Genetically engineered bacteria, pharmaceutical compositions thereof, and methods of modulating and treating diseases associated with hyperphenylalaninemia are disclosed.

The present application provides an immobilized enzyme, a preparation method therefor and an application thereof. The immobilized enzyme includes an epoxy resin carrier and an enzyme, the enzyme and the epoxy resin carrier are linked by a covalent bond, and the epoxy resin carrier is an LX-109S epoxy resin. The LX-109S epoxy resin is used as the epoxy resin carrier in the present application, such that on the basis of characteristics of the carrier itself, an immobilization effect of the carrier on the enzyme is more stable, and covalent bonding with the enzyme is firm without affecting the activity of the enzyme itself.

An aspect provides a method of increasing efficiency of somatic cell nuclear transfer using a substance (RS-1) increasing Rad51 activity, and a somatic cell nuclear transfer cell prepared according to the method. Another aspect provides a method of screening for a substance increasing Rad51 activity to increase efficiency of somatic cell nuclear transfer. When the substance increasing Rad51 activity is used, efficiency of somatic cell nuclear transfer may be increased.

The present invention generally relates to methods of biological reduction of metal-cyanide complexes after metal-cyanidation and methods of biologically hydrolysing cyanide. More particularly, the present invention allows the engineering of an integrated synthetic lixiviant biological system to be housed within a synthetic host (such as the cyanogenic Chromobacterium violaceum) for efficient precious metal recovery and toxic metal remediation of electronic waste; with up to four main components/modules in the design and engineering of the synthetic host: 1) synthetic cyanogenesis; 2) synthetic metal recovery; 3) synthetic cyanolysis; and 4) synthetic circuits for lixiviant biology. Bacteria capable of reducing ionic metal to ionic metal (such as gold or silver) as nanoparticles, comprising mercury(11) reductase (MerA) comprising a substitution mutation at position V317, Y441, C464, A323D, A414E, G415I, E416C, L417I, I418D, or A422N, are also disclosed. Processes of synthetic cyanide lixiviant production using genetically engineered bacterium transformed with a heterologous hydrogen cyanide synthase gene and a heterologous 3-phosphoglycerate dehydrogenase mutant gene are also disclosed. Processes of synthetic cyanolysis using a genetically engineered bacterium transformed with a heterologous nitrilase gene are also disclosed.

The present invention relates to a genetically engineered microorganism expressing (i) formate tetrahydrofolate (THF) ligase, methenyi-THF cyclohydrolase and methylene-THF dehydrogenase, (ii) the enzymes of the glycine cleavage system (GCS), (iii) serine deaminase and serine hydroxymethyltransferase (SHMT), (iv) an enzyme increasing the availability of NADPH, and (v) optionally formate dehydrogenase (FDH), and wherein the genetically engineered microorganism has been genetically engineered to express at least one of the enzymes of (i) to (v), wheren said enzyme is not expressed by the corresponding microorganism that has been used to prepare the genetically engineered microorganism, and wherein the enzymes of (i) to (v) are genomically expressed.