Isolation and Expression Pattern Analysis of Two Ferritin Genes in Tobacco

For understanding of the ferritin gene expression pattern and the mechanism of iron homeostasis in tobacco (Nicotiana tabaccum L.) plants, two full-length ferritin cDNAs, NtFerl and NtFer2, were isolated from tobacco seedlings and characterized. These cDNAs are 1 214 and 1 125 bp nucleotides and encode 25 1 and 259 amino acid residues, respectively. The deduced amino acid sequences showed that two tobacco ferritins share the same characteristics as the plant ferritins from Arabidopsis, soybean, and maize.Southern blotting analysis indicated that both NtFerl and NtFer2 were probably multicopy genes in the tobacco genome. Northern blotting analysis indicated that iron loading of tobacco plantlets increased the ferritin mRNA abundance and that NtFerl expression was higher and more sensitive to iron than NtFer2expression. Furthermore, NtFerl was expressed in both leaves and roots, whereas NtFer2 was expressed mainly in leaves.     

转铁蛋白基因烟草中内源铁蛋白基因的差异表达及含铁量的变化

铁蛋白是一种由24个亚基组成的高分子贮藏蛋白质,可以储存多达4500个铁原子,在动植物及微生物的新陈代谢中起着非常重要的作用。有研究表明,外源铁蛋白的大量表达可以提高植物储存铁离子的能力。为了明确外源铁蛋白基因转化植物中内源铁蛋白基因差异表达与植物含铁量的关系,本研究在成功获得2个烟草铁蛋白基因的全长cDNA克隆NtFerl（登录号：ay083924）和NtFer2（登录号：ay141105）的基础上,以烟草品种SR-1（Nicotiana tabacum cv．Petit Havana SR-1）为受体,培育了转铁蛋白基因烟草。将双元载体pBI121中的GUS基因用来自大豆的铁蛋白基因SoyFer1（登录号：m64337）置换,利用农杆菌介导法转化烟草叶盘,获得在CaMV35S启动子驱动表达的大豆铁蛋白基因转化烟草植株。Northern杂交和Western杂交分析表明外源铁蛋白基因在转基因烟草中得到了正确表达。比较转基因烟草和非转基因烟草的内源铁蛋白基因表达强度、叶片铁含量、根系铁还原酶活性、株高和鲜重表明,外源铁蛋白基因不但促进了NtFer1的表达,提高转基因植株的储存铁的能力和根系铁还原酶活性,而且促进植株的生长速度。以上结果说明,外源铁蛋白基因转化烟草中内源铁蛋白基因的表达、铁离子的还原吸收及光和作用都得到了进一步的提高。     

Differential Expression of Endogenous Ferritin Genes and Iron Homeostasis Alteration in Transgenic Tobacco Overexpressing Soybean Ferritin Gene

For studying the effects of endogenous ferritin gene expressions (NtFer1, GenBank accession number ay083924; and NtFer2, GenBank accession number ay141105) on the iron homeostasis in transgenic tobacco (Nicotiana tabacum L.) plants expressing soybean (Glycine max Merr) ferritin gene (SoyFer1, GenBank accession number m64337), the transgenic tobacco has been produced by placing soybean ferritin cDNA cassette under the control of the CaMV 35S promoter. The exogenous gene expression was examined by both Northern- and Western-blot analyses. Comparison of endogenous ferritin gene expressions between nontransformant and transgenic tobacco plants showed that the expression of NtFer1 was increased in the leaves of transgenic tobacco plants, whereas the NtFer2 expression was unchanged. The iron concentration in the leaves of transgenic tobacco plants was about 1.5-folds higher than that in nontransformant. Enhanced growth of transgenic tobacco was observed at the early development stages, resulting in plant height and fresh weights significantly greater than those in the nontransformant. These results demonstrated that exogenous ferritin expression induced increased expression of at least one of the endogenous ferritin genes in transgenic tobacco plants by enhancing the ferric chelate reductase activity and iron transport ability of the root, and improved the rate of photosynthesis.     

烟草内源铁蛋白NtFer1和NtFer2的相互作用

以2个烟草铁蛋白基因全长序列（NtFer1和Mnr2,GenBank登录号：AY083924和AY141105）为基础,利用细菌双杂交系统分析不同烟草铁蛋白亚基之间及相同铁蛋白亚基之间的互作关系,并利用Northern杂交分析2个铁蛋白基因的特异表达。结果表明,铁蛋白基因NtFer1和Mnr2在叶片中均有表达,同时2种亚基之间存在很强的互作关系,说明在叶片中组成铁蛋白的24个亚基可能有3种类型,或来自单一的NtFer1亚基,或来自单一的NtFer2亚基,也可能来源于不同的铁蛋白亚基。在烟草根部组织中只有铁蛋白NtFer1基因大量表达,而MFPr2基因的表达非常微弱,所以根部的铁蛋白大分子可能由单一的铁蛋白NtFer1亚基聚合而成的。     

Molecular properties and immune defense of two ferritin subunits from freshwater pearl mussel,Hyriopsis schlegelii

Ferritin is a conserved iron-binding protein involved in cellular iron metabolism and host defense. In the present study, two distinct cDNAs for ferritins in the freshwater pearl mussel Hyriopsis schlegelii were identified (designated as HsFer-1 and HsFer-2) by SMART RACE approach and expressed sequence tag (EST) analysis. The full-length cDNAs of HsFer-1 and HsFer-2 were of 760 and 877 bp, respectively. Both of the two cDNAs contained an open reading frame (ORF) of 522 bp encoding for 174 amino acid residues. Sequence characterization and homology alignment indicated that HsFer-1 and HsFer-2 had higher similarity to H-type subunit of vertebrate ferritins than L-type subunit. Analysis of the HsFer-1 and HsFer-2 untranslated regions (UTR) showed that both of them had an iron response element (IRE) in the 5′-UTR, which was considered to be the binding site for iron regulatory protein (IRP). Quantitative real-time PCR (qPCR) assays were employed to examine the mRNA expression profiles. Under normal physiological conditions, the expression level of both HsFer-1 and HsFer-2 mRNA were the highest in hepatopancreas, moderate in gonad, axe foot, intestine, kidney, heart, gill, adductor muscle and mantle, the lowest in hemocytes. After stimulation with bacteria Aeromonas hydrophila, HsFer-1 mRNA experienced a different degree of increase in the tissues of hepatopancreas, gonad and hemocytes, the peak level was 2.47-fold, 9.59-fold and 1.37-fold, respectively. Comparatively, HsFer-2 showed up-regulation in gonad but down-regulation in hepatopancreas and hemocytes. Varying expression patterns indicate that two types of ferritins in H. schlegelii might play different roles in response to bacterial challenge. Further bacteriostatic analysis showed that both the purified recombinant ferritins inhibited the growth of A. hydrophila to a certain degree. Collectively, our results suggest that HsFer-1 and HsFer-2 are likely to be functional proteins involved in immune defense against bacterial infection.     

Molecular cloning, expression and characterization of cDNAs encoding the ferritin subunits from the beetle, Apriona germari

Insect secreted ferritins are composed of subunits, which resemble heavy and light chains of vertebrate cytosolic ferritins. We describe here the cloning, expression and characterization of cDNAs encoding the ferritin heavy-chain homologue (HCH) and light-chain homologue (LCH) from the mulberry longicorn beetle, Apriona germari (Coleoptera, Cerambycidae). The A. germari ferritin LCH and HCH cDNA sequences were comprised of 672 and 636 bp encoding 224 and 212 amino acid residues, respectively. The A. germari ferritin HCH subunit contained the conserved motifs for the ferroxidase center typical of vertebrate ferritin heavy chains and the iron-responsive element (IRE) sequence with a predicted stem-loop structure was present in the 5′-untranslated region (UTR) of ferritin HCH mRNA. However, the A. germari ferritin LCH subunit had no IRE at its 5′-UTR and ferroxidase center residues. Phylogenetic analysis confirmed the deduced protein sequences of A. germari ferritin HCH and LCH being divided into two types, G type (LCH) and S type (HCH). Southern blot analysis suggested the possible presence of each A. germari ferritin subunit gene as a single copy and Northern blot analysis confirmed a higher expression pattern in midgut than fat body. The cDNAs encoding the A. germari ferritin subunits were expressed as approximately 30 kDa (LCH) and 26 kDa (HCH) polypeptides in baculovirus-infected insect cells. Western blot analysis and iron staining assay confirmed that A. germari ferritin has a native molecular mass of approximately 680 kDa.     

Secreted ferritin subunits are of two kinds in insects molecular cloning of cDNAs encoding two major subunits of secreted ferritin from Calpodes ethlius

In insects, holoferritin is easily visible in the vacuolar system of tissues that filter the hemolymph and, at least in Lepidoptera, is abundant in the hemolymph. Sequences reported for insect secreted ferritins from Lepidoptera and Diptera have high sequence diversity. We examined the nature of this diversity for the first time by analyzing sequences of cDNAs encoding two ferritin subunits from one species, Calpodes ethlius (Lepidoptera, Hesperiidae). We found that insect secreted ferritin subunits are of two types with little resemblance to each other. Ferritin was isolated from iron loaded hemolymph of C. ethlius fifth instar larvae by differential centrifugation. The N-terminal amino acid sequences for the nonglycosylated subunit with Mr 24,000 (S) and the largest glycosylated subunit with Mr 31,000 (G) were determined. The N-termini of the two subunits were different and were used to construct degenerate PCR primers. The same cDNA products were amplified from cDNA libraries from the midgut which secretes holoferritin and from the fat body which secretes iron-poor apoferritin. The G subunit most closely resembles the glycosylated ferritin subunit from Manduca sexta and the S subunit resembles the Drosophila small subunit. The S and G subunits from Calpodes were dissimilar and distinct from the cytosolic ferritins of vertebrates and invertebrates. Additional sequences were obtained by 5' and 3' RACE from separate fat body and midgut RACE libraries. cDNAs encoding both subunits had a consensus iron responsive element (IRE) in a conserved cap-distal location of their 5' UTR. An integrin-binding RGD motif found in the G subunit and conserved in Manduca may facilitate iron uptake through a calreticulin (mobilferrin)/integrin pathway. Calpodes and other insect ferritins have conserved cysteine residues to which fatty acids can be linked. Dynamic acylation of ferritin may slow but not prevent its passage out of the ER.     

Three ferritin subunits involved in immune defense from bay scallop Argopecten irradians

Ferritin is a ubiquitous protein that plays an important role in iron storage and iron-withholding strategy of innate immunity. In this study, three genes encoding different ferritin subunits were cloned from bay scallop Argopecten irradians (AiFer1, AiFer2 and AiFer3) by rapid amplification of cDNA ends (RACE) approaches based on the known ESTs. The open reading frames of the three ferritins are of 516 bp, 522 bp and 519 bp, encoding 171,173 and 172 amino acids, respectively. All the AiFers contain a putative Iron Regulatory Element (IRE) in their 5′-untranslated regions. The deduced amino acid sequences of AiFers possess both the ferroxidase center of mammalian H ferritin and the iron nucleation site of mammalian L ferritin. Gene structure study revealed two distinct structured genes encoding a ferritin subunit (AiFer3). Quantitative real-time PCR analysis indicated the significant up-regulation of AiFers in hemocytes after challenged with Listonella anguillarum, though the magnitudes of AiFer1 and AiFer2 were much higher than that of AiFer3. Taken together, these results suggest that AiFers are likely to play roles in both iron storage and innate immune defense against microbial infections.     

A novel ferritin subunit involved in shell formation from the pearl oyster (Pinctada fucata)

Iron is one of the most important minor elements in the shell of bivalves. This study was designed to investigate the involvement of ferritin, the principal protein for iron storage, in shell formation. A novel ferritin cDNA from the pearl oyster (Pinctada fucata) was isolated and characterized. The ferritin cDNA encodes a 206 amino acid polypeptide, which shares high similarity with snail soma ferritin and the H-chains of mammalian ferritins. Oyster ferritin mRNA shows the highest level of expression in the mantle, the organ for shell formation. In situ hybridization analysis revealed that oyster ferritin mRNA is expressed at the highest level at the mantle fold, a region essential for metal accumulation and contributes to metal incorporation into the shell. Taken together, these results suggest that ferritin is involved in shell formation by iron storage. The identification and characterization of oyster ferritin also helps to further understand the structural and functional properties of molluscan ferritins.     

Evidence for conservation of ferritin sequences among plants and animals and for a transit peptide in soybean

Ferritin is a large multisubunit protein that stores iron in plants, animals, and bacteria. In animals, the protein is mainly cytoplasmic and is highly conserved, while in plants ferritin is found in chloroplasts and other plastids. Ferritin is synthesized in plants as a larger precursor of the mature subunit. There is no sequence information for ferritin from plants, except an NH2-terminal peptide of 35 residues which shows little similarity to any known ferritin sequences or transit peptides (Laulhere, J. P., Laboure, A. M., and Briat, J. F. (1989) J. Biol. Chem. 264, 3629-3635). To understand the genetic origin and the location of ferritin synthesis in plant cells, as well as the structure of ferritin from plants, we have sequenced both CNBr peptides from pea seed ferritin and nucleotides of a soybean hypocotyl ferritin cDNA, identified using a frog ferritin cDNA as a probe. Comparison of pea and soybean sequences showed an identity of 89%. Alignment of the plant ferritin sequences with animal ferritins showed 55-65% sequence identity in the common regions. However, a peptide of 28 amino acids extended the NH2 terminus of the plant ferritins. Furthermore, the cDNA encoded additional amino acids which appear to be a transit peptide. None of the sequences in soybean ferritin were found in the tobacco chloroplast genome, suggesting, as does the transit peptide, a nuclear location of ferritin gene(s) in plants. Plant ferritin mRNA is 400-500 nucleotides longer than animal ferritin mRNAs, a difference accounted for in part by the extra peptides encoded. The size of soybean ferritin mRNA was constant in different tissues but expression varied in different tissues (leaf greater than hypocotyl). Thus, higher plants and animal ferritins display sequence homology and differential tissue expression. An ancient, common progenitor apparently gave rise to contemporary eukaryotic ferritins after specific modifications, e.g. transport to plasmids.     

Identification and molecular analysis of a ferritin subunit from red drum (Sciaenops ocellatus)

Ferritin is a conserved iron binding protein existing ubiquitously in prokaryotes and eukaryotes. In this study, the gene encoding a ferritin M subunit homologue (SoFer1) was cloned from red drum (Sciaenops ocellatus) and analyzed at expression and functional levels. The open reading frame of SoFer1 is 531 bp and preceded by a 5′-untranslated region that contains a putative Iron Regulatory Element (IRE) preserved in many ferritins. The deduced amino acid sequence of SoFer1 possesses both the ferroxidase center of mammalian H ferritin and the iron nucleation site of mammalian L ferritin. Expression of SoFer1 was tissue specific and responded positively to experimental challenges with Gram-positive and Gram-negative fish pathogens. Treatment of red drum liver cells with iron, copper, and oxidant significantly upregulated the expression of SoFer1 in time-dependent manners. To further examine the potential role of SoFer1 in antioxidation, red drum liver cells transfected transiently with SoFer1 were prepared. Compared to control cells, SoFer1 transfectants exhibited reduced production of reactive oxygen species following H₂O₂ challenge. Finally, to examine the iron binding potential of SoFer1, SoFer1 was expressed in and purified from Escherichia coli as a recombinant protein. Iron-chelating analysis showed that purified recombinant SoFer1 was capable of iron binding. Taken together, these results suggest that SoFer1 is likely to be a functional ferritin involved in iron sequestration, host immune defence against bacterial infection, and antioxidation.     

Each Member of the Poly-r(C)-binding Protein 1 (PCBP) Family Exhibits Iron Chaperone Activity toward Ferritin

The mechanisms through which iron-dependent enzymes receive their metal cofactors are largely unknown. Poly r(C)-binding protein 1 (PCBP1) is an iron chaperone for ferritin; both PCBP1 and its paralog PCBP2 are required for iron delivery to the prolyl hydroxylase that regulates HIF1. Here we show that PCBP2 is also an iron chaperone for ferritin. Co-expression of PCBP2 and human ferritins in yeast activated the iron deficiency response and increased iron deposition into ferritin. Depletion of PCBP2 in Huh7 cells diminished iron incorporation into ferritin. Both PCBP1 and PCBP2 were co-immunoprecipitated with ferritin in HEK293 cells, and expression of both PCBPs was required for ferritin complex formation in cells. PCBP1 and -2 exhibited high affinity binding to ferritin in vitro. Mammalian genomes encode 4 PCBPs, including the minimally expressed PCBPs 3 and 4. Expression of PCBP3 and -4 in yeast activated the iron deficiency response, but only PCBP3 exhibited strong interactions with ferritin. Expression of PCBP1 and ferritin in an iron-sensitive, ccc1 yeast strain intensified the toxic effects of iron, whereas expression of PCBP4 protected the cells from iron toxicity. Thus, PCBP1 and -2 form a complex for iron delivery to ferritin, and all PCBPs may share iron chaperone activity.     

Purification and characterization of phycoferritin from the blue-green alga, Arthrospira (Spirulina) platensis

Phycoferritin from the nutritionally important blue-green alga Arthrospira platensis has been isolated, by application of conventional biochemical techniques. The molecular mass, yield, iron and total neutral carbohydrate contents of the purified protein were 470 kDa, 0.044 mg g⁻¹ of Arthrospira, 1.4 and 20%, respectively. The iron content was much lower when compared to bacterial and mammalian ferritins. The P: Fe ratio of Arthrospira phycoferritin was 1: 3.5, a value akin to bacterioferritins. Native gel-electrophoresis revealed the presence of isoforms. Subunit analysis by SDS-PAGE and Western blotting showed a protein subunit with an apparent molecular mass of 18 kDa. Oligomeric forms of the protein subunit were also present. The phycoferritin exhibited cross-reactivity with anti-pea seed ferritin suggesting phylogenetic relationship with that of higher plants. Carbohydrate analysis of phycoferritin by GC-MS revealed the presence of sugars such as galactose, glucose and mannose similar to that of mammalian ferritins. Interestingly, the analysis also revealed sugars such as rhamnose, xylose and talose, which has not been reported in the structure of ferritins. Except for very low histidine content in phycoferritin, the rest of the amino acid composition resembled to ferritins of other species. UV-visible spectral analysis of the phycoferritin revealed the presence of haem groups, a property characteristic of bacterioferritins. The fluorescence intensity of phycoferritin was higher than equine spleen ferritin. Circular dichroic spectra revealed a lower degree of helicity.