Identification and characterization of potential probiotic lactic acid bacteria isolated from pig feces at various production stages.

Lactic acid bacteria (LAB) were isolated, identified, and characterized from pig feces at various growth stages and feed rations in order to be used as probiotic feed additives. Lactic acid bacteria numbers ranged from 7.10 ± 1.50 to 9.40 log CFUs/g for growing and lactating pigs, respectively. Isolates (n = 230) were identified by (GTG)5-polymerase chain reaction and partial sequence analysis of 16S rRNA. Major LAB populations were Limosilactobacillus reuteri (49.2%), Pediococcus pentosaceus (20%), Lactobacillus amylovorus (11.4%), and L. johnsonii (8.7%). In-vitro assays were performed, including surface characterization and tolerance to acid and bile salts. Several lactobacilli exhibited hydrophobic and aggregative characteristics and were able to withstand gastrointestinal tract conditions. In addition, lactobacilli showed starch- and phytate-degrading ability, as well as antagonistic activity against Gram-negative pathogens and the production of bacteriocin-like inhibitory substances. When resistance or susceptibility to antibiotics was evaluated, high phenotypic resistance to ampicillin, gentamicin, kanamycin, streptomycin, and tetracycline and susceptibility towards clindamycin and chloramphenicol was observed in the assayed LAB. Genotypic characterization showed that 5 out of 15 resistance genes were identified in lactobacilli; their presence did not correlate with phenotypic traits. Genes erm(B), strA, strB, and aadE conferring resistance to erythromycin and streptomycin were reported among all lactobacilli, whereas tet(M) gene was harbored by L. reuteri and L. amylovorus strains. Based on these results, 6 probiotic LAB strains (L. reuteri F207R/G9R/B66R, L. amylovorus G636T/S244T, and L. johnsonii S92R) can be selected to explore their potential as direct feed additives to promote swine health and replace antibiotics.

Des bactéries lactiques (LAB) ont été isolées, identifiées et caractérisées à partir de matières fécales de porc à différents stades de croissance et de rations alimentaires afin d'être utilisées comme additifs alimentaires probiotiques. Le nombre de bactéries lactiques variait de 7,10 ± 1,50 à 9,40 log UFC/g pour les porcs en croissance et en lactation, respectivement. Les isolats (n = 230) ont été identifiés par réaction d'amplification en chaîne par la (GTG)5-polymérase et analyse partielle de la séquence de l'ARNr 16S. Les principales populations de LAB étaient Limosilactobacillus reuteri (49,2 %), Pediococcus pentosaceus (20 %), Lactobacillus amylovorus (11,4 %) et L. johnsonii (8,7 %). Des tests in vitro ont été effectués, y compris la caractérisation de surface et la tolérance aux acides et aux sels biliaires. Plusieurs lactobacilles présentaient des caractéristiques hydrophobes et agrégatives et étaient capables de résister aux conditions du tractus gastro-intestinal. De plus, les lactobacilles ont montré une capacité de dégradation de l'amidon et des phytates, ainsi qu'une activité antagoniste contre les agents pathogènes à Gram négatif et la production de substances inhibitrices de type bactériocine. Lorsque la résistance ou la sensibilité aux antibiotiques a été évaluée, une résistance phénotypique élevée à l'ampicilline, à la gentamicine, à la kanamycine, à la streptomycine et à la tétracycline et une sensibilité à la clindamycine et au chloramphénicol ont été observées dans les LAB testés. La caractérisation génotypique a montré que cinq gènes de résistance sur 15 ont été identifiés dans les lactobacilles; leur présence n'était pas corrélée aux traits phénotypiques. Les gènes erm(B), strA, strB et aadE conférant une résistance à l'érythromycine et à la streptomycine ont été signalés parmi tous les lactobacilles, tandis que le gène tet(M) était hébergé par les souches L. reuteri et L. amylovorus. Sur la base de ces résultats, six souches probiotiques LAB (L. reuteri F207R/G9R/B66R, L. amylovorus G636T/S244T et L. johnsonii S92R) peuvent être sélectionnées pour explorer leur potentiel en tant qu'additifs alimentaires directs pour promouvoir la santé des porcs et remplacer les antibiotiques.(Traduit par Docteur Serge Messier).

Safety and Growth Optimization of Lactic Acid Bacteria Isolated From Feedlot Cattle for Probiotic Formula Design.

In order to eliminate the widespread use of antibiotics in livestock production, the research for alternatives has increased lately. This study examined the safety of 40 lactic acid bacteria (LAB) isolated from bovine feedlot environment and previously selected as potential probiotics. A high sensitivity prevalence to ampicillin (AMP, 100%), gentamicin (GEN, 96.3%), kanamycin (KAN, 96.3%), clindamycin (CLI, 85.2%), chloramphenicol (CHL, 92.6%) and streptomycin (STR, 88.9%) while moderate and high resistance against erythromycin (ERY, 48%) and tetracycline (TET, 79%) respectively, were determined. Feedlot enterococci and pediococci displayed high resistance to CLI, ERY, GEN and TET (73, 100, 54.5, and 73%, respectively). Among fifteen resistance genes investigated, seven were identified in lactobacilli; their presence not always was correlated with phenotypic resistance. STR resistance genes, aadA and ant(6) were observed in 7.4 and 3.7% of isolates, respectively; genes responsible for aminoglycosides resistance, such as bla (7.4%), and aph(3")-III (3.7%) were also recognized. In addition, resistance cat and tetS genes (3.7 and 7.4%, respectively) were harbored by feedlot lactobacilli strains. The presence of ermB gene in 22.3% of isolates, including two of the six strains phenotypically resistant to ERY, exhibited the highest prevalence among the assessed antibiotics. None of the feedlot lactobacilli harbored virulence factors genes, while positive PCR amplification for ace, agg, fsrA, and atpA genes was found for enterococci. With the objective of producing large cell biomass for probiotic delivery, growth media without peptone but containing glucose and skim milk powder (Mgl and Mlac) were selected as optimal. Lactobacillus acidophilus CRL2074, L. amylovorus CRL2115, L. mucosae CRL2069, and L. rhamnosus CRL2084 were strains selected as free of antibiotic resistance and virulence determinants, able to reach high cell numbers in non-expensive culture media and being compatible among them.