Joao P. C. Pinto scite author profile

BackgroundMembrane proteins comprise an important class of molecules whose study is largely frustrated by several intrinsic constraints, such as their hydrophobicity and added requirements for correct folding. Additionally, the complexity of the cellular mechanisms that are required to insert membrane proteins functionally in the membrane and to monitor their folding state makes it difficult to foresee the yields at which one can obtain them or to predict which would be the optimal production host for a given protein.Methods and FindingsWe describe a rational design approach to improve the lactic acid bacterium Lactococcus lactis as a producer of membrane proteins. Our transcriptome data shows that the two-component system CesSR, which senses cell envelope stresses of different origins, is one of the major players when L. lactis is forced to overproduce the endogenous membrane protein BcaP, a branched-chain amino acid permease. Growth of the BcaP-producing L. lactis strain and its capability to produce membrane proteins are severely hampered when the CesSR system itself or particular members of the CesSR regulon are knocked out, notably the genes ftsH, oxaA2, llmg_2163 and rmaB. Overexpressing cesSR reduced the growth defect, thus directly improving the production yield of BcaP. Applying this rationale to eukaryotic proteins, some of which are notoriously more difficult to produce, such as the medically-important presenilin complex, we were able to significantly diminish the growth defect seen in the wild-type strain and improve the production yield of the presenilin variant PS1Δ9-H6 more than 4-fold.ConclusionsThe results shed light into a key, and perhaps central, membrane protein quality control mechanism in L. lactis. Modulating the expression of CesSR benefited the production yields of membrane proteins from different origins. These findings reinforce L. lactis as a legitimate alternative host for the production of membrane proteins.

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pSEUDO, a Genetic Integration Standard for Lactococcus lactis

Pinto

Zeyniyev²,

Karsens³

et al. 2011

Appl Environ Microbiol

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Plasmid pSEUDO and derivatives were used to show that llmg_pseudo_10 in Lactococcus lactis MG1363 and its homologous locus in L. lactis IL1403 are suitable for chromosomal integrations. L. lactis MG1363 and IL1403 nisin-induced controlled expression (NICE) system derivatives (JP9000 and IL9000) and two general stress reporter strains (NZ9000::PhrcA-GFP and NZ9000::PgroES-GFP) enabling in vivo noninvasive monitoring of cellular fitness were constructed.

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Contribution of the CesR-regulated genes llmg0169 and llmg2164-2163 to Lactococcus lactis fitness

Roces¹,

Campelo²,

Veiga³

et al. 2009

International Journal of Food Microbiology

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Lactococcus lactis is one of the main components of the starter cultures used in cheese manufacture. As starter, L. lactis must tolerate harsh conditions encountered either during their production in bulk quantities or during dairy products processing. To face these hostile conditions, bacteria monitor the environment and respond by modifying gene expression appropriately. Previous transcriptomic studies showed that the two component system CesSR is the main pathway that triggers the cell envelope stress response in L. lactis treated with lactococcin 972 (Lcn972), a cell wall synthesis inhibiting bacteriocin. Among the CesR-regulated genes, llmg0169 and the operon llmg2164-2163, encoding proteins of unknown function, are among the highest up-regulated genes after activation of CesSR. In this study, we have assessed the contribution of these genes to the survival of L. lactis to different technologically-relevant stresses. Overexpressing and knock-out mutants of the genes were generated and their viability to low pH, heat, freeze-drying, presence of NaCl, cell wall antimicrobials and lytic phages attack was compared to the wild type strain. The genes llmg0169 and llmg2164-2163 contributed differently to L. lactis fitness. L. lactis Deltallmg0169 was very sensitive to heat treatment while L. lactis Deltallmg2164 was more sensitive to NaCl. Absence of both genes also compromised viability at low pH. On the contrary, higher expression levels of llmg0169 and llmg2164-2163, up to 26- and 14-fold increase determined by qRT-PCR, respectively, did not enhance L. lactis survival in any of the above stressful conditions (heat, pH and NaCl) or after freeze-drying. All the mutants displayed a similar phage susceptibility profile. Overexpression of llmg2164-2163 seemed to specifically protect L. lactis against the bacteriocin Lcn972 but not against other cell wall active antimicrobials. Based on our phenotypic analysis, the investigated genes are required to mount a proper response to guarantee survival of L. lactis under technologically-relevant stresses and their functionality could be a useful marker to select robust dairy starters.

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High-Resolution Chrono-Transcriptome of Lactococcus lactis Reveals That It Expresses Proteins with Adapted Size and pI upon Acidification and Nutrient Starvation

Pinto

Brouwer

Zeyniyev

et al. 2022

Appl Environ Microbiol

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This data set is a rich resource for microbiologists interested in common mechanisms of gene expression, regulation and in particular the physiology of L. lactis . Thus, similar to the common use of genome sequence data by the scientific community, the data set constitutes an extensive data repository for mining and an opportunity for bioinformaticians to develop novel tools for in-depth analysis.

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Joao P. C. Pinto

Efficient Overproduction of Membrane Proteins in Lactococcus lactis Requires the Cell Envelope Stress Sensor/Regulator Couple CesSR

pSEUDO, a Genetic Integration Standard for Lactococcus lactis

Contribution of the CesR-regulated genes llmg0169 and llmg2164-2163 to Lactococcus lactis fitness

High-Resolution Chrono-Transcriptome of Lactococcus lactis Reveals That It Expresses Proteins with Adapted Size and pI upon Acidification and Nutrient Starvation

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