A V Popova1,2,3, M M Shneider3,4, N P Arbatsky5, A A Kasimova5, S N Senchenkova5, A S Shashkov5, A S Dmitrenok5, A O Chizhov5, Y V Mikhailova6, D A Shagin7, O S Sokolova8, O Y Timoshina4,6, R S Kozlov3, K A Miroshnikov4, Y A Knirel5. 1. Moscow Institute of Physics and Technology (National Research University), Dolgoprudny, Moscow Region, Russia popova.av@mipt.ru popova_nastya86@mail.ru. 2. State Research Center for Applied Microbiology and Biotechnology, Obolensk, Moscow Region, Russia. 3. Institute of Antimicrobial Chemotherapy, Smolensk State Medical University, Smolensk, Russia. 4. Shemyakin-Ovchinnikov Institute of Bioorganic Chemistry, Russian Academy of Sciences, Moscow, Russia. 5. Zelinsky Institute of Organic Chemistry, Russian Academy of Sciences, Moscow, Russia. 6. Central Scientific Research Institute of Epidemiology, Moscow, Russia. 7. Pirogov Russian National Research Medical University, Moscow, Russia. 8. Lomonosov Moscow State University, Moscow, Russia.
Abstract
Acinetobacter baumannii is one of the most clinically important nosocomial pathogens. The World Health Organisation refers it to its «critical priority» category to develop new strategies for effective therapy. This microorganism is capable of producing structurally diverse capsular polysaccharides (CPSs), which serve as primary receptors for A. baumannii bacteriophages carrying polysaccharide-depolymerasing enzymes. In this study, eight novel bacterial viruses that specifically infect A. baumannii strains belonging to K2/K93, K32, K37, K44, K48, K87, K89 and K116 capsular types were isolated and characterized. The overall genomic architecture demonstrated that these viruses are representatives of the Friunavirus genus of the family Autographiviridae The linear double-stranded DNA phage genomes of 41,105-42,402 bp share high nucleotide sequence identity, except for genes encoding structural depolymerases or tailspikes which determine the host specificity. Deletion mutants lacking N-terminal domains of tailspike proteins were cloned, expressed and purified. The structurally defined CPSs of the phage bacterial hosts were cleaved with the specific recombinant depolymerases, and the resultant oligosaccharides that corresponded to monomers or/and dimers of the CPS repeats (K-units) were isolated. Structures of the derived oligosaccharides were established by nuclear magnetic resonance spectroscopy and high-resolution electrospray ionization mass spectrometry. The data obtained showed that all depolymerases studied were glycosidases that cleave specifically the A. baumannii CPSs by the hydrolytic mechanism, in most cases, by the linkage between the K-units.IMPORTANCE Acinetobacter baumannii, a nonfermentative, Gram-negative, aerobic bacterium, is one of the most significant nosocomial pathogens. The pathogenicity of A. baumannii is based on the cooperative action of many factors, one of them being the production of capsular polysaccharides (CPSs) that surround bacterial cells with a thick protective layer. Polymorphism of the chromosomal capsule loci is responsible for the observed high structural diversity of the CPSs. In this study, we describe eight novel lytic phages which have different tailspike depolymerases (TSDs) determining the interaction of the viruses with corresponding A. baumannii capsular types (K-types). Moreover, we elucidate the structures of oligosaccharide products obtained by cleavage of the CPSs by the recombinant depolymerases. We believe that as the TSDs determine phage specificity, the diversity of their structures should be taken into consideration as selection criteria for inclusion of certain phage candidate to the cocktail designed to control A. baumannii with different K-types.
Acinetobacter baumannii is one of the most clinically important nosocomial pathogens. The World Health Organisation refers it to its «critical priority» category to develop new strategies for effective therapy. This microorganism is capable of producing structurally diverse capsular polysaccharides (CPSs), which serve as primary receptors for A. baumanniibacteriophages carrying polysaccharide-depolymerasing enzymes. In this study, eight novel bacterial viruses that specifically infect A. baumannii strains belonging to K2/K93, K32, K37, K44, K48, K87, K89 and K116 capsular types were isolated and characterized. The overall genomic architecture demonstrated that these viruses are representatives of the Friunavirus genus of the family Autographiviridae The linear double-stranded DNA phage genomes of 41,105-42,402 bp share high nucleotide sequence identity, except for genes encoding structural depolymerases or tailspikes which determine the host specificity. Deletion mutants lacking N-terminal domains of tailspike proteins were cloned, expressed and purified. The structurally defined CPSs of the phage bacterial hosts were cleaved with the specific recombinant depolymerases, and the resultant oligosaccharides that corresponded to monomers or/and dimers of the CPS repeats (K-units) were isolated. Structures of the derived oligosaccharides were established by nuclear magnetic resonance spectroscopy and high-resolution electrospray ionization mass spectrometry. The data obtained showed that all depolymerases studied were glycosidases that cleave specifically the A. baumannii CPSs by the hydrolytic mechanism, in most cases, by the linkage between the K-units.IMPORTANCE Acinetobacter baumannii, a nonfermentative, Gram-negative, aerobic bacterium, is one of the most significant nosocomial pathogens. The pathogenicity of A. baumannii is based on the cooperative action of many factors, one of them being the production of capsular polysaccharides (CPSs) that surround bacterial cells with a thick protective layer. Polymorphism of the chromosomal capsule loci is responsible for the observed high structural diversity of the CPSs. In this study, we describe eight novel lytic phages which have different tailspike depolymerases (TSDs) determining the interaction of the viruses with corresponding A. baumanniicapsular types (K-types). Moreover, we elucidate the structures of oligosaccharide products obtained by cleavage of the CPSs by the recombinant depolymerases. We believe that as the TSDs determine phage specificity, the diversity of their structures should be taken into consideration as selection criteria for inclusion of certain phage candidate to the cocktail designed to control A. baumannii with different K-types.
Hospital-acquired or n class="Disease">nosocomial infections are the most frequent complications in hospitalized patients and the major reason for prolongation of hospital stays and mortality. Acinetobacter baumannii is one of the most significant nosocomial pathogens; it is characterized by intrinsic and acquired resistance to different antibiotics and disinfectants, tolerance to antiseptics and detergents, UV irradiation, and drying, and the ability to form biofilms on various biotic and abiotic surfaces (1, 2). A current prominent problem is the rapidly growing resistance of nosocomial A. baumannii strains to carbapenems, the drugs of choice for the treatment of severe hospital-acquired infections. In particular, resistance rates to carbapenems exceed 80% in nosocomial A. baumannii in Russia, and almost 25% of isolates are resistant to all clinically available antibiotics except colistin (3).
Application of lytic bacteriophages and phage-derived enzymes is one of the possible appron class="Chemical">aches to control the spread of multidrug-resistant A. baumannii strains. Bacteriophages are natural regulators of the population of microorganisms, their diversity in nature is extremely high, and they use a number of strategies to infect and destroy bacteria (4). The ability of bacteriophages to infect bacterial cells, first of all, depends on their ability to recognize specific determinants on the bacterial surface. Over recent years, a number of research groups have demonstrated that capsular polysaccharides (CPSs) are the primary receptors for A. baumanniibacteriophages carrying polysaccharide-degrading enzymes (5–9). The polymorphism of the chromosomal capsule loci (K loci [KL]) is responsible for the observed high diversity of CPS structures (10–12). To date, more than 140 KL variants have been identified by analysis of A. baumannii genome sequences (J. J. Kenyon, Queensland University of Technology, Brisbane, Australia, personal communication), and the CPS structures have been established for more than 40 capsular types (K types).
To our knowledge, among all publications devoted to A. baumanniin class="Chemical">polysaccharide-degrading enzymes, there are only two studies that describe the mechanisms of A. baumannii CPS cleavage by phage depolymerases. In particular, it has been established how the tailspike depolymerase (TSD) of podophage φAB6 hydrolyzed the CPS of A. baumannii clinical isolate Ab-54149, and the CPS-digested products were identified by one- and two-dimensional nuclear magnetic resonance (NMR) spectroscopy (6). In our previous work, we studied the interaction of depolymerases of four lytic phages with the corresponding A. baumannii CPSs (13). TSDs of three bacteriophages, Fri1, AS12, and BS46, were demonstrated to be specific glycosidases that cleave the CPSs of A. baumannii strains 28 (K19capsular type), 1432 (K27), and B05 (K9), respectively, by the hydrolytic mechanism. The TSD of bacteriophage AP22 was characterized as a polysaccharide lyase that cleaved the CPS of A. baumannii strain 1053 (K91) by β-elimination in hexuronic acid (d-ManNAcA) residues.
Herein, we present a characterization of several novel n class="Species">bacteriophages that infect A. baumannii strains belonging to K2/K93, K32, K37, K44, K48, K87, K89, and K116 capsular types and elucidate the mechanisms of specific CPS cleavage by depolymerases encoded in their genomes. We believe that the detailed characterization of new lytic phages and phage-encoded depolymerases will expand our understanding of virus-bacterial host interaction strategies. Most of all, within the scope of possible phage application, the search of lytic phages with different depolymerases seems to be the most reasonable approach to personalized medicine, when an antibacterial agent is selected strictly to the A. baumanniicapsular types circulating in a particular location/hospital.
RESULTS
Phage isolation, morphology, and host specificity.
Bacteriophages vB_AbaP_APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 were initially isolated on the n class="Species">bacterial lawns of A. baumannii ACICU (K2), LUH5549 (K32), NIPH146 (K37), NIPH70 (K44), NIPH615 (K48), LUH5547 (K87), LUH5552 (K89), and MAR303 (K116) from sewage and environmental (river water) samples by using an enrichment procedure in 2018. The phages were named according to a rational scheme for the nomenclature of viruses of Bacteria and Archaea (14), where APK is a short laboratory name which means
phage and the number of the K type that is infected by the phage, for example, APK2 indicates the phage isolated on the bacterial lawn of A. baumannii ACICU belonging to K2.
On the lawns of A. baumannii host strains, the phages formed clear plaques surrounded by haloes (Fig. 1A), indicating the presence of phage structural depolymerases degrading n class="Chemical">polysaccharide capsules (5–9, 15).
FIG 1
(A) Phage plaques with opaque haloes formed by phages APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 on A. baumannii ACICU (K2), LUH5549 (K32), NIPH146 (K37), NIPH70 (K44), NIPH615 (K48), LUH5547 (K87), LUH5552 (K89), and MAR303 (K116), respectively. (B) Phage APK2 spot titration from the top down (10-fold serial dilutions) on lawns of A. baumannii ACICU and B11911 after overnight incubation. (C) Spot test with serial 2-fold titration of purified recombinant depolymerase APK32_gp46 on A. baumannii LUH5549 lawn after 8 h of incubation.
(A) Phage plaques with opaque haloes formed by phages APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 on A. baumannii ACICU (K2), n class="Chemical">LUH5549 (K32), NIPH146 (K37), NIPH70 (K44), NIPH615 (K48), LUH5547 (K87), LUH5552 (K89), and MAR303 (K116), respectively. (B) Phage APK2 spot titration from the top down (10-fold serial dilutions) on lawns of A. baumannii ACICU and B11911 after overnight incubation. (C) Spot test with serial 2-fold titration of purified recombinant depolymerase APK32_gp46 on A. baumanniiLUH5549 lawn after 8 h of incubation.
As examined by transmission electron microscopy (TEM), all the phages had in class="Chemical">cosahedral heads of approximately 60 nm in diameter and short noncontractile tails of 10 nm in length (Fig. 2).
FIG 2
Transmission electron micrographs of phages APK2 (A), APK32 (B), APK37 (C), APK44 (D), APK48 (E), APK87 (F), APK89 (G), and APK116 (H). Staining with 1% uranyl acetate. Scale bar, 100 nm.
Transmission electron micrographs of phages APK2 (A), APK32 (B), APK37 (C), APK44 (D), APK48 (E), APK87 (F), APK89 (G), and APK116 (H). Staining with 1% uranyl acetate. Scale bar, 100 nm.The host specificity of phages APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 was tested using a collection of n class="Species">A. baumannii strains belonging to 56 different K types (Table 1). K loci identified in the genomes of these strains were annotated earlier, and CPS structures for most of them were biochemically characterized. It was found that all of the phages except for APK2 were highly specific and able to infect only a strain of a certain K type. Phage APK2 could infect the representatives of two capsular types, namely, A. baumannii ACICU (K2) and A. baumanniiB11911 (K93) (Fig. 1B). In return, phage APK93 isolated from another sample of wastewater on the bacterial lawn of A. baumanniiB11911 (K93) was able to infect A. baumannii ACICU (K2). Based on this observation, we suggest that structural depolymerases of these phages recognize and degrade a similar linkage in the CPS structures of A. baumannii strains ACICU and B11911.
TABLE 1
Acinetobacter baumannii strains used in this study for phage specificity determination
K type
A. baumannii strains with confirmed CPS structure
K locus GenBank accession no. or coordinates within whole-genome shotgun sequences
Reference or source
1
AYE
CU459141 (base position range, 3834156–3863316)
10
2
ACICU
CP000863 (base position range, 88768–115030)
10, 11, 18
3/22a
ATCC 17978/LUH5537
CP000521 (base position range, 56835–79908)/ KC526920
10, 20/11, 20
6
RBH4
KF130871
46
7
LUH5533
KC526894
11, 47
8
BAL097
KX712116
48
9
B05
MK331712
9
11
LUH5545
KC526904
11, 49
15
LUH5554
KC526900
11, 50
16
D4
MF522813
51
17
G7
KC118541
52
19
28
KU215659
53
20
A388
JQ684178
54
21
G21
MG231275
54
24
RCH51
KX756650
44
25
AB5075
BK008886
55
27
4190
KT266827
21
30
NIPH190
MN166189
22
32
LUH5549
KC526897
11, 19
33
NIPH67
MN166195
56
35
LUH5535
KC526896
50
37
NIPH146
APOU01000009 (base position range, 32574–53092)
20
42
LUH5550
KC526903
57
43
LUH5544
KC526905
11, 58
44
NIPH70
APRC01000043 (base position range, 97989–129118)
21
45
NIPH201
MN166190
22
46
NIPH329
MK609549
59
47
NIPH601
MN166193
58
48
NIPH615
MN166191
22
51
WM98b
MN148384
Unpublished
52
LUH5546
KC526899
11
53
D23
MH190222
60
54
RCH52
MG867726
48
55
BAL204
MN148381
61
57
BAL212
KY434631
62
58
BAL114
KT359617
Unpublished
61
NL4
To be registered
J. Kenyon, personal communication
73
SGH0703
MF362178
63, 64
74
BAL309
MN148383
61
80
LUH3712
KC526914
11, 44
81
LUH3713
KC526916
11
82
LUH5534
KC526908
11, 65
83
LUH5538
KC526898
11, 49
84
LUH5540
KC526902
11
85
LUH5543
KC526913
61
87
LUH5547
KC526918
11; this research
88
LUH5548
KC526910
11, 58
89
LUH5552
KC526919
11; this research
90
LUH5553
KC526917
11
91
1053
KM402814
66
92
B8300
CP021347 (base position range, 1420707–1451977)
Unpublished
93
B11911
BK010902
23
116
MAR-303
MK399425
24
125
MAR13-1452
MH306195
67
128
KZ-1093
MK399428
68
These KL clusters are closely related, although they are slightly different at the nucleotide level, but produce CPSs with identical structures.
Acinetobacter baumannii strains used in this study for phage specificity determinationThese KL clusters are closely related, although they are slightly different at the nucleotide level, but produce CPSs with identical structures.
Phage genome organization and comparison.
The phage linear genomes ranged from 41,105 to 42,402 bp in size, with direct terminal repeats (DTRs) of 381 to 417 bp at the genomes’ ends, containing between 49 and 54 predicted genes located only on the forward strands (Table 2). The G+C n class="Chemical">content of the genomes was 39.05% to 39.40%, similar to that of other A. baumannii viruses and close to the approximate average values for different A. baumannii strains (38.94% to 39.4% according to reference 16). No tRNA genes were identified. No genes encoding toxins and no products responsible for antibiotic resistance or related to lysogeny were determined in the phage genomes.
TABLE 2
General characteristics of phage genomes and phage-encoded TSDs
Phage name
Genome length (bp)
G+C content (%)
Total no. of genes
DTR length (bp)
GenBank accession no.
Phage-encoded depolymerases
Gene (protein ID)
Protein size (aa)
APK2
41,476
39.24
50
410
MK257719
APK2_43 (AZU99242.1)
693
APK32
41,142
39.31
52
396
MK257722
APK32_46 (AZU99395.1)
678
APK37
41,981
39.16
51
388
MK257723
APK37_44 (AZU99445.1)
822
APK44
41,461
39.07
50
382
MN604238
APK44_44 (QGK90444.1)
752
APK48
41,105
39.26
49
417
MN294712
APK48_43 (QFG06960.1)
740
APK87
42,402
39.05
54
381
MN604239
APK87_48 (QGK90498.1)
720
APK89
41,198
39.40
52
397
MN651570
APK89_46 (QGK90394.1)
748
APK116
41,765
39.08
49
409
MN807295
APK116_43 (QHS01530.1)
861
General characteristics of phage genomes and phage-enn class="Chemical">coded TSDs
Almost all of the predicted proteins encoded by APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 had very close homologues in the genomes of phages belonging to the genus Friunavirus of the subfamily Beijerinckvirinae (recently designated by the International n class="Chemical">Committee on Taxonomy of Viruses [ICTV]), within the family Autographiviridae.
Based on the functions of homologous proteins, early, middle, and late gene regions were identified in APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 genomes, as well as in the genome of phage Fri1 and other Fri1-like viruses, such as vB_AbaP_AS11 and vB_AbaP_AS12 (7).The functions of products encoded by genes of early regions (left parts of the genomes) were not determined, but it is likely that these proteins are involved in inhibiting or redirecting the n class="Chemical">activities of functionally important host system components to serve the needs of the viruses (17).
The middle regions of the phage genomes comprised nucleotide metabolism and DNA replication and repair genes enn class="Chemical">coding DNA primase, DNA helicase, ATP-dependent ligase, DNA polymerase I, 5′–3′ exonuclease, tRNA nucleotidyltransferase, endonuclease VII, phosphoesterase, deoxynucleotide monophosphate kinase, and also the gene encoding single-subunit viral RNA polymerase. Interestingly, genes encoding tRNA nucleotidyltransferases were absent in the genomes оf phages APK32, APK37, and APK48 and thus, most likely, are not essential for phage nucleotide metabolism. The presence of open reading frames (ORFs) encoding putative HNH endonucleases was also revealed in the middle clusters of all studied phages, exсept for phages APK89 and APK116. Some homing endonuclease genes were found immediately upstream (APK87_g25) or downstream (APK2_g22, APK37_g23, APK44_g23, APK48_g21) of the DNA polymerase I gene. In some cases, HNH endonuclease genes (APK32_g24, APK44_g21) interrupted the DNA polymerase gene into the two domains, and in some cases, they were located between genes encoding 5′–3′ exonuclease and DNA endonuclease VII (APK32_g29, APK48_g26) instead of genes encoding tRNA nucleotidyltransferase.
Late genome regions were highly conserved among all Fri1-like viruses, n class="Chemical">containing genes encoding structural proteins (head-tail connector protein, scaffolding protein, major capsid protein, tail tubular proteins A and B, internal virion proteins A, B, and C, and tailspike), proteins associated with bacterial cell lysis (holin and endolysin), and with proteins associated with the packaging of DNA (DNA maturase A and B) (Fig. 3).
FIG 3
Comparison of phage genomes using the following color scheme: light gray, genes with unknown functions; green, genes encoding enzymes of nucleotide metabolism, proteins involved in DNA replication and repair, and RNA polymerase; red, structural protein genes; yellow, genes encoding proteins associated with lysis; violet, DNA-packaging protein genes. Maps were created with Easyfig.
Comparison of phage genomes using the following n class="Chemical">color scheme: light gray, genes with unknown functions; green, genes encoding enzymes of nucleotide metabolism, proteins involved in DNA replication and repair, and RNA polymerase; red, structural protein genes; yellow, genes encoding proteins associated with lysis; violet, DNA-packaging protein genes. Maps were created with Easyfig.
The most variable regions of the phage genomes were among the early genes, genes encoding some hypothetical proteins, and gene regions enn class="Chemical">coding CPS-recognizing/degrading domains of phage tailspikes or structural depolymerases.
BLAST analysis revealed that the closest nucleotide sequence homologs of APK2 were phages APK93 (GenBank accessionno. MK257721), APK-2 (MK257720), IME200 (NC_028987), and vB_AbaP_AGC01 (MT263719). For these, the genome n class="Chemical">coverages obtained to an E-value of 0.0 were 99%, 99%, 96%, and 96%, with identities of 99.23%, 99.04%, 96.71%, and 94.69%, respectively. The phages APK32, APK37, APK44, APK48, APK87, APK89, and APK116 shared the highest percentage of DNA similarity with phages vB_AbaP_B1 (NC_042003), APK44, APK37, APK116, vB_ApiP_P2 (NC_042007), vB_AbaP_AS11 (NC_041915), and APK48, respectively.
Phage depolymerases.
Recently, it has been shown that tailspike proteins or structural depolymerases of A. baumannii phages direct the ability to infect the strains of certain K types (5–9). Depolymerases are highly specific enzymes that cleave n class="Chemical">CPS of definite structure for subsequent phage adsorption on the bacterial cell surface (15).
Tailspikes of phages APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 were formed by single proteins encoded by the genes located at the end of structural modules of phage genomes immediately after internal virion proteins A to C (Fig. 3; Table 2).At the aminoacid level, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 TSDs were found to differ significantly from the proteins encoded by the other A. baumannii phages deposited in GenBank, except for their N-terminal domains (approximately the first 160 aminoacids of the proteins). These domains were responsible for the attachment of variable CPS-recognizing/degrading parts of the tailspikes to the tail tubular structures of phage particles and, as expected, were very conservative within the phages of the same taxonomic group sharing similar morphology and structural components.BLASTp analysis revealed that APK2_gp43 was identical to the proteins encoded by phages vB_AbaP_APK2-2 (APK2-2_gp43; accession no. AZU99292) and vB_AbaP_APK93 (APK2_gp43; GenBank accession no. AZU99342) and was highly homologous to the proteins encoded by Acinetobacter phage IME200 (YP_009216489; 99% at the aminoacid level) and Acinetobacter phage SH-Ab 15519 (YP_009598268; 97% at the aminoacid level). This, most likely, indicates that tailspikes of phages APK2, IME200, and SH-Ab 15519 can interact specifically with CPS of the same structure.Deletion mutants lacking the N-terminal domains of the tailspikes were cloned, expressed, and purified by immobilized n class="Chemical">metal ion affinity chromatography, followed by ion-exchange chromatography. The recombinant proteins were stable for at least 2 months at 4°C, retaining sufficient depolymerase activities. An example of serial 2-fold titration of one of the purified recombinant depolymerases on the bacterial lawn of a host strain, after 8 h of incubation, is presented in Fig. 1C.
The spectra of depolymerase activity of recombinant proteins were tested against a panel of A. baumannii strains with the confirmed CPS structures (Table 1) belonging to 56 different K types. All purified recombinant depolymerases, except for APK2_gp43, were found to be highly specific and formed opaque haloes only on the bacterial lawns of A. baumannii strains of the corresponding K types. APK2_gp43 formed haloes on the bacterial lawns of K2 and K93 strains (data not shown), meaning that this depolymerase effectively degrades CPSs of both types.In order to investigate the role of TSDs in phage n class="Disease">infection of corresponding A. baumannii host cells, we have conducted a series of competition experiments (Fig. 4). For this, bacterial cell cultures preincubated with purified TSD proteins were mixed with several phage dilutions and plated on agar dishes. After overnight incubation, phage titers were measured. A negative-control experiment series where phage host bacterial cells were pretreated with bovine serum albumin (BSA) showed no significant differences in phage titers, whereas coincubation with APK2_gp43, APK32_gp46, APK37_gp44, APK44_gp44, APK48_gp43, APK87_gp48, APK89_gp46, and APK116_gp43 resulted in A. baumannii host cells becoming nonsusceptible to infection by the corresponding phages. Thus, the addition of 20 μM TSD proteins to the cells completely inhibits plaque formation. This means that the TSDs effectively degraded capsularpolysaccharide layers surrounding A. baumannii host cells and, after that, specific phages could not adsorb to the cells. The results obtained confirm that the CPSs are the primary receptors for the phages and that TSDs play a crucial role in the initial step of the phage-bacterial cell interaction.
FIG 4
Phage infection inhibition by the TSDs. Phage titers observed on the bacterial lawns after the treatment of A. baumannii host cells with phages only (left series), host cell cultures preincubated with BSA (as a negative control; middle series), and purified TSDs proteins (right series) followed by phage treatment. Error bars represent 1 standard deviation from the arithmetic mean.
Phage infection inhibition by the n class="Disease">TSDs. Phage titers observed on the bacterial lawns after the treatment of A. baumannii host cells with phages only (left series), host cell cultures preincubated with BSA (as a negative control; middle series), and purified TSDs proteins (right series) followed by phage treatment. Error bars represent 1 standard deviation from the arithmetic mean.
Structures of the CPSs of A. baumannii phage host strains.
To elucidate mechanisms of the action of phage depolymerases, structures of the phage host n class="Chemical">CPSs, which are the primary receptors for depolymerase-carrying bacteriophages, were characterized.
CPSs were isolated by n class="Chemical">phenol-water extraction from A. baumannii strains ACICU (18), LUH5549 (19), NIPH146 (20), NIPH70 (21), NIPH615 (22), LUH5547, LUH55552, B11911 (23), and MAR303 (24), belonging to K2, K32, K37, K44, K48, K87, K89, K93, and K116 capsular types, respectively. The structures of the K2, K32, K37, K44, K48, K93, and K116 CPSs were established earlier (Fig. 5–7). They are built up of tetrasaccharide (K2 and K93) or pentasaccharide (the other CPSs) repeats (K units) containing mainly d-Glc, d-Gal, d-GlcNAc, and d-GalNAc (common monosaccharides). The K2, K44, and K93 CPSs of strains ACICU, NIPH70, and B11911 also include derivatives of higher aldulosonic acids: 5,7-diamino-3,5,7,9-tetradeoxy-l-glycero-l-manno-non-2-ulosonic (pseudaminic) acid (Pse) or 5,7-diamino-3,5,7,9-tetradeoxy-d-glycero-d-galacto-non-2-ulosonic (legionaminic) acid (Leg).
FIG 5
Structures of the CPSs of A. baumannii NIPH70 (K44), NIPH146 (K37), NIPH615 (K48), and oligosaccharides 1 to 4 derived by depolymerization of the CPSs with phage TSDs (see also Table 3). In the NIPH70 (K44) CPS and oligosaccharide 1, R indicates N-acetyl or N-[(S)-3-hydroxybutanoyl] (∼1:2.5).
FIG 6
Structures of the CPSs of A. baumannii LUH5547 (K87), LUH5549 (K32), and LUH5552 (K89) and oligosaccharides 5 to 9 derived by depolymerization of the CPSs with phage TSDs (see also Table 3). (∼10% K units of the CPS of LUH5547 and oligosaccharide 5 carry an O-acetyl group at an unknown position).
FIG 7
Structures of the CPSs of A. baumannii B11911 (K93), ACICU (K2), MAR303 (K116), and oligosaccharides 10 to 15 derived by depolymerization of the CPSs with phage TSDs (for details, see Table 3).
Structures of the CPSs of n class="Species">A. baumannii NIPH70 (K44), NIPH146 (K37), NIPH615 (K48), and oligosaccharides 1 to 4 derived by depolymerization of the CPSs with phage TSDs (see also Table 3). In the NIPH70 (K44) CPS and oligosaccharide 1, R indicates N-acetyl or N-[(S)-3-hydroxybutanoyl] (∼1:2.5).
TABLE 3
Cleavage of A. baumannii CPSs with specific TSDs
Phage
Depolymerase
A. baumannii strain
CPS type
Linkage in the CPS that is cleaved by a specific depolymerasea
Data for depolymerization products
Monomer
Dimer
Structures
NMR data
APK44
gp44
NIPH70
K44
α-Legp5Ac7R-(2→6)-β-d-Galp (D→C)
1
Fig. 5
Table 5
APK37
gp44
NIPH146
K37
β-d-GalpNAc-(1→4)-β-d-GalpNAc (A→D)
2
3
Fig. 5
Table 6
APK48
gp43
NIPH615
K48
β-d-GlcpNAc-(1→3)-α-d-Glcp (A→D)
4
Fig. 5
APK87
gp48
LUH5547
K87
β-d-GlсpNAc-(1→3)-α-l-Rhap (A→D)
5
Fig. 6
Table 7
APK32
gp46
LUH5549
K32
α-d-GalpNAc-(1→3)-β-d-GalpNAc (A→C)
6
7
Fig. 6
Table 8
APK89
gp46
LUH5552
K89
β-d-GlcpNAc-(1→3)-α-d-GalNAcp (A→B)
8
9
Fig. 6
Table 9
APK2
gp43
B11911
K93
β-d-GalpNAc-(1→3)-β-d-Galp (A→B)
10
11
Fig. 7
Table 10
APK2
gp43
ACICU
K2
β-d-GalpNAc-(1→3)-β-d-Galp (A→B)
12
13
Fig. 7
APK116
gp43
MAR303
K116
β-d-GalpNAc-(1→3)-α-d-Galp (A→C)
14
15
Fig. 7
Table 11
For full CPS structures, see Fig. 5 to 7.
Structures of the CPSs of n class="Species">A. baumannii LUH5547 (K87), LUH5549 (K32), and LUH5552 (K89) and oligosaccharides 5 to 9 derived by depolymerization of the CPSs with phage TSDs (see also Table 3). (∼10% K units of the CPS of LUH5547 and oligosaccharide 5 carry an O-acetyl group at an unknown position).
Structures of the CPSs of n class="Species">A. baumannii B11911 (K93), ACICU (K2), MAR303 (K116), and oligosaccharides 10 to 15 derived by depolymerization of the CPSs with phage TSDs (for details, see Table 3).
Structures of the K87 and K89 CPSs of n class="Species">A. baumannii LUH5547 and LUH5552, respectively, have not been reported earlier but, according to our unpublished data, are as shown in Fig. 6. The CPS of strain LUH5552 has a pentasaccharide K unit, which in addition to common monosaccharidescontains 3-acetamido-3,6-dideoxy-d-galactose (Fuc3NAc). The CPS of LUH5547 is distinguished by the presence of d-GlcA, 6-deoxy-l-talose (l-6dTal), and three residues of l-rhamnose (l-Rha) in a heptasaccharide K unit. Details of the structure elucidation of these CPSs will be reported elsewhere.
Mechanism of cleavage of A. baumannii CPSs by phage depolymerases.
The purified CPSs of ACICU/B11911, LUH5549, NIPH146, NIPH70, NIPH615, and MAR303 were cleaved with recombinant depolymerases APK2_gp43, APK32_gp46, APK37_gp44, APK44_gp44, APK48_gp43, APK87_gp48, APK89_gp46, and APK116_gp43, and oligosaccharide products were fractionated by Fractogel TSK HW-40S gel permeation chromatography (Table 3). The CPSs of strains NIPH70 and LUH5547 gave a single oligosaccharide each (1 and 5, respectively, which corresponded to the K units [Fig. 5 and 6]). No K unit monomer, but a dimer 4, was obtained from the CPS of strain NIPH615 (Fig. 5). Each of the other CPSs afforded both a monomer and a dimer of the K unit: 2 and 3 from NIPH146 (Fig. 5), 6 and 7 from LUH5549, 8 and 9 from LUH5552 (Fig. 6), 10 and 11 from B11911, 12 and 13 from ACICU, and 14 and 15 from MAR303 (Fig. 7). All CPSs of the last group also gave K unit trimers and higher products.Cleavage of A. baumannii CPSs with specific n class="Disease">TSDs
For full CPS structures, see Fig. 5 to 7.Structures of the oligosaccharides obtained were established by one- and two-dimensional n class="Chemical">1H and 13C NMR spectroscopy (25) and were confirmed by high-resolution electrospray ionization mass spectrometry (HR ESI-MS) (Table 4). All oligosaccharides had the same monosaccharidecomposition as the CPSs they were derived from.
TABLE 4
HR ESI-MS data of oligosaccharides 1 to 15 derived by depolymerization of A. baumannii CPSs with specific TSDs
HR ESI-MS data of oligosaccharides 1 to 15 derived by depolymerization of A. n class="Disease">baumannii CPSs with specific TSDs
Abbreviations: 6dHex, n class="Chemical">6-deoxyhexose; Ac, acetyl; Hb, 3-hydroxybutanoyl; Hex, hexose; HexA, hexuronic acid; HexN, 2-amino-2-deoxyhexose; Non, 5,7-diamino-3,5,7,9-tetradeoxynon-2-ulosonic acid.
The 1H and n class="Chemical">13C NMR spectra of the K unit monomers were fully assigned by two-dimensional shift-correlated experiments (1H-1Hcorrelation spectroscopy [COSY], 1H-1H total correlation spectroscopy [TOCSY], and 1H-13C heteronuclear single quantum coherence [HSQC] spectroscopy) and compared with the data of the corresponding CPSs (Tables 5
to
11). Linkage and sequence analyses by two-dimensional 1H-1H rotating-frame nuclear Overhauser effect (ROESY) and 1H-13C heteronuclear multiple-bond correlation (HMBC) experiments enabled elucidation of full structures of the oligosaccharides, shown in Fig. 5 to 7.
TABLE 5
1H and 13C NMR chemical shifts of the K44 CPS of A. baumannii NIPH70 and oligosaccharide 1 derived by depolymerization of the CPS with phage depolymerase APK44_gp44
Residue
1H and 13C chemical shifts (δ, ppm)
H-1C-1
H-2C-2
H-3 (ax, eq)C-3
H-4C-4
H-5C-5
H-6 (a, b)C-6
H-7C-7
H-8C-8
H-9C-9
CPS (at 30°C) (21)
→3)-β-d-GalpNAc-(1→ A
4.54103.3
3.9352.5
3.8181.8
4.2069.1
3.6775.8
3.80, 3.8062.2
→3,6)-β-d-Galp-(1→ B
4.45106.0
3.6070.3
3.6878.1
4.0966.3
3.7674.5
3.83, 4.0471.0
→6)-β-d-Galp-(1→ С
4.40104.9
3.4871.9
3.6273.9
3.9269.7
3.7674.7
3.61, 3.8964.6
→4)-α-Legp5Ac7Hb-(2→ DHb
174.3
101.7
1.74, 2.9541.4
3.6378.7
3.7551.5
3.9573.1
3.8755.0
3.9468.5
1.1519.5
→4)-α-Legp5Ac7Ac-(2→ DAc
174.3
101.7
1.74, 2.9541.4
3.6378.7
3.7551.5
3.9573.1
3.8355.1
3.9468.4
1.1519.4
α-d-GlcpNAc-(1→ E
5.02 95.3
3.9554.7
3.5271.1
3.8172.1
3.9573.1
3.75, 3.8061.6
Oligosaccharide 1 (at 30°C)
→4)-β-Legp5Ac7Hb DHb
1.88, 2.4240.9
4.0078.0
3.8052.1
4.2370.9
3.8754.3
3.8467.7
1.1520.5
→4)-β-Legp5Ac7Ac DAc
1.88, 2.4240.9
4.0078.0
3.8052.1
4.2370.9
3.8354.4
3.8467.7
1.1320.4
→3)-β-d-GalpNAc-(1→ A
4.57103.2
3.9152.6
3.8481.8
4.1969.2
3.6775.9
3.81, 3.8162.3
→3,6)-β-d-Galp-(1→ B
4.47105.9
3.6070.3
3.6978.0
4.1166.0
3.7874.5
3.86, 4.0170.3
β-d-Galp-(1→ С
4.41104.7
3.5072.0
3.6374.0
3.9169.9
3.6876.4
3.75, 3.7562.2
α-d-GlcpNAc-(1→ E
5.03 95.1
3.9654.7
3.5371.0
3.8272.1
3.9773.1
3.73, 3.8061.5
Hb, (S)-3-hydroxybutanoyl. 1H NMR chemical shifts are italicized. Chemical shifts for NHb are δC 46.1 (C-2), 66.3–66.4 (C-3), and 23.5–23.7 (C-4), δH 2.36–2.40 (H-2), 4.16–4.18 (H-3), and 1.23–1.24 (H-4); for the N-acetyl groups, δC 23.3–23.7 (CH3), δH 1.95–2.04; for CO of NHb and NAc, 174.3–175.7.
TABLE 11
1H and 13C NMR chemical shifts of the K116 CPS from A. baumannii MAR303 and oligosaccharide 14 derived by depolymerization of the CPS with phage depolymerase APK116_gp43
Monosaccharide residue
1H and 13C chemical shifts (δ, ppm)
H-1,C-1
H-2,C-2
H-3,C-3
H-4,C-4
H-5,C-5
H-6a, 6b,C-6
CPSb (at 55°C) (24)
→3)-β-d-GalpNAc-(1→ A
4.66104.5
4.1152.9
3.8581.6
4.1669.4
3.7076.0
3.78,3.7862.7
→6)-β-d-Galp-(1→ B
4.48106.0
3.5672.0
3.6373.8
4.0269.7
3.7076.0
3.83, 3.8367.7
→3,4)-α-d-Galp-(1→ C
4.96100.4
3.7468.7
3.9180.9
4.3777.6
3.9471.9
3.74, 3.8162.4
→6)-α-d-GalpNAc-(1→ D
4.92103.1
3.9353.6
3.7872.1
3.9769.2
3.8574.8
3.92, 4.0870.4
β-d-Glcp-(1→ E
4.51104.1
3.3074.4
3.5077.0
3.4071.1
3.4977.2
62.13.75, 3.93
Oligosaccharidec14 (at 45°C)
→3)-α-d-GalpNAc Aα
5.2392.4
4.31n.f.
4.0278.3
4.2069.9
4.1271.4
3.7862.7
→3)-β-d-GalpNAc Aβ
4.7296.2
3.9753.9
3.8781.5
4.1469.3
4.1478.3
3.87, 3.8762.7
→6)-β-d-Galp-(1→ B
4.46105.8
3.5471.8
3.6473.8
3.9669.9
3.7075.9
3.87, 3.8768.0
→4)-α-d-Galp-(1→ C
4.9699.8
3.7269.7
3.9270.8
4.3577.6
3.9171.7
3.76, 3.8162.3
→6)-α-d-GalpNAc-(1→ D
4.90103.0
3.9153.6
3.7672.1
3.9669.9
3.8275.2
3.96, 4.0770.4
β-d-Glcp-(1→ E
4.50104.1
3.3074.4
3.5076.9
3.4070.9
3.4777.2
3.75, 3.9362.1
1H NMR chemical shifts are italicized.
Chemical shifts for the N-acetyl groups are δH 2.03–2.07, δC 23.7–24.1 (CH3), and 175.7–176.3 (CO).
Chemical shifts for the N-acetyl groups are δH 2.03–2.06, δC 23.6, 23.7 (CH3), and 176.0, 176.2 (CO).
1H and n class="Chemical">13C NMR chemical shifts of the K44 CPS of A. baumannii NIPH70 and oligosaccharide 1 derived by depolymerization of the CPS with phage depolymerase APK44_gp44
Hb, (S)-3-hydroxybutanoyl. n class="Chemical">1H NMR chemical shifts are italicized. Chemical shifts for NHb are δC 46.1 (C-2), 66.3–66.4 (C-3), and 23.5–23.7 (C-4), δH 2.36–2.40 (H-2), 4.16–4.18 (H-3), and 1.23–1.24 (H-4); for the N-acetyl groups, δC 23.3–23.7 (CH3), δH 1.95–2.04; for CO of NHb and NAc, 174.3–175.7.
1H and n class="Chemical">13C NMR chemical shifts of the K37 CPS of A. baumannii NIPH146 and oligosaccharide 2 derived by depolymerization of the CPS with phage depolymerase APK37_gp44
1H NMR chemical shifts are italicized. Chemical shifts for the n class="Chemical">N-acetyl groups are δH 2.03–2.07, δC 23.2–23.7 (Me), and 175.8–176.0 (CO).
When linked to Aα; δ 4.52 when linked to Aβ.When linked to Aα; δ 105.3 when linked to Aβ.1H and n class="Chemical">13C NMR chemical shifts of the O-deacetylated LUH5547 (K87) CPS (DPS) and oligosaccharide 5 derived by depolymerization of the CPS with phage depolymerase APK87_gp48
1H NMR chemical shifts are italicized. n.f., not found.Chemical shifts for the N-acetyl groups are δH 2.02, δC 23.5 (Me), and 175.5 (n class="Chemical">CO).
Chemical shifts for the N-acetyl groups are δH 2.06, δC 23.3 (Aα), 23.5 (Aβ) (both Me), and 176.3 (n class="Chemical">CO).
When linked to Aα; δ 4.96 when linked to Aβ.When linked to Aα; δ 103.3 when linked to Aβ.Assignment could be interchanged.Assignment could be interchanged.Assignment could be interchanged.Assignment could be interchanged.1H and n class="Chemical">13C NMR chemical shifts of the K32 CPS of A. baumanniiLUH5549 and oligosaccharide 6 derived by depolymerization of the CPS with phage depolymerase APK32_gp46
1H NMR chemical shifts are italicized. Chemical shifts for the n class="Chemical">N-acetyl groups are δH 1.96–2.09, δC 23.1–23.8 (Me), and 175.1–176.3 (CO).
Linked to Aα.Linked to Aβ.1H and n class="Chemical">13C NMR chemical shifts of the K89 CPS of A. baumanniiLUH5552 and oligosaccharide 8 derived by depolymerization of the CPS with depolymerase APK89_gp46
1H NMR chemical shifts are italicized. Chemical shifts for the n class="Chemical">N-acetyl groups are δH 1.99–2.08, δC 23.2–23.9 (Me), and 174.6–175.7 (CO).
Linked to Aα.Linked to Aβ.1H and n class="Chemical">13C NMR chemical shifts of the K93 CPS from A. baumanniiB11911 and oligosaccharide 10 derived by depolymerization of the CPS with depolymerase APK93_gp43
Hb, (R)-3-hydroxybutanoyl.n class="Chemical">1H NMR chemical shifts are italicized. Chemical shifts for the N-acetyl groups are δH 2.02–2.04, δC 23.5–23.8 (Me); for NHb, δC 46.4 (C-2), 66.3 (C-3), 23.6 (C-4), δH 2.35 (H-2), 4.16 (H-3), 1.22 (H-4); for CO groups, δC 175.7–176.2. n.f., not found.
Linked to AαLinked to Aβ.1H and n class="Chemical">13C NMR chemical shifts of the K116 CPS from A. baumanniiMAR303 and oligosaccharide 14 derived by depolymerization of the CPS with phage depolymerase APK116_gp43
1H NMR chemical shifts are italicized.Chemical shifts for the N-acetyl groups are δH 2.03–2.07, δC 23.7–24.1 (CH3), and 175.7–176.3 (n class="Chemical">CO).
Chemical shifts for the N-acetyl groups are δH 2.03–2.06, δC 23.6, 23.7 (CH3), and 176.0, 176.2 (n class="Chemical">CO).
The 13C NMR chemical shifts of all but two n class="Chemical">monosaccharide residues in the K unit monomers were essentially the same in the oligosaccharides and the corresponding CPSs, whereas those of the residues at the reducing and nonreducing ends of the oligosaccharides were different. On this basis, the glycosidic linkages that were cleaved in the CPSs by the TSDs could be identified (Table 3).
As expected, the monosaccharides that occupy the reducing end of the n class="Chemical">oligosaccharides (d-GlсNAc in 5 and 8, d-GalNAc in 2, 6, 10, and 12) were present in two anomeric forms (α and β), which showed in the 13C NMR spectrum the C-1 signals characteristic for nonlinked monosaccharides at δ 92.3–92.6 and 95.7–96.5, respectively (Tables 5
to
11). In oligosaccharide 1, the reducing end was occupied by a legionaminic acid derivative (Legp5Ac7R), as followed from a displacement of the C-6 signal of this monosaccharide from δ 73.1 in the CPS to δ 70.9 in 1 (Table 5). This difference reflected conversion, upon cleavage of the glyosidic linkage of the α-linked Legp5Ac7R residue with the axial carboxyl group, into a more stable β-anomer with the equatorial carboxyl group (26).
Furthermore, the 13С NMR chemical shifts of unit C (β-Gal) in 1 were typical of the n class="Chemical">corresponding nonsubstituted residues (Table 5) (27). Hence, this monosaccharide, which was substituted in the corresponding initial CPS, was located at the nonreducing end in 1 (Fig. 5). Unit B (β-Gal in 10, α-GalNAc in 8), unit C (β-GalNAc in 6), and unit D (α-Rha in 5, β-GalNAc in 2) were disubstituted in the CPSs but became monosubstituted in the corresponding oligosaccharides (Fig. 5–7). This conclusion followed from significant upfield displacements (by 7.3 to 10.2 ppm) of the signals for C-4 of unit D in 2 and C-3 of units B, C, or D in 5, 6, 8, and 10, compared with their positions in the corresponding CPSs (Tables 5 to 10). Therefore, these carbons that were linked in the CPSs became nonlinked in the oligosaccharides. These data defined the structures of the oligosaccharides obtained by depolymerization of the CPSs (Fig. 5–7) and, as a result, identified the linkages that were cleaved by phage depolymerases (Table 3).
TABLE 10
1H and 13C NMR chemical shifts of the K93 CPS from A. baumannii B11911 and oligosaccharide 10 derived by depolymerization of the CPS with depolymerase APK93_gp43
Monosaccharide residue
1H and 13C chemical shifts (δ, ppm)
H-1,C-1
H-2,C-2
H-3 (3ax, 3eq),C-3
H-4, C-4
H-5,C-5
H-6 (6a, 6b),C-6
H-7,C-7
H-8,C-8
H-9,C-9
CPS (at 65°C) (23)
→3)-β-d-GalpNAc-(1→ A
4.74
4.04
3.88
4.11
3.66
3.75, 3.75
103.9
53.0
81.1
69.7
76.0
62.5
→3,6)-β-d-Galp-(1→ B
4.48
3.63
3.72
4.17
3.87
3.69, 3.69
106.0
71.4
82.7
69.9
73.7
67.9
→6)-α-d-Galp-(1→ C
4.97
3.83
3.80
3.95
4.05
3.56, 3.95
100.1
69.7
70.7
70.7
70.8
65.1
β-Psep5Ac7RHb-(2→ D
1.57, 2.50
3.87
4.18
3.96
4.00
4.07
1.22
174.1
102.6
37.1
68.1
49.9
74.7
54.9
70.9
19.2
Oligosaccharide 10 (at 60°C)
→3)-α-d-GalpNAc Aα
5.23
4.31
4.02
420
4.11
3.74, 3.79
92.6
50.4
78.6
70.2
71.6
62.7
→3)-β-d-GalpNAc Aβ
4.71
3.98
3.85
4.13
3.67
3.74, 3.74
96.5
54.0
81.5
69.6
76.2
62.5
→6)-β-d-Galp-(1→ B(α)b
4.52
3.56
3.66
3.98
3.87
3.70, 3.70
106.1
72.0
74.0
69.9
73.9
68.0
→6)-β-d-Galp-(1→ B(β)c
4.47
3.56
3.66
3.98
3.87
3.70, 3.70
105.9
72.1
74.0
70.0
74.1
67.9
→6)-α-d-Galp-(1→ C
4.98
3.84
3.82
3.97
3.97
3.57, 3.95
100.0
69.6
70.8
70.8
70.6
65.1
β-Psep5Ac7RHb-(2→ D
1.59, 2.51
3.87
4.18
3.98
4.00
4.07
1.22
174.6
n.f.
37.1
68.0
49.9
74.7
54.9
70.8
19.0
Hb, (R)-3-hydroxybutanoyl.1H NMR chemical shifts are italicized. Chemical shifts for the N-acetyl groups are δH 2.02–2.04, δC 23.5–23.8 (Me); for NHb, δC 46.4 (C-2), 66.3 (C-3), 23.6 (C-4), δH 2.35 (H-2), 4.16 (H-3), 1.22 (H-4); for CO groups, δC 175.7–176.2. n.f., not found.
Linked to Aα
Linked to Aβ.
The CPSs of strains ACICU and B11911, having the same main chains consisting of disaccharide repeats but different side chains (Fig. 7), were cleaved with the same depolymerase APK2_gp43, in the same manner, by the β-d-GalpNAc-(1→3)-β-d-Galp (A→B) linkage (Fig. 7). The same linkage was also cleaved by a TSD of bacteriophage φAB6, in the CPS of A. baumannii 54149 (6), having the same structure as the CPS of strain ACICU.The 1H and n class="Chemical">13C NMR spectra of the larger oligosaccharides 3, 7, 9, and 11 showed two series of signals, one being the same as in the corresponding K unit monomers 2, 6, 8, and 10 and the other being the same as in the corresponding CPS K units. Based on these and HR ESI-MS data (Table 4), it was concluded that these oligosaccharides represented K unit dimers having the structures shown in Fig. 5 to 7. A comparison of the NMR spectra of oligosaccharide 4 and those of the CPS of strain NIPH615 (22), combined with the HR ESI-MS data (Table 4), showed that 4 was a K unit dimer with a β-d-GlcpNAc residue at the reducing end (Fig. 5).
DISCUSSION
In the scope of phage application for the development of preparations to n class="Chemical">control multidrug-resistant A. baumannii strains, a comprehensive characterization of prospective candidates to be included in these preparations is required. One of the important characteristics for the applied usage of virulent phages is a host range—the ability of a phage to demonstrate a lytic activity against diverse, clinically important bacterial strains that circulate in the area of estimated application. Taking into account that the CPSs are the primary receptors for depolymerase-carrying A. baumannii phages (5–9), we believe that the range of their lytic spectra depends on the prevalence of A. baumannii strains with appropriate CPS structures.
High diversity and variability of the CPS structures imply the existence of the same variety of phage depolymerases that can specifically ren class="Chemical">cognize and cleave different CPSs. Therefore, preparations (“cocktails”) comprising different phages with the corresponding CPS-recognizing proteins are required to eliminate bacteria of different capsular types within the same species. Certainly, in rare cases, several variants of K loci can be responsible for the synthesis of CPSs of the same structure (for example, KL3/22), or some phages like APK2, described in this work, are able to infect bacteria belonging to different K types. However, a genetic exchange within the population of A. baumannii strains and a rapid appearance of new capsular types are ongoing all the time. Therefore, the constant search for new phages with different K specificity is necessary.
Nowadays, phages that are specific to K1 (n class="Species">phage P1) (8), K2 (phages φAB6 and vB_AbaP_B3) (6, 8), K9 (phages vB_AbaP_B1, AM24, and BS46) (8, 9, 28), K19 (phages Fri1 and AS11) (7), K27 (phage AS12) (7), K45 (phage vB_AbaM_B9, which also performed lysis from without in a K30 strain) (29), and K91 (phage AP22) (13) capsular types of A. baumannii have been described. For some other depolymerase-carrying phages, there is no information as to which capsular type their A. baumannii host strains belong (30–32).
In this work, eight novel A. baumanniin class="Species">bacterial viruses and depolymerases, encoded in their genomes, were characterized. All phages share a similar genome organization with previously reported viruses of the Friunavirus genus, with the most variable region falling into gene regions encoding CPS-recognizing/degrading domains of tailspikes or structural depolymerases. Seven of the phages, namely, APK32, APK37, APK44, APKK48, APKK87, APKK89, and APK116, are the first reported viruses specific to A. baumannii strains of the K32, K37, K44, K48, K87, K89, and K116 capsular types, respectively. Phage APK2 was shown to infect A. baumannii K2 like the earlier described phages φAB6 (6) and vB_AbaP_B3 (8) and also A. baumannii K93 like phage APK93. Interestingly, phages APK2 and APK93 were initially isolated from different samples in 2018 and were given their names because of their isolation on the K2 and K93 bacterial lawns, respectively. Genome sequencing of these phages revealed that they are close homologs and that their receptor-recognizing/binding proteins or TSDs are completely identical. Therefore, these phages can be recognized as closely related variants.
Analysis of oligosaccharide products obtained by degradation of the A. n class="Disease">baumannii CPSs by recombinant depolymerases APK2_gp43, APK32_gp46, APK37_gp44, APK44_gp44, APK48_gp43, APK87_gp48, APK89_gp46, and APK116_gp43 showed that all TSDs studied were specific glycosidases that cleaved the CPSs by the hydrolytic mechanism, to give a monomer or/and an oligomer(s) of the K units. The specific interaction of the APK2_gp43 depolymerase with both K2 and K93 CPSs was suggested to be due to the similarity of their K units, which have identical main chains and differ only in their side chain structures (Fig. 7). Particularly identical are the linkages between the K2 and K93 K units that are cleaved by the APK2_gp43 depolymerase.
Worthy of note is that phages APK2, φAB6, and vB_AbaP_B3, with the same specificity to K2 A. baumannii strains, were independently isolated in remote geographic locations: Russia, China, and Portugal, respectively. The same situation has been observed for phages that infect n class="Species">A. baumannii strains of the K9 capsular type. These findings suggest that representatives of these K types are widely spread around the world and that the phages should adopt their receptor-binding/recognizing proteins to successfully infect them.
In conclusion, the n class="Chemical">comprehensive characterization of new lytic phages and phage-encoded TSDs expand our knowledge of virus-bacterial host interaction strategies. Numerous A. baumannii phages isolated by different research groups, in various geographic locations, have demonstrated “broad” or “narrow” lytic spectra. As each TSD specifically recognizes and enzymatically digests only certain CPS, we declare that the spectrum range of a depolymerase-carrying A. baumannii phage depends on the distribution of A. baumannii strains with appropriate CPS structure among all those tested in each particular case. That means the different phages, independently on broad or narrow spectra, could be efficiently used as antibacterial tools, depending on the clinical situation.
MATERIALS AND METHODS
Phage isolation, propagation, and purification.
For phage isolation, a collection of various n class="Species">A. baumannii strains with defined CPS structures (listed in Table 1), kindly provided by the members of research groups from different countries (see Acknowledgements), was used. Bacteriophages were isolated from sewage and environmental (river water) samples, in accordance with a previously reported procedure (33). The samples were cleared by low-speed centrifugation (7,000 × g for 30 min), the supernatants supplemented with LB medium were incubated for 16 to 18 h in the presence of growing A. baumannii strains belonging to capsular types of interest at 37°C, and then chloroform was added. Bacterial debris was pelleted by centrifugation at 7,000 × g for 30 min, followed by filtration of the supernatants through 1.20- and 0.45-µm-pore-size membrane filters. The purified filtrates were concentrated by ultracentrifugation at 85,000 × g at 4ºС for 2 h. The spot test method, as well as the plaque assay (34), was used to screen for the presence of lytic phage activity in the resulting concentrated preparations. The plates were incubated overnight at 37°C and examined for zones of lysis or plaque formation.
Single plaques formed on the lawns of sensitive A. baumannii strains were picked up inn class="Chemical">SM buffer (10 mM Tris-HCl, pH 7.5, 10 mM MgSO4, 100 mM NaCl) and replated three times, in order to obtain pure phage stock.
A. baumannii strainn class="Chemical">ACICU belonging to the K2 capsular type was used as the host for phage APK2 propagation, and A. baumannii strains NIPH70 (K44), NIPH146 (K37), NIPH615 (K48), LUH5547 (K87), LUH5549 (K32), LUH5552 (K89), and MAR303 (K116) were used as the hosts for phages APK44, APK37, APK48, APK87, APK32, APK89, and APK16 propagation, respectively.
The phages were propagated using a liquid culture of the A. baumannii host strains (optical density at 600 nm [OD600] of 0.3) at a multiplicity of n class="Disease">infection (MOI) of 0.1.
The phage particles were precipitated by polyethylene glycol (n class="Chemical">PEG) 8000 (to a final concentration of 10% and 500 mM NaCl). The final purification was executed by cesium chloride density gradient centrifugation at 100,000 × g (SW50.1 Ti rotor; Beckman Coulter Inc., Brea, CA, USA) for 24 h (35).
Phage host specificity determination.
The host specificity of the phages was tested against A. baumannii strains belonging to 56 different K types (presented in Table 1), using the double-layer method (34). For this, 300 µl of n class="Species">A. baumannii bacterial cultures grown in LB medium at 37°C to an OD600 of 0.3 was mixed with 4 ml of soft agar (LB broth supplemented with 0.6% agarose). The mixture was plated onto the nutrient agar. Then, the phage suspensions (∼109 PFU per ml) or purified recombinant depolymerases, and their several dilutions, were spotted on the soft agar lawns and incubated at 37°C for 18 to 24 h.
Phage infection inhibition assay.
The effect of purified TSD proteins APK2_gp43, APK32_gp46, APK37_gp44, APK44_gp44, APK48_gp43, APK87_gp48, APK89_gp46, and APK116_gp43 on the phage n class="Disease">infection of A. baumannii ACICU, LUH5549, NIPH146, NIPH70, NIPH615, LUH5547, LUH5552, and MAR303 host cells was assessed as following. A titer of 2 × 106 PFU/ml for phages APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 was chosen for the competition experiments. A. baumannii host strains were grown in LB medium at 37°C to an OD600 of 0.3. Then, 20 μM concentrations of corresponding TSD solutions were added to 100-μl aliquots of the cell cultures and incubated for 20 min at 37°C. One-hundred-microliter aliquots of the A. baumannii host cells without anything and with 20 μM BSA incubated for 20 min at 37°C served as controls. After the incubation, several dilutions of corresponding phages and 4 ml of soft agar were added to the mixtures and plated onto the nutrient agar. The plates were incubated overnight at 37°C and assayed for the number of lysis plaques. The experiment was performed in triplicate.
Electron microscopy.
The phage was examined by negative-contrast electron microscopy, using the following procedure. Three microliters of purified and concentrated phage preparation was applied to the carbon-coated 400 mesh copper grids and subjected to glow discharge using the Emitech K100X apparatus (Quorum Technologies, UK). Grids were then negatively stained with 1% uranyl acetate for 30 s, air dried, and analyzed using a JEOL JEM-2100 200-kV transmission electron microscope. Images of negatively stained phage particles were taken with a Gatan Ultrascan 1000XP charge-coupled-device (CCD) camera (14 µm pixels) and Gatan Digital Micrograph software with the following parameters: ×30,000 magnification, 0.5 to 1 µm defocus, 40-µm objective aperture, 2k by 2k pixel size unbinned image size, 3.4-Å pixel size.
DNA isolation and sequencing.
Phage genomic DNAs were isolated from concentrated and purified high-titer phage n class="Species">stocks by incubation in 0.5% SDS, 20 mM EDTA, and 50 µg/ml proteinase K at 56°C for 1 to 3 h. The DNAs were extracted with phenol-chloroform and then precipitated with ethanol supplemented with sodium acetate (35).
Genome sequencing was performed on the MiSeq platform using a Nextera DNA library preparation kit (Illumina, San Diego, CA). The generated reads were assembled de novo into a single contig using SPAdes v.3.13 (36). Further, the resulting sequences were checked by mapping reads against the assemblies with DNASTAR's Lasergene sequence analysis software, version 11.1.0 (DNASTAR, Inc., Madison, WI, USA) (37). Direct terminal repeats were determined as regions of greater n class="Chemical">coverage of sequencing reads mapped on assembled viral genome contigs. The ends were then verified directly by Sanger sequencing with outward-directed primers located inside and outside putative repeats.
Phage genome analysis.
Potential open reading frames (ORFs) were identified with the RAST automated annotation engine (38). Predicted proteins were searched against the NR (nonredundant) database of the NCBI and HHpred profile-profile search (39). The presence of tRNAs in the genome sequence was determined using tRNAscan-SE, version 2.0 (40). n class="Chemical">Comparative analysis of DNA genome sequences was performed using Easyfig (41).
Cloning, expression, and purification of the recombinant depolymerases.
The DNA fragments n class="Chemical">corresponding to the deletion mutants lacking N‐terminal domains of putative podophage depolymerases were amplified by PCR, using oligonucleotide primers indicated in Table 12, and cloned into the pTSL plasmid (GenBank accession no. KU314761) (42).
TABLE 12
Oligonucleotide primers used in this study for cloning of phage depolymerases
Oligonucleotide primers used in this study for cloning of phage depolymerasesUppercase letters indicate restriction endonuclease recognition sites.Expression vectors were transformed into chemically n class="Chemical">competent Escherichiacoli B834(DE3) cells. Protein expression was performed in LB medium supplemented with ampicillin at 100 µg/ml. Transformed cells were grown at 37°C until the optical density reached a value of 0.6 at 600 nm. The medium was cooled to the temperature of 18°C, followed by expression induction by the addition of isopropyl-1-thio-β-d-galactopyranoside (IPTG) to a final concentration of 0.5 to 1.0 mM. After further incubation at 18°C overnight (approximately 16 h), the cells were harvested by centrifugation at 10,000 × g for 15 min, at 4°C. The cell pellets were resuspended in buffer A (20 mM Tris [pH 8.0], 300 mM NaCl, 1/50 of the original cell volume), frozen, thawed, and disintegrated by sonication (Branson Ultrasonic, Danbury, CT, USA). The cell debris was removed by centrifugation at 15,000 × g at 4°C for 20 min. The supernatant was applied to 5-ml Ni2+-charged GE HisTrap columns (GE Healthcare Life Sciences, Chicago, IL, USA) equilibrated with buffer A, and the proteins were eluted with a 50-to-200 mM imidazole linear gradient in buffer A. Fractions containing the target protein were pooled and digested with tobacco etch virus (TEV) protease for 16 h at 20°C at a protease/protein ratio of 1/100 (wt/wt) to remove the His tag. The reaction mixture was simultaneously dialyzed against 10 mM Tris-HCl (pH 8.0) containing 1.0 mM 2-mercaptoethanol.
The cleaved proteins were clarified by filtration, loaded onto an ion-exchange MonoQ 10/100 GL column (GE Healthcare), and eluted with a 0-to-650 mM n class="Chemical">NaCl gradient in 20 mM Tris-HCl (pH 8.0) buffer. Protein-containing fractions were combined and concentrated to ∼5 ml using Sartorius ultrafiltration devices (Sartorius AG, Germany), with a molecular-weight cutoff of 50,000 Da.
Isolation and purification of the capsular polysaccharides.
A. baumannii ACICU, n class="Chemical">NIPH70, NIPH146, NIPH615, LUH5547, lUH5549, LUH5552, B11911, and MAR303 were cultivated in 2TY medium (16 g Bacto tryptone, 10 g Bacto yeast extract, and 5 g NaCl, adjusted to 1 liter with distilled H2O) for 16 h. Bacterial cells were harvested by centrifugation (10,000 × g, 20 min), washed with phosphate-buffered saline, suspended in aqueous 70 % acetone, precipitated, and dried in air.
Capsular polysaccharides (n class="Chemical">CPSs) were isolated by extraction of A. baumannii cells with 45% aqueous phenol for 30 min at 65 to 68°C (43). The extract was cooled and dialyzed without layer separation; then, insoluble contaminations were removed by centrifugation (12,000 × g, 20 min), and CPS preparations were purified as described previously (44). Briefly, aqueous 50% CCl3CO2H was added to a CPS solution in water at 4°C, a precipitate was removed by centrifugation, and the supernatant was dialyzed with distilled water and freeze-dried. The crude CPS preparations were heated with 2% HOAc (100°C, 3 h), and a lipid precipitate was removed by centrifugation (12,000 × g, 20 min). Purified CPS samples were isolated from the supernatant by gel permeation chromatography on a XK 26-mm (depth) by 70-cm (height) column (gel layer, 560 mm) (GE Healthcare) of Sephadex G-50 Superfine (Amersham Biosciences, Sweden) in 0.05 M pyridinium acetate buffer, pH 4.5. The flow rate was 0.5 ml min−1; elution was monitored with a differential refractometer (Knauer, Germany). Control of retention of the intact structure upon mild acid treatment was performed by NMR spectroscopy.
Cleavage of the CPSs with tailspike depolymerases.
Purified CPSs were solubilized in 20 mM n class="Chemical">Tris-HCl (pH 7.5) buffer, and 200 to 500 µg of the corresponding TSD proteins was added for digestion. The reaction mixture was stored at 37°C for 16 h.
CPS digestion products were frn class="Chemical">actionated by gel permeation chromatography on a XK 16-mm (depth) by 100-cm (height) column (gel layer, 800 mm) (GE Healthcare) of Fractogel TSK HW-40S (Toyo Soda, Japan) in 1% acetic acid at a flow rate of 0.5 ml min−1 and monitored as described above.
NMR spectroscopy.
Samples were deuterium exchanged by freeze-drying from 99.9% n class="Chemical">D2O and then examined as solution in 99.95% D2O. NMR spectra were recorded on a Bruker Avance II 600 MHz spectrometer (Bruker, Germany) at 30 to 60°C, as indicated in Tables 5 to 11. Sodium 3-trimethylsilylpropanoate-2,2,3,3-d4 (δH 0, δC −1.6) was used as an internal reference for calibration. Two-dimensional 1H-1Hcorrelation spectroscopy (COSY), 1H1H total correlation spectroscopy (TOCSY), 1H-1H rotating-frame Overhauser effect spectroscopy (ROESY), 1H-13C heteronuclear single-quantum coherence (HSQC), and 1H-13C heteronuclear multiple-bond correlation (HMBC) experiments were performed using standard Bruker software and were used for assignment of 1H and 13C NMR chemical shifts (25). The Bruker TopSpin 2.1 program was used to acquire and process the NMR data. A MLEV-17 spin-lock time of 60 ms and a mixing time of 200 ms were used in TOCSY and ROESY experiments, respectively. A 60-ms delay was used for evolution of long-range couplings to optimize the 1H,13C HMBC experiments for coupling constant JH,C 8 Hz.
Mass spectrometry.
High-resolution electrospray ionization mass spectrometry (HR ESI-MS) (45) was performed in the negative ion mode using a micrOTOF II instrument (Bruker Daltonics). Oligosaccharide samples (∼50 ng µl−1) were dissolved in a 1:1 (vol/vol) n class="Chemical">water-acetonitrile mixture and injected with a syringe at a flow rate of 3 µl min−1. The capillary entrance voltage was set at 3,200 V, and the interface temperature was set at 180°C. Nitrogen was used as the drying gas. The mass range was from m/z 50 to 3,500. Internal calibration was carried out with ESI calibrant solution (Agilent).
Data availability.
The genome sequences of vB_AbaP_APK2, APK32, APK37, APK44, APK48, APK87, APK89, and APK116 phages were deposited in GenBank under accessionnumbers MK257719, MK257722, MK257723, n class="CellLine">MN604238, MN294712, MN604239, MN651570, and MN807295, respectively (Table 2).
TABLE 6
1H and 13C NMR chemical shifts of the K37 CPS of A. baumannii NIPH146 and oligosaccharide 2 derived by depolymerization of the CPS with phage depolymerase APK37_gp44
Residue
1H and 13C chemical shifts (δ, ppm)
H-1C-1
H-2C-2
H-3C-3
H-4C-4
H-5C-5
H-6a, 6bC-6
CPS (at 30°C) (20)
→3)-β-d-GalpNAc-(1→ A
4.67104.4
4.1252.8
3.8581.7
4.1569.2
3.7075.8
3.81, 3.8162.5
→6)-β-d-Glcp-(1→ B
4.53105.5
3.3174.3
3.4777.0
3.6070.3
3.6075.5
3.72, 4.0166.7
→4)-α-d-Galp-(1→ C
4.9699.6
3.7468.8
3.9469.1
4.3677.4
3.9471.4
3.81, 3.8162.1
→4,6)-β-d-GalpNAc-(1→ D
4.91102.9
3.9153.6
3.7772.2
3.9180.9
3.8374.7
3.90, 4.0670.2
β-d-Glcp-(1→ E
4.48104.0
3.2974.3
3.4877.0
3.3971.0
3.4577.1
3.72, 3.9262.1
Oligosaccharide 2 (at 60°C)
→3)-α-d-GalpNAc Aα
5.2492.3
4.3350.0
4.0478.5
4.2069.8
4.1271.3
3.74-3.7862.3
→3)-β-d-GalpNAc Aβ
4.7196.3
3.9253.7
3.8981.5
4.1369.1
3.7075.9
3.74-3.7862.1
→6)-β-d-Glcp-(1→ B
4.58b105.1c
3.3174.0
3.4976.9
3.4970.7
4.6275.4
3.78, 3.9367.3
→4)-α-d-Galp-(1→ C
4.9899.4
3.7369.8
3.9669.0
4.1778.1
3.9371.5
3.84, 3.8462.0
→6)-β-d-GalpNAc-(1→ D
4.67103.7
3.9253.8
3.7572.1
3.9770.7
3.8574.6
3.96, 4.0670.5
β-d-Glcp-(1→ E
4.51104.0
3.3174.2
3.5176.9
3.4170.9
3.4677.0
3.75, 3.9361.9
1H NMR chemical shifts are italicized. Chemical shifts for the N-acetyl groups are δH 2.03–2.07, δC 23.2–23.7 (Me), and 175.8–176.0 (CO).
When linked to Aα; δ 4.52 when linked to Aβ.
When linked to Aα; δ 105.3 when linked to Aβ.
TABLE 7
1H and 13C NMR chemical shifts of the O-deacetylated LUH5547 (K87) CPS (DPS) and oligosaccharide 5 derived by depolymerization of the CPS with phage depolymerase APK87_gp48
Residue
1H and 13C chemical shifts (δ, ppm)
H-1 C-1
H-2C-2
H-3C-3
H-4C-4
H-5C-5
H-6a,6bC-6
DPS (at 50°C)b
→3)-β-d-GlcpNAc-(1→ A
4.75
3.85
3.66
3.53
3.49
3.78, 3.95
103.2
56.8
82.8
69.7
77.0
62.0
→3)-α-l-6dTalp-(1→ B
4.97
3.74
3.87
3.88
4.28
1.23
103.2
71.1
72.0
70.3
68.8
16.7
→2)-α-l-Rhap-(1→ C
5.08
4.01
3.95
3.48
3.75
1.30
97.7
79.8
71.1
73.5
70.5
18.0
→2,3)-α-l-Rhap-(1→ D
5.16
4.40
3.92
3.56
3.75
1.25
102.4
79.3
81.0
72.0
70.5
17.8f
→4)-β-d-GlcpA-(1→ E
4.78
3.39
3.77
3.81
3.95
104.8
74.5
77.2
78.3
76.1
174.1
→2)-α-d-Glcp-(1→ F
5.42
3.55
3.72
3.68
3.54
3.69, 3.77
100.0
78.2
72.8
72.4
73.0
61.1
α-l-Rhap-(1→ G
4.86
3.98
3.76
3.44
4.00
1.25
102.0
71.7
71.5
73.3
70.3
17.9f
Oligosaccharide 5 (at 40°C)c
→3)-α-d-GlcpNAc Aα
5.15
4.03
3.82
3.55
3.89
3.80, 3.86
92.4
54.9
80.7
69.8
73.1
62.0
→3)-β-d-GlcpNAc-(1→ Aβ
4.75
3.79
3.63
3.52
3.49
3.79, 3.92
95.7
57.8
83.1
69.8
77.3
62.1
→3)-α-l-6dTalp-(1→ B
4.98d
3.73
3.88
3.92
4.30
1.24
103.2e
71.3
72.1
70.3
68.8
16.8
→2)-α-l-Rhap-(1→ C
5.11
4.04
3.98
3.49
3.78
1.32
97.8
80.3
71.1
73.4g
70.6h
18.1
→2)-α-l-Rhap-(1→ D
5.27
4.16
3.90
3.50
3.78
1.27
102.4
81.4
71.2
73.6g
70.3h
17.8i
→4)-β-d-GlcpA-(1→ E
4.62
3.44
3.77
3.80
3.78
105.5
74.7
77.4
78.0
78.3
n.f.
→2)-α-d-Glcp-(1→ F
5.43
3.55
3.74
3.79
3.54
3.70, 3.81
99.7
78.2
72.9
72.2
73.2
61.2
α-l-Rhap-(1→ G
4.87
4.00
3.79
3.46
4.03
1.27
102.1
71.8
71.5
73.3
70.3
18.0i
1H NMR chemical shifts are italicized. n.f., not found.
Chemical shifts for the N-acetyl groups are δH 2.02, δC 23.5 (Me), and 175.5 (CO).
Chemical shifts for the N-acetyl groups are δH 2.06, δC 23.3 (Aα), 23.5 (Aβ) (both Me), and 176.3 (CO).
When linked to Aα; δ 4.96 when linked to Aβ.
When linked to Aα; δ 103.3 when linked to Aβ.
Assignment could be interchanged.
Assignment could be interchanged.
Assignment could be interchanged.
Assignment could be interchanged.
TABLE 8
1H and 13C NMR chemical shifts of the K32 CPS of A. baumannii LUH5549 and oligosaccharide 6 derived by depolymerization of the CPS with phage depolymerase APK32_gp46
Residue
1H and 13C chemical shifts (δ, ppm)
H-1C-1
H-2C-2
H-3C-3
H-4C-4
H-5C-5
H-6a, 6bC-6
CPS (at 65°C) (19)
→3)-β-d-GalpNAc-(1→ A
4.54104.1
3.8352.5
3.8981.3
4.0669.2
3.5975.9
3.74, 3.8262.6
→4)-β-d-GlcpA-(1→ B
4.58105.3
3.4073.5
3.6475.2
3.8481.2
4.0174.8
172.1
→3,4)-β-d-GalpNAc-(1→ C
4.53102.9
4.0652.8
3.8479.0
4.2274.9
3.7377.0
3.64, 3.6861.6
→6)-α-d-GlcpNAc-(1→ D
4.86 98.3
3.9055.3
3.8771.9
3.7170.9
4.3472.0
4.06, 4.3269.3
β-d-Glcp-(1→ E
4.47104.0
3.3574.5
3.4977.2
3.4071.2
3.4377.2
3.72, 3.9162.4
Oligosaccharide 6 (at 30°C)
→3)-α-d-GalpNAc Aα
5.2292.4
4.2950.2
4.0178.6
4.2069.8
4.1371.5
3.74, 3.7462.5
→3)-β-d-GalpNAc Aβ
4.6996.4
3.9953.6
3.8281.5
4.1369.1
3.6976.2
3.74, 3.7662.3
→4)-β-d-GlcpA-(1→ B(α)b
4.57105.3
3.3873.9
3.5975.1
3.7881.2
3.6977.8
175.5
→4)-β-d-GlcpA-(1→ B(β)c
4.51105.5
3.3873.8
3.5975.0
3.7881.2
3.6977.8
175.5
→4)-β-d-GalpNAc-(1→ C
4.55102.6
3.9753.3
3.7971.7
3.9877.5
3.7476.7
3.74, 3.7461.5
→6)-α-d-GlcpNAc-(1→ D
4.9099.5
3.9555.2
3.8771.7
3.6470.8
4.3172.3
3.91, 4.0769.2
β-d-Glcp-(1→ E
4.48103.9
3.3274.4
3.5076.9
3.4070.9
3.4477.1
3.73, 3.9162.0
1H NMR chemical shifts are italicized. Chemical shifts for the N-acetyl groups are δH 1.96–2.09, δC 23.1–23.8 (Me), and 175.1–176.3 (CO).
Linked to Aα.
Linked to Aβ.
TABLE 9
1H and 13C NMR chemical shifts of the K89 CPS of A. baumannii LUH5552 and oligosaccharide 8 derived by depolymerization of the CPS with depolymerase APK89_gp46
Monosaccharide residue
1H and 13C chemical shifts (δ, ppm)
H-1C-1
H-2C-2
H-3C-3
H-4C-4
H-5C-5
H-6a, 6bC-6
CPS (at 55°C)
→3)-β-d-GlcpNAc-(1→ A
4.59103.9
3.6955.3
3.7679.5
3.5972.8
3.4277.1
3.75, 3.9362.2
→3,4)-α-d-GalpNAc-(1→ B
5.4298.5
4.3950.1
3.8277.5
4.3676.0
3.9073.0
3.84, 3.8661.2
→6)-α-d-Glcp-(1→ C
5.0299.9
3.5173.1
3.8473.4
3.8270.0
4.2071.8
4.03, 4.1569.0
→2)-β-d-Fucp3NAc-(1→ D
4.61103.7
3.8475.7
4.1555.8
3.6871.8
3.8573.0
1.2817.0
β-d-Glcp-(1→ E
4.58103.5
3.3274.8
3.4877.1
3.3871.2
3.4377.5
3.74, 3.9462.5
Oligosaccharide 8 (at 35°C)
→3)-α-d-GlcpNAc Aα
5.1792.3
4.0153.8
3.9277.6
3.7072.2
3.8872.6
3.74, 3.9061.6
→3)-β-d-GlcpNAc Aβ
4.7695.9
3.7556.6
3.7479.8
3.6772.2
3.4777.1
3.79, 3.8461.8
→4)-α-d-GalpNAc-(1→ B
5.44b98.9b
4.2551.2c
3.9272.8
4.1179.3
3.9372.5
3.8761.2
→6)-α-d-Glcp-(1→ C
4.98101.6
3.5573.2
3.8273.8
3.7670.1
4.1772.3
3.92, 4.0469.1
→2)-β-d-Fucp3NAc-(1→ D
4.58103.6
3.8175.6
4.1555.8
3.6671.8
3.8773.1
1.2416.6
β-d-Glcp-(1→ E
4.57103.6
3.3074.6
3.4776.9
3.3771.1
3.4177.4
3.72, 3.9362.4
1H NMR chemical shifts are italicized. Chemical shifts for the N-acetyl groups are δH 1.99–2.08, δC 23.2–23.9 (Me), and 174.6–175.7 (CO).
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FIG 7