Concomitant conjugal transfer of reduced-bacteriophage-sensitivity mechanisms with lactose- and sucrose-fermenting ability in lactic streptococci

An Amazing Journey

This article describes my early life and the chance events leading to my becoming a microbiologist and then my embarking on a career developing the plasmid biology and genetics of lactococci used in milk fermentations.

Detection of bacteriophage-infected cells of Lactococcus lactis by using flow cytometry

Bacteriophage infection in dairy fermentation constitutes a serious problem worldwide. We have studied bacteriophage infection in Lactococcus lactis by using the flow cytometer. The first effect of the infection of the bacterium is a change from cells in chains toward single cells. We interpret this change as a consequence of a cease in cell growth, while the ongoing cell divisions leave the cells as single cells. Late in the infection cycle, cells with low-density cell walls appear, and these cells can be detected on cytograms of light scatter versus, for instance, fluorescence of stained DNA. We describe a new method for detection of phage infection in Lactococcus lactis dairy cultures. The method is based on flow cytometric detection of cells with low-density cell walls. The method allows fast and early detection of phage-infected bacteria, independently of which phage has infected the culture. The method can be performed in real time and therefore increases the chance of successful intervention in the fermentation process.

Novel sucrose transposons from plant strains of Lactococcus lactis

Lactococcus lactis strains isolated from vegetable products transferred the ability to ferment sucrose in conjugation experiments with the recipient strain L. lactis MG1614. Nisin production and sucrose fermentation were transferred together from two strains, but transfer also occurred from several other strains which did not produce nisin. Pulsed-field gel electrophoresis analysis showed that all transconjugants had acquired large chromosomal insertions at two main sites. Nisin sucrose transconjugants had gained inserts of 70 kb, while those that fermented sucrose without nisin production contained inserts of between 50 and 110 kb. Transconjugants from one donor had acquired a separate insertion of 55 kb which correlated with enhanced bacteriophage resistance, but contained neither nisin nor sucrose fermentation genes.

Genetic organization and functional analysis of a novel phage abortive infection system, AbiL, from Lactococcus lactis

A plasmid-encoded phage abortive infection mechanism (AbiL) was identified from Lactococcus lactis biovar. diacetylactis LD10-1. AbiL conferred complete resistance to the small isometric-headed phage phi 712 (936 species) and partial resistance to the prolate-headed phage phi c2 (c2 species) when introduced into L. lactis LM0230. However, AbiL was not effective against the small isometric-headed phage ul36 (P335 species). The AbiL determinant was sequenced and it consists of two open reading frames, abiLi and abiLii. Their encoded proteins did not share significant homology with any known proteins in the protein databases. Transcriptional analysis indicated that abiLi and abiLii are organized as a single operon. Deletion within abiLii abolished the phage resistance. The levels of four phi c2-specific transcripts, three within the early transcribed region and one within the late transcribed region, were examined by RT-PCR, no effect of AbiL on synthesis of these transcripts was detected, suggesting that AbiL may act at a point after the transcription of phi c2 in L. lactis.

AbiG, a genotypically novel abortive infection mechanism encoded by plasmid pCI750 of Lactococcus lactis subsp. cremoris UC653

AbiG is an abortive infection (Abi) mechanism encoded by the conjugative plasmid pCI750 originally isolated from Lactococcus lactis subsp. cremoris UC653. Insensitivity conferred by this Abi manifested itself as complete resistance to phi 712 (936 phage species) with only partial resistance to phi c2 (c2 species). The mechanism did not inhibit phage DNA replication. The smallest subclone of pCI750 which expressed the Abi phenotype contained a 3.5-kb insert which encoded two potential open reading frames. abiGi (750 bp) and abiGii (1,194 bp) were separated by 2 bp and appeared to share a single promoter upstream of abiGi. These open reading frames showed no significant homology to sequences of either the DNA or protein databases; however, they did exhibit the typical low G+C content (29 and 27%, respectively) characteristic of lactococcal abi genes. In fact, the G+C content of a 7.0-kb fragment incorporating the abiG locus was 30%, which may suggest horizontal gene transfer from a species of low G+C content. In this context, it is notable that remnants of IS elements were observed throughout this 7.0-kb region.

Bacteriophage resistance in Lactococcus

Lactic acid bacteria are industrial microorganisms used in many food fermentations. Lactococcus species are susceptible to bacteriophage infections that may result in slowed or failed fermentations. A substantial amount of research has focused on characterizing natural mechanisms by which bacterial cells defend themselves against phage. Numerous natural phage defense mechanisms have been identified and studied, and recent efforts have improved phage resistance by using molecular techniques. The study of how phages overcome these resistance mechanisms is also an important objective. New strategies to minimize the presence, virulence, and evolution of phage are being developed and are likely to be applied industrially.

A Strategy for Rotation of Different Bacteriophage Defenses in a Lactococcal Single-Strain Starter Culture System

A new strategy for starter culture rotations was developed for a series of phage-resistant clones genetically derived from a single strain of Lactococcus lactis subsp. lactis. Phage-resistant derivatives carrying different defense systems were constructed via conjugation with various plasmids encoding abortive infection (Abi/Hsp) and/or restriction and modification (R/M) systems of different specificity. The plasmids included pTR2030 (Hsp + R + /M + ), pTN20 (Abi + R + /M + ), pTRK11 (R + /M + ), and pTRK68 (R + /M + ). Selected phage-resistant transconjugants or transformants were evaluated in different rotation sequences through cycles of the Heap-Lawrence starter culture activity test in milk contaminated with phage and whey from the previous cycle. When used in consecutive sequence, derivative strains carrying the R/M systems encoded by pTN20, pTRK11, and pTRK68 retarded phage development when the initial levels of phage contamination were below 10 2 PFU/ml but not when levels were increased to 10 3 PFU/ml. Use of a derivative bearing pTR2030 (Hsp + R + /M + ) at the beginning of the rotation prevented phage development, even when the initial levels of phage contamination were high (10 6 PFU/ml). Alternating the type and specificity of R/M and Abi defenses through the rotation prevented phage proliferation and in some cases eliminated contaminating phages. A model rotation sequence for the phage defense rotation strategy was developed and performed successfully over nine cycles of the Heap-Lawrence starter culture activity test in the presence of high-titer commercial phage composites. This phage defense rotation strategy is designed to protect a highly specialized Lactococcus strain from phage attack during continuous and extended use in the dairy industry.

Transposable elements in Lactococci: a review

Genetic studies have identified the presence of transposable elements within the genus Lactococcus, which includes industrially important microorganisms used in the production of fermented dairy products. Three insertion sequences have been fully characterized in addition to several reports of transpositionlike events. The three insertion sequence elements, ISS1, IS904, and IS981, exhibit the physical and genetic properties characteristic of known insertion sequences. They are closely related to insertion sequences isolated from a wide variety of microorganisms. In lactococci, insertion sequence elements are associated with lactose and sucrose metabolism, proteinase activity, nisin production and immunity, conjugal transfer determinants, and bacteriophage resistance, which are attributes significant for growth in a milk environment. The characteristics, involvement in lactococcal evolution, and recent developments as tools for genetic engineering of the lactococcal elements are discussed.

Conjugal transfer in Lactococcus lactis of a 68-kilobase-pair chromosomal fragment containing the structural gene for the peptide bacteriocin nisin

Nisin-producing transconjugants were generated by mating nisin-producing strains of Lactococcus lactis subsp. lactis with derivatives of L. lactis subsp. lactis LM0230. The sucrose-utilizing ability and reduced bacteriophage sensitivity were also transferred with the nisin-producing character. Pulsed-field gel electrophoretic analysis of genomic DNA from donor, recipient, and nisin-producing transconjugants indicated that 68 kbp of DNA was transferred from the chromosome of the donor into the chromosome of the recipient in the conjugation process. The location of the transferred nisin structural gene spaN in the transconjugant HID500 was not stable, and cultures of strain HID500 were a mixture of different genotypes in which spaN was located at different positions in the chromosome on different SmaI fragments. ApaI, BglI, BssHII, NciI, SalI, and SmaI digests of genomic DNA were used to map the location of spaN in a donor (DL11) and a nisin-producing transconjugant (HID504).

Characterization of the novel nisin-sucrose conjugative transposon Tn5276 and its insertion in Lactococcus lactis

A novel, chromosomally located conjugative transposon in Lactococcus lactis, Tn5276, was identified and characterized. It encodes the production of and immunity to nisin, a lanthionine-containing peptide with antimicrobial activity, and the capacity to utilize sucrose via a phosphotransferase system. Conjugal transfer of Tn5276 was demonstrated from L. lactis NIZO R5 to different L. lactis strains and a recombination-deficient mutant. The integration of Tn5276 into the plasmid-free strain MG1614 was analyzed by using probes based on the gene for the nisin precursor (nisA) and the gene for sucrose-6-phosphate hydrolase (sacA). The transposon inserted at various locations in the MG1614 chromosome and showed a preference for orientation-specific insertion into a single target site (designated site 1). By using restriction mapping in combination with field inversion gel electrophoresis and DNA cloning of various parts of the element including its left and right ends, a physical map of the 70-kb Tn5276 was constructed, and the nisA and sacA genes were located. The nucleotide sequences of Tn5276 junctions in donor strain NIZO R5 and in site 1 of an MG1614-derived transconjugant were determined and compared with that of site 1 in recipient strain MG1614. The results show that the A + T-rich ends of Tn5276 are flanked by a direct hexanucleotide repeat in both the donor and the transconjugant but that the element does not contain a clear inverted repeat.

Phage abortive infection mechanism from Lactococcus lactis subsp. lactis, expression of which is mediated by an Iso-ISS1 element

A 5-kb DNA fragment conferring a phage abortive infection phenotype (Abi+) has been cloned from Lactococcus lactis subsp. lactis IL416. The Abi+ determinant was subcloned on a 2-kb fragment which carried an Iso-ISS1 element and an open reading frame of 753 bp designated ORFX. Deletion within ORFX entailed the loss of the Abi+ phenotype, establishing that ORFX is the structural abi-416 gene. The expression of abi-416 was shown to be mediated by the Iso-ISS1 element, which contains a sequence fitting the consensus sequence for gram-positive promoters.

Physical map of the chromosome of Lactococcus lactis subsp. lactis DL11 and localization of six putative rRNA operons

A physical map of the chromosome of Lactococcus lactis subsp. lactis DL11 was constructed by using the contour-clamped homogeneous electric field mode of pulsed-field gel electrophoresis in one- and two-dimensional separations to analyze restriction digests of high-molecular-weight genomic DNA. The map, which shows all the observed NotI and SmaI sites (six and 21, respectively) and 8 of approximately 30 SalI sites, is circular and yields a total size of 2.58 megabase pairs for the L. lactis subsp. lactis DL11 chromosome. By using rDNA from Mycoplasma capricolum to probe Southern blots of pulsed-and fixed-field digestion patterns, six putative rRNA operons were identified in L. lactis subsp. lactis DL11 and placed on the map of the chromosome. Five of these loci are clustered in a region representing only 20% of the chromosome. The presence of a SmaI site in each of the putative operons allowed the direction of transcription of each operon to be deduced.

Genetic construction of nisin-producing Lactococcus lactis subsp. cremoris and analysis of a rapid method for conjugation

Conjugation was used to construct nisin-producing Lactococcus lactis subsp. cremoris strains. Recipients were obtained by electroporation of L. lactis subsp. cremoris strains with the drug resistance plasmid pGK13 or pGB301. A method, direct-plate conjugation, was developed in which donor and recipient cells were concentrated and then combined directly on selective media. This method facilitated transfer of the nisin-sucrose (Nip+ Suc+) phenotype from the donor strain, L. lactis subsp. lactis 11454, to three L. lactis subsp. cremoris recipient strains. Nip+ Suc+ L. lactis subsp. cremoris transconjugants were obtained at frequencies which ranged from 10(-7) to 10(-8) per donor CFU. DNA-DNA hybridization to transconjugant DNAs, performed with an oligonucleotide probe synthesized to detect the nisin precursor gene, showed that this gene was transferred during conjugation but was not associated with detectable plasmid DNA. Further investigation indicated that L. lactis subsp. cremoris Nip+ Suc+ transconjugants retained the recipient strain phenotype with respect to bacteriophage resistance and acid production in milk. Results suggested that it would be feasible to construct nisin-producing L. lactis subsp. cremoris strains for application as mixed and multiple starter systems. Additionally, the direct-plate conjugation method required less time than filter or milk agar matings and may also be useful for investigations of conjugal mechanisms in these organisms.

Localization of Separate Genetic Loci for Reduced Sensitivity towards Small Isometric-Headed Bacteriophage sk1 and Prolate-Headed Bacteriophage c2 on pGBK17 from Lactococcus lactis subsp. lactis KR2

The mechanism of reduced sensitivity to the small isometric-headed bacteriophage sk1 encoded on a 19-kilobase (kb) Hpa II fragment subcloned from pKR223 of Lactococcus lactis subsp. lactis KR2 was examined. The reduced sensitivity to phage sk1 was due to a modest restriction/modification (R/M) system that was not active against prolate-headed phage c2. The genetic loci for the R/M system against sk1 and the abortive phage infection (Abi) mechanism effective against phage c2 were then localized by restriction mapping, subcloning, and deletion analysis. The restriction gene was localized to a region of a 2.7-kb Eco RV fragment and included an Eco RI site within that fragment. The modification gene was found to be physically separable from the restriction gene and was present on a 1.75-kb Bst EII- Xba I fragment. The genetic locus for the Abi phenotype against phage c2 was localized to a region containing a 1.3-kb Eco RI fragment. Attempts to clone the c2 Abi mechanism independent of the sk1 R/M system were unsuccessful, suggesting that expression of the abi genes required sequences upstream of the modification gene. Some pGBK17 (vector pGB301 plus a 19-kb Hpa II insert fragment) transformants exhibited the R/M system against phage sk1 but lost the Abi mechanism against phage c2. These transformants contained a 1.2- to 1.3-kb insertion in the Abi region. The data identified genetic loci on a cloned 19-kb Hpa II fragment responsible for restriction activity and for modification activity against a small isometric-headed phage and for Abi activity against prolate-headed phage c2. A putative insertion element was also found to inactivate the abi gene(s).

The conjugative plasmid pTR2030 encodes two bacteriophage defense mechanisms in lactococci, restriction modification (R+/M+) and abortive infection (Hsp+)

pTR2030 is a conjugative plasmid which encodes resistance to bacteriophage in lactococci by a mechanism that aborts the phage infection (Hsp+). Subcloning and in vivo deletion events showed that two independent mechanisms of resistance are located on a 13.6-kilobase Bg/II fragment cloned in pSA3; one mechanism is responsible for the abortive infection, and the other incodes a restriction modification system. The introduction of pTR2030 or the recombinant plasmid pTK6 resulted in the loss of a resident restriction modification plasmid in Lactococcus lactis NCK202 which was not previously identified.

DNA-DNA homology among lactose- and sucrose-fermenting transconjugants from Lactococcus lactis strains exhibiting reduced bacteriophage sensitivity

DNA-DNA homology between a reduced bacteriophage sensitivity (Rbs+) probe and DNA from both Rbs+ and Rbs- Lactococcus lactis strains was examined. Homology was detected between the probe and five plasmids (pCI750, pCC34, pEB56, pNP2, and pJS88) isolated from lactose-positive Rbs+ transconjugants and between the probe and genomic DNA of a sucrose-positive Rbs+ transconjugant. Additionally, hybridizations conducted between the probe and plasmids reported to encode abortive bacteriophage infection indicated homology with pTR2030 but not with pBF61 and pGBK17. The results suggest that a common genetic determinant(s) may be present in a variety of lactococcal plasmids coding for Rbs+.

Conjugal transfer of genetic material by Lactococcus lactis subsp. lactis 11007

Conjugal transfer of genetic material by Lactococcus lactis subsp. lactis 11007 was examined. A plasmid of 88 MDa (pJS88) was identified in addition to the previously reported conjugally transferred plasmids of 32 (pKB32) and 4.8 MDa. Proteinase activity, reduced bacteriophage sensitivity, bacteriocin resistance, and conjugal transfer ability were encoded by pJS88. The ability to metabolize lactose (Lac+) was encoded by pKB32, and the 4.8-MDa plasmid was cryptic. When a strain containing both pKB32 and pJS88 was mated with a recipient deficient in host-mediated homologous recombination (Rec-), a plasmid of 40 MDa (pJS40) was observed in approximately 50% of the Lac+ transconjugants. DNA-DNA hybridization results indicated that pJS40 contained homology with both pKB32 and pJS88. These results indicated that pKB32 was conjugally transferred via conduction and suggested that pJS40 is a deletion derivative of a pKB32::pJS88 cointegrate. A Rec- strain containing pKB32 and pJS88 mediated Lac+ conjugal transfer, suggesting that the pKB32::pJS88 cointegrate could form via a rec-independent event. Resolution of the pKB32::pJS88 cointegrate was observed in both Rec- and Rec+ hosts. Cointegrate formation and resolution via rec-independent mechanisms suggest the involvement of a transposable element in the Tn3 family.