Lactoferrin-binding proteins of Tritrichomonas foetus.

Tritrichomonas foetus is a common, sexually transmitted, protozoan parasite of cattle. It has an essential requirement for iron, which it obtains from host lactoferrin. However, specific lactoferrin-binding protein receptors have not yet been identified in T. foetus. To differentiate specific and nonspecific binding of lactoferrin, lactoferrin affinity chromatography and Western blotting was used to identify metabolically or surface-labeled T. foetus lactoferrin-binding proteins. Bovine lactoferrin was shown to bind more efficiently than human lactoferrin, and each of these bound much better than bovine transferrin. This is relevant because T. foetus is both species-specific and only infects the mucosal surface of the reproductive tract, which has little transferrin. Whereas the majority of lactoferrin binding was specific, competitive inhibition studies showed that nonspecific, charge-related binding of lactoferrin to T. foetus may also be involved. In the presence of bovine cervical mucus, binding of lactoferrin to T. foetus was diminished, suggesting that mucus has an effect on lactoferrin binding. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of surface biotinylated proteins affinity-purified on lactoferrin-Sepharose showed biotinylated bands at Mr values of 22, 49, 55, 72, and 155 kDa. Because lactoferrin-binding proteins may be susceptible to digestion by T. foetus extracellular cysteine proteinases, it is suspected that the 155-kDa protein is the specific lactoferrin-binding protein and that the lower-Mr lactoferrin-binding molecules may be fragmentation products that contain the lactoferrin-binding site; however, other interpretations are clearly feasible. It is possible that there may be multiple proteins or multimers of the same protein. In summary, the data showed that binding of lactoferrin to T. foetus may be regulated by an interplay of specific receptor interactions as well as by hydrophobic and charge-related interactions.     

Growth promotion and cell binding ability of bovine lactoferrin to Bifidobacterium longum

Lactoferrin, a major whey protein of human milk, is considered as growth promoter for bifidobacteria, the predominant microorganisms of human intestine. In the present study, in vitro growth promotion and cell binding ability of bovine lactoferrin to several strains of Bifidobacterium longum have been demonstrated. A dose-dependent as well as strain-dependent growth promotion effect by lactoferrin was observed. Cell binding ability of lactoferrin was inspected under an inverted confocal laser scanning microscope by incubation bacterial cells with biotinylated bovine lactoferrin and FITC-conjugated avidin. Fluorescence staining showed bovine lactoferrin binding to all tested strains. A lactoferrin-binding protein with a molecular weight of approximately 67 kDa was also detected in the extracted membrane and cytosolic fraction of each B. longum strain by far-Western blot technique using biotinylated lactoferrin and horseradish peroxidase-conjugated streptavidin. Based on these results, we suggest that existence of lactoferrin-binding protein could be a common characteristic in bifidobacteria. It can also be hypothesized that lactoferrin-binding protein in bifidobacteria is not only involved in growth stimulation mechanism but also could play different roles.     

Characterization of the human transferrin and lactoferrin receptors in Haemophilus influenzae

The expression of human transferrin and lactoferrin binding activity in Haemophilus influenzae, detected by a binding assay using human transferrin or lactoferrin conjugated to peroxidase, was regulated by the level of available iron in the medium. Transferrin binding activity was present in all H. influenzae isolates tested but not detected in other Haemophilus species or in species of Pasteurella or Actinobacillus. Lactoferrin binding activity was only detected in 1/15 H. influenzae isolates tested. The transferrin and lactoferrin receptors were shown to be specific for the respective human proteins by means of a competition binding assay. Competition binding assays also showed that iron-loaded transferrin was more effective at blocking the transferrin receptor than apotransferrin, but no differences in receptor blocking were observed between iron-loaded lactoferrin and apolactoferrin.     

The lipopolysaccharide (R type) as a common antigen of Neisseria gonorrhoeae. II. Use of hen antiserum to gonococcal lipopolysaccharide in a rapid slide test for the identification of N. gonorrhoeae from primary isolates and secondary cultures.

An antiserum has been prepared in hens to R-type gonococcal lipopolysaccharide (LPS) and used in a simple slide-agglutination test for the identification of Neisseria gonorrhoeae. Anti-LPS serum agglutinated gonococcal cells representative of the four colony types of N. gonorrhoeae. Absorption of the antiserum with LPS removed the agglutinating activity. Secondary cultures (1120) were tested without observation of the colony type and all were agglutinated. No agglutination occurred with strains of Neisseria meningitidis, Neisseria lactamica, non-pathogenic Neisseria. Pseudomonas aeruginosa, Branhamella catarrhalis, or with species of lactobacilli and Acinetobacter. Cross-reactivity of the antiserum occurred with some streptococci. The anti-LPS serum was used to identify N. gonorrhoeae in primary isolates from the cervix, urethra, and pharynx. Of 251 gonococcal isolates tested, 249 were agglutinated by the antiserum, while all of the corresponding second cultures were agglutinated. The antiserum did not agglutinate N. meningitidis found in primary isolates from pharyngeal specimens. Anti-LPS hen serum should be useful for the rapid identification of N. gonorrhoeae in primary isolates or secondary cultures.     

Lactoferrin binding molecules in human seminal plasma

During ejaculation, the iron binding protein lactoferrin binds to sperm and forms a major component of sperm-coating antigens. Physicochemical properties of lactoferrin in seminal plasma (SP) and on sperm differ from those of purified lactoferrin. These differences have been attributed to the binding of unknown seminal macromolecules to lactoferrin. We have studied lactoferrin binding molecules in SP. The SP samples were coated onto microtiter plates and tested for binding of biotinylated lactoferrin. SP was found to specifically bind biotinylated lactoferrin. This binding was competitively inhibited by coincubation with unlabeled lactoferrin but was not affected by control incubations done with human IgG or transferrin. Lactoferrin binding molecules in SP were biochemically characterized by using SDS-PAGE and ligand blotting. Biotinylated lactoferrin bound to SP molecules of approximately 120, 60 and 30 kDa. No binding was observed with biotinylated transferrin. The presence of molecules that associate with lactoferrin in SP was further studied by using crossed immunoelectrophoresis. Lactoferrin in SP immunoprecipitated as two peaks, one of which corresponded to purified lactoferrin. These results suggest that some lactoferrin molecules in SP are free and that others are associated with lactoferrin binding molecules. Binding of lactoferrin to lactoferrin binding molecules appears to change its physicochemical properties and thus could influence its biologic activity and its affinity to sperm.     

Examination of bovine lactoferrin binding to bifidobacteria

In the present study, lactoferrin binding to bifidobacteria and detection of lactoferrin-binding protein in membrane fractions of several bifidobacteria have been demonstrated. This is the first report showing the binding of bovine lactoferrin to four Bifidobacterium spp. (B. infantis, B. breve, B. bifidum, B. longum) incubated with biotinylated lactoferrin and fluorescein conjugated-avidin and observed under an inverted confocal laser scanning microscope. Fluorescence staining showed lactoferrin binding at the pole of the bacterial cells. A lactoferrin-binding protein with a molecular weight of approximately 67 kDa was also detected in the membrane fraction of Bifidobacterium spp. by far western blotting technique using biotinylated lactoferrin and horseradish peroxidase-conjugated streptavidin. Based on the results of this and previously reported studies, we suggest that binding of lactoferrin to Bifidobacterium longum is strain-dependent.     

Molecular characterization of LbpB, the second lactoferrin-binding protein of Neisseria meningitidis

The lbpA gene of Neisseria meningitidis encodes an outer membrane lactoferrin-binding protein and shows homology to the transferrin-binding protein, TbpA. Previously, we have detected part of an open reading frame upstream of lbpA . The putative product of this open reading frame, tentatively designated lbpB showed homology to the transferrin-binding protein TbpB, suggesting that the lactoferrrin receptor, like the transferrin receptor, consists of two proteins. The complete nucleotide sequence of lbpB was determined. The gene encodes a 77.5 kDa protein, probably a lipoprotein, with homology, 33% identity to the TbpB of N . meningitidis . A unique feature of LbpB is the presence of two stretches of negatively charged residues, which might be involved in lactoferrin binding. Antisera were raised against synthetic peptides corresponding to the C-terminal part of the putative protein and used to demonstrate that the gene is indeed expressed. Consistent with the presence of a putative Fur binding site upstream of the lbpB gene, expression of both LbpA and LbpB was proved to be iron regulated in Western blot experiments. The LbpB protein appeared to be less stable than TbpB in SDS-containing sample buffer. Isogenic mutants lacking either LbpA or LbpB exhibited a reduced ability to bind lactoferrin. In contrast to the lbpB mutant, the lbpA mutant was completely unable to use lactoferrin as a sole source of iron.     

Genetic relationships among Neisseria species assessed by comparative enzyme electrophoresis

The electrophoretic mobilities of 12 enzymes from 19 Neisseria species (including 6 strains of N. perflava), Gemella haemolysans, Escherichia coli and Branhamella catarrhalis were characterized by polyacrylamide slab gel electrophoresis. All strains and species tested exhibited qualitatively different zymogram patterns. Species and strain relationships were quantified by pairwise comparisons of all 12 enzyme systems to obtain similarity indices; these data were subjected to numerical clustering methods to obtain groups and a phenogram. The electrophoretic classification compared favourably with those obtained by other criteria. In addition, the quantitative clustering data indicated that N. ovis and N. caviae are sufficiently different from the other Neisseria species to warrant their separation into a distinct group. These two species also lacked the characteristic NADPH-diaphorase zymogram pattern found in all the other Neisseria species. Intra-species similarity indices were generally greater than the inter-species index values. However, certain species such as N. meningitidis and N. gonorrhoeae had similarity index values in the range of inter-strain index values.     

A note on hydrolysis of tributyrin by Branhamella and Neisseria

Sixty-three strains of Branhamella and Neisseria were tested by two methods for their ability to hydrolyse glycerol tributyrate. After the conventional plate test, gas liquid chromatographical (GLC) analysis of the agar medium was carried out to detect the hydrolysis product, butyric acid, and other volatile fatty acids. All strains of Branhamella catarrhalis, Neisseria caviae, N. cuniculi and N. ovis but no other Neisseria spp. gave positive results with the conventional test. With GLC, however, most strains of Branhamella and Neisseria were shown to liberate butyric acid. In addition, some strains liberated acetic and isovaleric acids. Greater amounts of butyric acid were produced by clinical strains, in particular B. catarrhalis , compared with reference strains. It was concluded that the conventional plate test for tributyrin hydrolysis differentiates B. catarrhalis, N. caviae, N. cuniculi and N. ovis from other Neisseria.     

Bacterial lactoferrin receptors: insights from characterizing the Moraxella bovis receptors.

Moraxella bovis is the causative agent of infectious conjunctivitis in cattle. Moraxella bovis isolates were shown to specifically bind bovine lactoferrin (bLf) and bovine transferrin (bTf) and to use these proteins as a source of iron to support the growth of iron-limited cells. Affinity isolation experiments with immobilized bTf yielded two proteins readily resolved by SDS-PAGE analysis, whereas only a single band of approximately 100 kDa was detected when immobilized bLf was used as the affinity ligand. Using a novel cloning strategy, regions containing the genes encoding the lactoferrin (Lf) and transferrin (Tf) receptor proteins were isolated and sequenced, demonstrating that they both consisted of two genes, with the tbpB or lbpB gene preceding the tbpA or lbpA gene. The cloned lbp genes were used to generate isogenic mutants deficient in lactoferrin binding protein A and (or) B, and the resulting strains were tested in growth and binding assays. The isogenic mutants were deficient in their use of bLf for growth and had substantially diminished bLf binding capability. The predicted amino acid sequence from the segment encoding Lf binding protein B revealed an internal amino acid homology suggesting it is a bi-lobed protein, with a C-lobe enriched in acidic amino acids, but without the evident clustering observed in Lf-binding proteins from other species.     

A note on hydrolysis of tributyrin by Branhamella and Neisseria

Sixty-three strains of Branhamella and Neisseria were tested by two methods for their ability to hydrolyse glycerol tributyrate. After the conventional plate test, gas liquid chromatographical (GLC) analysis of the agar medium was carried out to detect the hydrolysis product, butyric acid, and other volatile fatty acids. All strains of Branhamella catarrhalis, Neisseria caviae, N. cuniculi and N. ovis but no other Neisseria spp. gave positive results with the conventional test. With GLC, however, most strains of Branhamella and Neisseria were shown to liberate butyric acid. In addition, some strains liberated acetic and isovaleric acids. Greater amounts of butyric acid were produced by clinical strains, in particular B. catarrhalis, compared with reference strains. It was concluded that the conventional plate test for tributyrin hydrolysis differentiates B. catarrhalis, N. caviae, N. cuniculi and N. ovis from other Neisseria.     

Growth-promoting effects of lactoferrin on L. acidophilus and Bifidobacterium spp.

We investigated the effects of lactoferrin on the growth of L. acidophilus CH-2, Bifidobacterium breve ATCC 15700, B. longum ATCC 15707, B. infantis ATCC 15697, and B. bifidum ATCC 15696. The growth of L. acidophilus was stimulated by bovine holo-lactoferrin but not by apo-lactoferrin. With bifidobacteria, bovine lactoferrin stimulated growth of three strains: B. breve, B. infantis and B. bifidum under certain conditions. Both apoprotein and holoprotein had similar effects. However, B. longum growth was not affected by lactoferrin. Thus, the mechanism of stimulating growth of bifidobacteria may be different from that of L. acidophilus. By far-western blotting using biotinylated lactoferrin and horseradish peroxidase-conjugated streptavidin, lactoferrin-binding proteins were detected in the membrane protein fraction of L. acidophilus, B. bifidum, B. infantis and B. breve. The molecular weights of lactoferrin-binding proteins of L. acidophilus were estimated from SDS-polyacrylamide gel electrophoresis to be 27, 41 and 67 kDa, and those of the three bifidobacterial strains were estimated to be 67-69 kDa. However, no such lactoferrin-binding components were detected in the membrane fraction of B. longum. It is interesting that the appearance of lactoferrin-binding proteins in the membrane fraction of these species corresponds to their growth stimulation by lactoferrin.     

A note on susceptibility of Branhamella catarrhalis to heavy metals

The susceptibility of 56 strains of Branhamella catarrhalis and ten Neisseria spp. to arsenate, silver, nickel, mercury, lead, cadmium, chromium, manganese, iron, cobalt and molybdenum was tested with an agar dilution technique. All but two strains of B. catarrhalis were resistant to multiple metal ions. There were not sufficient differences in susceptibility, however, to allow the development of a typing scheme based on resistograms. Heavy metal resistance in Branhamella was unrelated to beta-lactamase production. Neisseria spp. were more susceptible to metal ions than B. catarrhalis and this may form the basis of a simple diagnostic test.     

The N-linked oligosaccharides of human lactoferrin are not required for binding to bacterial lactoferrin receptors.

The oligosaccharides of human lactoferrin were enzymatically removed with glycopeptidase F, resulting in a preparation containing partial and fully deglycosylated human lactoferrin. The derivatives were separated by Concanavalin A affinity chromatography and compared with native human lactoferrin with respect to their ability to bind to bacterial receptors. Competitive binding experiments demonstrated that the lactoferrin derivatives were equally capable as native lactoferrin in binding to receptors of Neisseria meningitidis, Neisseria gonorrhoeae, and Moraxella catarrhalis. This result indicates that the oligosaccharides on human lactoferrin are not essential for binding to the bacterial receptors.     

Comparison of the cell envelope proteins of Micrococcus cryophilus with those of Neisseria dnd Branhamella species.

In an attempt to elucidate the relation between Micrococcus cryophilus, Neisseria caviae, Neisseria ovis, and Branhamella catarrhalis, fractions derived from outer membranes of a strain of each organism were examined for protein composition by SDS - polyacrylamide gel electrophoresis. Micrococcus cryophilus outer membrane protein showed extensive similarities to that of N. ovis and contained a heat-modifiable protein which behaved almost identically with the corresponding bands previously shown to exist in N. caviae and N. ovis. Branhamella catarrhalis protein was distinctly different from those of M. cryophilus and the two 'false neisserias' N. caviae and N. ovis.     

Examination of bovine lactoferrin binding to bifidobacteria

In the present study, lactoferrin binding to bifidobacteria and detection of lactoferrin-binding protein in membrane fractions of several bifidobacteria have been demonstrated. This is the first report showing the binding of bovine lactoferrin to four Bifidobacterium spp. (B. infantis, B. breve, B. bifidum, and B. longum) incubated with biotinylated lactoferrin and fluorescein-conjugated avidin and observed under an inverted confocal laser scanning microscope. Fluorescence staining showed lactoferrin binding at the pole of the bacterial cells. A lactoferrin-binding protein with a molecular weight of approximately 67 kDa was also detected in the membrane fraction of Bifidobacterium spp. by far-western blotting technique using biotinylated lactoferrin and horseradish peroxidase-conjugated streptavidin. Based on the results of this and previously reported studies, we suggest that binding of lactoferrin to Bifidobacterium longum is strain dependent. Published in Russian Prikladnaya Biokhimiya i Mikrobiologiya, 2008, Vol. 44, No. 5, pp. 529–532.     

Identification of oral Neisseria species of animals

Ninety-seven strains of presumptive Neisseria spp. obtained from the dental plaque of a wide variety of animals and 21 strains from culture collections were compared by physiological tests, enzyme electrophoresis and isoelectric focusing of proteins. Three physiological groups based on the fermentation of maltose and production of extracellular polysaccharide were established. The ability of strains within these groups to reduce nitrate and nitrite differed. The electrophoretic mobility of dehydrogenases and isoelectric focusing patterns of proteins were not, however, characteristic of species or physiological groups. It is difficult, therefore, to identify new isolates of Neisseria because the criteria for describing species overlap. A rapid spot test was devised to distinguish Branhamella catarrhalis from other Neisseria by the absence of glucose-6-phosphate dehydrogenase.     

A note on susceptibility of Branhamella catarrhalis to heavy metals

The susceptibility of 56 strains of Branhamella catarrhalis and ten Neisseria spp. to arsenate, silver, nickel, mercury, lead, cadmium, chromium, manganese, iron, cobalt and molybdenum was tested with an agar dilution technique. All but two strains of B. catarrhalis were resistant to multiple metal ions. There were not sufficient differences in susceptibility, however, to allow the development of a typing scheme based on resistograms. Heavy metal resistance in Branhamella was unrelated to beta-lactamase production. Neisseria spp. were more susceptible to metal ions than B. catarrhalis and this may form the basis of a simple diagnostic test.     

Identification of the iroA gene product of Neisseria meningitidis as a lactoferrin receptor.

The iroA gene product is an iron limitation-inducible outer membrane protein of Neisseria meningitidis. A spontaneous mutant lacking the gene was unable to bind lactoferrin. Furthermore, Escherichia coli strains expressing the IroA protein were capable of binding lactoferrin. Apparently, the IroA protein functions as a lactoferrin receptor.