GNU 1084 (lane 4), strain GNU 1078 (lane 5), and strain 2032 (lane 6).

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FIG. 3. Representative Western blot of S48-3-17-positive A. baumannii clinical isolates after SDS-PAGE of the proteinase K-digested whole-cell lysates (10 µl each), transfer onto a PVDF membrane, and immunostaining with MAb S48-3-17. Bacteria are, from left to right, strain 34 (homologous strain; lane 1), strain 11 (lane 2), strain 18 (lane 3), strain 40 (lane 4), strain 10 (lane 5), strain 39 (lane 6).

The MAbs were subsequently tested by dot blotting with proteinase K-treated lysates from 80 A. baumannii clinical isolates.They were found to react with 46 strains (Fig. 4; Table 1); noneof the strains reacted with both antibodies. The specificitiesof the reactions could be confirmed by Western blotting (Fig.2 and 3, lanes 2 to 6). For both antibodies, the ladder patternsobtained were indistinguishable from those observed after immunostainingof the respective homologous LPS. No reactivity was observed whenthe two antibodies were tested with the Acinetobacter strainsof other genomic species or with the non-Acinetobacter strains(data not shown).

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FIG. 4. Reactivities of MAbs with A. baumannii clinical isolates by dot blotting. Bacterial lysates were diluted 1:3 in distilled water, dotted onto nitrocellulose membranes (1 µl per dot), and developed with MAb S48-3-13 (A) or MAb S48-3-17 (B). The positions of the strains on the membrane are listed in Table 1.

Determination of LPS phenotypes. To determine their LPS phenotypes, those strains (n = 34) which had not reacted with either antibody were also subjected toacid hydrolysis. A representative Western blot of the patternsobtained is shown in Fig. 5, and the patterns for the 34 strainsare listed in Table 1. All patterns so obtained were distinguishablefrom those observed for strains 24 and 34 obtained by Westernblotting with the homologous antibody and may thus represent thepatterns for additional serotypes within the species A. baumannii.No banding patterns were observed following staining with alkalinesilver nitrate (data not shown).

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FIG. 5. Representative Western blot of S48-3-13- and S48-3-17-negative A. baumannii clinical isolates after SDS-PAGE of the proteinase K-treated bacterial lysates (20 µl each), transfer onto a PVDF membrane, hydrolysis at 100°C for 1 h in 0.1 M HCl, and immunostaining with lipid A-specific MAb S1. Bacteria are, from left to right, strain 42 (lane A), strain GNU 1086 (lane B), strain NCTC 7844 (lane C), strain 36 (lane D), strain RUH 1205 (lane E), strain RUH 3204 (lane F), strain RUH 1486 (lane G), strain RUH 2180 (lane H), strain 10086 (lane I), and strain RUH 1907 (lane J).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

LPSs are amphiphilic molecules imbedded in the outer membranes of gram-negative bacteria (24, 25, 32). Serological andchemical analyses of the LPSs from several Acinetobacter strainshave shown they are of the smooth phenotype (13-17, 45, 46).Since S-LPS has been used as a basis for serotyping schemes forvarious bacterial species in the past (27, 32, 34, 35),such LPS antibodies could also be expected to be of value forthe differentiation of Acinetobacter strains. This technique couldthen also be implementable in clinical microbiology laboratories,which lack simple methods for the phenotypic identification ofAcinetobacter strains (3, 6, 43). By using rabbit antisera,this hypothesis was proven to be correct (29). However, althoughthey were shown to be highly specific, the antisera have the disadvantagethat they contain core-reactive and non-LPS antibodies, e.g.,capsular and protein antibodies, which would lead to false-positiveresults when the sera are used for identification purposes (29).MAbs, however, which react only with the O antigen of the LPScan be generated, and this specific reactivity thus makes themmore suitable for such a scheme. Moreover, the latter approachoffers the advantage that virtually unlimited amounts of antibodiesof homogeneous specificity can be madeavailable.

Since numerous studies have now confirmed that A. baumannii is the most prevalent species associated with outbreaks (3,43), MAbs were generated against the LPSs of two A. baumanniistrains and were investigated for their potential use for theidentification of strains belonging to this species. Two antibodies,S48-3-13 (IgG3) and S48-3-17 (IgG1), were selected and were shownto be highly specific for the homologous LPS by EIA and Westernblotting. The MAbs were then tested by dot and Western blottingwith 80 other clinical isolates previously identified by DNA-DNAhybridization to be A. baumannii. MAb S48-3-13 was found to reactwith 31 strains, and MAb S48-3-17 was found to react with 15 strains;none of the strains reacted with both antibodies. Among these46 strains, reactivity was observed with 11 of 14 strains (Table1) which we are certain were associated with nosocomial outbreaksin different northwestern European cities (7, 8), althoughone cannot exclude the possibility of potential "outbreak"-relatedstrains among the other isolates included in the mentioned studies.In the study by Dijkshoorn et al. (7) performed in 1995, thedistinction of four groups of A. baumannii strains (numbered 1to 4) by at least one genomic and one other typing method wasexplained by the possibility that the respective strains originatedfrom a common clonal origin (26). These four groups were thereforetermed clones I to IV (7). Interestingly, the 11 outbreak strainswhich were noted to react with the two antibodies belonged toA. baumannii clonal group I or II (Table 1); MAb S48-3-13 reactedonly with isolates of clone I (n = 9) and MAb S48-3-17 reactedonly with those of clone II (n = 2). The only exception was strainGNU 1086 (clone II), which did not react with either of the twoMAbs. Although initially surprising, this finding may be explainedby observations made in the study by Dijkshoorn et al. (7),in which strain GNU 1086 was found to have a ribotype patterndifferent from those of the other strains within this clonal group,despite identical amplified fragment length polymorphism and proteinprofile patterns (biotypes and antibiograms are not consideredsince these were not unique for this group [7]). Thus, thisstrain could represent a variant within this particular clonalgroup with which MAb S48-3-17 is unable to react. Another possibilityis that this strain has an entirely different clonal origin, despitehaving a high degree of similarity to the strains within clonalgroup II. This hypothesis is supported by the ladder pattern whichwas observed following acid hydrolysis of the LPS (see below),which differed from that observed for the LPS of strain 34 whenthe LPS was immunostained with MAb S48-3-17.

Strains of clones I and II have been proposed to have virulence factors related to invasiveness, transmissibility, or an enhancedability to colonize immunocompromised patients and therefore shouldbe a cause of concern in hospitals (7). Thus, since the twoMAbs reacted with strains having characteristics of clones I andII, respectively, they provide an easy way of tracing such strainsin the hospital environment (7), e.g., by means of a simple(latex) agglutination test. The other two isolates, strains GNU1081 and RUH 1752, could not be grouped in the previously mentionedstudy (7) and, as postulated (7), may represent additionalclones or groups within thisspecies.

Since no staining with alkaline silver nitrate was observed for those strains which had failed to react with MAb S48-3-13or MAb S48-3-17, we used a method in which lipid A, which is membranebound following acid hydrolysis of LPS which has been blottedonto a PVDF membrane, is detected with specific MAbs, thus allowingLPS phenotype determination. Ten additional banding patterns wereidentified. None of the patterns were identical, and they alsodiffered from the patterns observed for the LPSs from strains24 and 34 when the LPSs were immunostained with the homologousantibody; thus, they may represent additional serotypes withinthis species. Some strains did not show a banding pattern, whichmay be due to a reduced level of O-antigen expression or the naturalproduction of LPS which is of the rough phenotype. The lack ofstaining with alkaline silver nitrate has also been observed withother Acinetobacter strains, and possible reasons for this phenomenonhave extensively been discussed elsewhere (13, 14, 17, 45,46).

The possibility of the use of a scheme for the identification of Acinetobacter strains based on their O antigens is clearlydemonstrated in this report. The two antibodies described hereinare highly specific for the O antigen of the LPS from a largenumber of A. baumannii strains; no reactivity was observed withAcinetobacter strains of other genomic groups, including the pheno-and genotypically closely related genomic species 1 (A. calcoaceticus),3, and 13 sensu Tjernberg and Ursing (42), or with strains ofother gram-negative bacterial genera and species, such as Salmonella,E. coli, Serratia, Pseudomonas, S. maltophilia, or B. cepacia(data not shown). The LPSs of the A. baumannii strains which didnot react with either of the two antibodies as well as the LPSsof strains belonging to genomic species which are not clinicallyrelevant will be characterized in our laboratory, and MAbs againstthe O antigen will be generated in the future to fill the presentgaps.

	ACKNOWLEDGMENTS

We gratefully thank L. Dijkshoorn (Leiden University Medical Center, Leiden, The Netherlands) and R. Podschun (National ReferenceCenter of Klebsiella species, Kiel, Germany) for providing thestrains investigated in this study and V. Susott, D. Brötzmann,S. Cohrs, and S. Ruttkowski for excellent technical assistance.C. P. A. van Boven and L. Dijkshoorn are also thanked for theirsuggestions and critical review of themanuscript.

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Medical and Biochemical Microbiology, Research Center Borstel, Center forMedicine and Biosciences, Parkallee 22, D-23845 Borstel, Germany.Phone: 49-4537-188474. Fax: 49-4537-188419. E-mail: hbrade{at}fz-borstel.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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21. Knirel, Y. A., and N. K. Kochetkov. 1994. The structure of lipopolysaccharides of gram-negative bacteria. III. The structure of O-antigens: a review. Biochemistry (Moscow) 59:1325-1383.

22. Kuhn, H.-M., L. Brade, B. J. Appelmelk, S. Kusumoto, E. T. Rietschel, and H. Brade. 1992. Characterization of the epitope specificity of murine monoclonal antibodies directed against lipid A. Infect. Immun. 60:2201-2210[Abstract/Free Full Text].

23. Liu, P. V., H. Matsumoto, H. Kusama, and T. Bergan. 1983. Survey of heat-stable, major somatic antigens of Pseudomonas aeruginosa. Int. J. Syst. Bacteriol. 33:256-264[Abstract/Free Full Text].

24. Lugtenberg, B., and L. van Alphen. 1983. Molecular architecture and functioning of the outer membrane of Escherichia coli and other gram-negative bacteria. Biochim. Biophys. Acta 737:51-115[Medline].

25. Nikaido, H., and M. Vaara. 1987. Outer membrane, p. 7-22. In C. Neidhardt, J. L. Ingraham, K. B. Low, B. Magasanik, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella typhimurium: cellular and molecular biology. American Society for Microbiology, Washington, D.C.

26. Ørskov, F., and I. Ørskov. 1983. Summary of a workshop on the clone concept in the epidemiology, taxonomy, and evolution of the Enterobacteriaceae and other bacteria. J. Infect. Dis. 148:346-357[Medline].

27. Ørskov, I., F. Ørskov, B. Jann, and K. Jann. 1977. Serology, chemistry, and genetics of O and K antigens of Escherichia coli. Bacteriol. Rev. 44:667-710.

28. Pantophlet, R., L. Brade, and H. Brade. 1997. Detection of lipid A by monoclonal antibodies in S-form lipopolysaccharide after acidic treatment of immobilized LPS on Western blot. J. Endotox. Res. 4:89-95.

29. Pantophlet, R., L. Brade, L. Dijkshoorn, and H. Brade. 1998. Specificity of rabbit antisera against lipopolysaccharide of Acinetobacter. J. Clin. Microbiol. 36:1245-1250[Abstract/Free Full Text].

30. Popoff, M. Y., and L. Le Minor. 1992. Antigenic formulas of the Salmonella serovars, p. 2-145. In World Health Organization Collaborating Center for Reference and Research on Salmonella Institut Pasteur, Paris, France.

31. Raetz, C. R. H. 1990. Biochemistry of endotoxins. Annu. Rev. Biochem. 59:129-170[Medline].

32. Rietschel, E. T., and H. Brade. 1992. Bacterial endotoxins. Sci. Am. 267:26-33.

33. Rietschel, E. T., H. Brade, O. Holst, L. Brade, S. Müller-Loennies, U. Mamat, U. Zähringer, F. Beckmann, U. Seydel, K. Brandenburg, A. J. Ulmer, T. Mattern, H. Heine, J. Schletter, H. Loppnow, U. Schönbeck, H. D. Flad, S. Hauschildt, U. F. Schade, F. di Padova, S. Kusumoto, and R. R. Schumann. 1996. Bacterial endotoxin: chemical constitution, biological recognition, host response, and immunological detoxification. Curr. Top. Microbiol. Immunol. 216:39-81[Medline].

34. Rietschel, E. T., L. Brade, O. Holst, V. Kulshin, B. Lindner, A. P. Moran, F. U. Schade, U. Zähringer, and H. Brade. 1990. Molecular structure of bacterial endotoxin in relation to bioactivity, p. 15-32. In A. Nowotny, J. J. Spitzer, and E. J. Ziegler (ed.), Cellular and molecular aspects of endotoxin reactions. Elsevier Science Publishers, Amsterdam, The Netherlands.

35. Rietschel, E. T., L. Brade, B. Lindner, and U. Zähringer. 1992. Biochemistry of lipopolysaccharides, p. 3-42. In D. C. Morrison, and J. L. Ryan (ed.), Bacterial endotoxic lipopolysaccharides, vol. I. Molecular biochemistry and cellular biology. CRC Press, Inc., Boca Raton, Fla.

36. Rossau, R., A. van Landschoot, M. Gillis, and J. de Ley. 1991. Taxonomy of Moraxellaceae fam. nov., a new bacterial family to accommodate the genera Moraxella, Acinetobacter, and Psychrobacter and related organisms. Int. J. Syst. Bacteriol. 41:310-319[Abstract/Free Full Text].

37. Schable, B., D. Rhoden, R. Hugh, R. E. Weaver, N. Khardori, P. B. Smith, G. P. Bodey, and R. L. Anderson. 1989. Serological classification of Xanthomonas maltophilia (Pseudomonas maltophilia) based on heat-stable O antigens. J. Clin. Microbiol. 27:1011-1014[Abstract/Free Full Text].

38. Seifert, H., R. Baginski, A. Schulze, and G. Pulverer. 1993. The distribution of Acinetobacter species in clinical culture materials. Zentbl. Bakteriol. Parasitenkd. Infektionskr. Hyg. Abt. 1 Orig. 279:544-552.

39. Seifert, H., L. Dijkshoorn, P. Gerner-Smidt, N. Pelzer, I. Tjernberg, and M. Vaneechoutte. 1997. Distribution of Acinetobacter species on human skin: comparison of phenotypic and genotypic identification methods. J. Clin. Microbiol. 35:2819-2825[Abstract].

40. Seifert, H., A. Strate, A. Schulze, and G. Pulverer. 1993. Vascular catheter-related bloodstream infection due to Acinetobacter johnsonii (formerly Acinetobacter calcoaceticus var. lwoffii): report of 13 cases. Clin. Infect. Dis. 17:632-636[Medline].

41. Takayama, K., and N. Qureshi. 1992. Chemical structure of lipid A, p. 43-65. In D. C. Morrison, and J. L. Ryan (ed.), Bacterial endotoxic lipopolysaccharides, vol. I. Molecular biochemistry and cellular biology. CRC Press, Inc., Boca Raton, Fla.

42. Tjernberg, I., and J. Ursing. 1989. Clinical strains of Acinetobacter classified by DNA-DNA hybridization. APMIS 97:595-605[Medline].

43. Towner, K. J. 1997. Clinical importance and antibiotic resistance of Acinetobacter spp. J. Med. Microbiol. 46:721-746[Abstract/Free Full Text].

44. Towner, K. J., E. Bergogne-Bérézin, and C. A. Fewson. 1991. Acinetobacter: portrait of a genus, p. 1-24. In K. J. Towner, E. Bergogne-Bérézin, and C. A. Fewson (ed.), The biology of Acinetobacter: taxonomy, clinical importance, molecular biology, physiology, industrial relevance. Plenum Press, New York, N.Y.

45. Vinogradov, E. V., R. Pantophlet, L. Dijkshoorn, L. Brade, O. Holst, and H. Brade. 1996. Structural and serological characterization of two O-specific polysaccharides from Acinetobacter. Eur. J. Biochem. 239:602-610[Medline].

46. Vinogradov, E. V., R. Pantophlet, S. R. Haseley, L. Brade, O. Holst, and H. Brade. 1997. Structural and serological characterization of the O-specific polysaccharide from lipopolysaccharide of Acinetobacter calcoaceticus strain 7 (DNA-group 1). Eur. J. Biochem. 243:167-173[Medline].

47. Warskow, A. L., and E. Juni. 1972. Nutritional requirements of Acinetobacter strains isolated from soil, water, and sewage. J. Bacteriol. 112:1014-1016[Abstract/Free Full Text].

48. Weaver, R. E., and L. A. Actis. 1994. Identification of Acinetobacter species. J. Clin. Microbiol. 32:1833[Free Full Text].

49. Westphal, O., and K. Jann. 1965. Bacterial lipopolysaccharides. Extraction with phenol-water and further applications of the procedure. Methods Carbohydr. Chem. 5:83-91.

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1.	Baumann, P. 1968. Isolation of Acinetobacter from soil and water. J. Bacteriol. 96:39-42[Abstract/Free Full Text].
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14.	Haseley, S. R., O. Holst, and H. Brade. 1997. Structural and serological characterisation of the O-antigenic polysaccharide of the lipopolysaccharide from Acinetobacter haemolyticus strain ATCC 17906. Eur. J. Biochem. 244:761-766[Medline].
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16.	Haseley, S. R., O. Holst, and H. Brade. 1998. Structural studies of the O-antigen isolated from the phenol-soluble lipopolysaccharide of Acinetobacter baumannii (DNA group 2) strain 9. Eur. J. Biochem. 251:189-194[Medline].
17.	Haseley, S. R., R. Pantophlet, L. Brade, O. Holst, and H. Brade. 1997. Structural and serological characterisation of the O-antigenic polysaccharide of the lipopolysaccharide from Acinetobacter junii strain 65. Eur. J. Biochem. 245:477-481[Medline].
18.	Holst, O., A. J. Ulmer, H. Brade, H.-D. Flad, and E. T. Rietschel. 1996. Biochemistry and cell biology of bacterial endotoxins. FEMS Immunol. Med. Microbiol. 16:83-104[Medline].
19.	Horrevorts, A., K. Bergman, L. Kollee, I. Breuker, I. Tjernberg, and L. Dijkshoorn. 1995. Clinical and epidemiological investigations of Acinetobacter genomospecies 3 in a neonatal intensive care unit. J. Clin. Microbiol. 33:1567-1572[Abstract].
20.	Juni, E. 1984. Acinetobacter Brisou and Prevot 1954, 727^AL, p. 303-307. In N. R. Krieg (ed.), Bergey's manual of systematic bacteriology, vol. I. The Williams & Wilkins Co., Baltimore, Md.
21.	Knirel, Y. A., and N. K. Kochetkov. 1994. The structure of lipopolysaccharides of gram-negative bacteria. III. The structure of O-antigens: a review. Biochemistry (Moscow) 59:1325-1383.
22.	Kuhn, H.-M., L. Brade, B. J. Appelmelk, S. Kusumoto, E. T. Rietschel, and H. Brade. 1992. Characterization of the epitope specificity of murine monoclonal antibodies directed against lipid A. Infect. Immun. 60:2201-2210[Abstract/Free Full Text].
23.	Liu, P. V., H. Matsumoto, H. Kusama, and T. Bergan. 1983. Survey of heat-stable, major somatic antigens of Pseudomonas aeruginosa. Int. J. Syst. Bacteriol. 33:256-264[Abstract/Free Full Text].
24.	Lugtenberg, B., and L. van Alphen. 1983. Molecular architecture and functioning of the outer membrane of Escherichia coli and other gram-negative bacteria. Biochim. Biophys. Acta 737:51-115[Medline].
25.	Nikaido, H., and M. Vaara. 1987. Outer membrane, p. 7-22. In C. Neidhardt, J. L. Ingraham, K. B. Low, B. Magasanik, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella typhimurium: cellular and molecular biology. American Society for Microbiology, Washington, D.C.
26.	Ørskov, F., and I. Ørskov. 1983. Summary of a workshop on the clone concept in the epidemiology, taxonomy, and evolution of the Enterobacteriaceae and other bacteria. J. Infect. Dis. 148:346-357[Medline].
27.	Ørskov, I., F. Ørskov, B. Jann, and K. Jann. 1977. Serology, chemistry, and genetics of O and K antigens of Escherichia coli. Bacteriol. Rev. 44:667-710.
28.	Pantophlet, R., L. Brade, and H. Brade. 1997. Detection of lipid A by monoclonal antibodies in S-form lipopolysaccharide after acidic treatment of immobilized LPS on Western blot. J. Endotox. Res. 4:89-95.
29.	Pantophlet, R., L. Brade, L. Dijkshoorn, and H. Brade. 1998. Specificity of rabbit antisera against lipopolysaccharide of Acinetobacter. J. Clin. Microbiol. 36:1245-1250[Abstract/Free Full Text].
30.	Popoff, M. Y., and L. Le Minor. 1992. Antigenic formulas of the Salmonella serovars, p. 2-145. In World Health Organization Collaborating Center for Reference and Research on Salmonella Institut Pasteur, Paris, France.
31.	Raetz, C. R. H. 1990. Biochemistry of endotoxins. Annu. Rev. Biochem. 59:129-170[Medline].
32.	Rietschel, E. T., and H. Brade. 1992. Bacterial endotoxins. Sci. Am. 267:26-33.
33.	Rietschel, E. T., H. Brade, O. Holst, L. Brade, S. Müller-Loennies, U. Mamat, U. Zähringer, F. Beckmann, U. Seydel, K. Brandenburg, A. J. Ulmer, T. Mattern, H. Heine, J. Schletter, H. Loppnow, U. Schönbeck, H. D. Flad, S. Hauschildt, U. F. Schade, F. di Padova, S. Kusumoto, and R. R. Schumann. 1996. Bacterial endotoxin: chemical constitution, biological recognition, host response, and immunological detoxification. Curr. Top. Microbiol. Immunol. 216:39-81[Medline].
34.	Rietschel, E. T., L. Brade, O. Holst, V. Kulshin, B. Lindner, A. P. Moran, F. U. Schade, U. Zähringer, and H. Brade. 1990. Molecular structure of bacterial endotoxin in relation to bioactivity, p. 15-32. In A. Nowotny, J. J. Spitzer, and E. J. Ziegler (ed.), Cellular and molecular aspects of endotoxin reactions. Elsevier Science Publishers, Amsterdam, The Netherlands.
35.	Rietschel, E. T., L. Brade, B. Lindner, and U. Zähringer. 1992. Biochemistry of lipopolysaccharides, p. 3-42. In D. C. Morrison, and J. L. Ryan (ed.), Bacterial endotoxic lipopolysaccharides, vol. I. Molecular biochemistry and cellular biology. CRC Press, Inc., Boca Raton, Fla.
36.	Rossau, R., A. van Landschoot, M. Gillis, and J. de Ley. 1991. Taxonomy of Moraxellaceae fam. nov., a new bacterial family to accommodate the genera Moraxella, Acinetobacter, and Psychrobacter and related organisms. Int. J. Syst. Bacteriol. 41:310-319[Abstract/Free Full Text].
37.	Schable, B., D. Rhoden, R. Hugh, R. E. Weaver, N. Khardori, P. B. Smith, G. P. Bodey, and R. L. Anderson. 1989. Serological classification of Xanthomonas maltophilia (Pseudomonas maltophilia) based on heat-stable O antigens. J. Clin. Microbiol. 27:1011-1014[Abstract/Free Full Text].
38.	Seifert, H., R. Baginski, A. Schulze, and G. Pulverer. 1993. The distribution of Acinetobacter species in clinical culture materials. Zentbl. Bakteriol. Parasitenkd. Infektionskr. Hyg. Abt. 1 Orig. 279:544-552.
39.	Seifert, H., L. Dijkshoorn, P. Gerner-Smidt, N. Pelzer, I. Tjernberg, and M. Vaneechoutte. 1997. Distribution of Acinetobacter species on human skin: comparison of phenotypic and genotypic identification methods. J. Clin. Microbiol. 35:2819-2825[Abstract].
40.	Seifert, H., A. Strate, A. Schulze, and G. Pulverer. 1993. Vascular catheter-related bloodstream infection due to Acinetobacter johnsonii (formerly Acinetobacter calcoaceticus var. lwoffii): report of 13 cases. Clin. Infect. Dis. 17:632-636[Medline].
41.	Takayama, K., and N. Qureshi. 1992. Chemical structure of lipid A, p. 43-65. In D. C. Morrison, and J. L. Ryan (ed.), Bacterial endotoxic lipopolysaccharides, vol. I. Molecular biochemistry and cellular biology. CRC Press, Inc., Boca Raton, Fla.
42.	Tjernberg, I., and J. Ursing. 1989. Clinical strains of Acinetobacter classified by DNA-DNA hybridization. APMIS 97:595-605[Medline].
43.	Towner, K. J. 1997. Clinical importance and antibiotic resistance of Acinetobacter spp. J. Med. Microbiol. 46:721-746[Abstract/Free Full Text].
44.	Towner, K. J., E. Bergogne-Bérézin, and C. A. Fewson. 1991. Acinetobacter: portrait of a genus, p. 1-24. In K. J. Towner, E. Bergogne-Bérézin, and C. A. Fewson (ed.), The biology of Acinetobacter: taxonomy, clinical importance, molecular biology, physiology, industrial relevance. Plenum Press, New York, N.Y.
45.	Vinogradov, E. V., R. Pantophlet, L. Dijkshoorn, L. Brade, O. Holst, and H. Brade. 1996. Structural and serological characterization of two O-specific polysaccharides from Acinetobacter. Eur. J. Biochem. 239:602-610[Medline].
46.	Vinogradov, E. V., R. Pantophlet, S. R. Haseley, L. Brade, O. Holst, and H. Brade. 1997. Structural and serological characterization of the O-specific polysaccharide from lipopolysaccharide of Acinetobacter calcoaceticus strain 7 (DNA-group 1). Eur. J. Biochem. 243:167-173[Medline].
47.	Warskow, A. L., and E. Juni. 1972. Nutritional requirements of Acinetobacter strains isolated from soil, water, and sewage. J. Bacteriol. 112:1014-1016[Abstract/Free Full Text].
48.	Weaver, R. E., and L. A. Actis. 1994. Identification of Acinetobacter species. J. Clin. Microbiol. 32:1833[Free Full Text].
49.	Westphal, O., and K. Jann. 1965. Bacterial lipopolysaccharides. Extraction with phenol-water and further applications of the procedure. Methods Carbohydr. Chem. 5:83-91.