Expression in Escherichia coli of a secreted invertebrate ferritin.

The coding regions of the cDNAs for cytoplasmic soma ferritin and secreted yolk ferritin from the snail Lymnaea stagnalis were inserted into the prokaryotic expression vector pEMBLex2. The vector directed the synthesis in Escherichia coli of soma ferritin up to a concentration of 15% of soluble proteins. Soma ferritin was expressed as the multimeric protein (480 kDa). Its similarity with natural soma ferritin was confirmed by PAGE, immunostaining and electron microscopy. Yolk ferritin was expressed in the form of inclusion bodies. Attempts to refold and assemble the purified yolk ferritin subunit in vitro failed. The yolk ferritin coding sequence was therefore inserted into the expression vector pMAL-p2. At a growth temperature of the bacterial cells of 23 degrees C and at an isopropyl beta-D-thiogalactopyranoside concentration of 50 microM, about 5% of the induced MalE-yolk-ferritin fusion protein was secreted into the periplasmic space and could be purified by affinity chromatography on amylose; the rest occurred as insoluble cytoplasmic inclusion bodies. Soluble MalE-yolk-ferritin fusion protein was capable of assembly into ferritin-like particles. Fully assembled yolk apoferritin shells (610 kDa) were obtained by digestion of these particles with proteinase K (yield: 180 micrograms yolk ferritin/l bacterial culture). Recombinant yolk ferritin was capable of taking up iron in vitro. Yolk ferritin (610 kDa) and soma ferritin (480 kDa) were run to the pore limit of a non-denaturing 5-20% PAGE gradient gel. Under these conditions, yolk ferritin had a higher mobility than soma ferritin (480 kDa) and therefore the yolk ferritin may have a rather compact structure. A 41-amino-acid-residue stretch of the insertion, a distinctive feature of the yolk ferritin subunit, was deleted by site-directed mutagenesis. The MalE-yolk-ferritin variant thus obtained was readily degradable by proteinase K and could not be assembled into ferritin-like particles. Therefore residues in the deleted peptide must be important for the maintenance of the native structure.

cDNA cloning and deduced amino acid sequence of two ferritins: soma ferritin and yolk ferritin, from the snail Lymnaea stagnalis L.

Pulmonate freshwater snails contain two different ferritin types, soma ferritin and yolk ferritin. A cDNA library was constructed from midgut gland poly(A)-rich RNA of the snail Lymnaea stagnalis L. and recombinant clones encoding both ferritin types were obtained by immunoscreening. The longest cDNA inserts had a length of 859 bp (soma ferritin) and 1548 bp (yolk ferritin) and the specificity of these inserts was confirmed by immunoprecipitation of both ferritin types translated in vitro from hybrid-selected mRNAs. The 5' untranslated region (UTR) of the soma ferritin mRNA contains a 28-bp element which shows 64% sequence identity with the iron-responsive element (IRE) of vertebrate ferritin mRNAs. The soma ferritin mRNA is strongly translated in the wheat germ system but poorly translated in rabbit reticulocyte lysate. The yolk ferritin mRNA, which contains no IRE, is equally well translated in both in vitro translation systems. The deduced amino acid sequence of the soma ferritin subunit (174 amino acid residues, M(r) 20140) shows 50-70% sequence identity with subunits of vertebrate ferritins. After removal of an 18-amino-acid-residue signal sequence the deduced protein sequence of yolk ferritin contains 221 amino acids (M(r) 25438). Sequence identity of this chain with other eukaryotic ferritin chains is only 31-42%. Both snail ferritin sequences are more similar to the H-subunit type of vertebrate ferritins than to the L-type and both have the H-specific amino acid residues of the ferroxidase centre. The yolk ferritin sequence has a 42-amino-acid-residue insertion predicted to reside in the L loop of the subunit.

Structure, function, and evolution of ferritins.

The ferritins of animals and plants and the bacterioferritins (BFRs) have a common iron-storage function in spite of differences in cytological location and biosynthetic regulation. The plant ferritins and BFRs are more similar to the H chains of mammals than to mammalian L chains, with respect to primary structure and conservation of ferroxidase center residues. Hence they probably arose from a common H-type ancestor. The recent discovery in E. coli of a second type of iron-storage protein (FTN) resembling ferritin H chains raises the question of what the relative roles of these two proteins are in this organism. Mammalian L ferritins lack ferroxidase centers and form a distinct group. Comparison of the three-dimensional structures of mammalian and invertebrate ferritins, as well as computer modeling of plant ferritins and of BFR, indicate a well conserved molecular framework. The characterisation of numerous ferritin homopolymer variants has allowed the identification of some of the residues involved in iron uptake and an investigation of some of the functional differences between mammalian H and L chains.