about
Draft genome sequence of Enterococcus mundtii CRL1656Taxonomic Identity Resolution of Highly Phylogenetically Related Strains and Selection of Phylogenetic Markers by Using Genome-Scale Methods: The Bacillus pumilus Group CaseExpression of the agmatine deiminase pathway in Enterococcus faecalis is activated by the AguR regulator and repressed by CcpA and PTS(Man) systems.Genomic comparative analysis of the environmental Enterococcus mundtii against enterococcal representative species.Draft Genome Sequence of Lactococcus lactis subsp. lactis bv. diacetylactis CRL264, a Citrate-Fermenting Strain.Draft Genome Sequences of Four Enterococcus faecium Strains Isolated from Argentine Cheese.Enterococcus faecalis Uses a Phosphotransferase System Permease and a Host Colonization-Related ABC Transporter for Maltodextrin Uptake.Functional Analysis of the Citrate Activator CitO from Enterococcus faecalis Implicates a Divalent Metal in Ligand Binding.Oral immunization with live Lactococcus lactis expressing rotavirus VP8 subunit induces specific immune response in mice.CcpA-independent regulation of expression of the Mg2+ -citrate transporter gene citM by arginine metabolism in Bacillus subtilis.Biochemical and genetic characterization of the Enterococcus faecalis oxaloacetate decarboxylase complex.Acid-inducible transcription of the operon encoding the citrate lyase complex of Lactococcus lactis Biovar diacetylactis CRL264.Aroma compounds generation in citrate metabolism of Enterococcus faecium: Genetic characterization of type I citrate gene cluster.Genome sequence of the bacteriocin-producing Lactobacillus curvatus strain CRL705.Ca2+-citrate uptake and metabolism in Lactobacillus casei ATCC 334.Activation of the diacetyl/acetoin pathway in Lactococcus lactis subsp. lactis bv. diacetylactis CRL264 by acidic growth.Multivariate analysis of organic acids in fermented food from reversed-phase high-performance liquid chromatography data.Enzymes Required for Maltodextrin Catabolism in Enterococcus faecalis Exhibit Novel Activities.A chimeric vector for efficient chromosomal modification in Enterococcus faecalis and other lactic acid bacteria.Genome mining of lipolytic exoenzymes from Bacillus safensis S9 and Pseudomonas alcaliphila ED1 isolated from a dairy wastewater lagoon.Identification of malic and soluble oxaloacetate decarboxylase enzymes in Enterococcus faecalis.Disruption of the alsSD operon of Enterococcus faecalis impairs growth on pyruvate at low pH.Catabolite repression of the citST two-component system in Bacillus subtilis.Safety assessment and functional properties of four enterococci strains isolated from regional Argentinean cheeseGenetic and phenotypic features defining industrial relevant Lactococcus lactis, L. cremoris and L. lactis biovar. diacetylactis strainsProduction of human growth hormone by Lactococcus lactisImplications of the expression of Enterococcus faecalis citrate fermentation genes during infectionGenetic Engineering of Co-producing Antigen and the Mucosal Adjuvant 3' 5'- cyclic di Adenosine Monophosphate (c-di-AMP) as a Design Strategy to Develop a Mucosal Vaccine PrototypeBiogenic amines in fermented foodsα-Acetolactate synthase of Lactococcus lactis contributes to pH homeostasis in acid stress conditionsGeM-Pro: a tool for genome functional mining and microbial profilingEnterococcus faecalis MalR acts as a repressor of the maltose operons and additionally mediates their catabolite repression via direct interaction with seryl-phosphorylated-HPrThe KupA and KupB Proteins of Lactococcus lactis IL1403 Are Novel c-di-AMP Receptor Proteins Responsible for Potassium UptakeDiversity of volatile organic compound production from leucine and citrate in Enterococcus faecium
P50
Q24611102-8B49880C-BF45-4ADC-B404-3E5027DB9D34Q28829319-9BC9F605-BEB2-4C3F-A17B-87AE1308BEAFQ35025261-B149E3D6-879A-42F6-A3F1-741A5C58D612Q35190694-53380419-D8B1-4619-8436-B11A337BE8F9Q38265154-712A130F-ED3E-4EED-99B0-BE47EEFDD696Q38265159-BE80CBDC-C119-4C8E-9DE4-335BA922E0BDQ38288919-528249FA-DB93-4B6D-B89D-095E03A6B2E4Q38293349-46A67E1F-6E94-492B-9860-EA7214F07EA5Q39550884-1CB1139B-EC52-4C6E-A368-63A3045F98EDQ39705868-1FE0C5DD-5FC0-4809-9ACB-92EF262019B3Q39762115-A956AB96-31CA-46F5-ABE7-7404B7618B00Q40000428-BBB1B7E8-262F-4438-A8D1-F511FD39B09AQ40288950-6C50FD7E-F220-4B71-9499-FE24C256DE11Q40347691-07CC119A-F4B7-4572-BDB6-2E9B34810EA6Q41964854-24F82D54-487C-4AEA-9909-870ED6EFA482Q43111843-AAB9CB7E-1919-4EBA-AC36-BB869AB4494EQ47598137-C4AC9E6D-3AEF-4030-A867-6EBEAF5EC8BBQ47831259-D33A96E4-7852-4678-8735-4A5E99EEF10EQ50447483-C978EC38-8AD7-4E85-B5E8-ED79CDC7991DQ51716510-2433EFB9-F509-43F2-82B4-1564F0147278Q52610389-D41C1098-A280-4B52-B4CF-10E4ADE2F375Q52613162-56E73110-F489-4DE2-8F49-6230E4FA4564Q54459704-3B759C94-F788-4008-9DF4-EF2241DB8023Q57114400-B65B99AD-9D3E-44DE-AF92-D4A367648B89Q57154018-236EE972-8412-4539-ABFF-942367A13243Q57677319-81EBFD35-016C-4970-8F00-A731E25F19C2Q58601918-8B8CC30F-9ECB-42E4-9B8A-94A2119BFB2FQ58764447-E3BEEFCA-A134-46F9-BD50-34FCBB9740B4Q58900130-01FD1E0D-1465-4D4A-A55F-C284FFB803CEQ87517133-F7330840-0884-4642-AC4E-777B61F2F646Q91390718-FACFDF2A-C8DA-4368-8DCE-7DCF753D0D67Q91393098-0BFB0FA6-B143-48B6-95C0-9741C8634C2CQ91467479-42C6E929-B6DB-488B-BEA0-B03E2A7EB31AQ91903151-552517BB-8A27-4BA2-BD09-C74006E7647E
P50
description
Forscher
@de
investigador
@es
onderzoeker
@nl
researcher
@en
ricercatore
@it
研究員
@ja
研究者
@zh
name
Christian Magni
@en
Christian Magni
@nl
type
label
Christian Magni
@en
Christian Magni
@nl
prefLabel
Christian Magni
@en
Christian Magni
@nl
P106
P31
P496
0000-0002-5179-9700