Margarine is a common replacement for butter. As a water-in-oil emulsion, margarine needs emulsifiers to homogenize oil with its water-soluble components. However, to keep up with the worldwide trend of clean label, usage of food additives should be reduced. Using lipases (triacylglycerol acylhydrolases) to produce monoglyceride and diglyceride to replace chemical emulsifiers may be a novel solution. Nevertheless, most lipase-producing microorganisms are not generally recognized as safe (GRAS) and are not allowed in food products. Thus, in the present study, we aim to screen lipase-producing GRAS microorganisms to reduce the usage of food additives in margarine processing. First, 46 isolates from butter and 124 isolates from kefir and Camembert cheese were pre-selected for their emulsion activity by oil spreading assay. We identified 25 Gram-positive bacteria and 58 yeasts with emulsifying activities. We further typed these isolates using Enterobacterial repetitive intergenic consensus polymerase chain reaction (ERIC-PCR) and kept 18 Gram-positive bacteria and 17 yeasts as representative strains. After typing, we screened the crude lipases of the Gram-positive bacteria by their lipase activities with titration method. As a result, bacteria strains B043 and B013 showed the highest activities, 40.67±2.40 U/mL and 32.67±13.91 U/mL, respectively. We also tested the enzymatic activities of the yeasts with the API ZYM kit and quantified the lipase activities of 10 positive strains with lipase activity kit. Lipase activities of yeast strains CC11 (82.13±7.84 U/L) and CC05 (39.93±9.05 U/L) showed no significant difference when compared to the 0.58% commercial lipase (61.80±21.24 U/L) used for commercial margarine production (P>0.05). In summary, two bacteria and two yeasts were chosen for further investigation by their lipase activities. We identified the 2 bacteria using 16S rRNA gene and housekeeping gene analysis. The sequence analysis-based phylogenetic tree constructed by the neighbor-joining method confirmed isolate B043 as Leuconostoc pseudomesenteroides with 100% pheS and rpoA gene sequence similarity and confirmed isolate B013 as Lactobacillus plantarum subsp. plantarum with 100% and 93% pheS gene and rpoA gene sequence similarity, respectively. We also identified the 2 yeasts using internal transcribed spacers 1, 5.8S rRNA, and internal transcribed spacers 2 (ITS1-5.8S-ITS2) region sequence analysis, which confirmed isolate CC05 as Yarrowia lipolytica with 100% sequence similarity and confirmed isolate CC11 as Candida cylindracea with 100% sequence similarity. These strains are all generally recognized as safe (GRAS). We further compared the crude lipases from the four selected strains with 0.58% commercial lipase on their hydrolyzing abilities with acid value analysis in palm oil to ensure that they could be applied in margarine production. While 0.58% commercial lipase had the highest acid value (53.77±4.44 mg KOH/g), Y. lipolytica CC05 had the highest acid value (5.58±0.77 mg KOH/g) among the four microorganisms (P<0.05). We also assessed their monoglyceride and diglyceride producing abilities with thin-layer chromatography (TLC) and column chromatography. Components of hydrolyzed product by crude lipase from Y. lipolytica CC05 were 85.21% triglyceride, 10.66% diglyceride, and 1.31% monoglyceride. These results showed the potential of Y. lipolytica CC05 as an emulsifier producer. In the future, we will further enhance the production and activity of the lipase from Y. lipolytica CC05 by optimizing culture condition and purifying the enzyme. The final aim of this study is to develop a novel lipase that could be applied in margarine production to reduce its usage of food additives, keeping pace with the clean label world trend.