The properity of medium-chain-length polyhydroxyalkanoates (MCL-PHAs) possessing flexibility and elasticity are potentially used in cardiovascular, soft tissue engineering and drug delivery. This study investigated the PHA biosynthestic pathways of high-yield medium-chain-length PHAs producing strain Pseudomonas mosselii TO7. P. mosselii TO7 can produce PHA at a yield of more than 45% of its dry weight in mineral salt medium containing 0.5% octanoic acid and 1g/L (NH4)2SO4 after 40 hours incubation. The 3-hydroxyoctanoate monomer produced by shake flask cultivation in one stage made up 95% of the polymer composition. Initial culture medium pH level of 9 lead to increased PHA biosynthesis. P. mosselii TO7 can utilize palm kernel oil or soybean oil to produce PHA, however, using palm kernel oil having relatively higher crystallinity. The inhibitors studies including acrylic acid and 2-bromooctanoic acid indicated that β-oxidation of fatty acids is mainly used to synthesize PHA in P. mosselii TO7. Two class II PHA polymerase genes phaC1Pm and phaC2Pm of P. mosselii TO7 were heteroexpression in PHA-negative mutant P. putida GPp104 PHA-. The result demonstrated that when P. mosselii TO7 used 8-12 carbon fatty acids as a carbon source, the main enzyme was PhaC1Pm. The (R)-specific enoyl-CoA hydratase from P. mosselii TO7 (PhaJ4Pm) was identified, owing to (R)-specific enoyl-CoA hydratase play an important role for PHA biosynthesis from fatty acids in microorganism. Hetereoexpression of PhaJ4Pm in Escherichia coli LS5218 when feeding 12 carbon fatty acids, the result showed increased PHAs production and 3-hydroxyoctanoate monomer composition of PHA. Similar results also have appeared in P. mosselii TO7 when overexpression of PhaJ4Pm used 8 carbon fatty acids as a sole carbon source. Analysis of PhaJ4Pm enzyme activity using trans-2-octenoyl-CoA confirmed that PhaJ4Pm functions as a hydrase. A coupling reaction between PhaJ4Pm and PHA polymerase 1 from P. putida GPo1 (PhaC1Pp) displayed the PhaJ4-catalyzed products with R-specific stereospecificity. Our previous study indicated that class II PHA polymerase PhaC1Pp at mutation at L484V may affect the substrate specificity of enzyme. To explain substrate-specific related amino acid residue in class II PHA polymerase, PhaC1Pp was used. Saturation mutagenesis at residue leucine 484 in PhaC1Pp confirmed when the wild type leucine was switched with valine, a change in substrate-specificity was most significant. Constructing 3D enzyme models showed the amino acid residues at 481, 482, and 484 may influence PHA biosynthesis due to close to the enzyme catalytic residue His479. This study explores the characteristics of PHA produced from P. mosselii TO7, the effects of PhaC1Pm, PhaC2Pm and PhaJ4Pm on PHA biosynthesis, and providing analysis of substrate-specific related amino acid residue in a class II PHA polymerase PhaC1 Pp.