Abstract: Compounds, called liamocins from Aureobasidium pullulans, having the general structure in Formula 1 are disclosed. where R1 is either COCH3 or H; and R2 is between two to ten O-linked 3,5-dihydroxydecanoate; and R3 can be a polyol (e.g., L- or D-glycerol, L- or D-threitol, L- or D-erythritol, L- or D-arabitol, L- or D-xylitol, L- or D-lyxitol, L- or D-ribitol, L- or D-allitol, L- or D-altritol, L- or D-mannitol, L- or D-iditol, L- or D-gulitol, L- or D-glucitol (also called sorbitol), L- or D-galactitol (also called dulcitol), and L- or D-talitol), 2-amino-D-mannitol, 2N-acetylamino-D-mannitol, L-rhamnitol, or D-fucitol; except when R3 is D-mannitol, R2 is not 2 nor 3 O-linked 3,5-dihydroxydecanoate chains. These liamocins described above in addition to D-mannitol liamocin A1, D-mannitol liamocin A2, D-mannitol liamocin B1, and D-mannitol liamocin B2, alone or in combination with each other, can be used to kill certain bacteria and to treat certain bacterial infections.

Abstract: Compounds, called liamocins from Aureobasidium pullulans, having the general structure in Formula 1 are disclosed. where R1 is either COCH3 or H; and R2 is between two to ten O-linked 3,5-dihydroxydecanoate; and R3 can be a polyol (e.g., L- or D-glycerol, L- or D-threitol, L- or D-erythritol, L- or D-arabitol, L- or D-xylitol, L- or D-lyxitol, L- or D-ribitol, L- or D-allitol, L- or D-altritol, L- or D-mannitol, L- or D-iditol, L- or D-gulitol, L- or D-glucitol (also called sorbitol), L- or D-galactitol (also called dulcitol), and L- or D-talitol), 2-amino-D-mannitol, 2N-acetylamino-D-mannitol, L-rhamnitol, or D-fucitol; except when R3 is D-mannitol, R2 is not 2 nor 3 O-linked 3,5-dihydroxydecanoate chains. These liamocins described above in addition to D-mannitol liamocin A1, D-mannitol liamocin A2, D-mannitol liamocin B1, and D-mannitol liamocin B2, alone or in combination with each other, can be used to kill certain bacteria and to treat certain bacterial infections.

Abstract: Novel compounds, called liamocins from Aureobasidium pullulans, having the general structure in Formula 1 are disclosed. where R1 is either COCH3 or H; and R2 is between two to ten O-linked 3,5-dihydroxydecanoate; and R3 can be a polyol (e.g., L- or D-glycerol, L- or D-threitol, L- or D-erythritol, L- or D-arabitol, L- or D-xylitol, L- or D-lyxitol, L- or D-ribitol, L- or D-allitol, L- or D-altritol, L- or D-mannitol, L- or D-iditol, L- or D-gulitol, L- or D-glucitol (also called sorbitol), L- or D-galactitol (also called dulcitol), and L- or D-talitol), 2-amino-D-mannitol, 2N-acetylamino-D-mannitol, L-rhamnitol, or D-fucitol; except when R3 is D-mannitol, R2 is not 2 nor 3 O-linked 3,5-dihydroxydecanoate chains. These liamocins described above in addition to D-mannitol liamocin A1, D-mannitol liamocin A2, D-mannitol liamocin B1, and D-mannitol liamocin B2, alone or in combination with each other, can be used to kill certain bacteria and to treat certain bacterial infections.

Abstract: Novel compounds, called liamocins from Aureobasidium pullulans, having the general structure in Formula 1 are disclosed. where R1 is either COCH3 or H; and R2 is between two to ten O-linked 3,5-dihydroxydecanoate; and R3 can be a polyol (e.g., L- or D-glycerol, L- or D-threitol, L- or D-erythritol, L- or D-arabitol, L- or D-xylitol, L- or D-lyxitol, L- or D-ribitol, L- or D-allitol, L- or D-altritol, L- or D-mannitol, L- or D-iditol, L- or D-gulitol, L- or D-glucitol (also called sorbitol), L- or D-galactitol (also called dulcitol), and L- or D-talitol), 2-amino-D-mannitol, 2N-acetylamino-D-mannitol, L-rhamnitol, or D-fucitol; except when R3 is D-mannitol, R2 is not 2 nor 3 O-linked 3,5-dihydroxydecanoate chains. These liamocins described above in addition to D-mannitol liamocin A1, D-mannitol liamocin A2, D-mannitol liamocin B1, and D-mannitol liamocin B2, alone or in combination with each other, can be used to kill certain bacteria and to treat certain bacterial infections.

Abstract: The present disclosure is directed to methods for producing butyric acid comprising fermenting a lignocellulosic biomass hydrolysate using C. tyrobutyricum strain RPT-4213 under anaerobic conditions using dilute acid-pretreated hydrolysates of wheat straw, corn fiber, corn stover, rice hull, and switchgrass, for example.

Abstract: Ethanol losses due to bacterial contamination in fermentation cultures weakens the economics of biofuel production. Lactobacillus species are the predominant contaminant. Bacteriophage lytic enzymes are peptidoglycan hydrolases which degrade Gram positive cell walls when exposed externally and are a novel source of antimicrobials. The streptococcal phage ?SA2 endolysin construct demonstrated strong lytic activity towards 17 of 22 strains of lactobacilli, staphylococci or streptococci maintaining optimal specific activity under fermentation conditions toward L. fermentum substrates. Lactobacillus bacteriophage endolysin constructs LysA, LysA2 and LysgaY showed exolytic activity towards ˜60% of the lactobacilli tested including four L. fermentum isolates from fuel ethanol fermentations. Presence of ethanol (?5%) did not affect lytic activity. Lysins were able to reduce both L. fermentum and L. reuteri contaminants in mock fermentations of corn fiber hydrolysates.

Abstract: The present invention relates to an isolated Lactobacillus paracasei bacterium, deposited as NRRL B-50314, that secretes a bacteriocin. More specifically, the bacteriocin has antibacterial activity against a range of Gram-positive bacteria, including but not limited to Listeria monocytogenes, Staphylococcus aureus, Enterococcus faecalis, and other Lactobacillus species. Additionally, the bacteriocin has antibacterial activity against methicillin resistant Staphylococcus aureus.