Noel W. Dunn

The effect of nisin concentration and nutrient depletion on nisin production of Lactococcus lactis.

Abstract The kinetics of nisin production was studied in batch cultures using a construct of Lactococcuslactis subsp. lactis C2SmPrt−, containing a transposon (TnNip) that encodes nisin production. The introduction of TnNip into C2SmPrt−significantly lowered the specific growth rate and the maximum A620 reached was reduced from 15.2 to 11.0. The effect of nisin concentration and nutrient depletion on nisin production of the construct, C2SmPrt−(TnNip), was examined. Nisin production was found to be inhibited by high concentrations of nisin, when grown in excess nutrient, even though growth of the culture continued because nutrient limitation was not operating. However, in low nutrient concentrations nisin production was limited by nutrient depletion. The specific growth rate of C2SmPrt−(TnNip) was altered, by using different nutrient concentrations and different sugars, in order to examine the relationship between nisin production and growth. Nisin production was shown to be growth-associated for most of growth, but near the end of growth, when the specific growth rate was 0.05 h−1 or less, the production ceased.

Assessment of Stress Response of the Probiotic Lactobacillus acidophilus

Different aspects of stress response of Lactobacillus acidophilus were investigated. First, the sublethal and lethal levels of bile, heat, and NaCl stresses were determined. They were 0.05% and 0.5% (bile), 53°C and 60°C (heat), and 2% and 18% (NaCl), respectively. To evaluate the effect of each stress at log phase, log-phase cultures were challenged directly with the lethal level of each stress (control) and were compared to log-phase cultures that were pre-exposed to the sublethal level prior to the exposure at the lethal level (test). Some, if not most, of the cells were killed in the control cultures against each of the three stresses. However, in the test cultures, the number of cells that had survived increased significantly. It appears that L. acidophilus is capable of displaying adaptive response to stress. The adaptive response to one stress was also shown to provide cross-protection against different stresses tested. The effect of each stress on stationary-phase cultures was also investigated. In contrast to log-phase culture, stationary-phase culture was inherently resistant to stress.

Identification of a Cold Shock Gene in Lactic Acid Bacteria and the Effect of Cold Shock on Cryotolerance

Abstract. When Lactic Acid Bacterial cultures were frozen at −20°C for 24 h, the cell viability decreased drastically, but when they were cold shocked at 10°C for 2 h prior to freezing, viability improved significantly for the Lactococcus lactis subsp. lactis strains (25–37%) and Pediococcus pentosaceus PO2 (18%), but not for the Lactococcus lactis subsp. cremoris strains tested or for one strain of Lactobacillus helveticus LB1 and Streptococcus thermophilus TS2. When the period for cold shock was extended to 5 h, the viability increased even further for those strains that displayed cold shock cryotolerance. Use of degenerate PCR primers based on the major cold shock protein (csp) of both Escherichia coli and Bacillus subtilis resulted in PCR products from all strains tested. The PCR product from Lactococcus lactis ssp. lactis M474 was cloned and sequenced, and the deduced amino acid sequence displayed a high sequence similarity to other csps. Use of PCR primers based on the M474 sequence resulted in PCR products being produced only from the lactococcal strains studied and not from the Lactobacillus helveticus, Streptococcus thermophilus, or Pediococcus pentosaceus strains tested.

Improving nisin production by increasing nisin immunity/resistance genes in the producer organism Lactococcus lactis

Abstract The effect on nisin production of increasing nisin immunity/resistance genes in Lactococcus lactis subsp. lactis MG1363 was investigated. The 60-kb nisin immunity/resistance plasmid pND300, which was isolated from a non-nisin-producing strain, encodes five genes involved in nisin immunity/resistance, which are very similar to those of the immunity/resistance system encoded by the nisin-production transposon. The introduction of pND300 into MG1363(TnNip) resulted in the construct being able to produce significantly more nisin than the parent MG1363(TnNip). The introduction of pND314, which contains the nisin immunity/resistance genes subcloned into pSA3, into MG1363(TnNip) allowed the strain to grow more rapidly than the parent MG1363(TnNip) with a concomitant increase in the rate of nisin production. This work illustrates that introduction of pND300 and a derivative containing the nisin immunity/resistance system of pND300 into MG1363 (TnNip) can result in significant alterations to the kinetics of nisin production. These observations indicate approaches that may be used successfully to improve the economics of nisin production.

Cloning vectors for lactococci based on a plasmid encoding resistance to cadmium

Abstract. An 8.8-kb plasmid (pND302) was identified in Lactococcus lactis spp lactis M71 which encodes cadmium resistance (CdR). Most of the commercial lactococcal strains tested were sensitive to cadmium. Therefore, CdR should provide a useful selectable marker for constructing cloning vectors in lactococci. pND302 was mapped with a number of restriction enzymes and found to contain a unique EcoRI site suitable for cloning. Two E. coli/L. lactis shuttle cloning vectors, pND304 and pND624, were constructed by subcloning of the E. coli plasmids pBR322 and pGEM-7Zf(+) containing a 1.6-kb gene encoding nisin resistance (NisR) of lactococcal origin into the EcoRI site of pND302, separately. The E. coli DNA component of pND624 was removed and the resulting plasmid, pND625, consisted of only lactococcal DNA, expressing NisR and CdR, with two synthetic polylinkers that contain multiple restriction sites for versatile cloning. Both pND302 and pND625 can be transformed by electroporation into L. lactis LMO230 at 103/μg DNA and maintained stably in LMO230. The results indicated that pND302 and pND625 are potential food-grade cloning vectors for lactococci.

Crystalline cellulose degradation by a strain of Cellulomonas and its mutant derivatives

SummaryMutant derivatives of a strain of Cellulomonas (CS1-1) were shown to be able to degrade crystalline cellulose (cotton wool) more efficiently compared to the parent strain. These mutants were also more effective in the accumulation of reducing sugar in the growth medium under certain environmental conditions. Differences between the mutant derivatives and CS1-1 were reflected by assay of the amount and distribution of various cellulolytic enzymes.

Survival Response and Rearrangement of Plasmid DNA of Lactococcus lactis during Long-Term Starvation

ABSTRACT The survival response of Lactococcus lactis during long-term starvation was investigated. The cells were cultured with different levels of glucose (the sole energy source) and either were kept in the resultant spent medium or transferred to fresh medium (without glucose) for up to 2 years. The survival of the cells during starvation was not dependent on the nature of transition phase, as expected, but on the nature of medium in which the cells were kept. The proliferation of cells, despite the apparent lack of glucose, could have been due to some cells being able to utilize the small amounts of peptides still present in the spent medium or to use energy sources provided by the breakup of dead cells. The 1- and 2-year-old cultures contained cells with vastly changed morphotypes. When these isolates were examined, it was revealed that the original plasmids present in the parent were rearranged in a certain way, and an entirely new plasmid was generated. Changes were also evident in the chromosomal DNA and in gene expression. Furthermore, all of the isolates exhibited a growth advantage relative to the parent cells when grown in energy-limiting media. When they were tested against different types of stresses, they exhibited a higher resistance against the bile salt and hydrogen peroxide stresses compared to the parent. Because of the similar changes observed in the 2-year-old isolates, a similar survival strategy may be operational in those cells that survive for that length of time.

Expression of cloned Xanthomonasd-xylose catabolic genes in Zymomonas mobilis

Abstract A Xanthomonas XA1-1 HindIII DNA fragment which encodes enzymes involved in d -xylose catabolism was subcloned from pND70 into the HindIII site of pRK404 to give the plasmid pND90. pND90 was mobilized into Zymomonas mobilis ZM6100 using the mobilizing plasmid pRK2013. Expression of the d -xylose catabolic genes — d -xylose isomerase, d -xylose permease and xylulokinase — was demonstrated in the ZM6100 transconjugants although no new plasmids were visible in the transconjugants. A self-transmissible plasmid (pND91), which was larger than pND90 was conjugated from the ZM6100 transconjugants to Escherichia coli HB101. Restriction analysis and hybridization of pND91 indicated that the plasmid had arisen by recombination between pND90 and pRK2013 and that the XA1-1 HindIII DNA fragment encoding d -xylose catabolic enzymes was retained in pND91.

Isolation, cloning and characterisation of the abiI gene from Lactococcus lactis subsp. lactis M138 encoding abortive phage infection

Plasmid pND852 (56 kb) encodes nisin resistance and was isolated from Lactococcus lactis ssp lactis (L. lactis) M138 by conjugation to L. lactis LM0230. It conferred strong resistance to the isometric-headed phage phi 712 and partial resistance to the prolate-headed phage phi c2. A 2.6 kb HpaII fragment encoding phage resistance was cloned into the streptococcal/Bacillus hybrid vector pGB301 to generate pND817. The mechanism of phage resistance encoded by pND817 involved abortive infection and this was illustrated by a reduction in burst size from 166 to 6 at 30 degrees C and from 160 to 90 at 37 degrees C. Partial resistance was therefore retained at 37 degrees C. DNA sequencing revealed that the abortive infection was encoded by a single open reading frame (ORF), designated abiI, encoding a 332 amino acid protein. Neither abiI nor the predicted product showed significant homology to any existing sequence in the GenBank database. Frame shift mutation at the unique EcoRI site within the ORF resulted in loss of the Abi+ phenotype, confirming that the ORF is responsible for the encoded phage resistance.

Development of food-grade cloning and expression vectors for Lactococcus lactis

Aims:  To develop food‐grade cloning and expression vectors for use in genetic modification of Lactococcus lactis.