乳酸乳球菌乳脂亚种W56中质粒pJW566的生物学特性

从丹麦乳酪发酵启子乳酸乳球菌乳脂亚种 (Lactococcuslactissubsp .cremoris)W56中 ,分离到一个 2 2 4kb的质粒pJW566,将该质粒转化到无质粒且噬菌体敏感的L .lactisMG1 61 4、SMQ86菌株中 ,所得转化子对常见 963、c2和P335属的噬菌体具有一定抗性。经测定噬菌体以及含有pJW566的菌株所繁育的噬菌体效价 ,发现该质粒对外源DNA具有限制和修饰 (Re strictionandModification ,R M)作用。将pJW566转化到一株噬菌体敏感的乳酪工业生产菌株L .lactisCHCC2 2 81 ,在牛奶发酵中 ,表现出较强的噬菌体抗性。体外内切酶活性测定表明 ,该质粒具有的限制性内切酶需要Mg2 +和ATP ,而AdoMet(S adenosylmethionine,AdoMet)对酶活有促进作用     

限制和修饰系统LlaBⅢ在构建抗噬菌体菌株中的作用

限制和修饰(restriction and modification,R/M)系统是指由限制性内切酶和甲基化酶组成的单亚基或多亚基复合酶系统,两者通常成对出现,具有相同的DNA识别位点,其作用相反.R/M系统在原核生物中普遍存在,在保护细胞免遭外源病毒侵害方面具有重要作用[1].     

限制和修饰系统LlaBIII在构建抗噬菌体菌株中的作用

限制和修饰 (ｒｅｓｔｒｉｃｔｉｏｎａｎｄｍｏｄｉｆｉｃａｔｉｏｎ ,Ｒ Ｍ)系统是指由限制性内切酶和甲基化酶组成的单亚基或多亚基复合酶系统 ,两者通常成对出现 ,具有相同的ＤＮＡ识别位点 ,其作用相反。Ｒ Ｍ系统在原核生物中普遍存在 ,在保护细胞免遭外源病毒侵害方面具有重要作用[1] 。作为发酵剂的乳酸乳球菌在乳制品发酵中具有重要作用 ,但这类菌株极易遭受噬菌体感染 ,导致菌株产酸力降低 ,甚至发酵失败 ,造成严重的经济损失。所以在乳制品发酵过程中防止噬菌体感染就成为十分重要的问题。通过自然筛选或诱变处理等手段筛选噬菌…     

限制和修饰酶基因Lla BⅢ的克隆及分析

pJW566是从丹麦乳酪生产菌株Lactococcus lactis subsp.cremoris W56中分离到的,一个22.4kb,具有限制和修饰作用的质粒,内切酶ClaⅠ和pJW566不完全消化,所得片段与来自于质粒pVC5的氯霉素抗性基因连接得到一个携带有完整限制和修饰酶基因的质粒pJK1。基因亚克隆分析发现该基因位于约5kb的Sph0Ⅰ-Hin dⅢDNA片段上。序列分析表明该片段包含一个4572bp的开放阅读框架、编码一个由1576／1584个氨基酸残基组成的蛋白质,该基因命名为Lla BⅢ。蛋白质同源性查询发现在该蛋白的N－末端有7个保守区域,与R／M系统Ⅰ型和Ⅲ型内切酶有较高同源性,在蛋白的中间区域有4个代表N^6-腺苷酰甲基转移酶的特征序列,而蛋白的C－末端不同于任何已知蛋白。这种具有限制、修饰和可能的DNA识别作用的多功能蛋白,可能是一新的R／M系统。     

Additive Effects of Two Different Plasmid-Linked Restriction and Modification Systems in Lactococcus

Two plasmids, pND801 and pND802, encoding different restriction and modification systems were isolated from Lactococcus lactis ssp. lactis LL42-1 and Lactococcus lactis ssp. cremoris LC14-1, respectively. pND802 contained one Sphl restriction enzyme site and the whole plasmid was cloned into the Sphl site of the streptococcal/ E. coli shuttle vector pSA3 generating the plasmid pND803. pND803 was stably maintained in L.lactis MG1363 harbouring pND801. The combination of the two R/M systems within L.lactis MG1363 resulted in an additive resistance towards both isometric phage and prolate phage.     

Streptococcus cremoris M12R transconjugants carrying the conjugal plasmid pTR2030 are insensitive to attack by lytic bacteriophages.

Conjugal transfer of lactose-fermenting ability (Lac+), nisin resistance (Nisr), and phage resistance (Hsp+) was demonstrated in matings between Streptococcus lactis ME2 (donor) and Streptococcus cremoris M43a (recipient), a derivative of M12R. Transconjugants were detected by transfer of Lac+ and were found to exhibit Nisr and harbor a 40-megadalton plasmid (pTR1040). Fifty-six percent of Lac+ transconjugants were resistant to the S. cremoris M12R lytic phage. Efficiency of plaquing for phage m12r . M12 on a phage-resistant transconjugant, T2r-M43a, was less than 4.3 X 10(-10). Five additional phages which were virulent for S. cremoris M12R and isolated from industrial sources failed to plaque on S. cremoris T2r-M43a. Mating experiments with T2r-M43a revealed that phage resistance was accompanied by high-frequency conjugation ability (Tra+) and the appearance of both pTR1040 and pTR2030 encoding Lac+ Nisr and Tra+ Hsp+, respectively, in transconjugants of S. lactis LM2302. Phage-sensitive Lac+ transconjugants of S. cremoris M43a (T2s-M43a) showed no conjugal ability. These observations confirmed that pTR2030 was present and responsible for the phage resistance and conjugal ability exhibited by the S. cremoris transconjugant T2r-M43a. Unlike the S. lactis LM2302 transconjugant carrying pTR2030, resistance of T2r-M43a to phage was not affected at high temperatures (35 to 40 degrees C) or destabilized in repeated transfers through a starter culture activity test. These results demonstrated that phage resistance conferred by pTR2030 in the S. cremoris transconjugant was effective against industrially significant phages under fermentation conditions normally encountered during cheese manufacture.     

Streptococcus cremoris M12R transconjugants carrying the conjugal plasmid pTR2030 are insensitive to attack by lytic bacteriophages

Conjugal transfer of lactose-fermenting ability (Lac+), nisin resistance (Nisr), and phage resistance (Hsp+) was demonstrated in matings between Streptococcus lactis ME2 (donor) and Streptococcus cremoris M43a (recipient), a derivative of M12R. Transconjugants were detected by transfer of Lac+ and were found to exhibit Nisr and harbor a 40-megadalton plasmid (pTR1040). Fifty-six percent of Lac+ transconjugants were resistant to the S. cremoris M12R lytic phage. Efficiency of plaquing for phage m12r . M12 on a phage-resistant transconjugant, T2r-M43a, was less than 4.3 X 10(-10). Five additional phages which were virulent for S. cremoris M12R and isolated from industrial sources failed to plaque on S. cremoris T2r-M43a. Mating experiments with T2r-M43a revealed that phage resistance was accompanied by high-frequency conjugation ability (Tra+) and the appearance of both pTR1040 and pTR2030 encoding Lac+ Nisr and Tra+ Hsp+, respectively, in transconjugants of S. lactis LM2302. Phage-sensitive Lac+ transconjugants of S. cremoris M43a (T2s-M43a) showed no conjugal ability. These observations confirmed that pTR2030 was present and responsible for the phage resistance and conjugal ability exhibited by the S. cremoris transconjugant T2r-M43a. Unlike the S. lactis LM2302 transconjugant carrying pTR2030, resistance of T2r-M43a to phage was not affected at high temperatures (35 to 40 degrees C) or destabilized in repeated transfers through a starter culture activity test. These results demonstrated that phage resistance conferred by pTR2030 in the S. cremoris transconjugant was effective against industrially significant phages under fermentation conditions normally encountered during cheese manufacture.     

Stacking of three different restriction and modification systems in Lactococcus lactis by cotransformation

Four plasmids encoding restriction and modification (R/M) systems are described that are different in the specificity of their restrictive activity toward the small isometric phage p2 and prolate phage c2. The R/M plasmids were cotransformed into Lactococcus lactis MG1363 with pVS2, encoding resistance to chloramphenicol and erythromycin, to indicate successful transformation events. Analysis of cotransformants showed that three different R/M plasmids could be combined in L. lactis MG1363. The efficiency at which phage plaqued on the transformants decreased as the number of R/M plasmids increased. Some plasmid combinations were unstable suggesting replicon incompatibility.     

Cloning and analysis of the restriction-modification system LlaBI, a bacteriophage resistance system from Lactococcus lactis subsp. cremoris W56.

The genes coding for the type II restriction-modification (R/M) system LlaBI, which recognized the sequence 5'-C decreases TRYAG-3', have been cloned from a plasmid in Lactococcus lactis subsp. cremoris W56 and sequenced. The DNA sequence predicts an endonuclease of 299 amino acids (33 kDa) and a methylase of 580 amino acids (65 kDa). A 4.0-kb HindIII fragment in pSA3 was able to restrict bacteriophages, showing that the cloned R/M system can function as a phage defense mechanism in L. lactis.     

Conjugative co-transfer of lactose and bacteriophage resistance plasmids from Streptococcus cremoris UC653

Abstract When conjugative transfer of lactose-fermenting ability (Lac) was observed between Streptococcus cremoris UC653 (donor) and S. lactis MG1363 Sm (recipient), 70% of the Lac⁺ transconjugants had acquired total resistance to phage 712 and propagated phage C2 at a lower efficiency and with a reduced plaque size. Plasmid analysis of transconjugants combined with curing experiments showed that the Lac and phage resistance markers were associated with plasmids of 26 and 50 MDa, respectively. Some transconjugants contained a large plasmid of either 77 or 83 MDa which coded for both Lac and phage resistance. The phage resistance mechanism did not act at the adsorption stage and was not affected by incubation at 37°C.     

The ability of the plasmid-encoded restriction and modification system LlaBIII to protect Lactococcus lactis against bacteriophages

AIMS: To investigate the potential of the plasmid-encoded restriction and modification (R/M) system LlaBIII to protect Lactococcua lactis against bacteriophages during milk fermentations. METHODS AND RESULTS: The R/M system LlaBIII on plasmid pJW566 was cloned with a chloramphenicol cassette, resulting in plasmid pJK1. When introduced into L. lactis strains, pJK1 conferred increased phage resistance against the three most common lactococcal phage species 936, c2, and P335 and three unclassified industrial phages. The growth of the strains in RSM was not affected by the presence of plasmid pJK1. CONCLUSIONS: The plasmid-encoded R/M system LlaBIII has great ability to protect L. lactis strains against bacteriophages in milk fermentations. SIGNIFICANCE AND IMPACT OF THE STUDY: This study evaluates the ability of the LlaBIII R/M system to function as a phage defence mechanism which is an essential step prior to considering utilizing it for improving starter cultures.     

Molecular Properties of Streptococcus thermophilus Plasmid pER35 Encoding a Restriction Modification System

Bacteriophage attack on lactic fermentation bacteria (LFB) is costly to the dairy industry because it results in product loss. One mechanism used by LFB to protect themselves from bacteriophage attack is restriction of foreign DNA. Three plasmids, pER16, pER35, and pER36, from three different strains of the thermotolerant dairy fermentation bacterium Streptococcus thermophilus were sequenced. One of these plasmids, pER35, isolated from S. thermophilus ST135, encoded a type IC restriction-modification (R-M) system very similar to those encoded on plasmids pIL2614 in Lactococcus lactis subsp. lactis and pND861 in Lactococcus lactis biovar diacetylactis. The high degree of identity between the R-M systems encoded on pER35, pIL2614, and pND861 indicated the potential for horizontal transfer of these genes between different species of lactic fermentation bacteria. Similar to the functional R-M system encoded on pIL2614 that protects the mesophilic L. lactis subsp. lactis against phage attack, the R-M system on pER35 most likely functions in the same role in S. thermophilus ST135. The plasmid pER16 was found to encode the specificity subunit of the R-M system, but not the R or M subunits. In addition, all three plasmids encoded proteins that are present on other S. thermophilus plasmids, including a protein for rolling-circle replication (RepA) and a low-molecular-weight stress protein (Hsp). The presence of a complete R-M system encoded on a plasmid in S. thermophilus, a species that often lacks plasmids, is novel and may be beneficial for protecting S. thermophilus from bacteriophage attack under dairy fermentation conditions.     

A Starter Culture Rotation Strategy Incorporating Paired Restriction/ Modification and Abortive Infection Bacteriophage Defenses in a Single Lactococcus lactis Strain

Three derivatives of Lactococcus lactis subsp. lactis NCK203, each with a different pair of restriction/ modification (R/M) and abortive infection (Abi) phage defense systems, were constructed and then rotated in repeated cycles of a milk starter culture activity test (SAT). The rotation proceeded successfully through nine successive SATs in the presence of phage and whey containing phage from previous cycles. Lactococcus cultures were challenged with 2 small isometric-headed phages, (phi)31 and ul36, in one rotation series and with a composite of 10 industrial phages in another series. Two native lactococcal R(sup+)/M(sup+) plasmids, pTRK68 and pTRK11, and one recombinant plasmid, pTRK308, harboring a third distinct R/M system were incorporated into three NCK203 derivatives constructed separately for the rotation. The R(sup+)/M(sup+) NCK203 derivatives were transformed with high-copy-number plasmids encoding four Abi genes, abiA, abiC, per31, and per50. Various Abi and R/M combinations constructed in NCK203 were evaluated for their effects on cell growth, level of phage resistance, and retardation of phage development during repeated cycles of the SAT. The three NCK203 derivatives chosen for use in the SAT exhibited additive effects of the R/M and Abi phenotypes against sensitive phages. In such combinations, phage escaping restriction are prevented from completing their infective cycle by an abortive response that kills the host cell. The rotation series successfully controlled modified, recombinant, and mutant phages which were resistant to any one of the individual defense systems by presenting a different set of R/M and Abi defenses in the next test of the rotation.     

Sequence analysis and characterization of plasmids from Streptococcus thermophilus

The nucleotide sequences of eight plasmids isolated from seven Streptococcus thermophilus strains have been determined. Plasmids pSt04, pER1-1, and pJ34 are related and replicate via a rolling circle mechanism. Plasmid pJ34 encodes for a replication initiation protein (RepA) and a small polypeptide with unknown function. Plasmids pSt04 and pER1-1 carry in addition to repA genes coding for small heat shock proteins (sHsp). Expression of these proteins is induced at elevated temperatures or low pH and increases the thermo- and acid resistance. Plasmids pER1-2 and pSt22-2 show identical sequences with five putative open reading frames (ORFs). The gene products of ORF1 and ORF4 reveal some similarities to transposon encoded proteins of Bacillus subtilis and Tn916. ORF1 of plasmid pSt106 encodes a protein similar to resolvases of different Gram-positive bacteria. Integrity of ORF2 and 3, encoding a putative DNA primase and a replication protein, is essential for replication. ORF1 to 3 of plasmid pSt08, which are organized in a tricistronic operon, encode a RepA protein, an adenosine-specific methyltransferase, and a type II restriction endonuclease. Another type II restriction-modification (R/M) system is encoded on plasmid pSt0 which is highly similar to those encoded on lactococcal plasmid pHW393 and B. subtilis plasmid pXH13. Plasmid-free derivatives of strains St0 and St08 show increased phage sensitivity, indicating that in the wild-type strains the R/M systems are functionally expressed. Recombinant plasmids based on the replicons of plasmids pSt04, pJ34, pSt106, pSt08, and pSt0, are able to replicate in Lactococcus lactis and B. subtilis, respectively, whereas constructs carrying pER1-2 only replicate in S. thermophilus.     

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 10² PFU/ml but not when levels were increased to 10³ 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 (10⁶ 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.     

Conjugal transfer and characterization of bacteriocin plasmids in group N (lactic acid) streptococci.

Thirteen bacteriocin-producing strains of group N (lactic acid) streptococci were screened for their potential to transfer this property by conjugation to Streptococcus lactis subsp. diacetylactis Bu2-60. Bacteriocin production in three strains was plasmid encoded as shown by conjugal transfer and by analysis of cured, bacteriocin-negative derivatives of the donor strains and the transconjugants. With Streptococcus cremoris strains 9B4 and 4G6 and S. lactis subsp. diacetylactis 6F7 as donors, bacteriocin-producing transconjugants were isolated with frequencies ranging from ca. 2 X 10(-2) to 2 X 10(-1) per recipient cell. Bacteriocin-producing transconjugants had acquired a 39.6-megadalton plasmid from the donor strains 9B4 and 4G6, and a 75-megadalton plasmid from the donor strain 6F7. As shown by restriction endonuclease analysis, the plasmids from strains 9B4 and 4G6 were almost identical. The plasmid from strain 6F7 yielded some additional fragments not present in the two other plasmids. In hybridization experiments any of the three plasmids strongly hybridized with each other and with some other bacteriocin but nontransmissible plasmids from other S. cremoris strains. Homology was also detected to a variety of cryptic plasmids in lactic acid streptococci.     

Plasmid pC present in Salmonella enterica serovar Enteritidis PT14b strains encodes a restriction modification system

Salmonella enterica serovar Enteritidis (S. Enteritidis) possesses plasmids of different sizes and roles. Besides the serovar-specific virulence plasmid present in most field strains, S. Enteritidis can harbour plasmids of low molecular mass whose biological role is poorly understood. We therefore sequenced plasmid pC present in S. Enteritidis strains belonging to phage type PT14b. The size of plasmid was determined to be 5,269 bp and it was predicted to encode four open reading frames (ORFs). The first two ORFs were found (initial 3,230 bp) to be highly homologous to rom and mbeA genes of ColE1 plasmid of Escherichia coli. Proteins encoded by the other two ORFs were 99% homologous to a restriction methylase and restriction endonuclease encoded by plasmid pECO29 of a field strain of E. coli. Using insertional mutagenesis we confirmed experimentally that the plasmid pC-encoded restriction modification system was functional and could explain the high resistance of S. Enteritidis PT14b strains to phage infection.     

Characterization of AbiR, a novel multicomponent abortive infection mechanism encoded by plasmid pKR223 of Lactococcus lactis subsp. lactis KR2

The native lactococcal plasmid pKR223 encodes two distinct phage resistance mechanisms, a restriction and modification (R/M) system designated LlaKR2I and an abortive infection mechanism (Abi) which affects prolate-headed-phage proliferation. The nucleotide sequence of a 16,174-bp segment of pKR223 encompassing both the R/M and Abi determinants has been determined, and sequence analysis has validated the novelty of the Abi system, which has now been designated AbiR. Analysis of deletion and insertion clones demonstrated that AbiR was encoded by two genetic loci, separated by the LlaKR2I R/M genes. Mechanistic studies on the AbiR phenotype indicated that it was heat sensitive and that it impeded phage DNA replication. These data indicated that AbiR is a novel multicomponent, heat-sensitive, "early"-functioning Abi system and is the first lactococcal Abi system described which is encoded by two separated genetic loci.     

Phage resistance in lactic acid bacteria

The interactions between lactic acid bacteria and their phages are commercially significant. Current research has focused on the elucidation of the mechanisms and genetics of phage resistance. Phage resistance genes have been linked to plasmid DNA for Streptococcus lactis and Streptococcus cremoris, and preliminary studies suggest the operation of mechanisms such as the prevention of phage adsorption, restriction/modification, and abortive infection. Some phage resistance plasmids can be conjugally transferred, providing a means of dissemination among phage-sensitive strains for the construction of phage-resistant starter cultures.     

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) HpaII 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 EcoRV fragment and included an EcoRI 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 BstEII-XbaI fragment. The genetic locus for the Abi phenotype against phage c2 was localized to a region containing a 1.3-kb EcoRI 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 HpaII 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 HpaII 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).