Chun-Qiang Liu

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.

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.

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.

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.

Genetic and transcriptional analysis of a novel plasmid-encoded copper resistance operon from Lactococcus lactis

A plasmid-borne copper resistance operon (lco) was identified from Lactococcus lactis subsp. lactis LL58-1. The lco operon consists of three structural genes lcoABC. The predicted products of lcoA and lcoB were homologous to chromosomally encoded prolipoprotein diacylglyceral transferases and two uncharacterized proteins respectively, and the product of lcoC is similar to several multicopper oxidases, which are generally plasmid-encoded. This genetic organization represents a new combination of genes for copper resistance in bacteria. The three genes are co-transcribed from a copper-inducible promoter, which is controlled by lcoRS encoding a response regulator and a kinase sensor. The five genes are flanked by two insertion sequences, almost identical to IS-LL6 from L. lactis. Transposon mutagenesis and subcloning analysis indicated that the three structural genes were all required for copper resistance. Copper assay results showed that the extracellular concentration of copper of L. lactis LM0230 containing the lco operon was significantly higher than that of the host strain when copper was added at concentrations from 2 to 3 mM. The results suggest that the lco operon conferred copper resistance by reducing the intracellular accumulation of copper ions in L. lactis.

A Potential Food-Grade Cloning Vector for Streptococcus thermophilus That Uses Cadmium Resistance as the Selectable Marker

ABSTRACT A potential food-grade cloning vector, pND919, was constructed and transformed into S. thermophilus ST3-1, a plasmid-free strain. The vector contains DNAs from two different food-approved organisms, Streptococcus thermophilus and Lactococcus lactis. The 5.0-kb pND919 is a derivative of the cloning vector pND918 (9.3 kb) and was constructed by deletion of the 4.3-kb region of pND918 which contained DNA from non-food-approved organisms. pND919 carries a heterologous native cadmium resistance selectable marker from L. lactis M71 and expresses the Cdr phenotype in S. thermophilus transformants. With the S. thermophilus replicon derived from the shuttle vector pND913, pND919 is able to replicate in the two S. thermophilus industrial strains tested, ST3-1 and ST4-1. Its relatively high retention rate in S. thermophilus further indicates its usefulness as a potential food-grade cloning vector. To our knowledge, this is the first report of a replicative potential food-grade vector for the industrially important organism S. thermophilus.

A plasmid-encoded two-component regulatory system involved in copper-inducible transcription in Lactococcus lactis

Two regulatory genes (lcoR and lcoS) were identified from a plasmid-borne lactococcal copper resistance determinant and characterized by transcriptional fusion to the promoterless chloramphenicol acetyltransferase gene (cat). RT-PCR analysis indicates that lcoR and lcoS are organized within an operon, controlling the transcription of cat in a copper-inducible manner. The amino acid sequences deduced from lcoR and lcoS show homology to the response and sensor proteins of known two-component regulatory systems. Deletion within either lcoS or both genes inactivated the copper-dependent activity, suggesting the presence of no trans-acting lcoR and lcoS homologs in the lactococcal host chromosome. The transcription start site involved in copper induction was mapped by primer extension.

Plasmid-encoded copper resistance in Lactococcus lactis

A 54-kb plasmid (pND306) from Lactococcus lactis subsp. lactis 1252D encoded resistance to both Cu and Sn . The copper resistance determinant was subcloned on a 12.8-kb PvuII DNA fragment and mapped using a number of restriction endonucleases. Six other copper resistant lactococcal strains were also identified and all contained multiple plasmids. Plasmids in five of these strains showed strong hybridization with a probe made using the 12.8-kb DNA fragment, however no chromosomal homologs were detected. The copper resistance determinant was further isolated as a 10.6-kb SphI fragment and used to construct pND968 that expresses resistance to both copper and nisin.

Simultaneous expression of genes encoding endoglucanase and β-glucosidase in Zymomonas mobilis

SummaryAs a step towards constructing strains of Z. mobilis capable of converting cellulose to ethanol, DNA fragments encoding endoglucanase (from Xanthomonas albilineans) and β-glucosidase (from either X.albilineans or Pseudomonas sp.) were linked on the same vector and transferred to Z. mobilis. All clones expressed endoglucanase. β-Glucosidase was only produced by clones containing the Xanthomonas gene, and when two copies of this gene were present the β-glucosidase activity was higher.

Nucleotide sequence and thermostability of pND324, a 3.6-kb plasmid from Lactococcus lactis

Abstract A 3.6-kb plasmid, designated pND324, was isolated from Lactococcus lactis subsp. lactis LL57-1. Sequence analysis revealed the presence of three open reading frames, rep324, orfX1 and orfX2, which are flanked by two non-coding regions, ori324 and cisE. The minimal replication region of pND324 consists of ori324 and rep324, which is closely related to the lactococcal θ-type replicons of the pWV02/pCI305 family. pND324 was stable at both 30 °C and 37 °C, whereas derivatives that lack cisE were highly unstable at 37 °C, indicating that cisE is essential for thermostability. Sequences that are similar to orfX1 are commonly present in the lactococcal θ-type plasmids. The orfX2 product is homologous to TrfA, a 43-kDa protein of the E. coli theta-type plasmid RK2 required for replication and maintenance. Plasmid deletion and stability analyses showed that orfX2 is involved in the thermostability of pND324. Based on the minimal replication region of pND324, an integrative cloning vector, designated pND421, was constructed. In L. lactis LM0230, cells that carried pND421 integrated into its host chromosomal DNA could be recovered readily following incubation at 37 °C for 40 generations. The integrated plasmid was totally stable for at least 100 generations without selection at 30 °C.