Metabolic and Transcriptomic Adaptation of
            <i>Lactococcus lactis</i>
            subsp.
            <i>lactis</i>
            Biovar diacetylactis in Response to Autoacidification and Temperature Downshift in Skim Milk

Raynaud, Sandy; Perrin, Rémi; Cocaign‐Bousquet, Muriel; Loubière, Pascal

doi:10.1128/aem.71.12.8016-8023.2005

Cited by 42 publications

(53 citation statements)

References 40 publications

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“…Enzymes encoded by these genes reportedly contribute to raising internal pH in acidification conditions by liberation of NH 3 and are induced by acid stress (8), (47). These genes are reportedly downregulated in the presence of O 2 in different bacterial species (e.g., see references 16 and 26).…”

Section: Resultsmentioning

confidence: 99%

Impact of Aeration and Heme-Activated Respiration on Lactococcus lactis Gene Expression: Identification of a Heme-Responsive Operon

Pedersen¹,

Garrigues²,

Tuphile³

et al. 2008

J Bacteriol

123

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Lactococcus lactis is a widely used food bacterium mainly characterized for its fermentation metabolism. However, this species undergoes a metabolic shift to respiration when heme is added to an aerobic medium. Respiration results in markedly improved biomass and survival compared to fermentation. Whole-genome microarrays were used to assess changes in L. lactis expression under aerobic and respiratory conditions compared to static growth, i.e., nonaerated. We observed the following. (i) Stress response genes were affected mainly by aerobic fermentation. This result underscores the differences between aerobic fermentation and respiration environments and confirms that respiration growth alleviates oxidative stress. (ii) Functions essential for respiratory metabolism, e.g., genes encoding cytochrome bd oxidase, menaquinone biosynthesis, and heme uptake, are similarly expressed under the three conditions. This indicates that cells are prepared for respiration once O 2 and heme become available. (iii) Expression of only 11 genes distinguishes respiration from both aerobic and static fermentation cultures. Among them, the genes comprising the putative ygfCBA operon are strongly induced by heme regardless of respiration, thus identifying the first hemeresponsive operon in lactococci. We give experimental evidence that the ygfCBA genes are involved in heme homeostasis.

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Section: Resultsmentioning

confidence: 99%

Impact of Aeration and Heme-Activated Respiration on Lactococcus lactis Gene Expression: Identification of a Heme-Responsive Operon

Pedersen¹,

Garrigues²,

Tuphile³

et al. 2008

J Bacteriol

123

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“…It is well known that the diminished growth rate, whatever the cause of the slowing down, has large implications for global gene expression, affecting functions such as amino acid transporters, sugar metabolism, large and small ribosomal subunits, etc. (30,31). On the other hand, it is expected that very few genes will show variation of expression during exponential growth phases in which specific rates are comparable.…”

Section: Discussionmentioning

confidence: 99%

“…lactis is considered a model lactic acid bacterium, encountered extensively in numerous food fermentation processes, particularly in cheese production, industrial processes, and natural ecosystems. DNA arrays for L. lactis strain IL-1403, the first lactococcal strain to be sequenced (6), have recently been used for transcriptome analysis of L. lactis pure cultures (4,19,30,31). However, in most cases, L. lactis lives together with multiple microorganisms such as lactobacilli, corynebacteria, and yeasts (7,11,24,26,28,33,35).…”

mentioning

confidence: 99%

Transcriptome Analysis of Lactococcus lactis in Coculture with Saccharomyces cerevisiae

Maligoy

Mercade

Cocaign‐Bousquet

et al. 2008

Appl Environ Microbiol

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The study of microbial interactions in mixed cultures remains an important conceptual and methodological challenge for which transcriptome analysis could prove to be the essential method for improving our understanding. However, the use of whole-genome DNA chips is often restricted to the pure culture of the species for which the chips were designed. In this study, massive cross-hybridization was observed between the foreign cDNA and the specific Lactococcus lactis DNA chip. A very simple method is proposed to considerably decrease this nonspecific hybridization, consisting of adding the microbial partner's DNA. A correlation was established between the resulting cross-hybridization and the phylogenetic distance between the microbial partners. The response of L. lactis to the presence of Saccharomyces cerevisiae was analyzed during the exponential growth phase in fermentors under defined growth conditions. Although no differences between growth kinetics were observed for the pure and the mixed cultures of L. lactis, the mRNA levels of 158 genes were significantly modified. More particularly, a strong reorientation of pyrimidine metabolism was observed when L. lactis was grown in mixed cultures. These changes in transcript abundance were demonstrated to be regulated by the ethanol produced by the yeast and were confirmed by an independent method (quantitative reverse transcription-PCR).

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“…A number of studies have appeared that describe successful transcriptome or proteome analyses on samples from fermented substrates and even from highly complex materials such as fecal samples (81,178). Most studies of dairy fermentations use skim milk, in which the precipitation of casein may be prevented by pretreatment with sodium citrate (126,139). These studies have revealed several previously undescribed metabolic adaptations upon growth in milk, such as the induction of pyruvate-formate lyase in S. thermophilus that may serve as the supply of formate required for the biosynthesis of purine bases or other anabolic processes (37) (Fig.…”

Section: Genomics Approaches For Mixed-culture Researchmentioning

confidence: 99%

Unraveling Microbial Interactions in Food Fermentations: from Classical to Genomics Approaches

Sieuwerts

Bok

Hugenholtz

et al. 2008

Appl Environ Microbiol

264

178

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3Fermentation, the microbial degradation of organic compounds without net oxidation, is an important process in the global carbon cycle and is also exploited worldwide for the production and preservation of food. It is one of the oldest food-processing technologies known, with some records dating back to 6,000 B.C. (50). The link between food and microbiology was laid by Pasteur, who found that yeasts were responsible for alcoholic fermentation (106). Since that discovery, scientific and industrial interests in food microbiology started to grow and continue to increase today. The number of food products that rely on fermentation in one or more steps of their production is tremendous. They form an important constituent of the daily diet and rank among the most innovative product categories in the food industry.Most of the important microorganisms applied in the production of fermented foods have been studied for decades, yielding a wealth of information on their physiology and genetics in relation to product functionalities, such as the development of flavor, taste, and texture. The recent emergence of genomics has opened new avenues for the systematic analysis of microbial metabolism and the responses of microorganisms to their environment. Additionally, genomics has boosted research on important food microbes (22,90,93). Much of this research focuses on the performance of a single strain, including its interactions with the food matrix. However, food fermentations are typically carried out by mixed cultures consisting of multiple strains or species. Population dynamics play a crucial role in the performance of mixed-culture fermentations, and for many years, studies on mixed-culture food fermentations have focused on analyzing population dynamics using classical and molecular methods. Many of these studies are mainly descriptive, and relatively little is known about the mechanisms governing population dynamics in general and the molecular interactions that occur between the consortium members in particular. The availability of genome sequences for several species that are of industrial importance as well as technological advances in functional genomics enable new approaches to study food microbiology beyond the single species level and allow an integral analysis of the interactions and metabolic activity in mixed cultures.Here we review the current knowledge on important food fermentation processes, focusing on the bacterial interactions.In addition, we illustrate how genomics approaches may contribute to the elucidation of the interaction networks between microbes, including interactions with the food environment. This information may find application in the industry through rational optimization and increased control over mixed-culture fermentations.

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Metabolic and Transcriptomic Adaptation of Lactococcus lactis subsp. lactis Biovar diacetylactis in Response to Autoacidification and Temperature Downshift in Skim Milk

Cited by 42 publications

References 40 publications

Impact of Aeration and Heme-Activated Respiration on Lactococcus lactis Gene Expression: Identification of a Heme-Responsive Operon

Impact of Aeration and Heme-Activated Respiration on Lactococcus lactis Gene Expression: Identification of a Heme-Responsive Operon

Transcriptome Analysis of Lactococcus lactis in Coculture with Saccharomyces cerevisiae

Unraveling Microbial Interactions in Food Fermentations: from Classical to Genomics Approaches

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