Cellulose Fermentation by an Asporogenous Mutant and an Ethanol-Tolerant Mutant of Clostridium thermocellum

Two mutants of Clostridium thermocellum were isolated after UV light mutagenesis. Mutant A1, selected as asporogenous, exhibited a fermentation pattern similar to that of the wild type. However, at pH 6.5, the mutant degraded 12% more cellulose than did the wild type, leading to enhanced ethanol production. Mutant 647, selected as ethanol tolerant, was able to grow in medium containing 4% ethanol. During the early stage of the exponential growth phase, ethanol was produced as the main product, up to a concentration of about 9 g/liter. After 3 days of culture, 48.3 g (89% of the initial amount) of degraded cellulose per liter was fermented into 12.7 g of ethanol per liter.

Enhanced Cellulose Fermentation by an Asporogenous and Ethanol-Tolerant Mutant of Clostridium thermocellum

A mutant of Clostridium thermocellum isolated after UV mutagenesis and selection for resistance to fluoropyruvate was found to be asporogenous and ethanol tolerant. The mutant was also an ethanol hyperproducer, able to ferment 63 g of cellulose into 14.5 g of ethanol per liter of medium. The ratio of ethanol to total organic acids produced by the mutant was increased, and H(2) production was decreased. Culture conditions were optimized for ethanol production by the new strain.

A Lactobacillus helveticus-Specific DNA Probe Detects Restriction Fragment Length Polymorphisms in This Species

A cloned 2-kb EcoRI fragment (fragment f) from a 34-kb plasmid of Lactobacillus helveticus CNRZ 1094 was shown by dot blot to specifically hybridize to total DNAs of 75 L. helveticus strains. No hybridization was found with L. acidophilus, L. crispatus, L. delbrueckii subsp. bulgaricus, L. delbrueckii subsp. lactis, L. gasseri, or L. intestinalis strains. When Southern blots of EcoRI digests of L. helveticus strains were probed with fragment f, these strains displayed restriction fragment length polymorphisms on the basis of which they could be grouped into several clusters.

Polyphasic study of Chryseobacterium strains isolated from diseased aquatic animals

Members of most Chryseobacterium species occur in aquatic environments or food products, while strains of some other species are pathogenic to humans and animals. A collection of 52 Chryseobacterium sp. strains isolated from diseased fish, one frog isolate and 22 reference strains were included in a polyphasic taxonomy study. Fourteen clusters of strains were delineated following the comparison of whole-cell protein profiles. Most of these clusters were confirmed when the phenotypic and RAPD profiles and the 16S rRNA gene sequences were compared. Fatty acid composition helped differentiate the Chryseobacterium strains from members of related genera. None of the fish isolates could be allocated to the two species previously reported from fish but two isolates belonged to C. joostei, while the frog isolate was identified as Elizabethkingia meningoseptica, a human pathogen previously included in the genus Chryseobacterium. Three clusters grouping from 3 to 13 isolates will probably constitute the core of new Chryseobacterium species but all other isolates occupied separate or uncertain positions in the genus. This study further demonstrated the overall high similarity displayed by most Chryseobacterium strains whatever the technique used and the resulting difficulty in delineating new species in the genus. Members of this bacterial group should be considered potential emergent pathogens in various fish and frog species, farming conditions and geographical areas.

The EstA esterase is responsible for the main capacity of Lactococcus lactis to synthesize short chain fatty acid esters in vitro

AIMS

Esters of short-chain fatty acids and alcohols participate significantly in the overall flavour of foods. The capacity of the lactic acid bacterium Lactococcus lactis to synthesize such esters is known even though the enzymes involved in the process are not well identified. The objective of our work is to determine whether the esterase is responsible for the whole capacity of L. lactis to synthesize esters in vitro.

METHODS AND RESULTS

A negative mutant for the esterase was constructed and its capacity to synthesize short chain fatty acid esters from different substrate couples was compared to that of the wild type. We observed that the esterase is responsible for the main ester synthesis activity of L. lactis in vitro. However, in the presence of some substrates, the esterase negative mutant still synthesizes low amounts of esters.

CONCLUSIONS

In favourable environmental conditions, the L. lactis esterase is responsible for the main ester synthesizing activity, even though another pathway for ester synthesis probably exists.

SIGNIFICANCE AND IMPACT OF THE STUDY

Since esters are potent aroma compounds, esterase is probably a key enzyme in the development of food flavour.

Polyphasic investigation of the diversity within Lactobacillus plantarum related strains revealed two L. plantarum subgroups

The diversity of 140 strains related to Lactobacillus plantarum was investigated using a polyphasic approach combining two molecular techniques: randomly amplified polymorphic DNA fingerprinting (RAPD) and Southern hybridisation with a pyr probe on BglI digests of chromosomal DNA, as well as phenotypic characterization. The RAPD technique allowed us to classify a subset of 60 representative strains into four groups. One group belonged to Lactobacillus paraplantarum, the second to Lactobacillus pentosus and the two remaining groups to L. plantarum (G(L)p1 and G(L)p2). The Southern hybridisation technique (F. Bringel, M.-C. Curk and J.-C. Hubert, Int. J. Syst. Bacteriol. 46: 588-594, 1996) revealed nine groups of profiles (I to IX). Results indicated an excellent convergence between RAPD and hybridisation classifications for more than 93% (56/60) of the strains studied. When we compared the fermentation patterns of the L. plantarum strains, three differences were found. Melezitose fermentation was not fermented by the G(L)p2 RAPD group, unlike the G(L)p1 RAPD group which included L. plantarum type strain NCIMB11974T. Second, alpha-methyl-D-mannoside was fermented by a majority of the strains of the G(L)p1 RAPD group but by none of the strains in the G(L)p2 RAPD group. Third, dulcitol was catabolized by nearly half of the strains of the G(L)p2 RAPD group but by none of the strains in the G(L)p1 RAPD group. Molecular diversity within L. plantarum was confirmed using Southern profiles, PCR amplification and subsequent sequencing of these PCR products. A 773 bp sequence overlapping the pyrDF genes showed high homology: at least 97% identical in L. plantarum strains (V to IX) and 99.9% identical in hybridisation groups VII and VIII. The same G-T transversion which destroyed the pyrF BglI site was found in 11 strains (hybridisation groups VI, VII and VIII). DNA rearrangements were identified downstream from the pyr genes, by PCR amplification and Southern hybridisation profile analysis in three strains of hybridisation groups VIII and IX, two of which also harboured the G-T transversion.

In vivo evidence for two active nuclease motifs in the double-strand break repair enzyme RexAB of Lactococcus lactis

In bacteria, double-strand DNA break (DSB) repair involves an exonuclease/helicase (exo/hel) and a short regulatory DNA sequence (Chi) that attenuates exonuclease activity and stimulates DNA repair. Despite their key role in cell survival, these DSB repair components show surprisingly little conservation. The best-studied exo/hel, RecBCD of Escherichia coli, is composed of three subunits. In contrast, RexAB of Lactococcus lactis and exo/hel enzymes of other low-guanine-plus-cytosine branch gram-positive bacteria contain two subunits. We report that RexAB functions via a novel mechanism compared to that of the RecBCD model. Two potential nuclease motifs are present in RexAB compared with a single nuclease in RecBCD. Site-specific mutagenesis of the RexA nuclease motif abolished all nuclease activity. In contrast, the RexB nuclease motif mutants displayed strongly reduced nuclease activity but maintained Chi recognition and had a Chi-stimulated hyperrecombination phenotype. The distinct phenotypes resulting from RexA or RexB nuclease inactivation lead us to suggest that each of the identified active nuclease sites in RexAB is involved in the degradation of one DNA strand. In RecBCD, the single RecB nuclease degrades both DNA strands and is presumably positioned by RecD. The presence of two nucleases would suggest that this RecD function is dispensable in RexAB.

Distinctive features of homologous recombination in an 'old' microorganism, Lactococcus lactis

Homologous recombination is needed to assure faithful inheritance of DNA material, especially under stress conditions. The same enzymes that repair broken chromosomes via recombination also generate biodiversity. Their activities may result in intrachromosomal rearrangements, assimilation of foreign DNA, or a combination of these events. It is generally supposed that homologous recombination systems are conserved, and function the same way everywhere as they do in Escherichia coli, the accepted paradigm. Studies in an 'older' microorganism, the gram-positive bacterium of the low GC branch Lactococcus lactis, confirm that many enzymes are conserved across species lines. However, the main components of the double strand break (DSB) repair system, an exonuclease/helicase (Exo/hel) and a short DNA modulator sequence Chi, differ markedly between bacteria, especially when compared to the gram-negative analogues. Based on our studies, a model is proposed for the functioning of the two-subunit Exo/hel of L. lactis and other gram-positive bacteria, which differs from that of the three-subunit E. coli enzyme. The differences between bacterial DSB repair systems may underlie a selection for diversity when dealing with DSB. These and other features of homologous recombination in L. lactis are discussed.

Identification of Mur, an atypical peptidoglycan hydrolase derived from Leuconostoc citreum

A gene encoding a protein homologous to known bacterial N-acetyl-muramidases has been cloned from Leuconostoc citreum by a PCR-based approach. The encoded protein, Mur, consists of 209 amino acid residues with a calculated molecular mass of 23,821 Da including a 31-amino-acid putative signal peptide. In contrast to most of the other known peptidoglycan hydrolases, L. citreum Mur protein does not contain amino acid repeats involved in cell wall binding. The purified L. citreum Mur protein was shown to exhibit peptidoglycan-hydrolyzing activity by renaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. An active chimeric protein was constructed by fusion of L. citreum Mur to the C-terminal repeat-containing domain (cA) of AcmA, the major autolysin of Lactococcus lactis. Expression of the Mur-cA fusion protein was able to complement an acmA mutation in L. lactis; normal cell separation after cell division was restored by Mur-cA expression.

Characterization of natural isolates of Lactobacillus strains to be used as starter cultures in dairy fermentation

The technological relevant characteristics of five homofermentative lactobacilli strains, isolated from natural fermented hard cheeses, were studied. Isolates CRL 581 and CRL 654, from Argentinian artesanal hard cheeses, and isolates CRL 1177, CRL 1178, and CRL 1179, from Italian Grana cheeses, were identified as Lactobacillus delbrueckii subsp. lactis and Lactobacillus helveticus, respectively, by physiological and biochemical tests, SDS-PAGE of whole-cell proteins and sequencing of the variable (V1) region of the 16S ribosomal DNA. All strains showed high levels of beta-galactosidase activity. However, proteolytic activity varied widely among isolates. Strains CRL 581, CRL 654, and CRL 1177 hydrolyzed alpha- and beta-caseins and were able to coagulate reconstituted skim milk in less than 16 h at 42 degrees C. According to the substrate specificity, these proteinases have a caseinolytic activity comparable to that of the P(III)-type of lactococcal proteinases. No strains produced inhibitor substances (bacteriocin) and all were insensitive to attack by 14 L. helveticus- and L. delbrueckii subsp. lactis-specific bacteriophages.

Molecular diversity of lactic acid bacteria from cassava sour starch (Colombia)

Lactic acid bacteria and more particularly lactobacilli and Leuconostoc, are widely found in a wide variety of traditional fermented foods of tropical countries, made with cereals, tubers, meat or fish. These products represent a source of bacterial diversity that cannot be accurately analysed using classical phenotypic and biochemical tests. In the present work, the identification and the molecular diversity of lactic acid bacteria isolated from cassava sour starch fermentation were assessed by using a combination of complementary molecular methods: Randomly Amplified Polymorphic DNA fingerprinting (RAPD), plasmid profiling, hybridization using rRNA phylogenetic probes and partial 16S rDNA sequencing. The results revealed a large diversity of bacterial species (Lb. manihotivorans, Lb. plantarum, Lb. casei, Lb. hilgardii, Lb. buchneri, Lb. fermentum, Ln. mesenteroides and Pediococcus sp.). However, the most frequently isolated species were Lb. plantarum and Lb. manihotivorans. The RAPD analysis revealed a large molecular diversity between Lb. manihotivorans or Lb. plantarum strains. These results, observed on a rather limited number of samples, reveal that significant bacterial diversity is generated in traditional cassava sour starch fermentations. We propose that the presence of the amylolytic Lb. manihotivorans strains could have a role in sour starch processing.

Molecular diversity and relationship within Lactococcus lactis, as revealed by randomly amplified polymorphic DNA (RAPD)

Lactococcus lactis strains are widely used in industrial dairy fermentations. Conventional phenotypic tests have been used for years to classify members of this species into two subspecies, lactis and cremoris, and play a key role in the choice of strains to be used in particular cheese fermentations. DNA hybridisation techniques have also been used for strain classification, giving rise to two genome homology groups. However, results showed discrepancies between the two methods of classification. We applied the randomly amplified polymorphic DNA fingerprinting (RAPD) technique to resolve previous contradictions in lactococcal classifications. Unlike usual RAPD methods, we use three primers to classify 113 strains and integrate the resulting information by a digitised programme used for this purpose. Our analysis revealed three major RAPD groups, designated G1, G2 and G3. G1 and G3 contain strains of the lactis subspecies, and G2 contains strains of the cremoris subspecies, as previously defined by phenotypic characteristics. Moreover, group G1 corresponds to one genome homology group, and groups G2 and G3 correspond to the second one. The taxonomic structure within L. lactis is therefore unusual: two distinct genetic groups of strains show indistinguishable phenotypes, while conversely, two phenotypically distinct groups are genetically homologous. We hypothesize that a subfamily of the subsp. lactis group gave rise to the cremoris subspecies.

Estimation of the state of the bacterial cell wall by fluorescent In situ hybridization

Fluorescent in situ hybridization (FISH) is now a widely used method for identification of bacteria at the single-cell level. With gram-positive bacteria, the thick peptidoglycan layer of a cell wall presents a barrier for entry of horseradish peroxidase (HRP)-labeled probes. Therefore, such probes do not give any signal in FISH unless cells are first treated with enzymes which hydrolyze the peptidoglycan. We explored this feature of FISH to detect cells which have undergone permeabilization due to expression of autolytic enzymes. Our results indicate that FISH performed with HRP-labeled probes provides a sensitive method to estimate the states of cell walls of individual gram-positive bacteria.

Characterization of IS1201, an insertion sequence isolated from Lactobacillus helveticus

IS1201, a 1387-bp insertion sequence isolated from Lactobacillus helveticus, was identified by its nucleotide (nt) sequence. It carries a single open reading frame encoding a 369-amino-acid protein, which shares homology with transposases found in a class of related IS, including ISRm3 from Rhizobium meliloti, IS256 from Staphylococcus aureus, IS6120 from Mycobacterium smegmatis, IS1081 from M. bovis, IST2 from Thiobacillus ferroxidans and IS406 from Pseudomonas cepacia. IS1201 has terminal inverted repeats of 24 bp in length and a target site duplication of 8 bp. Its copy number ranges from 3 to about 16 per L. helveticus genome. No homology was found between the nt sequence of IS1201 and those of the other bacterial IS from the same class. These results, together with previous observations [de los Reyes-Gavilán et al., Appl. Environ. Microbiol., 58 (1992) 3429-3432], confirm that IS1201 can be used as a specific DNA probe for the identification of L. helveticus strains.