Antibacterial activity of seminalplasmin, a basic protein from bovine seminal plasma

Seminalplasmin, a 6,000 dalton antimicrobial protein present in bovine seminal plasma, is shown to inhibit growth and/or RNA synthesis in several bacterial species. In only one strain out of twenty one belonging to fourteen species, did both RNA synthesis and growth appear to be resistant to seminalplasmin. The antibacterial activity of seminalplasmin, in the case of E. coli, was also studied as a function of its concentration and of time; the minimal concentration of the protein required for 100% bactericidal activity was only about twice that required for 100% bacteriostatic activity. The killing of E. coli cells proceeded in two phases, a slow phase and then a rapid one, and required several hours for completion. Several bacterial species tested secreted proteases into the medium that destroyed seminalplasmin.     

Bacteriolytic activity of seminalplasmin

Seminalplasmin, an antimicrobial protein from bovine seminal plasma, lysed both Gram-positive and Gram-negative bacteria but not Candida albicans. The lytic activity was not lysozyme-like and was not affected by inhibitors of RNA or protein synthesis or by azide; it was strongly inhibited by divalent cations like Ca2+, Mn2+ and Mg2+ at millimolar concentrations. Maximum lysis of Escherichia coli was obtained at 37 degrees C; heat treatment of E. coli drastically reduced its susceptibility to lysis by seminalplasmin. E. coli cells in the stationary phase of growth were lysed much less than those in the exponential phase, and those grown in an enriched medium were lysed much more than those grown in a minimal medium. It appears that the lytic activity of seminalplasmin is due to the activation of an autolysin.     

Isolation and characterization of autolysis-defective mutants of Escherichia coli that are resistant to the lytic activity of seminalplasmin.

Two temperature-sensitive autolysis-defective mutants of Escherichia coli were isolated and shown to be resistant to lysis induced by seminalplasmin, an antimicrobial protein from bovine seminal plasma, as well as to lysis induced by ampicillin, D-cycloserine and nocardicin, at 37 or 42 degrees C but not at 30 degrees C. The mutants were, however, sensitive to inhibition of RNA synthesis by seminalplasmin even at the nonpermissive temperature. Temperature-resistant revertants of the mutants were sensitive to lysis induced by the various antibiotics at 37 or 42 degrees C. The mutations in both strains were mapped at 58 min on the E. coli linkage map. The lysis resistance of the mutants was phenotypically suppressed by the addition of NaCl. Partial suppression of the lysis-resistant phenotype was also observed in a relA genetic background.     

Seminalplasmin, an antimicrobial protein from bovine seminal plasma, inhibits peptidoglycan synthesis in Escherichia coli

Seminalplasmin, an antimicrobial protein from bovine seminal plasma, inhibited peptidoglycan synthesis in Escherichia coli in a concentration-dependent manner. The inhibition of peptidoglycan synthesis appears to be a cause rather than a consequence of growth inhibition as it was observed soon after the addition of the antibiotic even in E. coli cells whose growth was totally inhibited by chloramphenicol.     

Binding of seminalplasmin to the plasma and acrosomal membranes of bovine spermatozoa. Fluorescence studies on the changes in the lipid-phase fluidity

The binding of seminalplasmin, a protein secreted by the accessory sex glands of bull, to the plasma and outer acrosomal membrane of bovine spermatozoa was studied using three different fluorescent probes. 8-Anilino-1-naphthalenesulfonate fluorescence, pyrene excimer fluorescence and diphenylhexatriene fluorescence polarisation studies indicate that seminalplasmin binds to the spermatozoal membranes, and leads to an increase in the fluidity of both the plasma and the acrosomal membranes. Calcium was found to have no influence on the interaction of seminalplasmin with the spermatozoal membranes. These results suggest that protein(s) present in the seminal plasma could interact with spermatozoal membranes and increase their fluidity.     

Characterization by cDNA cloning of the mRNA for seminalplasmin, the major basic protein of bull semen

A cDNA library derived from poly(A)+RNA of bull seminal vesicle tissue was screened with synthetic DNA probes specific for seminalplasmin (SAP), the major basic protein of bull semen. From a number of positive clones, pBSV12, containing a 577-bp insert, was identified and sequenced. The derived amino acid sequence comprises the known amino acid sequence of SAP with an amino terminal representing a putative signal sequence; at the carboxyl terminus the sequence contains an additional lysine residue. Present experimental data do not distinguish between two potential SAP precursor molecules, each starting with a methionine residue and differing by 10 amino acid residues in the leader peptide. Comparative Northern analysis reveals a SAP-specific mRNA of 700 bp, which lacks RNA from bovine testis as well as from seminal vesicle tissue of a bull calf; hence, expression of the SAP gene appears to be under androgen and/or developmental control. Southern analysis indicates that one gene appears to specify SAP. SAP-like DNA sequences were detected in ovine and porcine genomic DNA.     

Cloning and expression in E. coli of a synthetic gene for the bacteriocidal protein caltrin/seminalplasmin

A synthetic gene coding for the bacteriocidal protein caltrin/seminalplasmin was constructed and expressed in Escherichia coli as a fusion with beta-galactosidase. The gene was designed with a recognition site for the plasma protease, Factor Xa, coded for immediately prior to the N-terminus of caltrin. The beta-galactosidase-caltrin fusion protein was cleaved with Factor Xa to give caltrin, which was identified by its size on SDS-PAGE, its ability to react with an antiserum raised to the N-terminal nonapeptide of caltrin and its N-terminal amino acid sequence. After partial purification, synthetic caltrin was found to be active in an assay involving inhibition of growth of E.coli.     

Characterization of a new bioactive protein from bovine seminal fluid

A new acidic seminal fluid protein (aSFP) was purified from bovine seminal fluid, using anion exchange chromatography and FPLC on MonoQ. The purified aSFP displays a pI of 4.8 and an apparent molecular weight of 14 kDa. Homogeneity of aSFP was demonstrated by FPLC and SDS-polyacrylamide gel electrophoresis. Monospecific anti-aSFP IgGs were employed to characterize aSFP in bovine seminal plasma and seminal vesicle secretion by immuno blot analysis. Proteinchemical characterization of aSFP included amino acid analysis as well as determination of 23 amino acid residues of the N-terminal sequence of aSFP. According to this sequence, aSFP appears to represent a hitherto unknown protein. aSFP stimulated cell division and progesterone secretion of bovine granulosa cells in vitro in a potent and dose dependent manner. aSFP appears to be a potent growth factor with effects on ovarian granulosa cells.     

Inhibition of DNA polymerization and DNA transcription to RNA by seminal plasma peptides

An oligopeptide fraction purified from the extracellular compartment of bull semen and strongly interacting with DNA was shown to hinder mononucleotide polymerizations to DNA and RNA in vitro. The fraction, collectively called seminal plasma inhibitor, was active in the endogenous DNA and RNA polymerase reactions of the nuclei from rat hepatocytes and in the analogous nucleotide polymerizations catalyzed by purified enzymes of bacterial origin. The type of the induced inhibition was studied using the RNA polymerase from Escherichia coli as a representative nucleotidyl transferase. In the enzymatic polycondensation of mononucleotides, the seminal plasma inhibitor appeared to exert its effect mainly by a competitive inhibition for the utilization of DNA templates without specificity with respect to the source and the base sequence of DNA. Concavities of the plots of V0/Vi versus the amounts of inhibitor in the nucleotide polymerizing reactions and of the Dixon plots in the assays of RNA polymerase from E. coli suggested that the isolated oligopeptide fraction contained more than one active molecular species with differential effects at low and high doses. Preliminary results on the microheterogeneity of the seminal plasma inhibitor supported this contention.     

Interaction of seminalplasmin with chlortetracycline, a fluorescent chelate probe of Ca2+

The interaction of seminalplasmin with chlortetracycline, a fluorescent chelate probe of Ca2+, was studied. The results indicate that seminalplasmin binds to chlortetracycline. The binding is not influenced by salt. Both Ca2+ and seminalplasmin probably bind to the same site on chlortetracycline. Seminalplasmin also reduced the Tb3+-associated fluorescence of bovine spermatozoal plasma membrane. These results are discussed in relation to the inhibitory effect of seminalplasmin on the uptake of Ca2+ in bovine spermatozoa.     

Seminalplasmin, the major basic protein of bull seminal plasma, is a secretory protein of the seminal vesicles.

From the experimental results of three independent methods: (1) indirect immunofluorescence employing monospecific anti-seminalplasmin-IgGs, (2) cell-free translation of poly(A)+ RNA from seminal vesicle and testicular tissue, as well as (3) Northern analysis of poly(A)+ RNA of the latter tissues with a synthetic seminalplasmin-specific antisense DNA probe, it is concluded that the biosynthesis of seminalplasmin occurs in seminal vesicles but not in testis.     

Purification of the gene 0.3 protein of bacteriophage T7, an inhibitor of the DNA restriction system of Escherichia coli

The gene 0.3 protein of bacteriophage T7 prevents the DNA restriction system of EScherichia coli from interfering with T7 infection. A mutant strain of T7 that greatly overproduces the 0.3 protein has been constructed and used for purification of this protein. The 0.3 protein ws found to be extremely acidic and can be separated from virtually all other proteins of the infected cell by chromatography on DEAE-cellulose. Residual contaminating proteins and nucleic acids can be removed by gel filtration, but an even simpler final purification is possible, because under appropriate conditions the 0.3 protein is soluble in high concentrations of ethanol. Thus, a simple, essentially two-step purification can produce about 50 mg of pure 0.3 protein from 30 liters of culture. The purified protein appears to be a dimer of identical subunits. AS expected from its known function during infection, the purified 0.3 protein inhibits the nuclease and ATPase activities of partially purified Eco B, the DNA restriction enzyme of E. coli B, but it does not interfere with several different type II endonucleases tested. The inhibition of Eco B appears to require stoichiometric rather than catalytic amounts of 0.3 protein.     

Seminalplasmin,the major basic protein of bull seminal plasma,is a secretory protein of the seminal vesicles

From the experimental results of three independent methods: (1) indirect immunofluorescence employing monospecific anti-seminalplasmin-IgGs, (2) cell-free translation of poly(A)⁺ RNA from seminal vesicle and testicular tissue, as well as (3) Northern analysis of poly(A)⁺ RNA of the latter tissues with a synthetic seminalplasmin-specific antisense DNA probe, it is concluded that the biosynthesis of seminalplasmin occurs in seminal vesicles but not in testis.     

Induction of autolysis in starved Escherichia coli cells by seminalplasmin, an antimicrobial protein from bovine seminal plasma

Abstract A pair of relA ⁺ and relA E. coli strains, otherwise isogenic, were studied with regard to the susceptibility of starved cells to lysis induced by the natural peptide seminalplasmin. Starved relA cells were more sensitive to seminalplasmin-induced lysis when compared to starved relA ⁺ cells. Nevertheless, pronounced lysis of starved relA ⁺ cells was observed with increase in the concentration of seminalplasmin. In conctrast, ampicillin could not lyse starved relA ⁺ cells even at very high concentrations. Further, seminalplasmin could cause loss of viability and degradation of peptidoglycan in starved relA ⁺ cells. These observations suggest that, unlike many other antibiotics, seminalplasmin can induce autolysis under the conditions of a stringent response.