Cloning and expression in Escherichia coli of secondary lymphoid-tissue chemokine (SLC) gene / 生物工程学报

Secondary lymphoid-tissue chemokine (SLC) is a type of CC chemokine identified by searching the Expressed Sequence Tag (EST) database. The full-length SLC gene was synthesized based on human SLC sequence using SOE-PCR. The sequenced SLC gene was cloned into expression vector pTMF and pALM, which used to transform Escherichia coli. Then the E. coli was cultured and induced according to protocol. The expressed target protein was identified by Western blotting. The target protein was expressed as soluble protein as well as inclusion bodies, the ratio of these two forms target protein varied with the difference conditions of culture and induction. The target protein was purified with the methods of nickel-nitrilotriacetic acid (Ni-NTA) metal-affinity chromatography. The results of electrophoresis of the purified target protein showed that the molecular weight was larger than the predicted molecular weight.

Studies of the expression, purification, renaturation and biologic activity of an anti-CEA immunotoxin / 生物工程学报

A recombinant immunotoxin named CEA/PE38/KDEL was constructed, which was composed of anti-CEA single-chain Fv and the truncated and modified form of Pseudomonas exotoxin (PE38/KDEL). The CEA/PE38/KDEL immunotoxin was expressed in the E. coli strain BL21 (DE3)-star as inclusion bodies. The denatured inclusion bodies were purified with Ni-NTA chelate agarose, then the constant gradient dialysis was used to perform the refolding of the CEA/PE38/KDEL immunotoxin. Results of FACS and MTT assay indicate that the refolded immunotoxins keep potent and specific cytotoxicity to tumor cells bearing CEA antigens.

Protein splicing and its application / 生物工程学报

Protein splicing is a newly discovered posttranslational editing process that removes an internal protein fragment from the protein precursor. During the splicing process the internal protein fragment, intein, triggered the self-excision from the precursor protein and the concomitant ligation of the flanking protein fragments, exteins. The self-catalysis requires neither auxiliary enzymes nor cofactors and only involves four intramolecular reactions. A number of key catalytic residues in inteins and flanking fragments have been identified, which led to the development of the protein splicing process as a protein engineering tool. Controllable cleavage of the peptide bond at either the N or the C terminus of an intein has allowed the design of novel strategies for manipulation of protein and peptides. Affinity purification of recombinant proteins can be facilitated by fusion the target protein with an intein. The fusion also creates C-terminal thioester, which expands the scope of chemical ligation in protein. Inteins can be engineered in a "split and inverted" configuration to form a cyclic polypeptide consisting of the sequence linking two intein subdomains. This article summarizes the recent advance in the mechanism of protein splicing and its applications in protein purification, protein ligation and protein cyclization.

Escherichia coli disulfide-forming related proteins: structures, functions and their application in gene engineering for expressing heterologous proteins in Escherichia coli / 生物工程学报

The formation of disulfide bonds in secreted proteins of E. coli is a synergetic process depending on a series of Dsb proteins containing DsbA, DsbB, DsbC, DsbD, DsbE and DsbG. DsbA functions as an oxidant to form a disulfide bond between two -SH- in vivo and DsbB reactivates DsbA by reoxidizing it. Both DsbC and DsbG, two periplasmic proteins with isomerase activity, can correct mis-paired disulfide bonds introduced by DsbA although they recognize different substrates. DsbD, an inner membrane protein, plays a role in reducing DsbC and DsbG in vivo. It is regarded that DsbE has the similar function with DsbD. All DsbA, DsbC and DsbG have chaperone activity besides involving in the formation of disulfide bonds. Furthermore, their chaperone activity can promote the formation of protein disulfide bonds. There are a few reports dealing with soluble expression of heterologous proteins containing disulfide bonds assisted by DsbA and DsbC in E. coli. So far there has been no reports about the soluble expression of heterologous proteins promoted by DsbG. Our experiments first demonstrated that both DsbC and DsbG can improve the expression of single chain antibodies as soluble and functional forms in E. coli, and DsbG has additive effects with DsbC.