Active-Site His85 of Pasteurella dagmatis Sialyltransferase Facilitates Productive Sialyl Transfer and So Prevents Futile Hydrolysis of CMP-Neu5Ac.

Sialyltransferases of the GT-80 glycosyltransferase family are considered multifunctional because of the array of activities detected. They exhibit glycosyl transfer, trans-sialylation, and hydrolysis activities. How these enzymes utilize their active-site residues in balancing the different enzymatic activities is not well understood. In this study of Pasteurella dagmatis α2,3sialyltransferase, we show that the conserved His85 controls efficiency and selectivity of the sialyl transfer. A His85→Asn variant was 200 times less efficient than wild-type for sialylation of lactose, and exhibited relaxed site selectivity to form not only the α2,3- but also the α2,6-sialylated product (21 %). The H85N variant was virtually inactive in trans-sialylation but showed almost the same CMP-Neu5Ac hydrolase activity as wild-type. The competition between sialyl transfer and hydrolysis in the conversion of CMP-Neu5Ac was dependent on the lactose concentration; this was characterized by a kinetic partition ratio of 85 m-1 for the H85N variant, compared to 17 000 m-1 for the wild-type enzyme. His85 promotes the productive sialyl transfer to lactose and so prevents hydrolysis of CMP-Neu5Ac in the reaction.

Characterization of a multifunctional α2,3-sialyltransferase from Pasteurella dagmatis.

A new multifunctional α2,3-sialyltransferase has been discovered in Pasteurella dagmatis. The enzyme, in short PdST, was identified from the P. dagmatis genome by sequence similarity with sialyltransferases of glycosyltransferase family GT-80. In addition to its regioselective sialyltransferase activity (5.9 U/mg; pH 8.0), purified PdST is alternatively active at low pH as α2,3-sialidase (0.5 U/mg; pH 4.5) and α2,3-trans-sialidase (1.0 U/mg; pH 4.5). It also shows cytidine-5'-monophosphate N-acetyl-neuraminic (CMP-Neu5Ac) hydrolase activity (3.7 U/mg; pH 8.0) when no sialyl acceptor substrate is present in the reaction. After sialyltransferase PmST1 from P. multocida, PdST is the second member of family GT-80 to display this remarkable catalytic promiscuity. A unique feature of PdST, however, is a naturally occurring Ser-to-Thr substitution within a highly conserved Y(112)DDGS(116) sequence motif. In PmST1, the equivalent Ser(143) is involved in binding of the CMP-Neu5Ac donor substrate. Reversion of the natural mutation in a T116S-PdST variant resulted in a marked increase in α2,3-trans-sialidase side activity (4.0 U/mg; pH 4.5), whereas the major sialyltransferase activity was lowered (3.8 U/mg; pH 8.0). The Michaelis-Menten constant for CMP-Neu5Ac was decreased 4-fold in T116S mutant when compared with wild-type PdST (KM=1.1 mM), indicating that residue 116 of PdST contributes to a delicate balance between substrate binding and catalytic activity. D-Galactose and various ß-D-galactosides function as sialyl acceptors from CMP-Neu5Ac, whereas other hexoses (e.g. D-glucose) are inactive. Structure comparison was used to rationalize the particular acceptor substrate specificity of PdST in relation to other GT-80 sialyltransferases that show strict α2,3-regioselectivity, but are flexible in using α/ß-galactosides for sialylation.

Sequential two-step multienzyme synthesis of tumor-associated sialyl T-antigens and derivatives.

A series of α2-3-sialylated ß1-3-linked galactosides, including sialyl T-antigens, 3'-sialyl galacto-N-biose, 3'-sialyl lacto-N-biose, and their derivatives containing natural and non-natural sialic acid forms have been synthesized from simple monosaccharides using an efficient sequential two-step multienzyme approach.

Complete switch from α-2,3- to α-2,6-regioselectivity in Pasteurella dagmatis ß-D-galactoside sialyltransferase by active-site redesign.

Structure-guided active-site redesign of a family GT-80 ß-D-galactoside sialyltransferase (from Pasteurella dagmatis) to change enzyme regioselectivity from α-2,3 in the wild type to α-2,6 in a P7H-M117A double mutant is reported. Biochemical data for sialylation of lactose together with protein crystal structures demonstrate highly precise enzyme engineering.

Occurrence of [copper, zinc]-cofactored superoxide dismutase in Pasteurella haemolytica and its serotype distribution.

Fifty-two ovine strains of Pasteurella haemolytica and P. trehalosi representing serotypes 1-16 were examined for the presence of [copper, zinc]superoxide dismutase DNA sequences. This was done using a combination of polymerase chain reaction with degenerate primers based on the sequence of the [Cu,Zn]superoxide dismutase gene (sodC) in related species and Southern hybridization using a fragment of sodC from P. haemolytica A2 serotype as a probe. Both detection methods identified a fragment of the sodC gene in 9/9 strains of P. haemolytica serotype 2 examined and in 5/8 strains of serotype 7. No evidence of this gene was found in any other serotype of P. haemolytica or in any P. trehalosi serotype. Comparison of DNA sequence showed near identity between sodC from the A2 and A7 serotypes of P. haemolytica and substantial similarity (70%) to sodC previously sequenced in P. multocida, Haemophilus parainfluenzae and H. influenzae. Analysis by gel electrophoresis of the superoxide dismutase activity present in cell lysates showed that one or more superoxide dismutase is present in all serotypes. However, cyanide-inhibitable activity, corresponding to [Cu,Zn]superoxide dismutase, was detected only in those strains of serotypes A2 and A7 which showed evidence of the sodC gene fragment.

Divergent activity and function of superoxide dismutases in Pasteurella haemolytica serotypes A1 and A2 and Pasteurella trehalosi serotype T10.

Representative strains of Pasteurella haemolytica serotypes A1 and A2 and Pasteurella trehalosi serotype T10 were examined for the presence of superoxide dismutase. Visualisation of superoxide dismutase enzyme activity on polyacrylamide gels, and specific inhibition with potassium cyanide verified a copper/zinc (Cu/Zn) superoxide dismutase only in serotype A2 whereas serotypes A1 and T10 showed other superoxide dismutase activity. Using a simple freeze-thaw method the cellular location of superoxide dismutase enzyme activity was determined in all three serotypes. In serotypes A1 and A2 but not T10 superoxide dismutases were located in the periplasm. The viability of serotypes A2 and T10 cells in the presence of exogenous superoxide was unchanged over a 30 min period, whereas serotype A1 cells declined in viability between 15 and 30 min. Purified immunoglobulin from sheep convalescent serum did not reduce superoxide dismutase activity in the serotypes in an in vitro assay. The presence of this enzyme within the pasteurellae suggests a supportive role in the virulence of this major pathogen of ruminants.

Rapid identification of Haemophilus somnus, Histophilus ovis and Actinobacillus seminis using the API ZYM system.

The API ZYM system, a commercially-available technique that measures bacterial enzyme activity was used to test 43 isolates identified as H. somnus, H. ovis or A. seminis and 19 from related genera. The enzyme patterns resulting from the API ZYM differentiated H. somnus and H. ovis from A. seminis and related genera but not from each other. An identification scheme based on 9 of the enzymes in the API ZYM and a few simple biochemical tests is proposed for the rapid and reliable identification of these bacteria in a diagnostic bacteriology laboratory.

Comparing different isolates of Pasteurella haemolytica from beef calves using their in vitro antimicrobial sensitivity patterns.

In vitro studies, using disc diffusion and agar dilution techniques, were carried out to compare susceptibilities to selected antimicrobial agents of 30 isolates of Pasteurella haemolytica from healthy calves and 30 isolates from calves with transit fever. There was no difference in susceptibility patterns between isolates from healthy calves and isolates from diseased calves or between isolates of serotype A1 and isolates of serotype A2. Penicillin resistance was associated with production of beta-lactamase.

Phenotypic and genetic relationships of so-called Moraxella (Pasteurella) anatipestifer to the Flavobacterium/Cytophaga group.

So-called Moraxella (or Pasteurella) anatipestifer and members of the Flavobacterium/Cytophaga group exhibit remarkable common features: lack of flagellation, low guanine + cytosine content of the chromosomal DNA, production of menaquinones and branched-chain fatty acids, absence of carbohydrate fermentation, and similar patterns of hydrolytic enzymes. Using the renaturation method of DNA:DNA hybridization two urease-negative European isolates and the urease-positive type strain (which was isolated in the United States) of M. P. anatipestifer were shown to have about 85% of their genome DNA base sequences in common; they may represent two subspecies. The type strain of this species was neither measurably related to the type species of the genus Moraxella nor to selected members of the family Pasteurellaceae (Pohl 1981). On the other hand, low but significant degrees of DNA binding between selected strains of so-called M. anatipestifer, Cytophaga marinoflava, Flavobacterium meningosepticum, F. odoratum and F. pectinovorum were observed. On the basis of these findings the transfer of the so-called M. anatipestifer to the Flavobacterium/Cytophaga group (family Cytophagaceae) is proposed. More detailed investigations are required to establish its relationship at the genus level.

Novel protease produced by a Pasteurella trehalosi serotype 10 isolate from a pneumonic bighorn sheep: characteristics and potential relevance to protection.

A strain of Pasteurella trehalosi serotype 10, E(CO)-100, isolated from a bighorn sheep that had succumbed to pneumonic pasteurellosis during an epizootic, was compared to well-characterized strains of P. trehalosi serotype 10 and Mannheimia haemolytica serotype 1. The gene for leukotoxin A (lktA) from E(CO)-100 was sequenced and found to be identical on an amino acid basis to a published sequence for lktA from P. trehalosi serotype 10. However, the toxic activity in culture supernatant measured over time for E(CO)-100 was quite different from reference strains. Typically, the ability of the supernatant to lyse target cells increases over time corresponding to the logarithmic growth of the organism, peaks at mid to late phase, then declines gradually. Supernatant from E(CO)-100 exhibited a sharp decline in toxicity after mid-logarithmic growth to undetectable levels. Investigation of this anomaly using a commercial kit with a porcine gelatin/bovine albumin substrate matrix revealed high protease activity in the supernatant of this strain compared to another P. trehalosi serotype 10 and to a M. haemolytica serotype 1. Protease activity was also visualized using gelatin based zymogram gels. This protease was not substrate specific as it was shown to degrade leukotoxin. Activity was neutralized by bighorn sera in a titratable manner. There was an association between the ability to neutralize protease and low pneumonic lung scores in bighorn sheep experimentally challenged with E(CO)-100 (r=0.5, P=0.1). This previously unidentified protease may be an important protective antigen in vaccines designed to prevent pneumonic pasteurellosis resulting from P. trehalosi in bighorn sheep.

Distribution of indole-producing urease-negative pasteurellas in animals.

Three hundred fifty-six animal isolates of indole-positive urease-negative cultures of Pasteurella, which would formerly have been classified as P. multocida, were examined with respect to their relationship to the recently described P. multocida subspecies (ssp.) multocida, septica, and gallicida and P. canis, P. stomatis/Taxon 16, and Pasteurella sp. B. Two hundred sixty-three (73.9%) of the cultures could be identified with one of these taxa, and 93 isolates (26.1%), representing 17 different biotypes, were unassignable. Pasteurella multocida ssp. multocida was the predominant taxon throughout and in most of the 25 animal species from which isolations were made. In dogs, P. canis was the most frequent. Different degrees of host predilection were observed also in P. multocida ssp. septica for cats, P. canis for sheep, and 2 of the unassignable biotypes for cattle and dogs, respectively. Overall, the respiratory tract was the most frequent source of isolates, but a propensity of P. multocida ssp. septica for localization in the central nervous system of cats was noted.

Evaluation of seven commercial oxidase test products with Pasteurella.

Seven commercial oxidase reagents were tested with 50 isolates each of Pasteurella multocida and P haemolytica. Each group of organisms consisted of a variety of serotypes from many locations and animal sources. Pasteurella multocida and P haemolytica were expected to be 90% oxidase-positive; however, only 2 commercial reagents were positive for greater than 90% of P multocida isolates. These were the Taxo N Dics and the Bacto-Differentiation Discs Oxidase. Only the Taxo N Discs were positive for greater than 90% of P haemolytica isolates. The 5 other commercial reagents demonstrated a variety of results. Pathotec Cytochrome Oxidase Strips were not positive with any of the 100 isolates tested. Correlation was not observed between dimethyl-p-phenylenediamine vs tetramethyl-p-phenylenediamine and the percentage of positive reactions.

Comparison of DNA:DNA homology and enzymatic activity between Pasteurella haemolytica and related species.

A commercially available microbiological identification system and DNA:DNA hybridization were used to determine relationships between and within serovars 1-13 of Pasteurella haemolytica, and between P haemolytica and P multocida and 4 species of Actinobacillus. All serovars of P haemolytica that belonged to biovar A were related with mean DNA homology of 78%, whereas all serovars of P haemolytica that belonged to biovar T were related to each other with mean DNA homology of 90%. The DNA:DNA hybridization between strains of biovars A and T ranged from 3 to 13%, indicating little or no genetic relationship between the 2 biovars of P haemolytica. The DNA homology between all serovars of P haemolytica and other species of non-P haemolytica bacteria tested (P multocida and actinobacilli) was less than 14%, suggestive of essentially no genetic relationship of P haemolytica with the ATCC reference strains of the genus Pasteurella or the genus Actinobacillus. Enzymatic differences were observed between P haemolytica and the other non-P haemolytica bacteria tested; however, the microbiological identification system that uses enzymatic reactions could not distinguish among biovars of P haemolytica. Results of this research support other data that suggest that biovars A and T of P haemolytica should be classified as separate species, but do not support the inclusion of either biovar A or T within the genus Actinobacillus.

Mechanistic study of CMP-Neu5Ac hydrolysis by α2,3-sialyltransferase from Pasteurella dagmatis.

Bacterial sialyltransferases of the glycosyltransferase family GT-80 exhibit pronounced hydrolase activity toward CMP-activated sialyl donor substrates. Using in situ proton NMR, we show that hydrolysis of CMP-Neu5Ac by Pasteurella dagmatis α2,3-sialyltransferase (PdST) occurs with axial-to-equatorial inversion of the configuration at the anomeric center to release the α-Neu5Ac product. We propose a catalytic reaction through a single displacement-like mechanism where water replaces the sugar substrate as a sialyl group acceptor. PdST variants having His(284) in the active site replaced by Asn, Asp or Tyr showed up to 10(4)-fold reduced activity, but catalyzed CMP-Neu5Ac hydrolysis with analogous inverting stereochemistry. The proposed catalytic role of His(284) in the PdST hydrolase mechanism is to facilitate the departure of the CMP leaving group.